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|
// Copyright 2018 The gVisor Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// Package shm implements sysv shared memory segments.
//
// Known missing features:
//
// - SHM_LOCK/SHM_UNLOCK are no-ops. The sentry currently doesn't implement
// memory locking in general.
//
// - SHM_HUGETLB and related flags for shmget(2) are ignored. There's no easy
// way to implement hugetlb support on a per-map basis, and it has no impact
// on correctness.
//
// - SHM_NORESERVE for shmget(2) is ignored, the sentry doesn't implement swap
// so it's meaningless to reserve space for swap.
//
// - No per-process segment size enforcement. This feature probably isn't used
// much anyways, since Linux sets the per-process limits to the system-wide
// limits by default.
//
// Lock ordering: mm.mappingMu -> shm registry lock -> shm lock
package shm
import (
"fmt"
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/context"
"gvisor.dev/gvisor/pkg/errors/linuxerr"
"gvisor.dev/gvisor/pkg/hostarch"
"gvisor.dev/gvisor/pkg/log"
"gvisor.dev/gvisor/pkg/sentry/fs"
"gvisor.dev/gvisor/pkg/sentry/kernel/auth"
"gvisor.dev/gvisor/pkg/sentry/kernel/ipc"
ktime "gvisor.dev/gvisor/pkg/sentry/kernel/time"
"gvisor.dev/gvisor/pkg/sentry/memmap"
"gvisor.dev/gvisor/pkg/sentry/pgalloc"
"gvisor.dev/gvisor/pkg/sentry/usage"
"gvisor.dev/gvisor/pkg/sync"
"gvisor.dev/gvisor/pkg/syserror"
)
// Registry tracks all shared memory segments in an IPC namespace. The registry
// provides the mechanisms for creating and finding segments, and reporting
// global shm parameters.
//
// +stateify savable
type Registry struct {
// userNS owns the IPC namespace this registry belong to. Immutable.
userNS *auth.UserNamespace
// mu protects all fields below.
mu sync.Mutex `state:"nosave"`
// reg defines basic fields and operations needed for all SysV registries.
//
// Withing reg, there are two maps, Objects and KeysToIDs.
//
// reg.objects holds all referenced segments, which are removed on the last
// DecRef. Thus, it cannot itself hold a reference on the Shm.
//
// Since removal only occurs after the last (unlocked) DecRef, there
// exists a short window during which a Shm still exists in Shm, but is
// unreferenced. Users must use TryIncRef to determine if the Shm is
// still valid.
//
// keysToIDs maps segment keys to IDs.
//
// Shms in keysToIDs are guaranteed to be referenced, as they are
// removed by disassociateKey before the last DecRef.
reg *ipc.Registry
// Sum of the sizes of all existing segments rounded up to page size, in
// units of page size.
totalPages uint64
}
// NewRegistry creates a new shm registry.
func NewRegistry(userNS *auth.UserNamespace) *Registry {
return &Registry{
userNS: userNS,
reg: ipc.NewRegistry(userNS),
}
}
// FindByID looks up a segment given an ID.
//
// FindByID returns a reference on Shm.
func (r *Registry) FindByID(id ipc.ID) *Shm {
r.mu.Lock()
defer r.mu.Unlock()
mech := r.reg.FindByID(id)
if mech == nil {
return nil
}
s := mech.(*Shm)
// Take a reference on s. If TryIncRef fails, s has reached the last
// DecRef, but hasn't quite been removed from r.reg.objects yet.
if s != nil && s.TryIncRef() {
return s
}
return nil
}
// dissociateKey removes the association between a segment and its key,
// preventing it from being discovered in the registry. This doesn't necessarily
// mean the segment is about to be destroyed. This is analogous to unlinking a
// file; the segment can still be used by a process already referencing it, but
// cannot be discovered by a new process.
func (r *Registry) dissociateKey(s *Shm) {
r.mu.Lock()
defer r.mu.Unlock()
s.mu.Lock()
defer s.mu.Unlock()
if s.obj.Key != linux.IPC_PRIVATE {
r.reg.DissociateKey(s.obj.Key)
s.obj.Key = linux.IPC_PRIVATE
}
}
// FindOrCreate looks up or creates a segment in the registry. It's functionally
// analogous to open(2).
