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// Copyright 2019 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 proc
import (
"bytes"
"fmt"
"io"
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/sentry/context"
"gvisor.dev/gvisor/pkg/sentry/fsimpl/kernfs"
"gvisor.dev/gvisor/pkg/sentry/kernel"
"gvisor.dev/gvisor/pkg/sentry/kernel/auth"
"gvisor.dev/gvisor/pkg/sentry/limits"
"gvisor.dev/gvisor/pkg/sentry/mm"
"gvisor.dev/gvisor/pkg/sentry/safemem"
"gvisor.dev/gvisor/pkg/sentry/usage"
"gvisor.dev/gvisor/pkg/sentry/usermem"
"gvisor.dev/gvisor/pkg/sentry/vfs"
"gvisor.dev/gvisor/pkg/syserror"
)
// mm gets the kernel task's MemoryManager. No additional reference is taken on
// mm here. This is safe because MemoryManager.destroy is required to leave the
// MemoryManager in a state where it's still usable as a DynamicBytesSource.
func getMM(task *kernel.Task) *mm.MemoryManager {
var tmm *mm.MemoryManager
task.WithMuLocked(func(t *kernel.Task) {
if mm := t.MemoryManager(); mm != nil {
tmm = mm
}
})
return tmm
}
// getMMIncRef returns t's MemoryManager. If getMMIncRef succeeds, the
// MemoryManager's users count is incremented, and must be decremented by the
// caller when it is no longer in use.
func getMMIncRef(task *kernel.Task) (*mm.MemoryManager, error) {
if task.ExitState() == kernel.TaskExitDead {
return nil, syserror.ESRCH
}
var m *mm.MemoryManager
task.WithMuLocked(func(t *kernel.Task) {
m = t.MemoryManager()
})
if m == nil || !m.IncUsers() {
return nil, io.EOF
}
return m, nil
}
type bufferWriter struct {
buf *bytes.Buffer
}
// WriteFromBlocks writes up to srcs.NumBytes() bytes from srcs and returns
// the number of bytes written. It may return a partial write without an
// error (i.e. (n, nil) where 0 < n < srcs.NumBytes()). It should not
// return a full write with an error (i.e. srcs.NumBytes(), err) where err
// != nil).
func (w *bufferWriter) WriteFromBlocks(srcs safemem.BlockSeq) (uint64, error) {
written := srcs.NumBytes()
for !srcs.IsEmpty() {
w.buf.Write(srcs.Head().ToSlice())
srcs = srcs.Tail()
}
return written, nil
}
// auxvData implements vfs.DynamicBytesSource for /proc/[pid]/auxv.
//
// +stateify savable
type auxvData struct {
kernfs.DynamicBytesFile
task *kernel.Task
}
var _ dynamicInode = (*auxvData)(nil)
// Generate implements vfs.DynamicBytesSource.Generate.
func (d *auxvData) Generate(ctx context.Context, buf *bytes.Buffer) error {
m, err := getMMIncRef(d.task)
if err != nil {
return err
}
defer m.DecUsers(ctx)
// Space for buffer with AT_NULL (0) terminator at the end.
auxv := m.Auxv()
buf.Grow((len(auxv) + 1) * 16)
for _, e := range auxv {
var tmp [8]byte
usermem.ByteOrder.PutUint64(tmp[:], e.Key)
buf.Write(tmp[:])
usermem.ByteOrder.PutUint64(tmp[:], uint64(e.Value))
buf.Write(tmp[:])
}
return nil
}
// execArgType enumerates the types of exec arguments that are exposed through
// proc.
type execArgType int
const (
cmdlineDataArg execArgType = iota
environDataArg
)
// cmdlineData implements vfs.DynamicBytesSource for /proc/[pid]/cmdline.
