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// 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 vfs2
import (
"fmt"
"time"
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/errors/linuxerr"
"gvisor.dev/gvisor/pkg/sentry/arch"
"gvisor.dev/gvisor/pkg/sentry/kernel"
ktime "gvisor.dev/gvisor/pkg/sentry/kernel/time"
"gvisor.dev/gvisor/pkg/sentry/limits"
"gvisor.dev/gvisor/pkg/sentry/vfs"
"gvisor.dev/gvisor/pkg/syserror"
"gvisor.dev/gvisor/pkg/waiter"
"gvisor.dev/gvisor/pkg/hostarch"
)
// fileCap is the maximum allowable files for poll & select. This has no
// equivalent in Linux; it exists in gVisor since allocation failure in Go is
// unrecoverable.
const fileCap = 1024 * 1024
// Masks for "readable", "writable", and "exceptional" events as defined by
// select(2).
const (
// selectReadEvents is analogous to the Linux kernel's
// fs/select.c:POLLIN_SET.
selectReadEvents = linux.POLLIN | linux.POLLHUP | linux.POLLERR
// selectWriteEvents is analogous to the Linux kernel's
// fs/select.c:POLLOUT_SET.
selectWriteEvents = linux.POLLOUT | linux.POLLERR
// selectExceptEvents is analogous to the Linux kernel's
// fs/select.c:POLLEX_SET.
selectExceptEvents = linux.POLLPRI
)
// pollState tracks the associated file description and waiter of a PollFD.
type pollState struct {
file *vfs.FileDescription
waiter waiter.Entry
}
// initReadiness gets the current ready mask for the file represented by the FD
// stored in pfd.FD. If a channel is passed in, the waiter entry in "state" is
// used to register with the file for event notifications, and a reference to
// the file is stored in "state".
func initReadiness(t *kernel.Task, pfd *linux.PollFD, state *pollState, ch chan struct{}) {
if pfd.FD < 0 {
pfd.REvents = 0
return
}
file := t.GetFileVFS2(pfd.FD)
if file == nil {
pfd.REvents = linux.POLLNVAL
return
}
if ch == nil {
defer file.DecRef(t)
} else {
state.file = file
state.waiter, _ = waiter.NewChannelEntry(ch)
file.EventRegister(&state.waiter, waiter.EventMaskFromLinux(uint32(pfd.Events)))
}
r := file.Readiness(waiter.EventMaskFromLinux(uint32(pfd.Events)))
pfd.REvents = int16(r.ToLinux()) & pfd.Events
}
// releaseState releases all the pollState in "state".
func releaseState(t *kernel.Task, state []pollState) {
for i := range state {
if state[i].file != nil {
state[i].file.EventUnregister(&state[i].waiter)
state[i].file.DecRef(t)
}
}
}
// pollBlock polls the PollFDs in "pfd" with a bounded time specified in "timeout"
// when "timeout" is greater than zero.
//
// pollBlock returns the remaining timeout, which is always 0 on a timeout; and 0 or
// positive if interrupted by a signal.
func pollBlock(t *kernel.Task, pfd []linux.PollFD, timeout time.Duration) (time.Duration, uintptr, error) {
var ch chan struct{}
if timeout != 0 {
ch = make(chan struct{}, 1)
}
// Register for event notification in the files involved if we may
// block (timeout not zero). Once we find a file that has a non-zero
// result, we stop registering for events but still go through all files
// to get their ready masks.
state := make([]pollState, len(pfd))
defer releaseState(t, state)
n := uintptr(0)
for i := range pfd {
initReadiness(t, &pfd[i], &state[i], ch)
if pfd[i].REvents != 0 {
n++
ch = nil
}
}
if timeout == 0 {
return timeout, n, nil
}
haveTimeout := timeout >= 0
for n == 0 {
var err error
// Wait for a notification.
timeout, err = t.BlockWithTimeout(ch, haveTimeout, timeout)
if err != nil {
if linuxerr.Equals(linuxerr.ETIMEDOUT, err) {
err = nil
}
return timeout, 0, err
}
// We got notified, count how many files are ready. If none,
// then this was a spurious notification, and we just go back
// to sleep with the remaining timeout.
for i := range state {
if state[i].file == nil {
continue
}
r := state[i].file.Readiness(waiter.EventMaskFromLinux(uint32(pfd[i].Events)))
rl := int16(r.ToLinux()) & pfd[i].Events
if rl != 0 {
pfd[i].REvents = rl
n++
}
}
}
return timeout, n, nil
}
// copyInPollFDs copies an array of struct pollfd unless nfds exceeds the max.
