// See the file LICENSE for copyright and licensing information. // Adapted from Plan 9 from User Space's src/cmd/9pfuse/fuse.c, // which carries this notice: // // The files in this directory are subject to the following license. // // The author of this software is Russ Cox. // // Copyright (c) 2006 Russ Cox // // Permission to use, copy, modify, and distribute this software for any // purpose without fee is hereby granted, provided that this entire notice // is included in all copies of any software which is or includes a copy // or modification of this software and in all copies of the supporting // documentation for such software. // // THIS SOFTWARE IS BEING PROVIDED "AS IS", WITHOUT ANY EXPRESS OR IMPLIED // WARRANTY. IN PARTICULAR, THE AUTHOR MAKES NO REPRESENTATION OR WARRANTY // OF ANY KIND CONCERNING THE MERCHANTABILITY OF THIS SOFTWARE OR ITS // FITNESS FOR ANY PARTICULAR PURPOSE. // Package fuse enables writing FUSE file systems on Linux, OS X, and FreeBSD. // // On OS X, it requires OSXFUSE (http://osxfuse.github.com/). // // There are two approaches to writing a FUSE file system. The first is to speak // the low-level message protocol, reading from a Conn using ReadRequest and // writing using the various Respond methods. This approach is closest to // the actual interaction with the kernel and can be the simplest one in contexts // such as protocol translators. // // Servers of synthesized file systems tend to share common // bookkeeping abstracted away by the second approach, which is to // call fs.Serve to serve the FUSE protocol using an implementation of // the service methods in the interfaces FS* (file system), Node* (file // or directory), and Handle* (opened file or directory). // There are a daunting number of such methods that can be written, // but few are required. // The specific methods are described in the documentation for those interfaces. // // The hellofs subdirectory contains a simple illustration of the fs.Serve approach. // // Service Methods // // The required and optional methods for the FS, Node, and Handle interfaces // have the general form // // Op(ctx context.Context, req *OpRequest, resp *OpResponse) error // // where Op is the name of a FUSE operation. Op reads request // parameters from req and writes results to resp. An operation whose // only result is the error result omits the resp parameter. // // Multiple goroutines may call service methods simultaneously; the // methods being called are responsible for appropriate // synchronization. // // The operation must not hold on to the request or response, // including any []byte fields such as WriteRequest.Data or // SetxattrRequest.Xattr. // // Errors // // Operations can return errors. The FUSE interface can only // communicate POSIX errno error numbers to file system clients, the // message is not visible to file system clients. The returned error // can implement ErrorNumber to control the errno returned. Without // ErrorNumber, a generic errno (EIO) is returned. // // Error messages will be visible in the debug log as part of the // response. // // Interrupted Operations // // In some file systems, some operations // may take an undetermined amount of time. For example, a Read waiting for // a network message or a matching Write might wait indefinitely. If the request // is cancelled and no longer needed, the context will be cancelled. // Blocking operations should select on a receive from ctx.Done() and attempt to // abort the operation early if the receive succeeds (meaning the channel is closed). // To indicate that the operation failed because it was aborted, return fuse.EINTR. // // If an operation does not block for an indefinite amount of time, supporting // cancellation is not necessary. // // Authentication // // All requests types embed a Header, meaning that the method can // inspect req.Pid, req.Uid, and req.Gid as necessary to implement // permission checking. The kernel FUSE layer normally prevents other // users from accessing the FUSE file system (to change this, see // AllowOther, AllowRoot), but does not enforce access modes (to // change this, see DefaultPermissions). // // Mount Options // // Behavior and metadata of the mounted file system can be changed by // passing MountOption values to Mount. // package fuseshim import ( "bytes" "encoding/json" "errors" "fmt" "io" "os" "sync" "syscall" "time" "unsafe" "github.com/jacobsa/fuse/internal/fusekernel" ) // A Conn represents a connection to a mounted FUSE file system. type Conn struct { // Ready is closed when the mount is complete or has failed. Ready <-chan struct{} // MountError stores any error from the mount process. Only valid // after Ready is closed. MountError error // File handle for kernel communication. Only safe to access if // rio or wio is held. dev *os.File wio sync.RWMutex rio sync.RWMutex // Protocol version negotiated with InitRequest/InitResponse. proto fusekernel.Protocol } // Mount mounts a new FUSE connection on the named directory // and returns a connection for reading and writing FUSE messages. // // After a successful return, caller must call Close to free // resources. // // Even on successful return, the new mount is not guaranteed to be // visible until after Conn.Ready is closed. See Conn.MountError for // possible errors. Incoming requests on Conn must be served to make // progress. func Mount(dir string, options ...MountOption) (*Conn, error) { conf := mountConfig{ options: make(map[string]string), } for _, option := range options { if err := option(&conf); err != nil { return nil, err } } ready := make(chan struct{}, 1) c := &Conn{ Ready: ready, } f, err := mount(dir, &conf, ready, &c.MountError) if err != nil { return nil, err } c.dev = f if err := initMount(c, &conf); err != nil { c.Close() return nil, err } return c, nil } type OldVersionError struct { Kernel fusekernel.Protocol LibraryMin fusekernel.Protocol } func (e *OldVersionError) Error() string { return fmt.Sprintf("kernel FUSE version is too old: %v < %v", e.Kernel, e.LibraryMin) } func initMount(c *Conn, conf *mountConfig) error { req, err := c.ReadRequest() if err != nil { if err == io.EOF { return fmt.Errorf("missing init, got EOF") } return err } r, ok := req.