//
// +stateify savable
type cmdlineData struct {
kernfs.DynamicBytesFile
task *kernel.Task
// arg is the type of exec argument this file contains.
arg execArgType
}
var _ dynamicInode = (*cmdlineData)(nil)
// Generate implements vfs.DynamicBytesSource.Generate.
func (d *cmdlineData) Generate(ctx context.Context, buf *bytes.Buffer) error {
m, err := getMMIncRef(d.task)
if err != nil {
return err
}
defer m.DecUsers(ctx)
// Figure out the bounds of the exec arg we are trying to read.
var ar usermem.AddrRange
switch d.arg {
case cmdlineDataArg:
ar = usermem.AddrRange{
Start: m.ArgvStart(),
End: m.ArgvEnd(),
}
case environDataArg:
ar = usermem.AddrRange{
Start: m.EnvvStart(),
End: m.EnvvEnd(),
}
default:
panic(fmt.Sprintf("unknown exec arg type %v", d.arg))
}
if ar.Start == 0 || ar.End == 0 {
// Don't attempt to read before the start/end are set up.
return io.EOF
}
// N.B. Technically this should be usermem.IOOpts.IgnorePermissions = true
// until Linux 4.9 (272ddc8b3735 "proc: don't use FOLL_FORCE for reading
// cmdline and environment").
writer := &bufferWriter{buf: buf}
if n, err := m.CopyInTo(ctx, usermem.AddrRangeSeqOf(ar), writer, usermem.IOOpts{}); n == 0 || err != nil {
// Nothing to copy or something went wrong.
return err
}
// On Linux, if the NULL byte at the end of the argument vector has been
// overwritten, it continues reading the environment vector as part of
// the argument vector.
if d.arg == cmdlineDataArg && buf.Bytes()[buf.Len()-1] != 0 {
if end := bytes.IndexByte(buf.Bytes(), 0); end != -1 {
// If we found a NULL character somewhere else in argv, truncate the
// return up to the NULL terminator (including it).
buf.Truncate(end)
return nil
}
// There is no NULL terminator in the string, return into envp.
arEnvv := usermem.AddrRange{
Start: m.EnvvStart(),
End: m.EnvvEnd(),
}
// Upstream limits the returned amount to one page of slop.
// https://elixir.bootlin.com/linux/v4.20/source/fs/proc/base.c#L208
// we'll return one page total between argv and envp because of the
// above page restrictions.
if buf.Len() >= usermem.PageSize {
// Returned at least one page already, nothing else to add.
return nil
}
remaining := usermem.PageSize - buf.Len()
if int(arEnvv.Length()) > remaining {
end, ok := arEnvv.Start.AddLength(uint64(remaining))
if !ok {
return syserror.EFAULT
}
arEnvv.End = end
}
if _, err := m.CopyInTo(ctx, usermem.AddrRangeSeqOf(arEnvv), writer, usermem.IOOpts{}); err != nil {
return err
}
// Linux will return envp up to and including the first NULL character,
// so find it.
if end := bytes.IndexByte(buf.Bytes()[ar.Length():], 0); end != -1 {
buf.Truncate(end)
}
}
return nil
}
// +stateify savable
type commInode struct {
kernfs.DynamicBytesFile
task *kernel.Task
}
func newComm(task *kernel.Task, ino uint64, perm linux.FileMode) *kernfs.Dentry {
inode := &commInode{task: task}
inode.DynamicBytesFile.Init(task.Credentials(), ino, &commData{task: task}, perm)
d := &kernfs.Dentry{}
d.Init(inode)
return d
}
func (i *commInode) CheckPermissions(ctx context.Context, creds *auth.Credentials, ats vfs.AccessTypes) error {
// This file can always be read or written by members of the same thread
// group. See fs/proc/base.c:proc_tid_comm_permission.
