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// Copyright 2018 Google LLC
//
// 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 gofer
import (
"fmt"
"sync"
"gvisor.googlesource.com/gvisor/pkg/p9"
"gvisor.googlesource.com/gvisor/pkg/refs"
"gvisor.googlesource.com/gvisor/pkg/sentry/context"
"gvisor.googlesource.com/gvisor/pkg/sentry/device"
"gvisor.googlesource.com/gvisor/pkg/sentry/fs"
"gvisor.googlesource.com/gvisor/pkg/sentry/fs/fsutil"
"gvisor.googlesource.com/gvisor/pkg/sentry/socket/unix/transport"
"gvisor.googlesource.com/gvisor/pkg/unet"
)
// +stateify savable
type endpointMaps struct {
// mu protexts the direntMap, the keyMap, and the pathMap below.
mu sync.RWMutex `state:"nosave"`
// direntMap links sockets to their dirents.
// It is filled concurrently with the keyMap and is stored upon save.
// Before saving, this map is used to populate the pathMap.
direntMap map[transport.BoundEndpoint]*fs.Dirent
// keyMap links MultiDeviceKeys (containing inode IDs) to their sockets.
// It is not stored during save because the inode ID may change upon restore.
keyMap map[device.MultiDeviceKey]transport.BoundEndpoint `state:"nosave"`
// pathMap links the sockets to their paths.
// It is filled before saving from the direntMap and is stored upon save.
// Upon restore, this map is used to re-populate the keyMap.
pathMap map[transport.BoundEndpoint]string
}
// add adds the endpoint to the maps.
// A reference is taken on the dirent argument.
//
// Precondition: maps must have been locked with 'lock'.
func (e *endpointMaps) add(key device.MultiDeviceKey, d *fs.Dirent, ep transport.BoundEndpoint) {
e.keyMap[key] = ep
d.IncRef()
e.direntMap[ep] = d
}
// remove deletes the key from the maps.
//
// Precondition: maps must have been locked with 'lock'.
func (e *endpointMaps) remove(key device.MultiDeviceKey) {
endpoint := e.get(key)
delete(e.keyMap, key)
d := e.direntMap[endpoint]
d.DecRef()
delete(e.direntMap, endpoint)
}
// lock blocks other addition and removal operations from happening while
// the backing file is being created or deleted. Returns a function that unlocks
// the endpoint map.
func (e *endpointMaps) lock() func() {
e.mu.Lock()
return func() { e.mu.Unlock() }
}
// get returns the endpoint mapped to the given key.
//
// Precondition: maps must have been locked for reading.
func (e *endpointMaps) get(key device.MultiDeviceKey) transport.BoundEndpoint {
return e.keyMap[key]
}
// session holds state for each 9p session established during sys_mount.
//
// +stateify savable
type session struct {
refs.AtomicRefCount
// conn is a unet.Socket that wraps the readFD/writeFD mount option,
// see fs/gofer/fs.go.
conn *unet.Socket `state:"nosave"`
// msize is the value of the msize mount option, see fs/gofer/fs.go.
msize uint32 `state:"wait"`
// version is the value of the version mount option, see fs/gofer/fs.go.
version string `state:"wait"`
// cachePolicy is the cache policy. It may be either cacheAll or cacheNone.
cachePolicy cachePolicy `state:"wait"`
// aname is the value of the aname mount option, see fs/gofer/fs.go.
aname string `state:"wait"`
// The client associated with this session. This will be initialized lazily.
client *p9.Client `state:"nosave"`
// The p9.File pointing to attachName via the client. This will be initialized
// lazily.
attach contextFile `state:"nosave"`
// Flags provided to the mount.
superBlockFlags fs.MountSourceFlags `state:"wait"`
// connID is a unique identifier for the session connection.
connID string `state:"wait"`
// inodeMappings contains mappings of fs.Inodes associated with this session
// to paths relative to the attach point, where inodeMappings is keyed by
// Inode.StableAttr.InodeID.
inodeMappings map[uint64]string `state:"wait"`
// mounter is the EUID/EGID that mounted this file system.
mounter fs.FileOwner `state:"wait"`
// endpoints is used to map inodes that represent socket files to their
// corresponding endpoint. Socket files are created as regular files in the
// gofer and their presence in this map indicate that they should indeed be
// socket files. This allows unix domain sockets to be used with paths that
// belong to a gofer.