//
// FindOrCreate returns a reference on Shm.
func (r *Registry) FindOrCreate(ctx context.Context, pid int32, key ipc.Key, size uint64, mode linux.FileMode, private, create, exclusive bool) (*Shm, error) {
if (create || private) && (size < linux.SHMMIN || size > linux.SHMMAX) {
// "A new segment was to be created and size is less than SHMMIN or
// greater than SHMMAX." - man shmget(2)
//
// Note that 'private' always implies the creation of a new segment
// whether IPC_CREAT is specified or not.
return nil, linuxerr.EINVAL
}
r.mu.Lock()
defer r.mu.Unlock()
if r.reg.ObjectCount() >= linux.SHMMNI {
// "All possible shared memory IDs have been taken (SHMMNI) ..."
// - man shmget(2)
return nil, syserror.ENOSPC
}
if !private {
shm, err := r.reg.Find(ctx, key, mode, create, exclusive)
if err != nil {
return nil, err
}
// Validate shm-specific parameters.
if shm != nil {
shm := shm.(*Shm)
if size > shm.size {
// "A segment for the given key exists, but size is greater than
// the size of that segment." - man shmget(2)
return nil, linuxerr.EINVAL
}
shm.IncRef()
return shm, nil
}
}
var sizeAligned uint64
if val, ok := hostarch.Addr(size).RoundUp(); ok {
sizeAligned = uint64(val)
} else {
return nil, linuxerr.EINVAL
}
if numPages := sizeAligned / hostarch.PageSize; r.totalPages+numPages > linux.SHMALL {
// "... allocating a segment of the requested size would cause the
// system to exceed the system-wide limit on shared memory (SHMALL)."
// - man shmget(2)
return nil, syserror.ENOSPC
}
// Need to create a new segment.
s, err := r.newShmLocked(ctx, pid, key, fs.FileOwnerFromContext(ctx), fs.FilePermsFromMode(mode), size)
if err != nil {
return nil, err
}
// The initial reference is held by s itself. Take another to return to
// the caller.
s.IncRef()
return s, nil
}
// newShmLocked creates a new segment in the registry.
//
// Precondition: Caller must hold r.mu.
func (r *Registry) newShmLocked(ctx context.Context, pid int32, key ipc.Key, creator fs.FileOwner, perms fs.FilePermissions, size uint64) (*Shm, error) {
mfp := pgalloc.MemoryFileProviderFromContext(ctx)
if mfp == nil {
panic(fmt.Sprintf("context.Context %T lacks non-nil value for key %T", ctx, pgalloc.CtxMemoryFileProvider))
}
effectiveSize := uint64(hostarch.Addr(size).MustRoundUp())
fr, err := mfp.MemoryFile().Allocate(effectiveSize, usage.Anonymous)
if err != nil {
return nil, err
}
shm := &Shm{
mfp: mfp,
registry: r,
size: size,
effectiveSize: effectiveSize,
obj: ipc.NewObject(r.reg.UserNS, ipc.Key(key), creator, creator, perms),
fr: fr,
creatorPID: pid,
changeTime: ktime.NowFromContext(ctx),
}
shm.InitRefs()
if err := r.reg.Register(shm); err != nil {
return nil, err
}
r.totalPages += effectiveSize / hostarch.PageSize
return shm, nil
}
// IPCInfo reports global parameters for sysv shared memory segments on this
// system. See shmctl(IPC_INFO).
func (r *Registry) IPCInfo() *linux.ShmParams {
return &linux.ShmParams{
ShmMax: linux.SHMMAX,
ShmMin: linux.SHMMIN,
ShmMni: linux.SHMMNI,
ShmSeg: linux.SHMSEG,
ShmAll: linux.SHMALL,
}
}
// ShmInfo reports linux-specific global parameters for sysv shared memory
// segments on this system. See shmctl(SHM_INFO).
func (r *Registry) ShmInfo() *linux.ShmInfo {
r.mu.Lock()
defer r.mu.Unlock()
return &linux.ShmInfo{
UsedIDs: int32(r.reg.LastIDUsed()),
ShmTot: r.totalPages,
ShmRss: r.totalPages, // We could probably get a better estimate from memory accounting.
ShmSwp: 0, // No reclaim at the moment.
}
}
// remove deletes a segment from this registry, deaccounting the memory used by
// the segment.
//
// Precondition: Must follow a call to r.dissociateKey(s).
func (r *Registry) remove(s *Shm) {
r.mu.Lock()
defer r.mu.Unlock()
s.mu.Lock()
defer s.mu.Unlock()
if s.obj.Key != linux.IPC_PRIVATE {
panic(fmt.Sprintf("Attempted to remove %s from the registry whose key is still associated", s.debugLocked()))
}
r.reg.DissociateID(s.obj.ID)
r.totalPages -= s.effectiveSize / hostarch.PageSize
}
// Release drops the self-reference of each active shm segment in the registry.