//
// N.B. This check is currently a no-op as we don't yet support writing and
// this file is world-readable anyways.
t := kernel.TaskFromContext(ctx)
if t != nil && t.ThreadGroup() == i.task.ThreadGroup() && !ats.MayExec() {
return nil
}
return i.DynamicBytesFile.CheckPermissions(ctx, creds, ats)
}
// commData implements vfs.DynamicBytesSource for /proc/[pid]/comm.
//
// +stateify savable
type commData struct {
kernfs.DynamicBytesFile
task *kernel.Task
}
var _ dynamicInode = (*commData)(nil)
// Generate implements vfs.DynamicBytesSource.Generate.
func (d *commData) Generate(ctx context.Context, buf *bytes.Buffer) error {
buf.WriteString(d.task.Name())
buf.WriteString("\n")
return nil
}
// idMapData implements vfs.DynamicBytesSource for /proc/[pid]/{gid_map|uid_map}.
//
// +stateify savable
type idMapData struct {
kernfs.DynamicBytesFile
task *kernel.Task
gids bool
}
var _ dynamicInode = (*idMapData)(nil)
// Generate implements vfs.DynamicBytesSource.Generate.
func (d *idMapData) Generate(ctx context.Context, buf *bytes.Buffer) error {
var entries []auth.IDMapEntry
if d.gids {
entries = d.task.UserNamespace().GIDMap()
} else {
entries = d.task.UserNamespace().UIDMap()
}
for _, e := range entries {
fmt.Fprintf(buf, "%10d %10d %10d\n", e.FirstID, e.FirstParentID, e.Length)
}
return nil
}
// mapsData implements vfs.DynamicBytesSource for /proc/[pid]/maps.
//
// +stateify savable
type mapsData struct {
kernfs.DynamicBytesFile
task *kernel.Task
}
var _ dynamicInode = (*mapsData)(nil)
// Generate implements vfs.DynamicBytesSource.Generate.
func (d *mapsData) Generate(ctx context.Context, buf *bytes.Buffer) error {
if mm := getMM(d.task); mm != nil {
mm.ReadMapsDataInto(ctx, buf)
}
return nil
}
// smapsData implements vfs.DynamicBytesSource for /proc/[pid]/smaps.
//
// +stateify savable
type smapsData struct {
kernfs.DynamicBytesFile
task *kernel.Task
}
var _ dynamicInode = (*smapsData)(nil)
// Generate implements vfs.DynamicBytesSource.Generate.
func (d *smapsData) Generate(ctx context.Context, buf *bytes.Buffer) error {
if mm := getMM(d.task); mm != nil {
mm.ReadSmapsDataInto(ctx, buf)
}
return nil
}
// +stateify savable
type taskStatData struct {
kernfs.DynamicBytesFile
task *kernel.Task
// If tgstats is true, accumulate fault stats (not implemented) and CPU
// time across all tasks in t's thread group.
tgstats bool
// pidns is the PID namespace associated with the proc filesystem that
// includes the file using this statData.
pidns *kernel.PIDNamespace
}
var _ dynamicInode = (*taskStatData)(nil)
// Generate implements vfs.DynamicBytesSource.Generate.
