// Copyright 2020 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 host import ( "gvisor.dev/gvisor/pkg/abi/linux" "gvisor.dev/gvisor/pkg/context" "gvisor.dev/gvisor/pkg/errors/linuxerr" "gvisor.dev/gvisor/pkg/marshal/primitive" "gvisor.dev/gvisor/pkg/sentry/arch" "gvisor.dev/gvisor/pkg/sentry/kernel" "gvisor.dev/gvisor/pkg/sentry/unimpl" "gvisor.dev/gvisor/pkg/sentry/vfs" "gvisor.dev/gvisor/pkg/sync" "gvisor.dev/gvisor/pkg/syserror" "gvisor.dev/gvisor/pkg/usermem" ) // TTYFileDescription implements vfs.FileDescriptionImpl for a host file // descriptor that wraps a TTY FD. // // +stateify savable type TTYFileDescription struct { fileDescription // mu protects the fields below. mu sync.Mutex `state:"nosave"` // session is the session attached to this TTYFileDescription. session *kernel.Session // fgProcessGroup is the foreground process group that is currently // connected to this TTY. fgProcessGroup *kernel.ProcessGroup // termios contains the terminal attributes for this TTY. termios linux.KernelTermios } // InitForegroundProcessGroup sets the foreground process group and session for // the TTY. This should only be called once, after the foreground process group // has been created, but before it has started running. func (t *TTYFileDescription) InitForegroundProcessGroup(pg *kernel.ProcessGroup) { t.mu.Lock() defer t.mu.Unlock() if t.fgProcessGroup != nil { panic("foreground process group is already set") } t.fgProcessGroup = pg t.session = pg.Session() } // ForegroundProcessGroup returns the foreground process for the TTY. func (t *TTYFileDescription) ForegroundProcessGroup() *kernel.ProcessGroup { t.mu.Lock() defer t.mu.Unlock() return t.fgProcessGroup } // Release implements fs.FileOperations.Release. func (t *TTYFileDescription) Release(ctx context.Context) { t.mu.Lock() t.fgProcessGroup = nil t.mu.Unlock() t.fileDescription.Release(ctx) } // PRead implements vfs.FileDescriptionImpl.PRead. // // Reading from a TTY is only allowed for foreground process groups. Background // process groups will either get EIO or a SIGTTIN. func (t *TTYFileDescription) PRead(ctx context.Context, dst usermem.IOSequence, offset int64, opts vfs.ReadOptions) (int64, error) { t.mu.Lock() defer t.mu.Unlock() // Are we allowed to do the read? // drivers/tty/n_tty.c:n_tty_read()=>job_control()=>tty_check_change(). if err := t.checkChange(ctx, linux.SIGTTIN); err != nil { return 0, err } // Do the read. return t.fileDescription.PRead(ctx, dst, offset, opts) } // Read implements vfs.FileDescriptionImpl.Read. // // Reading from a TTY is only allowed for foreground process groups. Background // process groups will either get EIO or a SIGTTIN. func (t *TTYFileDescription) Read(ctx context.Context, dst usermem.IOSequence, opts vfs.ReadOptions) (int64, error) { t.mu.Lock() defer t.mu.Unlock() // Are we allowed to do the read? // drivers/tty/n_tty.c:n_tty_read()=>job_control()=>tty_check_change(). if err := t.checkChange(ctx, linux.SIGTTIN); err != nil { return 0, err } // Do the read. return t.fileDescription.Read(ctx, dst, opts) } // PWrite implements vfs.FileDescriptionImpl.PWrite. func (t *TTYFileDescription) PWrite(ctx context.Context, src usermem.IOSequence, offset int64, opts vfs.WriteOptions) (int64, error) { t.mu.Lock() defer t.mu.Unlock() // Check whether TOSTOP is enabled. This corresponds to the check in // drivers/tty/n_tty.c:n_tty_write(). if t.termios.LEnabled(linux.TOSTOP) { if err := t.checkChange(ctx, linux.SIGTTOU); err != nil { return 0, err } } return t.fileDescription.PWrite(ctx, src, offset, opts) } // Write implements vfs.FileDescriptionImpl.Write. func (t *TTYFileDescription) Write(ctx context.Context, src usermem.IOSequence, opts vfs.WriteOptions) (int64, error) { t.mu.Lock() defer t.mu.Unlock() // Check whether TOSTOP is enabled. This corresponds to the check in // drivers/tty/n_tty.c:n_tty_write(). if t.termios.LEnabled(linux.TOSTOP) { if err := t.checkChange(ctx, linux.SIGTTOU); err != nil { return 0, err } } return t.fileDescription.Write(ctx, src, opts) } // Ioctl implements vfs.FileDescriptionImpl.Ioctl. func (t *TTYFileDescription) Ioctl(ctx context.Context, io usermem.IO, args arch.SyscallArguments) (uintptr, error) { task := kernel.TaskFromContext(ctx) if task == nil { return 0, linuxerr.ENOTTY } // Ignore arg[0]. This is the real FD: fd := t.inode.hostFD ioctl := args[1].Uint64() switch ioctl { case linux.TCGETS: termios, err := ioctlGetTermios(fd) if err != nil { return 0, err } _, err = termios.CopyOut(task, args[2].Pointer()) return 0, err case linux.TCSETS, linux.TCSETSW, linux.TCSETSF: t.mu.Lock() defer t.mu.Unlock() if err := t.checkChange(ctx, linux.SIGTTOU); err != nil { return 0, err } var termios linux.Termios if _, err := termios.CopyIn(task, args[2].Pointer()); err != nil { return 0, err } err := ioctlSetTermios(fd, ioctl, &termios) if