func copyInPollFDs(t *kernel.Task, addr hostarch.Addr, nfds uint) ([]linux.PollFD, error) {
if uint64(nfds) > t.ThreadGroup().Limits().GetCapped(limits.NumberOfFiles, fileCap) {
return nil, linuxerr.EINVAL
}
pfd := make([]linux.PollFD, nfds)
if nfds > 0 {
if _, err := linux.CopyPollFDSliceIn(t, addr, pfd); err != nil {
return nil, err
}
}
return pfd, nil
}
func doPoll(t *kernel.Task, addr hostarch.Addr, nfds uint, timeout time.Duration) (time.Duration, uintptr, error) {
pfd, err := copyInPollFDs(t, addr, nfds)
if err != nil {
return timeout, 0, err
}
// Compatibility warning: Linux adds POLLHUP and POLLERR just before
// polling, in fs/select.c:do_pollfd(). Since pfd is copied out after
// polling, changing event masks here is an application-visible difference.
// (Linux also doesn't copy out event masks at all, only revents.)
for i := range pfd {
pfd[i].Events |= linux.POLLHUP | linux.POLLERR
}
remainingTimeout, n, err := pollBlock(t, pfd, timeout)
err = syserror.ConvertIntr(err, syserror.EINTR)
// The poll entries are copied out regardless of whether
// any are set or not. This aligns with the Linux behavior.
if nfds > 0 && err == nil {
if _, err := linux.CopyPollFDSliceOut(t, addr, pfd); err != nil {
return remainingTimeout, 0, err
}
}
return remainingTimeout, n, err
}
// CopyInFDSet copies an fd set from select(2)/pselect(2).
func CopyInFDSet(t *kernel.Task, addr hostarch.Addr, nBytes, nBitsInLastPartialByte int) ([]byte, error) {
set := make([]byte, nBytes)
if addr != 0 {
if _, err := t.CopyInBytes(addr, set); err != nil {
return nil, err
}
// If we only use part of the last byte, mask out the extraneous bits.
//
// N.B. This only works on little-endian architectures.
if nBitsInLastPartialByte != 0 {
set[nBytes-1] &^= byte(0xff) << nBitsInLastPartialByte
}
}
return set, nil
}
func doSelect(t *kernel.Task, nfds int, readFDs, writeFDs, exceptFDs hostarch.Addr, timeout time.Duration) (uintptr, error) {
if nfds < 0 || nfds > fileCap {
return 0, linuxerr.EINVAL
}
// Calculate the size of the fd sets (one bit per fd).
nBytes := (nfds + 7) / 8
nBitsInLastPartialByte := nfds % 8
// Capture all the provided input vectors.
r, err := CopyInFDSet(t, readFDs, nBytes, nBitsInLastPartialByte)
if err != nil {
return 0, err
}
w, err := CopyInFDSet(t, writeFDs, nBytes, nBitsInLastPartialByte)
if err != nil {
return 0, err
}
e, err := CopyInFDSet(t, exceptFDs, nBytes, nBitsInLastPartialByte)
if err != nil {
return 0, err
}
// Count how many FDs are actually being requested so that we can build
// a PollFD array.
fdCount := 0
for i := 0; i < nBytes; i++ {
v := r[i] | w[i] | e[i]
for v != 0 {
v &= (v - 1)
fdCount++
}
}
// Build the PollFD array.
pfd := make([]linux.PollFD, 0, fdCount)
var fd int32
for i := 0; i < nBytes; i++ {
rV, wV, eV := r[i], w[i], e[i]
v := rV | wV | eV
m := byte(1)
for j := 0; j < 8; j++ {
if (v & m) != 0 {
// Make sure the fd is valid and decrement the reference
// immediately to ensure we don't leak. Note, another thread
// might be about to close fd. This is racy, but that's
// OK. Linux is racy in the same way.
file := t.GetFileVFS2(fd)
if file == nil {
return 0, linuxerr.EBADF
}
file.DecRef(t)
var mask int16
if (rV & m) != 0 {
mask |= selectReadEvents
}
if (wV & m) != 0 {
mask |= selectWriteEvents
}
if (eV & m) != 0 {
mask |= selectExceptEvents
}
pfd = append(pfd, linux.PollFD{
FD: fd,
Events: mask,
})
}
fd++
m <<= 1
}
}
// Do the syscall, then count the number of bits set.
if _, _, err = pollBlock(t, pfd, timeout); err != nil {
return 0, syserror.ConvertIntr(err, syserror.EINTR)
}
// r, w, and e are currently event mask bitsets; unset bits corresponding
// to events that *didn't* occur.
bitSetCount := uintptr(0)
for idx := range pfd {
events := pfd[idx].REvents
i, j := pfd[idx].FD/8, uint(pfd[idx].FD%8)
m := byte(1) << j
if r[i]&m != 0 {
if (events & selectReadEvents) != 0 {
bitSetCount++
} else {
r[i] &^= m
}
}
if w[i]&m != 0 {
if (events & selectWriteEvents) != 0 {
bitSetCount++
} else {
w[i] &^= m
}
}
if e[i]&m != 0 {
if (events & selectExceptEvents) != 0 {
bitSetCount++
} else {
e[i] &^= m
}
}
}
// Copy updated vectors back.