func (s *taskStatData) Generate(ctx context.Context, buf *bytes.Buffer) error {
fmt.Fprintf(buf, "%d ", s.pidns.IDOfTask(s.task))
fmt.Fprintf(buf, "(%s) ", s.task.Name())
fmt.Fprintf(buf, "%c ", s.task.StateStatus()[0])
ppid := kernel.ThreadID(0)
if parent := s.task.Parent(); parent != nil {
ppid = s.pidns.IDOfThreadGroup(parent.ThreadGroup())
}
fmt.Fprintf(buf, "%d ", ppid)
fmt.Fprintf(buf, "%d ", s.pidns.IDOfProcessGroup(s.task.ThreadGroup().ProcessGroup()))
fmt.Fprintf(buf, "%d ", s.pidns.IDOfSession(s.task.ThreadGroup().Session()))
fmt.Fprintf(buf, "0 0 " /* tty_nr tpgid */)
fmt.Fprintf(buf, "0 " /* flags */)
fmt.Fprintf(buf, "0 0 0 0 " /* minflt cminflt majflt cmajflt */)
var cputime usage.CPUStats
if s.tgstats {
cputime = s.task.ThreadGroup().CPUStats()
} else {
cputime = s.task.CPUStats()
}
fmt.Fprintf(buf, "%d %d ", linux.ClockTFromDuration(cputime.UserTime), linux.ClockTFromDuration(cputime.SysTime))
cputime = s.task.ThreadGroup().JoinedChildCPUStats()
fmt.Fprintf(buf, "%d %d ", linux.ClockTFromDuration(cputime.UserTime), linux.ClockTFromDuration(cputime.SysTime))
fmt.Fprintf(buf, "%d %d ", s.task.Priority(), s.task.Niceness())
fmt.Fprintf(buf, "%d ", s.task.ThreadGroup().Count())
// itrealvalue. Since kernel 2.6.17, this field is no longer
// maintained, and is hard coded as 0.
fmt.Fprintf(buf, "0 ")
// Start time is relative to boot time, expressed in clock ticks.
fmt.Fprintf(buf, "%d ", linux.ClockTFromDuration(s.task.StartTime().Sub(s.task.Kernel().Timekeeper().BootTime())))
var vss, rss uint64
s.task.WithMuLocked(func(t *kernel.Task) {
if mm := t.MemoryManager(); mm != nil {
vss = mm.VirtualMemorySize()
rss = mm.ResidentSetSize()
}
})
fmt.Fprintf(buf, "%d %d ", vss, rss/usermem.PageSize)
// rsslim.
fmt.Fprintf(buf, "%d ", s.task.ThreadGroup().Limits().Get(limits.Rss).Cur)
fmt.Fprintf(buf, "0 0 0 0 0 " /* startcode endcode startstack kstkesp kstkeip */)
fmt.Fprintf(buf, "0 0 0 0 0 " /* signal blocked sigignore sigcatch wchan */)
fmt.Fprintf(buf, "0 0 " /* nswap cnswap */)
terminationSignal := linux.Signal(0)
if s.task == s.task.ThreadGroup().Leader() {
terminationSignal = s.task.ThreadGroup().TerminationSignal()
}
fmt.Fprintf(buf, "%d ", terminationSignal)
fmt.Fprintf(buf, "0 0 0 " /* processor rt_priority policy */)
fmt.Fprintf(buf, "0 0 0 " /* delayacct_blkio_ticks guest_time cguest_time */)
fmt.Fprintf(buf, "0 0 0 0 0 0 0 " /* start_data end_data start_brk arg_start arg_end env_start env_end */)
fmt.Fprintf(buf, "0\n" /* exit_code */)
return nil
}
// statmData implements vfs.DynamicBytesSource for /proc/[pid]/statm.
//
// +stateify savable
type statmData struct {
kernfs.DynamicBytesFile
task *kernel.Task
}
var _ dynamicInode = (*statmData)(nil)
// Generate implements vfs.DynamicBytesSource.Generate.
func (s *statmData) Generate(ctx context.Context, buf *bytes.Buffer) error {
var vss, rss uint64
s.task.WithMuLocked(func(t *kernel.Task) {
if mm := t.MemoryManager(); mm != nil {
vss = mm.VirtualMemorySize()
rss = mm.ResidentSetSize()
}
})
fmt.Fprintf(buf, "%d %d 0 0 0 0 0\n", vss/usermem.PageSize, rss/usermem.PageSize)
return nil
}
// statusData implements vfs.DynamicBytesSource for /proc/[pid]/status.