err == nil { t.termios.FromTermios(termios) } return 0, err case linux.TIOCGPGRP: // Args: pid_t *argp // When successful, equivalent to *argp = tcgetpgrp(fd). // Get the process group ID of the foreground process group on this // terminal. pidns := kernel.PIDNamespaceFromContext(ctx) if pidns == nil { return 0, linuxerr.ENOTTY } t.mu.Lock() defer t.mu.Unlock() // Map the ProcessGroup into a ProcessGroupID in the task's PID namespace. pgID := primitive.Int32(pidns.IDOfProcessGroup(t.fgProcessGroup)) _, err := pgID.CopyOut(task, args[2].Pointer()) return 0, err case linux.TIOCSPGRP: // Args: const pid_t *argp // Equivalent to tcsetpgrp(fd, *argp). // Set the foreground process group ID of this terminal. t.mu.Lock() defer t.mu.Unlock() // Check that we are allowed to set the process group. if err := t.checkChange(ctx, linux.SIGTTOU); err != nil { // drivers/tty/tty_io.c:tiocspgrp() converts -EIO from tty_check_change() // to -ENOTTY. if linuxerr.Equals(linuxerr.EIO, err) { return 0, linuxerr.ENOTTY } return 0, err } // Check that calling task's process group is in the TTY session. if task.ThreadGroup().Session() != t.session { return 0, linuxerr.ENOTTY } var pgIDP primitive.Int32 if _, err := pgIDP.CopyIn(task, args[2].Pointer()); err != nil { return 0, err } pgID := kernel.ProcessGroupID(pgIDP) // pgID must be non-negative. if pgID < 0 { return 0, linuxerr.EINVAL } // Process group with pgID must exist in this PID namespace. pidns := task.PIDNamespace() pg := pidns.ProcessGroupWithID(pgID) if pg == nil { return 0, linuxerr.ESRCH } // Check that new process group is in the TTY session. if pg.Session() != t.session { return 0, linuxerr.EPERM } t.fgProcessGroup = pg return 0, nil case linux.TIOCGWINSZ: // Args: struct winsize *argp // Get window size. winsize, err := ioctlGetWinsize(fd) if err != nil { return 0, err } _, err = winsize.CopyOut(task, args[2].Pointer()) return 0, err case linux.TIOCSWINSZ: // Args: const struct winsize *argp // Set window size. // Unlike setting the termios, any process group (even background ones) can // set the winsize. var winsize linux.Winsize if _, err := winsize.CopyIn(task, args[2].Pointer()); err != nil { return 0, err } err := ioctlSetWinsize(fd, &winsize) return 0, err // Unimplemented commands. case linux.TIOCSETD, linux.TIOCSBRK, linux.TIOCCBRK, linux.TCSBRK, linux.TCSBRKP, linux.TIOCSTI, linux.TIOCCONS, linux.FIONBIO, linux.TIOCEXCL, linux.TIOCNXCL, linux.TIOCGEXCL, linux.TIOCNOTTY, linux.TIOCSCTTY, linux.TIOCGSID, linux.TIOCGETD, linux.TIOCVHANGUP, linux.TIOCGDEV, linux.TIOCMGET, linux.TIOCMSET, linux.TIOCMBIC, linux.TIOCMBIS, linux.TIOCGICOUNT, linux.TCFLSH, linux.TIOCSSERIAL, linux.TIOCGPTPEER: unimpl.EmitUnimplementedEvent(ctx) fallthrough default: return 0, linuxerr.ENOTTY } } // checkChange checks that the process group is allowed to read, write, or // change the state of the TTY. // // This corresponds to Linux drivers/tty/tty_io.c:tty_check_change(). The logic // is a bit convoluted, but documented inline. // // Preconditions: t.mu must be held. func (t *TTYFileDescription) checkChange(ctx context.Context, sig linux.Signal) error { task := kernel.TaskFromContext(ctx) if task == nil { // No task? Linux does not have an analog for this case, but // tty_check_change only blocks specific cases and is // surprisingly permissive. Allowing the change seems // appropriate. return nil } tg := task.ThreadGroup() pg := tg.ProcessGroup() // If the session for the task is different than the session for the // controlling TTY, then the change is allowed. Seems like a bad idea, // but that's exactly what linux does. if tg.Session() != t.fgProcessGroup.Session() { return nil } // If we are the foreground process group, then the change is allowed. if pg == t.fgProcessGroup { return nil } // We are not the foreground process group. // Is the provided signal blocked or ignored? if (task.SignalMask()&linux.SignalSetOf(sig) != 0) || tg.SignalHandlers().IsIgnored(sig) { // If the signal is SIGTTIN, then we are attempting to read // from the TTY. Don't send the signal and return EIO. if sig == linux.SIGTTIN { return syserror.EIO } // Otherwise, we are writing or changing terminal state. This is allowed. return nil } // If the process group is an orphan, return EIO. if pg.IsOrphan() { return syserror.EIO } // Otherwise, send the signal to the process group and return ERESTARTSYS. // // Note that Linux also unconditionally sets TIF_SIGPENDING on current, // but this isn't necessary in gVisor because the rationale given in // 040b6362d58f "tty: fix leakage of -ERESTARTSYS to userland" doesn't // apply: the sentry will handle -ERESTARTSYS in // kernel.runApp.execute() even if the kernel.Task isn't interrupted. // // Linux ignores the result of kill_pgrp(). _ = pg.SendSignal(kernel.SignalInfoPriv(sig)) return syserror.ERESTARTSYS }