if readFDs != 0 {
if _, err := t.CopyOutBytes(readFDs, r); err != nil {
return 0, err
}
}
if writeFDs != 0 {
if _, err := t.CopyOutBytes(writeFDs, w); err != nil {
return 0, err
}
}
if exceptFDs != 0 {
if _, err := t.CopyOutBytes(exceptFDs, e); err != nil {
return 0, err
}
}
return bitSetCount, nil
}
// timeoutRemaining returns the amount of time remaining for the specified
// timeout or 0 if it has elapsed.
//
// startNs must be from CLOCK_MONOTONIC.
func timeoutRemaining(t *kernel.Task, startNs ktime.Time, timeout time.Duration) time.Duration {
now := t.Kernel().MonotonicClock().Now()
remaining := timeout - now.Sub(startNs)
if remaining < 0 {
remaining = 0
}
return remaining
}
// copyOutTimespecRemaining copies the time remaining in timeout to timespecAddr.
//
// startNs must be from CLOCK_MONOTONIC.
func copyOutTimespecRemaining(t *kernel.Task, startNs ktime.Time, timeout time.Duration, timespecAddr hostarch.Addr) error {
if timeout <= 0 {
return nil
}
remaining := timeoutRemaining(t, startNs, timeout)
tsRemaining := linux.NsecToTimespec(remaining.Nanoseconds())
_, err := tsRemaining.CopyOut(t, timespecAddr)
return err
}
// copyOutTimevalRemaining copies the time remaining in timeout to timevalAddr.
//
// startNs must be from CLOCK_MONOTONIC.
func copyOutTimevalRemaining(t *kernel.Task, startNs ktime.Time, timeout time.Duration, timevalAddr hostarch.Addr) error {
if timeout <= 0 {
return nil
}
remaining := timeoutRemaining(t, startNs, timeout)
tvRemaining := linux.NsecToTimeval(remaining.Nanoseconds())
_, err := tvRemaining.CopyOut(t, timevalAddr)
return err
}
// pollRestartBlock encapsulates the state required to restart poll(2) via
// restart_syscall(2).
//
// +stateify savable
type pollRestartBlock struct {
pfdAddr hostarch.Addr
nfds uint
timeout time.Duration
}
// Restart implements kernel.SyscallRestartBlock.Restart.
func (p *pollRestartBlock) Restart(t *kernel.Task) (uintptr, error) {
return poll(t, p.pfdAddr, p.nfds, p.timeout)
}
func poll(t *kernel.Task, pfdAddr hostarch.Addr, nfds uint, timeout time.Duration) (uintptr, error) {
remainingTimeout, n, err := doPoll(t, pfdAddr, nfds, timeout)
// On an interrupt poll(2) is restarted with the remaining timeout.
if linuxerr.Equals(linuxerr.EINTR, err) {
t.SetSyscallRestartBlock(&pollRestartBlock{
pfdAddr: pfdAddr,
nfds: nfds,
timeout: remainingTimeout,
})
return 0, syserror.ERESTART_RESTARTBLOCK
}
return n, err
}
// Poll implements linux syscall poll(2).
func Poll(t *kernel.Task, args arch.SyscallArguments) (uintptr, *kernel.SyscallControl, error) {
pfdAddr := args[0].Pointer()
nfds := uint(args[1].Uint()) // poll(2) uses unsigned long.
timeout := time.Duration(args[2].Int()) * time.Millisecond
n, err := poll(t, pfdAddr, nfds, timeout)
return n, nil, err
}
// Ppoll implements linux syscall ppoll(2).
func Ppoll(t *kernel.Task, args arch.SyscallArguments) (uintptr, *kernel.SyscallControl, error) {
pfdAddr := args[0].Pointer()
nfds := uint(args[1].Uint()) // poll(2) uses unsigned long.
timespecAddr := args[2].Pointer()
maskAddr := args[3].Pointer()
maskSize := uint(args[4].Uint())
timeout, err := copyTimespecInToDuration(t, timespecAddr)
if err != nil {
return 0, nil, err
}
var startNs ktime.Time
if timeout > 0 {
startNs = t.Kernel().MonotonicClock().Now()
}
if err := setTempSignalSet(t, maskAddr, maskSize); err != nil {
return 0, nil, err
}
_, n, err := doPoll(t, pfdAddr, nfds, timeout)
copyErr := copyOutTimespecRemaining(t, startNs, timeout, timespecAddr)
// doPoll returns EINTR if interrupted, but ppoll is normally restartable
// if interrupted by something other than a signal handled by the
// application (i.e. returns ERESTARTNOHAND). However, if
// copyOutTimespecRemaining failed, then the restarted ppoll would use the
// wrong timeout, so the error should be left as EINTR.