(*InitRequest) if !ok { return fmt.Errorf("missing init, got: %T", req) } min := fusekernel.Protocol{fusekernel.ProtoVersionMinMajor, fusekernel.ProtoVersionMinMinor} if r.Kernel.LT(min) { req.RespondError(Errno(syscall.EPROTO)) c.Close() return &OldVersionError{ Kernel: r.Kernel, LibraryMin: min, } } proto := fusekernel.Protocol{fusekernel.ProtoVersionMaxMajor, fusekernel.ProtoVersionMaxMinor} if r.Kernel.LT(proto) { // Kernel doesn't support the latest version we have. proto = r.Kernel } c.proto = proto s := &InitResponse{ Library: proto, MaxReadahead: conf.maxReadahead, MaxWrite: maxWrite, Flags: fusekernel.InitBigWrites | conf.initFlags, } r.Respond(s) return nil } // A Request represents a single FUSE request received from the kernel. // Use a type switch to determine the specific kind. // A request of unrecognized type will have concrete type *Header. type Request interface { // Hdr returns the Header associated with this request. Hdr() *Header // RespondError responds to the request with the given error. RespondError(error) String() string } // A RequestID identifies an active FUSE request. type RequestID uint64 // A NodeID is a number identifying a directory or file. // It must be unique among IDs returned in LookupResponses // that have not yet been forgotten by ForgetRequests. type NodeID uint64 // A HandleID is a number identifying an open directory or file. // It only needs to be unique while the directory or file is open. type HandleID uint64 // The RootID identifies the root directory of a FUSE file system. const RootID NodeID = fusekernel.RootID // A Header describes the basic information sent in every request. type Header struct { Conn *Conn `json:"-"` // connection this request was received on ID RequestID // unique ID for request Node NodeID // file or directory the request is about Uid uint32 // user ID of process making request Gid uint32 // group ID of process making request Pid uint32 // process ID of process making request // for returning to reqPool msg *Message } func (h *Header) String() string { return fmt.Sprintf("ID=%#x Node=%#x Uid=%d Gid=%d Pid=%d", h.ID, h.Node, h.Uid, h.Gid, h.Pid) } func (h *Header) Hdr() *Header { return h } func (h *Header) noResponse() { putMessage(h.msg) } func (h *Header) respond(msg []byte) { out := (*fusekernel.OutHeader)(unsafe.Pointer(&msg[0])) out.Unique = uint64(h.ID) h.Conn.respond(msg) putMessage(h.msg) } // An ErrorNumber is an error with a specific error number. // // Operations may return an error value that implements ErrorNumber to // control what specific error number (errno) to return. type ErrorNumber interface { // Errno returns the the error number (errno) for this error. Errno() Errno } const ( // ENOSYS indicates that the call is not supported. ENOSYS = Errno(syscall.ENOSYS) // ESTALE is used by Serve to respond to violations of the FUSE protocol. ESTALE = Errno(syscall.ESTALE) ENOENT = Errno(syscall.ENOENT) EIO = Errno(syscall.EIO) EPERM = Errno(syscall.EPERM) // EINTR indicates request was interrupted by an InterruptRequest. // See also fs.Intr. EINTR = Errno(syscall.EINTR) ERANGE = Errno(syscall.ERANGE) ENOTSUP = Errno(syscall.ENOTSUP) EEXIST = Errno(syscall.EEXIST) ) // DefaultErrno is the errno used when error returned does not // implement ErrorNumber. const DefaultErrno = EIO var errnoNames = map[Errno]string{ ENOSYS: "ENOSYS", ESTALE: "ESTALE", ENOENT: "ENOENT", EIO: "EIO", EPERM: "EPERM", EINTR: "EINTR", EEXIST: "EEXIST", } // Errno implements Error and ErrorNumber using a syscall.Errno. type Errno syscall.Errno var _ = ErrorNumber(Errno(0)) var _ = error(Errno(0)) func (e Errno) Errno() Errno { return e } func (e Errno) String() string { return syscall.Errno(e).Error() } func (e Errno) Error() string { return syscall.Errno(e).Error() } // ErrnoName returns the short non-numeric identifier for this errno. // For example, "EIO". func (e Errno) ErrnoName() string { s := errnoNames[e] if s == "" { s = fmt.Sprint(e.Errno()) } return s } func (e Errno) MarshalText() ([]byte, error) { s := e.ErrnoName() return []byte(s), nil } func (h *Header) RespondError(err error) { errno := DefaultErrno if ferr, ok := err.(ErrorNumber); ok { errno = ferr.Errno() } // FUSE uses negative errors! // TODO: File bug report against OSXFUSE: positive error causes kernel panic. buf := NewBuffer(0) hOut := (*fusekernel.OutHeader)(unsafe.Pointer(&buf[0])) hOut.Error = -int32(errno) h.respond(buf) } // All requests read from the kernel, without data, are shorter than // this. var maxRequestSize = syscall.Getpagesize() var bufSize = maxRequestSize + maxWrite // reqPool is a pool of messages. // // Lifetime of a logical message is from getMessage to putMessage. // getMessage is called by ReadRequest. putMessage is called by // Conn.ReadRequest, Request.Respond, or Request.RespondError. // // Messages in the pool are guaranteed to have conn and off zeroed, // buf allocated and len==bufSize, and Hdr set. var reqPool struct { Mu sync.Mutex Freelist []*Message } func allocMessage() *Message { m := &Message{buf: make([]byte, bufSize)} m.Hdr = (*fusekernel.InHeader)(unsafe.Pointer(&m.buf[0])) return m } func getMessage(c *Conn) (m *Message) { reqPool.Mu.Lock() l := len(reqPool.Freelist) if l != 0 { m = reqPool.Freelist[l-1] reqPool.Freelist = reqPool.Freelist[:l-1] } reqPool.Mu.Unlock() if m == nil { m = allocMessage() } m.conn = c return m } func putMessage(m *Message) { m.buf = m.buf[:bufSize] m.conn = nil m.off = 0 reqPool.Mu.Lock() reqPool.Freelist = append(reqPool.Freelist, m) reqPool.Mu.Unlock() } // a message represents the bytes of a single FUSE message type Message struct { conn *Conn buf []byte // all bytes Hdr *fusekernel.InHeader // header off int // offset for reading additional fields } func (m *Message) Len() uintptr { return uintptr(len(m.buf) - m.off) } func (m *Message) Data() (p unsafe.Pointer) { if m.off < len(m.buf) { p = unsafe.Pointer(&m.buf[m.off]) } return p } func (m *Message) Bytes() []byte { return m.buf[m.off:] } func (m *Message) Header() Header { h := m.Hdr return Header{ Conn: m.conn, ID: RequestID(h.Unique), Node: NodeID(h.Nodeid), Uid: h.Uid, Gid: h.Gid, Pid: h.Pid, msg: m, } } // Destroy the message, releasing its resources. The message must not be used // further. func (m *Message) Destroy() { putMessage(m) } // FileMode returns a Go os.FileMode from a Unix mode. func FileMode(unixMode uint32) os.FileMode { mode := os.FileMode(unixMode & 0777) switch unixMode & syscall.S_IFMT { case syscall.S_IFREG: // nothing case syscall.S_IFDIR: mode |= os.ModeDir case syscall.S_IFCHR: mode |= os.ModeCharDevice | os.ModeDevice case syscall.S_IFBLK: mode |= os.ModeDevice case syscall.S_IFIFO: mode |= os.ModeNamedPipe case syscall.S_IFLNK: mode |= os.ModeSymlink case syscall.S_IFSOCK: mode |= os.ModeSocket default: // no idea mode |= os.ModeDevice } if unixMode&syscall.S_ISUID != 0 { mode |= os.ModeSetuid } if unixMode&syscall.S_ISGID != 0 { mode |= os.ModeSetgid } return mode } type noOpcode struct { Opcode uint32 } func (m noOpcode) String() string { return fmt.Sprintf("No opcode %v", m.Opcode) } type malformedMessage struct { } func (malformedMessage) String() string { return "malformed message" } // Close closes the FUSE connection. func (c *Conn) Close() error { c.wio.Lock() defer c.wio.Unlock() c.rio.Lock() defer c.rio.Unlock() return c.dev.Close() } // caller must hold wio or rio func (c *Conn) fd() int { return int(c.dev.Fd()) } func (c *Conn) Protocol() fusekernel.Protocol { return c.proto } // Read and sanity check a message from the kernel. Return io.EOF when the // kernel has hung up. The offset will point to the limit of the header. // // The message must later be disposed of by calling m.Destroy. func (c *Conn) ReadMessage() (m *Message, err error) { m = getMessage(c) loop: c.rio.RLock() n, err := syscall.Read(c.fd(), m.buf) c.rio.RUnlock() if err == syscall.EINTR { // OSXFUSE sends EINTR to userspace when a request interrupt // completed before it got sent to userspace? goto loop } if err != nil && err != syscall.ENODEV { m.Destroy() return nil, err } if n <= 0 { m.Destroy() return nil, io.EOF } m.buf = m.buf[:n] if n < fusekernel.InHeaderSize { m.Destroy() return nil, errors.New("fuse: message too short") } // FreeBSD FUSE sends a short length in the header // for FUSE_INIT even though the actual read length is correct. if n == fusekernel.InHeaderSize+fusekernel.InitInSize && m.Hdr.Opcode == fusekernel.OpInit && m.Hdr.Len < uint32(n) { m.Hdr.Len = uint32(n) } // OSXFUSE sometimes sends the wrong m.Hdr.Len in a FUSE_WRITE message. if m.Hdr.Len < uint32(n) && m.Hdr.Len >= uint32(unsafe.Sizeof(fusekernel.WriteIn{})) && m.Hdr.Opcode == fusekernel.OpWrite { m.Hdr.Len = uint32(n) } if m.Hdr.Len != uint32(n) { // prepare error message before returning m to pool err := fmt.Errorf("fuse: read %d opcode %d but expected %d", n, m.Hdr.Opcode, m.Hdr.Len) m.Destroy() return nil, err } m.off = fusekernel.InHeaderSize return } // ReadRequest returns the next FUSE request from the kernel. // // Caller must call either Request.Respond or Request.RespondError in // a reasonable time. Caller must not retain Request after that call. func (c *Conn) ReadRequest() (Request, error) { // Read a message. m, err := c.ReadMessage() if err != nil { return nil, err } // Convert to data structures. // Do not trust kernel to hand us well-formed data. var req Request switch m.Hdr.Opcode { default: goto unrecognized case fusekernel.OpLookup: buf := m.Bytes() n := len(buf) if n == 0 || buf[n-1] != '\x00' { goto corrupt } req = &LookupRequest{ Header: m.Header(), Name: string(buf[:n-1]), } case fusekernel.OpForget: in := (*fusekernel.ForgetIn)(m.Data()) if m.Len() < unsafe.Sizeof(*in) { goto corrupt } req = &ForgetRequest{ Header: m.Header(), N: in.Nlookup, } case fusekernel.OpGetattr: switch { case c.proto.LT(fusekernel.Protocol{7, 9}): req = &GetattrRequest{ Header: m.Header(), } default: in := (*fusekernel.GetattrIn)(m.Data()) if m.Len() < unsafe.Sizeof(*in) { goto corrupt } req = &GetattrRequest{ Header: m.Header(), Flags: fusekernel.GetattrFlags(in.GetattrFlags), Handle: HandleID(in.Fh), } } case fusekernel.OpSetattr: in := (*fusekernel.SetattrIn)(m.Data()) if m.Len() < unsafe.Sizeof(*in) { goto corrupt } req = &SetattrRequest{ Header: m.Header(), Valid: fusekernel.SetattrValid(in.Valid), Handle: HandleID(in.Fh), Size: in.Size, Atime: time.Unix(int64(in.Atime), int64(in.AtimeNsec)), Mtime: time.Unix(int64(in.Mtime), int64(in.MtimeNsec)), Mode: FileMode(in.Mode), Uid: in.Uid, Gid: in.Gid, Bkuptime: in.BkupTime(), Chgtime: in.Chgtime(), Flags: in.Flags(), } case fusekernel.OpReadlink: if len(m.Bytes()) > 0 { goto corrupt } req = &ReadlinkRequest{ Header: m.Header(), } case fusekernel.OpSymlink: // m.Bytes() is "newName\0target\0" names := m.Bytes() if len(names) == 0 || names[len(names)-1] != 0 { goto corrupt } i := bytes.IndexByte(names, '\x00') if i < 0 { goto corrupt } newName, target := names[0:i], names[i+1:len(names)-1] req = &SymlinkRequest{ Header: m.Header(), NewName: string(newName), Target: string(target), } case fusekernel.OpLink: in := (*fusekernel.LinkIn)(m.Data()) if m.Len() < unsafe.Sizeof(*in) { goto corrupt } newName := m.Bytes()[unsafe.Sizeof(*in):] if len(newName) < 2 || newName[len(newName)-1] != 0 { goto corrupt } newName = newName[:len(newName)-1] req = &LinkRequest{ Header: m.Header(), OldNode: NodeID(in.Oldnodeid), NewName: string(newName), } case fusekernel.OpMknod: size := fusekernel.MknodInSize(c.proto) if m.Len() < size { goto corrupt } in := (*fusekernel.MknodIn)(m.Data()) name := m.Bytes()[size:] if len(name) < 2 || name[len(name)-1] != '\x00' { goto corrupt } name = name[:len(name)-1] r := &MknodRequest{ Header: m.Header(), Mode: FileMode(in.Mode), Rdev: in.Rdev, Name: string(name), } if c.proto.GE(fusekernel.Protocol{7, 12}) { r.Umask = FileMode(in.Umask) & os.ModePerm } req = r case fusekernel.OpMkdir: size := fusekernel.MkdirInSize(c.proto) if m.Len() < size { goto corrupt } in := (*fusekernel.MkdirIn)(m.Data()) name := m.Bytes()[size:] i := bytes.IndexByte(name, '\x00') if i < 0 { goto corrupt } r := &MkdirRequest{ Header: m.Header(), Name: string(name[:i]), // observed on Linux: mkdirIn.Mode & syscall.S_IFMT == 0, // and this causes FileMode to go into it's "no idea" // code branch; enforce type to directory Mode: FileMode((in.Mode &^ syscall.S_IFMT) | syscall.S_IFDIR), } if c.proto.GE(fusekernel.Protocol{7, 12}) { r.Umask = FileMode(in.Umask) & os.ModePerm } req = r case fusekernel.OpUnlink, fusekernel.OpRmdir: buf := m.Bytes() n := len(buf) if n == 0 || buf[n-1] != '\x00' { goto corrupt } req = &RemoveRequest{ Header: m.Header(), Name: string(buf[:n-1]), Dir: m.Hdr.Opcode == fusekernel.OpRmdir, } case fusekernel.OpRename: in := (*fusekernel.RenameIn)(m.Data()) if m.Len() < unsafe.Sizeof(*in) { goto corrupt } newDirNodeID := NodeID(in.Newdir) oldNew := m.Bytes()[unsafe.Sizeof(*in):] // oldNew should be "old\x00new\x00" if len(oldNew) < 4 { goto corrupt } if oldNew[len(oldNew)-1] != '\x00' { goto corrupt } i := bytes.IndexByte(oldNew, '\x00') if i < 0 { goto corrupt } oldName, newName := string(oldNew[:i]), string(oldNew[i+1:len(oldNew)-1]) req = &RenameRequest{ Header: m.Header(), NewDir: newDirNodeID, OldName: oldName, NewName: newName, } case fusekernel.OpOpendir, fusekernel.OpOpen: in := (*fusekernel.OpenIn)(m.Data()) if m.Len() < unsafe.Sizeof(*in) { goto corrupt } req = &OpenRequest{ Header: m.Header(), Dir: m.Hdr.Opcode == fusekernel.OpOpendir, Flags: fusekernel.OpenFlags(in.Flags), } case fusekernel.OpRead, fusekernel.OpReaddir: in := (*fusekernel.ReadIn)(m.Data()) if m.Len() < fusekernel.ReadInSize(c.proto) { goto corrupt } r := &ReadRequest{ Header: m.Header(), Dir: m.Hdr.Opcode == fusekernel.OpReaddir, Handle: HandleID(in.Fh), Offset: int64(in.Offset), Size: int(in.Size), } if c.proto.GE(fusekernel.Protocol{7, 9}) { r.Flags = fusekernel.ReadFlags(in.ReadFlags) r.LockOwner = in.LockOwner r.FileFlags = fusekernel.OpenFlags(in.Flags) } req = r case fusekernel.OpWrite: in := (*fusekernel.WriteIn)(m.Data()) if m.Len() < fusekernel.WriteInSize(c.proto) { goto corrupt } r := &WriteRequest{ Header: m.Header(), Handle: HandleID(in.Fh), Offset: int64(in.Offset), Flags: fusekernel.WriteFlags(in.WriteFlags), } if c.proto.GE(fusekernel.Protocol{7, 9}) { r.LockOwner = in.LockOwner r.FileFlags = fusekernel.OpenFlags(in.Flags) } buf := m.Bytes()[fusekernel.WriteInSize(c.proto):] if uint32(len(buf)) < in.Size { goto corrupt } r.Data = buf req = r case fusekernel.OpStatfs: req = &StatfsRequest{ Header: m.Header(), } case fusekernel.OpRelease, fusekernel.OpReleasedir: in := (*fusekernel.ReleaseIn)(m.Data()) if m.Len() < unsafe.Sizeof(*in) { goto corrupt } req = &ReleaseRequest{ Header: m.Header(), Dir: m.Hdr.Opcode == fusekernel.OpReleasedir, Handle: HandleID(in.Fh), Flags: fusekernel.OpenFlags(in.Flags), ReleaseFlags: fusekernel.ReleaseFlags(in.ReleaseFlags), LockOwner: in.LockOwner, } case fusekernel.OpFsync, fusekernel.OpFsyncdir: in := (*fusekernel.FsyncIn)(m.Data()) if m.Len() < unsafe.Sizeof(*in) { goto corrupt } req = &FsyncRequest{ Dir: m.Hdr.Opcode == fusekernel.OpFsyncdir, Header: m.Header(), Handle: HandleID(in.Fh), Flags: in.FsyncFlags, } case fusekernel.OpSetxattr: in := (*fusekernel.SetxattrIn)(m.Data()) if m.Len() < unsafe.Sizeof(*in) { goto corrupt } m.off += int(unsafe.Sizeof(*in)) name := m.Bytes() i := bytes.IndexByte(name, '\x00') if i < 0 { goto corrupt } xattr := name[i+1:] if uint32(len(xattr)) < in.Size { goto corrupt } xattr = xattr[:in.Size] req = &SetxattrRequest{ Header: m.Header(), Flags: in.Flags, Position: in.GetPosition(), Name: string(name[:i]), Xattr: xattr, } case fusekernel.OpGetxattr: in := (*fusekernel.GetxattrIn)(m.Data()) if m.Len() < unsafe.Sizeof(*in) { goto corrupt } name := m.Bytes()[unsafe.Sizeof(*in):] i := bytes.IndexByte(name, '\x00') if i < 0 { goto corrupt } req = &GetxattrRequest{ Header: m.Header(), Name: string(name[:i]), Size: in.Size, Position: in.GetPosition(), } case fusekernel.OpListxattr: in := (*fusekernel.GetxattrIn)(m.Data()) if m.Len() < unsafe.Sizeof(*in) { goto corrupt } req = &ListxattrRequest{ Header: m.Header(), Size: in.Size, Position: in.GetPosition(), } case fusekernel.OpRemovexattr: buf := m.Bytes() n := len(buf) if n == 0 || buf[n-1] != '\x00' { goto corrupt } req = &RemovexattrRequest{ Header: m.Header(), Name: string(buf[:n-1]), } case fusekernel.OpFlush: in := (*fusekernel.FlushIn)(m.Data()) if m.Len() < unsafe.Sizeof(*in) { goto corrupt } req = &FlushRequest{ Header: m.Header(), Handle: HandleID(in.Fh), Flags: in.FlushFlags, LockOwner: in.LockOwner, } case fusekernel.OpInit: in := (*fusekernel.InitIn)(m.Data()) if m.Len() < unsafe.Sizeof(*in) { goto corrupt } req = &InitRequest{ Header: m.Header(), Kernel: fusekernel.Protocol{in.Major, in.Minor}, MaxReadahead: in.MaxReadahead, Flags: fusekernel.InitFlags(in.Flags), } case fusekernel.OpGetlk: panic("fusekernel.OpGetlk") case fusekernel.OpSetlk: panic("fusekernel.OpSetlk") case fusekernel.OpSetlkw: panic("fusekernel.OpSetlkw") case fusekernel.OpAccess: in := (*fusekernel.AccessIn)(m.Data()) if m.Len() < unsafe.Sizeof(*in) { goto corrupt } req = &AccessRequest{ Header: m.Header(), Mask: in.Mask, } case fusekernel.OpCreate: size := fusekernel.CreateInSize(c.proto) if m.Len() < size { goto corrupt } in := (*fusekernel.CreateIn)(m.Data()) name := m.Bytes()[size:] i := bytes.IndexByte(name, '\x00') if i < 0 { goto corrupt } r := &CreateRequest{ Header: m.Header(), Flags: fusekernel.OpenFlags(in.Flags), Mode: FileMode(in.Mode), Name: string(name[:i]), } if c.proto.GE(fusekernel.Protocol{7, 12}) { r.Umask = FileMode(in.Umask) & os.ModePerm } req = r case fusekernel.OpInterrupt: in := (*fusekernel.InterruptIn)(m.Data()) if m.Len() < unsafe.Sizeof(*in) { goto corrupt } req = &InterruptRequest{ Header: m.Header(), IntrID: RequestID(in.Unique), } case fusekernel.OpBmap: panic("fusekernel.OpBmap") case fusekernel.OpDestroy: req = &DestroyRequest{ Header: m.Header(), } // OS X case fusekernel.OpSetvolname: panic("fusekernel.OpSetvolname") case fusekernel.OpGetxtimes: panic("fusekernel.OpGetxtimes") case fusekernel.OpExchange: panic("fusekernel.OpExchange") } return req, nil corrupt: m.Destroy() return nil, fmt.Errorf("fuse: malformed message") unrecognized: // Unrecognized message. // Assume higher-level code will send a "no idea what you mean" error. h := m.Header() return &h, nil } type bugShortKernelWrite struct { Written int64 Length int64 Error string Stack string } func (b bugShortKernelWrite) String() string { return fmt.Sprintf("short kernel write: written=%d/%d error=%q stack=\n%s", b.Written, b.Length, b.Error, b.Stack) } type bugKernelWriteError struct { Error string Stack string } func (b bugKernelWriteError) String() string { return fmt.Sprintf("kernel write error: error=%q stack=\n%s", b.Error, b.Stack) } // safe to call even with nil error func errorString(err error) string { if err == nil { return "" } return err.Error() } func (c *Conn) writeToKernel(msg []byte) error { out := (*fusekernel.OutHeader)(unsafe.Pointer(&msg[0])) out.Len = uint32(len(msg)) return c.WriteToKernel(msg) } func (c *Conn) WriteToKernel(msg []byte) error { c.wio.RLock() defer c.wio.RUnlock() _, err := syscall.Write(c.fd(), msg) return err } func (c *Conn) respond(msg []byte) { c.writeToKernel(msg) } type notCachedError struct{} func (notCachedError) Error() string { return "node not cached" } var _ ErrorNumber = notCachedError{} func (notCachedError) Errno() Errno { // Behave just like if the original syscall.ENOENT had been passed // straight through. return ENOENT } var ( ErrNotCached = notCachedError{} ) // sendInvalidate sends an invalidate notification to kernel. // // A returned ENOENT is translated to a friendlier error. func (c *Conn) sendInvalidate(msg []byte) error { switch err := c.writeToKernel(msg); err { case syscall.ENOENT: return ErrNotCached default: return err } } // InvalidateNode invalidates the kernel cache of the attributes and a // range of the data of a node. // // Giving offset 0 and size -1 means all data. To invalidate just the // attributes, give offset 0 and size 0. // // Returns ErrNotCached if the kernel is not currently caching the // node. func (c *Conn) InvalidateNode(nodeID NodeID, off int64, size int64) error { buf := NewBuffer(unsafe.Sizeof(fusekernel.NotifyInvalInodeOut{})) h := (*fusekernel.OutHeader)(unsafe.Pointer(&buf[0])) // h.Unique is 0 h.Error = fusekernel.NotifyCodeInvalInode out := (*fusekernel.NotifyInvalInodeOut)(buf.Alloc(unsafe.Sizeof(fusekernel.NotifyInvalInodeOut{}))) out.Ino = uint64(nodeID) out.Off = off out.Len = size return c.sendInvalidate(buf) } // InvalidateEntry invalidates the kernel cache of the directory entry // identified by parent directory node ID and entry basename. // // Kernel may or may not cache directory listings. To invalidate // those, use InvalidateNode to invalidate all of the data for a // directory. (As of 2015-06, Linux FUSE does not cache directory // listings.) // // Returns ErrNotCached if the kernel is not currently caching the // node. func (c *Conn) InvalidateEntry(parent NodeID, name string) error { const maxUint32 = ^uint32(0) if uint64(len(name)) > uint64(maxUint32) { // very unlikely, but we don't want to silently truncate return syscall.ENAMETOOLONG } buf := NewBuffer(unsafe.Sizeof(fusekernel.NotifyInvalEntryOut{}) + uintptr(len(name)) + 1) h := (*fusekernel.OutHeader)(unsafe.Pointer(&buf[0])) // h.Unique is 0 h.Error = fusekernel.NotifyCodeInvalEntry out := (*fusekernel.NotifyInvalEntryOut)(buf.Alloc(unsafe.Sizeof(fusekernel.NotifyInvalEntryOut{}))) out.Parent = uint64(parent) out.Namelen = uint32(len(name)) buf = append(buf, name...) buf = append(buf, '\x00') return c.sendInvalidate(buf) } // An InitRequest is the first request sent on a FUSE file system. type InitRequest struct { Header `json:"-"` Kernel fusekernel.Protocol // Maximum readahead in bytes that the kernel plans to use. MaxReadahead uint32 Flags fusekernel.InitFlags } var _ = Request(&InitRequest{}) func (r *InitRequest) String() string { return fmt.Sprintf("Init [%s] %v ra=%d fl=%v", &r.Header, r.Kernel, r.MaxReadahead, r.Flags) } // An InitResponse is the response to an InitRequest. type InitResponse struct { Library fusekernel.Protocol // Maximum readahead in bytes that the kernel can use. Ignored if // greater than InitRequest.MaxReadahead. MaxReadahead uint32 Flags fusekernel.InitFlags // Maximum size of a single write operation. // Linux enforces a minimum of 4 KiB. MaxWrite uint32 } func (r *InitResponse) String() string { return fmt.Sprintf("Init %+v", *r) } // Respond replies to the request with the given response. func (r *InitRequest) Respond(resp *InitResponse) { buf := NewBuffer(unsafe.Sizeof(fusekernel.InitOut{})) out := (*fusekernel.InitOut)(buf.Alloc(unsafe.Sizeof(fusekernel.InitOut{}))) out.Major = resp.Library.Major out.Minor = resp.Library.Minor out.MaxReadahead = resp.MaxReadahead out.Flags = uint32(resp.Flags) out.MaxWrite = resp.MaxWrite // MaxWrite larger than our receive buffer would just lead to // errors on large writes. if out.MaxWrite > maxWrite { out.MaxWrite = maxWrite } r.respond(buf) } // A StatfsRequest requests information about the mounted file system. type StatfsRequest struct { Header `json:"-"` } var _ = Request(&StatfsRequest{}) func (r *StatfsRequest) String() string { return fmt.Sprintf("Statfs [%s]", &r.Header) } // Respond replies to the request with the given response. func (r *StatfsRequest) Respond(resp *StatfsResponse) { buf := NewBuffer(unsafe.Sizeof(fusekernel.StatfsOut{})) out := (*fusekernel.StatfsOut)(buf.Alloc(unsafe.Sizeof(fusekernel.StatfsOut{}))) out.St = fusekernel.Kstatfs{ Blocks: resp.Blocks, Bfree: resp.Bfree, Bavail: resp.Bavail, Files: resp.Files, Bsize: resp.Bsize, Namelen: resp.Namelen, Frsize: resp.Frsize, } r.respond(buf) } // A StatfsResponse is the response to a StatfsRequest. type StatfsResponse struct { Blocks uint64 // Total data blocks in file system. Bfree uint64 // Free blocks in file system. Bavail uint64 // Free blocks in file system if you're not root. Files uint64 // Total files in file system. Ffree uint64 // Free files in file system. Bsize uint32 // Block size Namelen uint32 // Maximum file name length? Frsize uint32 // Fragment size, smallest addressable data size in the file system. } func (r *StatfsResponse) String() string { return fmt.Sprintf("Statfs %+v", *r) } // An AccessRequest asks whether the file can be accessed // for the purpose specified by the mask. type AccessRequest struct { Header `json:"-"` Mask uint32 } var _ = Request(&AccessRequest{}) func (r *AccessRequest) String() string { return fmt.Sprintf("Access [%s] mask=%#x", &r.Header, r.Mask) } // Respond replies to the request indicating that access is allowed. // To deny access, use RespondError. func (r *AccessRequest) Respond() { buf := NewBuffer(0) r.respond(buf) } // An Attr is the metadata for a single file or directory. type Attr struct { Valid time.Duration // how long Attr can be cached Inode uint64 // inode number Size uint64 // size in bytes Blocks uint64 // size in 512-byte units Atime time.Time // time of last access Mtime time.Time // time of last modification Ctime time.Time // time of last inode change Crtime time.Time // time of creation (OS X only) Mode os.FileMode // file mode Nlink uint32 // number of links Uid uint32 // owner uid Gid uint32 // group gid Rdev uint32 // device numbers Flags uint32 // chflags(2) flags (OS X only) BlockSize uint32 // preferred blocksize for filesystem I/O } func unix(t time.Time) (sec uint64, nsec uint32) { nano := t.UnixNano() sec = uint64(nano / 1e9) nsec = uint32(nano % 1e9) return } func (a *Attr) attr(out *fusekernel.Attr, proto fusekernel.Protocol) { out.Ino = a.Inode out.Size = a.Size out.Blocks = a.Blocks out.Atime, out.AtimeNsec = unix(a.Atime) out.Mtime, out.MtimeNsec = unix(a.Mtime) out.Ctime, out.CtimeNsec = unix(a.Ctime) out.SetCrtime(unix(a.Crtime)) out.Mode = uint32(a.Mode) & 0777 switch { default: out.Mode |= syscall.S_IFREG case a.Mode&os.ModeDir != 0: out.Mode |= syscall.S_IFDIR case a.Mode&os.ModeDevice != 0: if a.Mode&os.ModeCharDevice != 0 { out.Mode |= syscall.S_IFCHR } else { out.Mode |= syscall.S_IFBLK } case a.Mode&os.ModeNamedPipe != 0: out.Mode |= syscall.S_IFIFO case a.Mode&os.ModeSymlink != 0: out.Mode |= syscall.S_IFLNK case a.Mode&os.ModeSocket != 0: out.Mode |= syscall.S_IFSOCK } if a.Mode&os.ModeSetuid != 0 { out.Mode |= syscall.S_ISUID } if a.Mode&os.ModeSetgid != 0 { out.Mode |= syscall.S_ISGID } out.Nlink = a.Nlink out.Uid = a.Uid out.Gid = a.Gid out.Rdev = a.Rdev out.SetFlags(a.Flags) if proto.GE(fusekernel.Protocol{7, 9}) { out.Blksize = a.BlockSize } return } // A GetattrRequest asks for the metadata for the file denoted by r.Node. type GetattrRequest struct { Header `json:"-"` Flags fusekernel.GetattrFlags Handle HandleID } var _ = Request(&GetattrRequest{}) func (r *GetattrRequest) String() string { return fmt.Sprintf("Getattr [%s] %#x fl=%v", &r.Header, r.Handle, r.Flags) } // Respond replies to the request with the given response. func (r *GetattrRequest) Respond(resp *GetattrResponse) { size := fusekernel.AttrOutSize(r.Header.Conn.proto) buf := NewBuffer(size) out := (*fusekernel.AttrOut)(buf.Alloc(size)) out.AttrValid = uint64(resp.Attr.Valid / time.Second) out.AttrValidNsec = uint32(resp.Attr.Valid % time.Second / time.Nanosecond) resp.Attr.attr(&out.Attr, r.Header.Conn.proto) r.respond(buf) } // A GetattrResponse is the response to a GetattrRequest. type GetattrResponse struct { Attr Attr // file attributes } func (r *GetattrResponse) String() string { return fmt.Sprintf("Getattr %+v", *r) } // A GetxattrRequest asks for the extended attributes associated with r.Node. type GetxattrRequest struct { Header `json:"-"` // Maximum size to return. Size uint32 // Name of the attribute requested. Name string // Offset within extended attributes. // // Only valid for OS X, and then only with the resource fork // attribute. Position uint32 } var _ = Request(&GetxattrRequest{}) func (r *GetxattrRequest) String() string { return fmt.Sprintf("Getxattr [%s] %q %d @%d", &r.Header, r.Name, r.Size, r.Position) } // Respond replies to the request with the given response. func (r *GetxattrRequest) Respond(resp *GetxattrResponse) { if r.Size == 0 { buf := NewBuffer(unsafe.Sizeof(fusekernel.GetxattrOut{})) out := (*fusekernel.GetxattrOut)(buf.Alloc(unsafe.Sizeof(fusekernel.GetxattrOut{}))) out.Size = uint32(len(resp.Xattr)) r.respond(buf) } else { buf := NewBuffer(uintptr(len(resp.Xattr))) buf = append(buf, resp.Xattr...) r.respond(buf) } } // A GetxattrResponse is the response to a