// It is called when the kernel.IPCNamespace containing r is being destroyed.
func (r *Registry) Release(ctx context.Context) {
// Because Shm.DecRef() may acquire the same locks, collect the segments to
// release first. Note that this should not race with any updates to r, since
// the IPC namespace containing it has no more references.
toRelease := make([]*Shm, 0)
r.mu.Lock()
r.reg.ForAllObjects(
func(o ipc.Mechanism) {
s := o.(*Shm)
s.mu.Lock()
if !s.pendingDestruction {
toRelease = append(toRelease, s)
}
s.mu.Unlock()
},
)
r.mu.Unlock()
for _, s := range toRelease {
r.dissociateKey(s)
s.DecRef(ctx)
}
}
// Shm represents a single shared memory segment.
//
// Shm segments are backed directly by an allocation from platform memory.
// Segments are always mapped as a whole, greatly simplifying how mappings are
// tracked. However note that mremap and munmap calls may cause the vma for a
// segment to become fragmented; which requires special care when unmapping a
// segment. See mm/shm.go.
//
// Segments persist until they are explicitly marked for destruction via
// MarkDestroyed().
//
// Shm implements memmap.Mappable and memmap.MappingIdentity.
//
// +stateify savable
type Shm struct {
// ShmRefs tracks the number of references to this segment.
//
// A segment holds a reference to itself until it is marked for
// destruction.
//
// In addition to direct users, the MemoryManager will hold references
// via MappingIdentity.
ShmRefs
mfp pgalloc.MemoryFileProvider
// registry points to the shm registry containing this segment. Immutable.
registry *Registry
// size is the requested size of the segment at creation, in
// bytes. Immutable.
size uint64
// effectiveSize of the segment, rounding up to the next page
// boundary. Immutable.
//
// Invariant: effectiveSize must be a multiple of hostarch.PageSize.
effectiveSize uint64
// fr is the offset into mfp.MemoryFile() that backs this contents of this
// segment. Immutable.
fr memmap.FileRange
// mu protects all fields below.
mu sync.Mutex `state:"nosave"`
obj *ipc.Object
// attachTime is updated on every successful shmat.
attachTime ktime.Time
// detachTime is updated on every successful shmdt.
detachTime ktime.Time
// changeTime is updated on every successful changes to the segment via
// shmctl(IPC_SET).
changeTime ktime.Time
// creatorPID is the PID of the process that created the segment.
creatorPID int32
// lastAttachDetachPID is the pid of the process that issued the last shmat
// or shmdt syscall.
lastAttachDetachPID int32
// pendingDestruction indicates the segment was marked as destroyed through
// shmctl(IPC_RMID). When marked as destroyed, the segment will not be found
// in the registry and can no longer be attached. When the last user
// detaches from the segment, it is destroyed.
pendingDestruction bool
}
// ID returns object's ID.
func (s *Shm) ID() ipc.ID {
return s.obj.ID
}
// Object implements ipc.Mechanism.Object.
func (s *Shm) Object() *ipc.Object {
return s.obj
}
// Destroy implements ipc.Mechanism.Destroy. No work is performed on shm.Destroy
// because a different removal mechanism is used in shm. See Shm.MarkDestroyed.
func (s *Shm) Destroy() {
}
// Lock implements ipc.Mechanism.Lock.
func (s *Shm) Lock() {
s.mu.Lock()
}
// Unlock implements ipc.mechanism.Unlock.
//
// +checklocksignore
func (s *Shm) Unlock() {
s.mu.Unlock()
}
// Precondition: Caller must hold s.mu.
func (s *Shm) debugLocked() string {
return fmt.Sprintf("Shm{id: %d, key: %d, size: %d bytes, refs: %d, destroyed: %v}",
s.obj.ID, s.obj.Key, s.size, s.ReadRefs(), s.pendingDestruction)
}
// MappedName implements memmap.MappingIdentity.MappedName.
func (s *Shm) MappedName(ctx context.Context) string {
s.mu.Lock()
defer s.mu.Unlock()
return fmt.Sprintf("SYSV%08d", s.obj.Key)
}
// DeviceID implements memmap.MappingIdentity.DeviceID.
func (s *Shm) DeviceID() uint64 {
return shmDevice.DeviceID()
}
// InodeID implements memmap.MappingIdentity.InodeID.
func (s *Shm) InodeID() uint64 {
// "shmid gets reported as "inode#" in /proc/pid/maps. proc-ps tools use
// this. Changing this will break them." -- Linux, ipc/shm.c:newseg()
return uint64(s.obj.ID)
}
// DecRef drops a reference on s.