//
// TODO: there are few possible races with someone stat'ing the
// file and another deleting it concurrently, where the file will not be
// reported as socket file.
endpoints *endpointMaps `state:"wait"`
}
// Destroy tears down the session.
func (s *session) Destroy() {
s.conn.Close()
}
// Revalidate implements MountSource.Revalidate.
func (s *session) Revalidate(ctx context.Context, name string, parent, child *fs.Inode) bool {
return s.cachePolicy.revalidate(ctx, name, parent, child)
}
// Keep implements MountSource.Keep.
func (s *session) Keep(d *fs.Dirent) bool {
return s.cachePolicy.keep(d)
}
// ResetInodeMappings implements fs.MountSourceOperations.ResetInodeMappings.
func (s *session) ResetInodeMappings() {
s.inodeMappings = make(map[uint64]string)
}
// SaveInodeMapping implements fs.MountSourceOperations.SaveInodeMapping.
func (s *session) SaveInodeMapping(inode *fs.Inode, path string) {
// This is very unintuitive. We *CANNOT* trust the inode's StableAttrs,
// because overlay copyUp may have changed them out from under us.
// So much for "immutable".
sattr := inode.InodeOperations.(*inodeOperations).fileState.sattr
s.inodeMappings[sattr.InodeID] = path
}
// newInodeOperations creates a new 9p fs.InodeOperations backed by a p9.File and attributes
// (p9.QID, p9.AttrMask, p9.Attr).
//
// Endpoints lock must not be held if socket == false.
func newInodeOperations(ctx context.Context, s *session, file contextFile, qid p9.QID, valid p9.AttrMask, attr p9.Attr, socket bool) (fs.StableAttr, *inodeOperations) {
deviceKey := device.MultiDeviceKey{
Device: attr.RDev,
SecondaryDevice: s.connID,
Inode: qid.Path,
}
sattr := fs.StableAttr{
Type: ntype(attr),
DeviceID: goferDevice.DeviceID(),
InodeID: goferDevice.Map(deviceKey),
BlockSize: bsize(attr),
}
if s.endpoints != nil {
if socket {
sattr.Type = fs.Socket
} else {
// If unix sockets are allowed on this filesystem, check if this file is
// supposed to be a socket file.
unlock := s.endpoints.lock()
if s.endpoints.get(deviceKey) != nil {
sattr.Type = fs.Socket
}
unlock()
}
}
fileState := &inodeFileState{
s: s,
file: file,
sattr: sattr,
key: deviceKey,
}
uattr := unstable(ctx, valid, attr, s.mounter, s.client)
return sattr, &inodeOperations{
fileState: fileState,
cachingInodeOps: fsutil.NewCachingInodeOperations(ctx, fileState, uattr, s.superBlockFlags.ForcePageCache),
}
}
// Root returns the root of a 9p mount. This mount is bound to a 9p server
// based on conn. Otherwise configuration parameters are:
//
// * dev: connection id
// * filesystem: the filesystem backing the mount
// * superBlockFlags: the mount flags describing general mount options
// * opts: parsed 9p mount options
func Root(ctx context.Context, dev string, filesystem fs.Filesystem, superBlockFlags fs.MountSourceFlags, o opts) (*fs.Inode, error) {
// The mounting EUID/EGID will be cached by this file system. This will
// be used to assign ownership to files that the Gofer owns.