GetxattrRequest. type GetxattrResponse struct { Xattr []byte } func (r *GetxattrResponse) String() string { return fmt.Sprintf("Getxattr %x", r.Xattr) } // A ListxattrRequest asks to list the extended attributes associated with r.Node. type ListxattrRequest struct { Header `json:"-"` Size uint32 // maximum size to return Position uint32 // offset within attribute list } var _ = Request(&ListxattrRequest{}) func (r *ListxattrRequest) String() string { return fmt.Sprintf("Listxattr [%s] %d @%d", &r.Header, r.Size, r.Position) } // Respond replies to the request with the given response. func (r *ListxattrRequest) Respond(resp *ListxattrResponse) { if r.Size == 0 { buf := NewBuffer(unsafe.Sizeof(fusekernel.GetxattrOut{})) out := (*fusekernel.GetxattrOut)(buf.Alloc(unsafe.Sizeof(fusekernel.GetxattrOut{}))) out.Size = uint32(len(resp.Xattr)) r.respond(buf) } else { buf := NewBuffer(uintptr(len(resp.Xattr))) buf = append(buf, resp.Xattr...) r.respond(buf) } } // A ListxattrResponse is the response to a ListxattrRequest. type ListxattrResponse struct { Xattr []byte } func (r *ListxattrResponse) String() string { return fmt.Sprintf("Listxattr %x", r.Xattr) } // Append adds an extended attribute name to the response. func (r *ListxattrResponse) Append(names ...string) { for _, name := range names { r.Xattr = append(r.Xattr, name...) r.Xattr = append(r.Xattr, '\x00') } } // A RemovexattrRequest asks to remove an extended attribute associated with r.Node. type RemovexattrRequest struct { Header `json:"-"` Name string // name of extended attribute } var _ = Request(&RemovexattrRequest{}) func (r *RemovexattrRequest) String() string { return fmt.Sprintf("Removexattr [%s] %q", &r.Header, r.Name) } // Respond replies to the request, indicating that the attribute was removed. func (r *RemovexattrRequest) Respond() { buf := NewBuffer(0) r.respond(buf) } // A SetxattrRequest asks to set an extended attribute associated with a file. type SetxattrRequest struct { Header `json:"-"` // Flags can make the request fail if attribute does/not already // exist. Unfortunately, the constants are platform-specific and // not exposed by Go1.2. Look for XATTR_CREATE, XATTR_REPLACE. // // TODO improve this later // // TODO XATTR_CREATE and exist -> EEXIST // // TODO XATTR_REPLACE and not exist -> ENODATA Flags uint32 // Offset within extended attributes. // // Only valid for OS X, and then only with the resource fork // attribute. Position uint32 Name string Xattr []byte } var _ = Request(&SetxattrRequest{}) func trunc(b []byte, max int) ([]byte, string) { if len(b) > max { return b[:max], "..." } return b, "" } func (r *SetxattrRequest) String() string { xattr, tail := trunc(r.Xattr, 16) return fmt.Sprintf("Setxattr [%s] %q %x%s fl=%v @%#x", &r.Header, r.Name, xattr, tail, r.Flags, r.Position) } // Respond replies to the request, indicating that the extended attribute was set. func (r *SetxattrRequest) Respond() { buf := NewBuffer(0) r.respond(buf) } // A LookupRequest asks to look up the given name in the directory named by r.Node. type LookupRequest struct { Header `json:"-"` Name string } var _ = Request(&LookupRequest{}) func (r *LookupRequest) String() string { return fmt.Sprintf("Lookup [%s] %q", &r.Header, r.Name) } // Respond replies to the request with the given response. func (r *LookupRequest) Respond(resp *LookupResponse) { size := fusekernel.EntryOutSize(r.Header.Conn.proto) buf := NewBuffer(size) out := (*fusekernel.EntryOut)(buf.Alloc(size)) out.Nodeid = uint64(resp.Node) out.Generation = resp.Generation out.EntryValid = uint64(resp.EntryValid / time.Second) out.EntryValidNsec = uint32(resp.EntryValid % time.Second / time.Nanosecond) out.AttrValid = uint64(resp.Attr.Valid / time.Second) out.AttrValidNsec = uint32(resp.Attr.Valid % time.Second / time.Nanosecond) resp.Attr.attr(&out.Attr, r.Header.Conn.proto) r.respond(buf) } // A LookupResponse is the response to a LookupRequest. type LookupResponse struct { Node NodeID Generation uint64 EntryValid time.Duration Attr Attr } func (r *LookupResponse) String() string { return fmt.Sprintf("Lookup %+v", *r) } // An OpenRequest asks to open a file or directory type OpenRequest struct { Header `json:"-"` Dir bool // is this Opendir? Flags fusekernel.OpenFlags } var _ = Request(&OpenRequest{}) func (r *OpenRequest) String() string { return fmt.Sprintf("Open [%s] dir=%v fl=%v", &r.Header, r.Dir, r.Flags) } // Respond replies to the request with the given response. func (r *OpenRequest) Respond(resp *OpenResponse) { buf := NewBuffer(unsafe.Sizeof(fusekernel.OpenOut{})) out := (*fusekernel.OpenOut)(buf.Alloc(unsafe.Sizeof(fusekernel.OpenOut{}))) out.Fh = uint64(resp.Handle) out.OpenFlags = uint32(resp.Flags) r.respond(buf) } // A OpenResponse is the response to a OpenRequest. type OpenResponse struct { Handle HandleID Flags fusekernel.OpenResponseFlags } func (r *OpenResponse) String() string { return fmt.Sprintf("Open %+v", *r) } // A CreateRequest asks to create and open a file (not a directory). type CreateRequest struct { Header `json:"-"` Name string Flags fusekernel.OpenFlags Mode os.FileMode Umask os.FileMode } var _ = Request(&CreateRequest{}) func (r *CreateRequest) String() string { return fmt.Sprintf("Create [%s] %q fl=%v mode=%v umask=%v", &r.Header, r.Name, r.Flags, r.Mode, r.Umask) } // Respond replies to the request with the given response. func (r *CreateRequest) Respond(resp *CreateResponse) { eSize := fusekernel.EntryOutSize(r.Header.Conn.proto) buf := NewBuffer(eSize + unsafe.Sizeof(fusekernel.OpenOut{})) e := (*fusekernel.EntryOut)(buf.Alloc(eSize)) e.Nodeid = uint64(resp.Node) e.Generation = resp.Generation e.EntryValid = uint64(resp.EntryValid / time.Second) e.EntryValidNsec = uint32(resp.EntryValid % time.Second / time.Nanosecond) e.AttrValid = uint64(resp.Attr.Valid / time.Second) e.AttrValidNsec = uint32(resp.Attr.Valid % time.Second / time.Nanosecond) resp.Attr.attr(&e.Attr, r.Header.Conn.proto) o := (*fusekernel.OpenOut)(buf.Alloc(unsafe.Sizeof(fusekernel.OpenOut{}))) o.Fh = uint64(resp.Handle) o.OpenFlags = uint32(resp.Flags) r.respond(buf) } // A CreateResponse is the response to a CreateRequest. // It describes the created node and opened handle. type CreateResponse struct { LookupResponse OpenResponse } func (r *CreateResponse) String() string { return fmt.Sprintf("Create %+v", *r) } // A MkdirRequest asks to create (but not open) a directory. type MkdirRequest struct { Header `json:"-"` Name string Mode os.FileMode Umask os.FileMode } var _ = Request(&MkdirRequest{}) func (r *MkdirRequest) String() string { return fmt.Sprintf("Mkdir [%s] %q mode=%v umask=%v", &r.Header, r.Name, r.Mode, r.Umask) } // Respond replies to the request with the given response. func (r *MkdirRequest) Respond(resp *MkdirResponse) { size := fusekernel.EntryOutSize(r.Header.Conn.proto) buf := NewBuffer(size) out := (*fusekernel.EntryOut)(buf.Alloc(size)) out.Nodeid = uint64(resp.Node) out.Generation = resp.Generation out.EntryValid = uint64(resp.EntryValid / time.Second) out.EntryValidNsec = uint32(resp.EntryValid % time.Second / time.Nanosecond) out.AttrValid = uint64(resp.Attr.Valid / time.Second) out.AttrValidNsec = uint32(resp.Attr.Valid % time.Second / time.Nanosecond) resp.Attr.attr(&out.Attr, r.Header.Conn.proto) r.respond(buf) } // A MkdirResponse is the response to a MkdirRequest. type MkdirResponse struct { LookupResponse } func (r *MkdirResponse) String() string { return fmt.Sprintf("Mkdir %+v", *r) } // A ReadRequest asks to read from an open file. type ReadRequest struct { Header `json:"-"` Dir bool // is this Readdir? Handle HandleID Offset int64 Size int Flags fusekernel.ReadFlags LockOwner uint64 FileFlags fusekernel.OpenFlags } var _ = Request(&ReadRequest{}) func (r *ReadRequest) String() string { return fmt.Sprintf("Read [%s] %#x %d @%#x dir=%v fl=%v lock=%d ffl=%v", &r.Header, r.Handle, r.Size, r.Offset, r.Dir, r.Flags, r.LockOwner, r.FileFlags) } // Respond replies to the request with the given response. func (r *ReadRequest) Respond(resp *ReadResponse) { buf := NewBuffer(uintptr(len(resp.Data))) buf = append(buf, resp.Data...) r.respond(buf) } // A ReadResponse is the response to a ReadRequest. type ReadResponse struct { Data []byte } func (r *ReadResponse) String() string { return fmt.Sprintf("Read %d", len(r.Data)) } type jsonReadResponse struct { Len uint64 } func (r *ReadResponse) MarshalJSON() ([]byte, error) { j := jsonReadResponse{ Len: uint64(len(r.Data)), } return json.Marshal(j) } // A ReleaseRequest asks to release (close) an open file handle. type ReleaseRequest struct { Header `json:"-"` Dir bool // is this Releasedir? Handle HandleID Flags fusekernel.OpenFlags // flags from OpenRequest ReleaseFlags fusekernel.ReleaseFlags LockOwner uint32 } var _ = Request(&ReleaseRequest{}) func (r *ReleaseRequest) String() string { return fmt.Sprintf("Release [%s] %#x fl=%v rfl=%v owner=%#x", &r.Header, r.Handle, r.Flags, r.ReleaseFlags, r.LockOwner) } // Respond replies to the request, indicating that the handle has been released. func (r *ReleaseRequest) Respond() { buf := NewBuffer(0) r.respond(buf) } // A DestroyRequest is sent by the kernel when unmounting the file system. // No more requests will be received after this one, but it should still be // responded to. type DestroyRequest struct { Header `json:"-"` } var _ = Request(&DestroyRequest{}) func (r *DestroyRequest) String() string { return fmt.Sprintf("Destroy [%s]", &r.Header) } // Respond replies to the request. func (r *DestroyRequest) Respond() { buf := NewBuffer(0) r.respond(buf) } // A ForgetRequest is sent by the kernel when forgetting about r.Node // as returned by r.N lookup requests. type ForgetRequest struct { Header `json:"-"` N uint64 } var _ = Request(&ForgetRequest{}) func (r *ForgetRequest) String() string { return fmt.Sprintf("Forget [%s] %d", &r.Header, r.N) } // Respond replies to the request, indicating that the forgetfulness has been recorded. func (r *ForgetRequest) Respond() { // Don't reply to forget messages. r.noResponse() } // A Dirent represents a single directory entry. type Dirent struct { // Inode this entry names. Inode uint64 // Type of the entry, for example DT_File. // // Setting this is optional. The zero value (DT_Unknown) means // callers will just need to do a Getattr when the type is // needed. Providing a type can speed up operations // significantly. Type DirentType // Name of the entry Name string } // Type of an entry in a directory listing. type DirentType uint32 const ( // These don't quite match os.FileMode; especially there's an // explicit unknown, instead of zero value meaning file. They // are also not quite syscall.DT_*; nothing says the FUSE // protocol follows those, and even if they were, we don't // want each fs to fiddle with syscall. // The shift by 12 is hardcoded in the FUSE userspace // low-level C library, so it's safe here. DT_Unknown DirentType = 0 DT_Socket DirentType = syscall.S_IFSOCK >> 12 DT_Link DirentType = syscall.S_IFLNK >> 12 DT_File DirentType = syscall.S_IFREG >> 12 DT_Block DirentType = syscall.S_IFBLK >> 12 DT_Dir DirentType = syscall.S_IFDIR >> 12 DT_Char DirentType = syscall.S_IFCHR >> 12 DT_FIFO DirentType = syscall.S_IFIFO >> 12 ) func (t DirentType) String() string { switch t { case DT_Unknown: return "unknown" case DT_Socket: return "socket" case DT_Link: return "link" case DT_File: return "file" case DT_Block: return "block" case DT_Dir: return "dir" case DT_Char: return "char" case DT_FIFO: return "fifo" } return "invalid" } // AppendDirent appends the encoded form of a directory entry to data // and returns the resulting slice. func AppendDirent(data []byte, dir Dirent) []byte { de := fusekernel.Dirent{ Ino: dir.Inode, Namelen: uint32(len(dir.Name)), Type: uint32(dir.Type), } de.Off = uint64(len(data) + fusekernel.DirentSize + (len(dir.Name)+7)&^7) data = append(data, (*[fusekernel.DirentSize]byte)(unsafe.Pointer(&de))[:]...) data = append(data, dir.Name...) n := fusekernel.DirentSize + uintptr(len(dir.Name)) if n%8 != 0 { var pad [8]byte data = append(data, pad[:8-n%8]...) } return data } // A WriteRequest asks to write to an open file. type WriteRequest struct { Header Handle HandleID Offset int64 Data []byte Flags fusekernel.WriteFlags LockOwner uint64 FileFlags fusekernel.OpenFlags } var _ = Request(&WriteRequest{}) func (r *WriteRequest) String() string { return fmt.Sprintf("Write [%s] %#x %d @%d fl=%v lock=%d ffl=%v", &r.Header, r.Handle, len(r.Data), r.Offset, r.Flags, r.LockOwner, r.FileFlags) } type jsonWriteRequest struct { Handle HandleID Offset int64 Len uint64 Flags fusekernel.WriteFlags } func (r *WriteRequest) MarshalJSON() ([]byte, error) { j := jsonWriteRequest{ Handle: r.Handle, Offset: r.Offset, Len: uint64(len(r.Data)), Flags: r.Flags, } return json.Marshal(j) } // Respond replies to the request with the given response. func (r *WriteRequest) Respond(resp *WriteResponse) { buf := NewBuffer(unsafe.Sizeof(fusekernel.WriteOut{})) out := (*fusekernel.WriteOut)(buf.Alloc(unsafe.Sizeof(fusekernel.WriteOut{}))) out.Size = uint32(resp.Size) r.respond(buf) } // A WriteResponse replies to a write indicating how many bytes were written. type WriteResponse struct { Size int } func (r *WriteResponse) String() string { return fmt.Sprintf("Write %+v", *r) } // A SetattrRequest asks to change one or more attributes associated with a file, // as indicated by Valid. type SetattrRequest struct { Header `json:"-"` Valid fusekernel.SetattrValid Handle HandleID Size uint64 Atime time.Time Mtime time.Time Mode os.FileMode Uid uint32 Gid uint32 // OS X only Bkuptime time.Time Chgtime time.Time Crtime time.Time Flags uint32 // see chflags(2) } var _ = Request(&SetattrRequest{}) func (r *SetattrRequest) String() string { var buf bytes.Buffer fmt.Fprintf(&buf, "Setattr [%s]", &r.Header) if r.Valid.Mode() { fmt.Fprintf(&buf, " mode=%v", r.Mode) } if r.Valid.Uid() { fmt.Fprintf(&buf, " uid=%d", r.Uid) } if r.Valid.Gid() { fmt.Fprintf(&buf, " gid=%d", r.Gid) } if