//
// Precondition: Caller must not hold s.mu.
func (s *Shm) DecRef(ctx context.Context) {
s.ShmRefs.DecRef(func() {
s.mfp.MemoryFile().DecRef(s.fr)
s.registry.remove(s)
})
}
// Msync implements memmap.MappingIdentity.Msync. Msync is a no-op for shm
// segments.
func (s *Shm) Msync(context.Context, memmap.MappableRange) error {
return nil
}
// AddMapping implements memmap.Mappable.AddMapping.
func (s *Shm) AddMapping(ctx context.Context, _ memmap.MappingSpace, _ hostarch.AddrRange, _ uint64, _ bool) error {
s.mu.Lock()
defer s.mu.Unlock()
s.attachTime = ktime.NowFromContext(ctx)
if pid, ok := context.ThreadGroupIDFromContext(ctx); ok {
s.lastAttachDetachPID = pid
} else {
// AddMapping is called during a syscall, so ctx should always be a task
// context.
log.Warningf("Adding mapping to %s but couldn't get the current pid; not updating the last attach pid", s.debugLocked())
}
return nil
}
// RemoveMapping implements memmap.Mappable.RemoveMapping.
func (s *Shm) RemoveMapping(ctx context.Context, _ memmap.MappingSpace, _ hostarch.AddrRange, _ uint64, _ bool) {
s.mu.Lock()
defer s.mu.Unlock()
// RemoveMapping may be called during task exit, when ctx
// is context.Background. Gracefully handle missing clocks. Failing to
// update the detach time in these cases is ok, since no one can observe the
// omission.
if clock := ktime.RealtimeClockFromContext(ctx); clock != nil {
s.detachTime = clock.Now()
}
// If called from a non-task context we also won't have a threadgroup
// id. Silently skip updating the lastAttachDetachPid in that case.
if pid, ok := context.ThreadGroupIDFromContext(ctx); ok {
s.lastAttachDetachPID = pid
} else {
log.Debugf("Couldn't obtain pid when removing mapping to %s, not updating the last detach pid.", s.debugLocked())
}
}
// CopyMapping implements memmap.Mappable.CopyMapping.
func (*Shm) CopyMapping(context.Context, memmap.MappingSpace, hostarch.AddrRange, hostarch.AddrRange, uint64, bool) error {
return nil
}
// Translate implements memmap.Mappable.Translate.
func (s *Shm) Translate(ctx context.Context, required, optional memmap.MappableRange, at hostarch.AccessType) ([]memmap.Translation, error) {
var err error
if required.End > s.fr.Length() {
err = &memmap.BusError{linuxerr.EFAULT}
}
if source := optional.Intersect(memmap.MappableRange{0, s.fr.Length()}); source.Length() != 0 {
return []memmap.Translation{
{
Source: source,
File: s.mfp.MemoryFile(),
Offset: s.fr.Start + source.Start,
Perms: hostarch.AnyAccess,
},
}, err
}
return nil, err
}
// InvalidateUnsavable implements memmap.Mappable.InvalidateUnsavable.
func (s *Shm) InvalidateUnsavable(ctx context.Context) error {
return nil
}
// AttachOpts describes various flags passed to shmat(2).
type AttachOpts struct {
Execute bool
Readonly bool
Remap bool
}
// ConfigureAttach creates an mmap configuration for the segment with the
// requested attach options.
//
// Postconditions: The returned MMapOpts are valid only as long as a reference
// continues to be held on s.
func (s *Shm) ConfigureAttach(ctx context.Context, addr hostarch.Addr, opts AttachOpts) (memmap.MMapOpts, error) {
s.mu.Lock()
defer s.mu.Unlock()
if s.pendingDestruction && s.ReadRefs() == 0 {
return memmap.MMapOpts{}, syserror.EIDRM
}
creds := auth.CredentialsFromContext(ctx)
if !s.obj.CheckPermissions(creds, fs.PermMask{
Read: true,
Write: !opts.Readonly,
Execute: opts.Execute,
}) {
// "The calling process does not have the required permissions for the
// requested attach type, and does not have the CAP_IPC_OWNER capability
// in the user namespace that governs its IPC namespace." - man shmat(2)
return memmap.MMapOpts{}, linuxerr.EACCES
}
return memmap.MMapOpts{
Length: s.size,
Offset: 0,
Addr: addr,
Fixed: opts.Remap,
Perms: hostarch.AccessType{
Read: true,
Write: !opts.Readonly,
Execute: opts.Execute,
},
MaxPerms: hostarch.AnyAccess,
Mappable: s,
MappingIdentity: s,
}, nil
}
// EffectiveSize returns the size of the underlying shared memory segment. This
// may be larger than the requested size at creation, due to rounding to page
// boundaries.