mounter := fs.FileOwnerFromContext(ctx)
conn, err := unet.NewSocket(o.fd)
if err != nil {
return nil, err
}
// Construct the session.
s := &session{
connID: dev,
conn: conn,
msize: o.msize,
version: o.version,
cachePolicy: o.policy,
aname: o.aname,
superBlockFlags: superBlockFlags,
mounter: mounter,
}
if o.privateunixsocket {
s.endpoints = newEndpointMaps()
}
// Construct the MountSource with the session and superBlockFlags.
m := fs.NewMountSource(s, filesystem, superBlockFlags)
// Send the Tversion request.
s.client, err = p9.NewClient(s.conn, s.msize, s.version)
if err != nil {
// Drop our reference on the session, it needs to be torn down.
s.DecRef()
return nil, err
}
// Notify that we're about to call the Gofer and block.
ctx.UninterruptibleSleepStart(false)
// Send the Tattach request.
s.attach.file, err = s.client.Attach(s.aname)
ctx.UninterruptibleSleepFinish(false)
if err != nil {
// Same as above.
s.DecRef()
return nil, err
}
qid, valid, attr, err := s.attach.getAttr(ctx, p9.AttrMaskAll())
if err != nil {
s.attach.close(ctx)
// Same as above, but after we execute the Close request.
s.DecRef()
return nil, err
}
sattr, iops := newInodeOperations(ctx, s, s.attach, qid, valid, attr, false)
return fs.NewInode(iops, m, sattr), nil
}
// newEndpointMaps creates a new endpointMaps.
func newEndpointMaps() *endpointMaps {
return &endpointMaps{
direntMap: make(map[transport.BoundEndpoint]*fs.Dirent),
keyMap: make(map[device.MultiDeviceKey]transport.BoundEndpoint),
pathMap: make(map[transport.BoundEndpoint]string),
}
}
// fillKeyMap populates key and dirent maps upon restore from saved
// pathmap.
func (s *session) fillKeyMap(ctx context.Context) error {
unlock := s.endpoints.lock()
defer unlock()
for ep, dirPath := range s.endpoints.pathMap {
_, file, err := s.attach.walk(ctx, splitAbsolutePath(dirPath))
if err != nil {
return fmt.Errorf("error filling endpointmaps, failed to walk to %q: %v", dirPath, err)
}
qid, _, attr, err := file.getAttr(ctx, p9.AttrMaskAll())
if err != nil {
return fmt.Errorf("failed to get file attributes of %s: %v", dirPath, err)
}
key := device.MultiDeviceKey{
Device: attr.RDev,
SecondaryDevice: s.connID,
Inode: qid.Path,
}
s.endpoints.keyMap[key] = ep
}
return nil
}
// fillPathMap populates paths for endpoints from dirents in direntMap
// before save.
func (s *session) fillPathMap() error {
unlock := s.endpoints.lock()
defer unlock()
for ep, dir := range s.endpoints.direntMap {
mountRoot := dir.MountRoot()
defer mountRoot.DecRef()
dirPath, _ := dir.FullName(mountRoot)
if dirPath == "" {
return fmt.Errorf("error getting path from dirent")
}
s.endpoints.pathMap[ep] = dirPath
}
return nil
}
// restoreEndpointMaps recreates and fills the key and dirent maps.
func (s *session) restoreEndpointMaps(ctx context.Context) error {
// When restoring, only need to create the keyMap because the dirent and path
// maps got stored through the save.
s.endpoints.keyMap = make(map[device.MultiDeviceKey]transport.BoundEndpoint)
if err := s.fillKeyMap(ctx); err != nil {
return fmt.Errorf("failed to insert sockets into endpoint map: %v", err)
}
// Re-create pathMap because it can no longer be trusted as socket paths can
// change while process continues to run. Empty pathMap will be re-filled upon
// next save.
s.endpoints.pathMap = make(map[transport.BoundEndpoint]string)
return nil
}
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