r.Valid.Size() { fmt.Fprintf(&buf, " size=%d", r.Size) } if r.Valid.Atime() { fmt.Fprintf(&buf, " atime=%v", r.Atime) } if r.Valid.AtimeNow() { fmt.Fprintf(&buf, " atime=now") } if r.Valid.Mtime() { fmt.Fprintf(&buf, " mtime=%v", r.Mtime) } if r.Valid.MtimeNow() { fmt.Fprintf(&buf, " mtime=now") } if r.Valid.Handle() { fmt.Fprintf(&buf, " handle=%#x", r.Handle) } else { fmt.Fprintf(&buf, " handle=INVALID-%#x", r.Handle) } if r.Valid.LockOwner() { fmt.Fprintf(&buf, " lockowner") } if r.Valid.Crtime() { fmt.Fprintf(&buf, " crtime=%v", r.Crtime) } if r.Valid.Chgtime() { fmt.Fprintf(&buf, " chgtime=%v", r.Chgtime) } if r.Valid.Bkuptime() { fmt.Fprintf(&buf, " bkuptime=%v", r.Bkuptime) } if r.Valid.Flags() { fmt.Fprintf(&buf, " flags=%#x", r.Flags) } return buf.String() } // Respond replies to the request with the given response, // giving the updated attributes. func (r *SetattrRequest) Respond(resp *SetattrResponse) { size := fusekernel.AttrOutSize(r.Header.Conn.proto) buf := NewBuffer(size) out := (*fusekernel.AttrOut)(buf.Alloc(size)) out.AttrValid = uint64(resp.Attr.Valid / time.Second) out.AttrValidNsec = uint32(resp.Attr.Valid % time.Second / time.Nanosecond) resp.Attr.attr(&out.Attr, r.Header.Conn.proto) r.respond(buf) } // A SetattrResponse is the response to a SetattrRequest. type SetattrResponse struct { Attr Attr // file attributes } func (r *SetattrResponse) String() string { return fmt.Sprintf("Setattr %+v", *r) } // A FlushRequest asks for the current state of an open file to be flushed // to storage, as when a file descriptor is being closed. A single opened Handle // may receive multiple FlushRequests over its lifetime. type FlushRequest struct { Header `json:"-"` Handle HandleID Flags uint32 LockOwner uint64 } var _ = Request(&FlushRequest{}) func (r *FlushRequest) String() string { return fmt.Sprintf("Flush [%s] %#x fl=%#x lk=%#x", &r.Header, r.Handle, r.Flags, r.LockOwner) } // Respond replies to the request, indicating that the flush succeeded. func (r *FlushRequest) Respond() { buf := NewBuffer(0) r.respond(buf) } // A RemoveRequest asks to remove a file or directory from the // directory r.Node. type RemoveRequest struct { Header `json:"-"` Name string // name of the entry to remove Dir bool // is this rmdir? } var _ = Request(&RemoveRequest{}) func (r *RemoveRequest) String() string { return fmt.Sprintf("Remove [%s] %q dir=%v", &r.Header, r.Name, r.Dir) } // Respond replies to the request, indicating that the file was removed. func (r *RemoveRequest) Respond() { buf := NewBuffer(0) r.respond(buf) } // A SymlinkRequest is a request to create a symlink making NewName point to Target. type SymlinkRequest struct { Header `json:"-"` NewName, Target string } var _ = Request(&SymlinkRequest{}) func (r *SymlinkRequest) String() string { return fmt.Sprintf("Symlink [%s] from %q to target %q", &r.Header, r.NewName, r.Target) } // Respond replies to the request, indicating that the symlink was created. func (r *SymlinkRequest) Respond(resp *SymlinkResponse) { size := fusekernel.EntryOutSize(r.Header.Conn.proto) buf := NewBuffer(size) out := (*fusekernel.EntryOut)(buf.Alloc(size)) out.Nodeid = uint64(resp.Node) out.Generation = resp.Generation out.EntryValid = uint64(resp.EntryValid / time.Second) out.EntryValidNsec = uint32(resp.EntryValid % time.Second / time.Nanosecond) out.AttrValid = uint64(resp.Attr.Valid / time.Second) out.AttrValidNsec = uint32(resp.Attr.Valid % time.Second / time.Nanosecond) resp.Attr.attr(&out.Attr, r.Header.Conn.proto) r.respond(buf) } // A SymlinkResponse is the response to a SymlinkRequest. type SymlinkResponse struct { LookupResponse } // A ReadlinkRequest is a request to read a symlink's target. type ReadlinkRequest struct { Header `json:"-"` } var _ = Request(&ReadlinkRequest{}) func (r *ReadlinkRequest) String() string { return fmt.Sprintf("Readlink [%s]", &r.Header) } func (r *ReadlinkRequest) Respond(target string) { buf := NewBuffer(uintptr(len(target))) buf = append(buf, target...) r.respond(buf) } // A LinkRequest is a request to create a hard link. type LinkRequest struct { Header `json:"-"` OldNode NodeID NewName string } var _ = Request(&LinkRequest{}) func (r *LinkRequest) String() string { return fmt.Sprintf("Link [%s] node %d to %q", &r.Header, r.OldNode, r.NewName) } func (r *LinkRequest) Respond(resp *LookupResponse) { size := fusekernel.EntryOutSize(r.Header.Conn.proto) buf := NewBuffer(size) out := (*fusekernel.EntryOut)(buf.Alloc(size)) out.Nodeid = uint64(resp.Node) out.Generation = resp.Generation out.EntryValid = uint64(resp.EntryValid / time.Second) out.EntryValidNsec = uint32(resp.EntryValid % time.Second / time.Nanosecond) out.AttrValid = uint64(resp.Attr.Valid / time.Second) out.AttrValidNsec = uint32(resp.Attr.Valid % time.Second / time.Nanosecond) resp.Attr.attr(&out.Attr, r.Header.Conn.proto) r.respond(buf) } // A RenameRequest is a request to rename a file. type RenameRequest struct { Header `json:"-"` NewDir NodeID OldName, NewName string } var _ = Request(&RenameRequest{}) func (r *RenameRequest) String() string { return fmt.Sprintf("Rename [%s] from %q to dirnode %d %q", &r.Header, r.OldName, r.NewDir, r.NewName) } func (r *RenameRequest) Respond() { buf := NewBuffer(0) r.respond(buf) } type MknodRequest struct { Header `json:"-"` Name string Mode os.FileMode Rdev uint32 Umask os.FileMode } var _ = Request(&MknodRequest{}) func (r *MknodRequest) String() string { return fmt.Sprintf("Mknod [%s] Name %q mode=%v umask=%v rdev=%d", &r.Header, r.Name, r.Mode, r.Umask, r.Rdev) } func (r *MknodRequest) Respond(resp *LookupResponse) { size := fusekernel.EntryOutSize(r.Header.Conn.proto) buf := NewBuffer(size) out := (*fusekernel.EntryOut)(buf.Alloc(size)) out.Nodeid = uint64(resp.Node) out.Generation = resp.Generation out.EntryValid = uint64(resp.EntryValid / time.Second) out.EntryValidNsec = uint32(resp.EntryValid % time.Second / time.Nanosecond) out.AttrValid = uint64(resp.Attr.Valid / time.Second) out.AttrValidNsec = uint32(resp.Attr.Valid % time.Second / time.Nanosecond) resp.Attr.attr(&out.Attr, r.Header.Conn.proto) r.respond(buf) } type FsyncRequest struct { Header `json:"-"` Handle HandleID // TODO bit 1 is datasync, not well documented upstream Flags uint32 Dir bool } var _ = Request(&FsyncRequest{}) func (r *FsyncRequest) String() string { return fmt.Sprintf("Fsync [%s] Handle %v Flags %v", &r.Header, r.Handle, r.Flags) } func (r *FsyncRequest) Respond() { buf := NewBuffer(0) r.respond(buf) } // An InterruptRequest is a request to interrupt another pending request. The // response to that request should return an error status of EINTR. type InterruptRequest struct { Header `json:"-"` IntrID RequestID // ID of the request to be interrupt. } var _ = Request(&InterruptRequest{}) func (r *InterruptRequest) Respond() { // nothing to do here r.noResponse() } func (r *InterruptRequest) String() string { return fmt.Sprintf("Interrupt [%s] ID %v", &r.Header, r.IntrID) }