func (s *Shm) EffectiveSize() uint64 {
return s.effectiveSize
}
// IPCStat returns information about a shm. See shmctl(IPC_STAT).
func (s *Shm) IPCStat(ctx context.Context) (*linux.ShmidDS, error) {
s.mu.Lock()
defer s.mu.Unlock()
// "The caller must have read permission on the shared memory segment."
// - man shmctl(2)
creds := auth.CredentialsFromContext(ctx)
if !s.obj.CheckPermissions(creds, fs.PermMask{Read: true}) {
// "IPC_STAT or SHM_STAT is requested and shm_perm.mode does not allow
// read access for shmid, and the calling process does not have the
// CAP_IPC_OWNER capability in the user namespace that governs its IPC
// namespace." - man shmctl(2)
return nil, linuxerr.EACCES
}
var mode uint16
if s.pendingDestruction {
mode |= linux.SHM_DEST
}
// Use the reference count as a rudimentary count of the number of
// attaches. We exclude:
//
// 1. The reference the caller holds.
// 2. The self-reference held by s prior to destruction.
//
// Note that this may still overcount by including transient references
// used in concurrent calls.
nattach := uint64(s.ReadRefs()) - 1
if !s.pendingDestruction {
nattach--
}
ds := &linux.ShmidDS{
ShmPerm: linux.IPCPerm{
Key: uint32(s.obj.Key),
UID: uint32(creds.UserNamespace.MapFromKUID(s.obj.Owner.UID)),
GID: uint32(creds.UserNamespace.MapFromKGID(s.obj.Owner.GID)),
CUID: uint32(creds.UserNamespace.MapFromKUID(s.obj.Creator.UID)),
CGID: uint32(creds.UserNamespace.MapFromKGID(s.obj.Creator.GID)),
Mode: mode | uint16(s.obj.Perms.LinuxMode()),
Seq: 0, // IPC sequences not supported.
},
ShmSegsz: s.size,
ShmAtime: s.attachTime.TimeT(),
ShmDtime: s.detachTime.TimeT(),
ShmCtime: s.changeTime.TimeT(),
ShmCpid: s.creatorPID,
ShmLpid: s.lastAttachDetachPID,
ShmNattach: nattach,
}
return ds, nil
}
// Set modifies attributes for a segment. See shmctl(IPC_SET).
func (s *Shm) Set(ctx context.Context, ds *linux.ShmidDS) error {
s.mu.Lock()
defer s.mu.Unlock()
creds := auth.CredentialsFromContext(ctx)
if !s.obj.CheckOwnership(creds) {
return linuxerr.EPERM
}
uid := creds.UserNamespace.MapToKUID(auth.UID(ds.ShmPerm.UID))
gid := creds.UserNamespace.MapToKGID(auth.GID(ds.ShmPerm.GID))
if !uid.Ok() || !gid.Ok() {
return linuxerr.EINVAL
}
// User may only modify the lower 9 bits of the mode. All the other bits are
// always 0 for the underlying inode.
mode := linux.FileMode(ds.ShmPerm.Mode & 0x1ff)
s.obj.Perms = fs.FilePermsFromMode(mode)
s.obj.Owner.UID = uid
s.obj.Owner.GID = gid
s.changeTime = ktime.NowFromContext(ctx)
return nil
}
// MarkDestroyed marks a segment for destruction. The segment is actually
// destroyed once it has no references. MarkDestroyed may be called multiple
// times, and is safe to call after a segment has already been destroyed. See
// shmctl(IPC_RMID).
func (s *Shm) MarkDestroyed(ctx context.Context) {
s.registry.dissociateKey(s)
s.mu.Lock()
if s.pendingDestruction {
s.mu.Unlock()
return
}
s.pendingDestruction = true
s.mu.Unlock()
// Drop the self-reference so destruction occurs when all
// external references are gone.
//
// N.B. This cannot be the final DecRef, as the caller also
// holds a reference.
s.DecRef(ctx)
return
}
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