//
// Note that this means that if err is nil but copyErr is not, copyErr is
// ignored. This is consistent with Linux.
if linuxerr.Equals(linuxerr.EINTR, err) && copyErr == nil {
err = syserror.ERESTARTNOHAND
}
return n, nil, err
}
// Select implements linux syscall select(2).
func Select(t *kernel.Task, args arch.SyscallArguments) (uintptr, *kernel.SyscallControl, error) {
nfds := int(args[0].Int()) // select(2) uses an int.
readFDs := args[1].Pointer()
writeFDs := args[2].Pointer()
exceptFDs := args[3].Pointer()
timevalAddr := args[4].Pointer()
// Use a negative Duration to indicate "no timeout".
timeout := time.Duration(-1)
if timevalAddr != 0 {
var timeval linux.Timeval
if _, err := timeval.CopyIn(t, timevalAddr); err != nil {
return 0, nil, err
}
if timeval.Sec < 0 || timeval.Usec < 0 {
return 0, nil, linuxerr.EINVAL
}
timeout = time.Duration(timeval.ToNsecCapped())
}
startNs := t.Kernel().MonotonicClock().Now()
n, err := doSelect(t, nfds, readFDs, writeFDs, exceptFDs, timeout)
copyErr := copyOutTimevalRemaining(t, startNs, timeout, timevalAddr)
// See comment in Ppoll.
if linuxerr.Equals(linuxerr.EINTR, err) && copyErr == nil {
err = syserror.ERESTARTNOHAND
}
return n, nil, err
}
// +marshal
type sigSetWithSize struct {
sigsetAddr uint64
sizeofSigset uint64
}
// Pselect implements linux syscall pselect(2).
func Pselect(t *kernel.Task, args arch.SyscallArguments) (uintptr, *kernel.SyscallControl, error) {
nfds := int(args[0].Int()) // select(2) uses an int.
readFDs := args[1].Pointer()
writeFDs := args[2].Pointer()
exceptFDs := args[3].Pointer()
timespecAddr := args[4].Pointer()
maskWithSizeAddr := args[5].Pointer()
timeout, err := copyTimespecInToDuration(t, timespecAddr)
if err != nil {
return 0, nil, err
}
var startNs ktime.Time
if timeout > 0 {
startNs = t.Kernel().MonotonicClock().Now()
}
if maskWithSizeAddr != 0 {
if t.Arch().Width() != 8 {
panic(fmt.Sprintf("unsupported sizeof(void*): %d", t.Arch().Width()))
}
var maskStruct sigSetWithSize
if _, err := maskStruct.CopyIn(t, maskWithSizeAddr); err != nil {
return 0, nil, err
}
if err := setTempSignalSet(t, hostarch.Addr(maskStruct.sigsetAddr), uint(maskStruct.sizeofSigset)); err != nil {
return 0, nil, err
}
}
n, err := doSelect(t, nfds, readFDs, writeFDs, exceptFDs, timeout)
copyErr := copyOutTimespecRemaining(t, startNs, timeout, timespecAddr)
// See comment in Ppoll.
if linuxerr.Equals(linuxerr.EINTR, err) && copyErr == nil {
err = syserror.ERESTARTNOHAND
}
return n, nil, err
}
// copyTimespecInToDuration copies a Timespec from the untrusted app range,
// validates it and converts it to a Duration.
//
// If the Timespec is larger than what can be represented in a Duration, the
// returned value is the maximum that Duration will allow.
//
// If timespecAddr is NULL, the returned value is negative.
func copyTimespecInToDuration(t *kernel.Task, timespecAddr hostarch.Addr) (time.Duration, error) {
// Use a negative Duration to indicate "no timeout".
timeout := time.Duration(-1)
if timespecAddr != 0 {
var timespec linux.Timespec
if _, err := timespec.CopyIn(t, timespecAddr); err != nil {
return 0, err
}
if !timespec.Valid() {
return 0, linuxerr.EINVAL
}
timeout = time.Duration(timespec.ToNsecCapped())
}
return timeout, nil
}
func setTempSignalSet(t *kernel.Task, maskAddr hostarch.Addr, maskSize uint) error {
if maskAddr == 0 {
return nil
}
if maskSize != linux.SignalSetSize {
return linuxerr.EINVAL
}
var mask linux.SignalSet
if _, err := mask.CopyIn(t, maskAddr); err != nil {
return err
}
mask &^= kernel.UnblockableSignals
oldmask := t.SignalMask()
t.SetSignalMask(mask)
t.SetSavedSignalMask(oldmask)
return nil
}
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