//
// +stateify savable
type statusData struct {
kernfs.DynamicBytesFile
task *kernel.Task
pidns *kernel.PIDNamespace
}
var _ dynamicInode = (*statusData)(nil)
// Generate implements vfs.DynamicBytesSource.Generate.
func (s *statusData) Generate(ctx context.Context, buf *bytes.Buffer) error {
fmt.Fprintf(buf, "Name:\t%s\n", s.task.Name())
fmt.Fprintf(buf, "State:\t%s\n", s.task.StateStatus())
fmt.Fprintf(buf, "Tgid:\t%d\n", s.pidns.IDOfThreadGroup(s.task.ThreadGroup()))
fmt.Fprintf(buf, "Pid:\t%d\n", s.pidns.IDOfTask(s.task))
ppid := kernel.ThreadID(0)
if parent := s.task.Parent(); parent != nil {
ppid = s.pidns.IDOfThreadGroup(parent.ThreadGroup())
}
fmt.Fprintf(buf, "PPid:\t%d\n", ppid)
tpid := kernel.ThreadID(0)
if tracer := s.task.Tracer(); tracer != nil {
tpid = s.pidns.IDOfTask(tracer)
}
fmt.Fprintf(buf, "TracerPid:\t%d\n", tpid)
var fds int
var vss, rss, data uint64
s.task.WithMuLocked(func(t *kernel.Task) {
if fdTable := t.FDTable(); fdTable != nil {
fds = fdTable.Size()
}
if mm := t.MemoryManager(); mm != nil {
vss = mm.VirtualMemorySize()
rss = mm.ResidentSetSize()
data = mm.VirtualDataSize()
}
})
fmt.Fprintf(buf, "FDSize:\t%d\n", fds)
fmt.Fprintf(buf, "VmSize:\t%d kB\n", vss>>10)
fmt.Fprintf(buf, "VmRSS:\t%d kB\n", rss>>10)
fmt.Fprintf(buf, "VmData:\t%d kB\n", data>>10)
fmt.Fprintf(buf, "Threads:\t%d\n", s.task.ThreadGroup().Count())
creds := s.task.Credentials()
fmt.Fprintf(buf, "CapInh:\t%016x\n", creds.InheritableCaps)
fmt.Fprintf(buf, "CapPrm:\t%016x\n", creds.PermittedCaps)
fmt.Fprintf(buf, "CapEff:\t%016x\n", creds.EffectiveCaps)
fmt.Fprintf(buf, "CapBnd:\t%016x\n", creds.BoundingCaps)
fmt.Fprintf(buf, "Seccomp:\t%d\n", s.task.SeccompMode())
// We unconditionally report a single NUMA node. See
// pkg/sentry/syscalls/linux/sys_mempolicy.go.
fmt.Fprintf(buf, "Mems_allowed:\t1\n")
fmt.Fprintf(buf, "Mems_allowed_list:\t0\n")
return nil
}
// ioUsage is the /proc/<pid>/io and /proc/<pid>/task/<tid>/io data provider.
type ioUsage interface {
// IOUsage returns the io usage data.
IOUsage() *usage.IO
}
// +stateify savable
type ioData struct {
kernfs.DynamicBytesFile
ioUsage
}
var _ dynamicInode = (*ioData)(nil)
// Generate implements vfs.DynamicBytesSource.Generate.
func (i *ioData) Generate(ctx context.Context, buf *bytes.Buffer) error {
io := usage.IO{}
io.Accumulate(i.IOUsage())
fmt.Fprintf(buf, "char: %d\n", io.CharsRead)
fmt.Fprintf(buf, "wchar: %d\n", io.CharsWritten)
fmt.Fprintf(buf, "syscr: %d\n", io.ReadSyscalls)
fmt.Fprintf(buf, "syscw: %d\n", io.WriteSyscalls)
fmt.Fprintf(buf, "read_bytes: %d\n", io.BytesRead)
fmt.Fprintf(buf, "write_bytes: %d\n", io.BytesWritten)
fmt.Fprintf(buf, "cancelled_write_bytes: %d\n", io.BytesWriteCancelled)
return nil
}
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