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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 p9
import (
"io"
"runtime/debug"
"sync/atomic"
"golang.org/x/sys/unix"
"gvisor.dev/gvisor/pkg/errors/linuxerr"
"gvisor.dev/gvisor/pkg/fd"
"gvisor.dev/gvisor/pkg/fdchannel"
"gvisor.dev/gvisor/pkg/flipcall"
"gvisor.dev/gvisor/pkg/log"
"gvisor.dev/gvisor/pkg/sync"
"gvisor.dev/gvisor/pkg/unet"
)
// Server is a 9p2000.L server.
type Server struct {
// attacher provides the attach function.
attacher Attacher
options AttacherOptions
// pathTree is the full set of paths opened on this server.
//
// These may be across different connections, but rename operations
// must be serialized globally for safely. There is a single pathTree
// for the entire server, and not per connection.
pathTree *pathNode
// renameMu is a global lock protecting rename operations. With this
// lock, we can be certain that any given rename operation can safely
// acquire two path nodes in any order, as all other concurrent
// operations acquire at most a single node.
renameMu sync.RWMutex
}
// NewServer returns a new server. attacher may be nil.
func NewServer(attacher Attacher) *Server {
opts := AttacherOptions{}
if attacher != nil {
opts = attacher.ServerOptions()
}
return &Server{
attacher: attacher,
options: opts,
pathTree: newPathNode(),
}
}
// connState is the state for a single connection.
type connState struct {
// server is the backing server.
server *Server
// fids is the set of active FIDs.
//
// This is used to find FIDs for files.
fidMu sync.Mutex
fids map[FID]*fidRef
// tags is the set of active tags.
//
// The given channel is closed when the
// tag is finished with processing.
tagMu sync.Mutex
tags map[Tag]chan struct{}
// messageSize is the maximum message size. The server does not
// do automatic splitting of messages.
messageSize uint32
// version is the agreed upon version X of 9P2000.L.Google.X.
// version 0 implies 9P2000.L.
version uint32
// reqGate counts requests that are still being handled.
reqGate sync.Gate
// -- below relates to the legacy handler --
// recvMu serializes receiving from conn.
recvMu sync.Mutex
// recvIdle is the number of goroutines in handleRequests() attempting to
// lock recvMu so that they can receive from conn. recvIdle is accessed
// using atomic memory operations.
recvIdle int32
// If recvShutdown is true, at least one goroutine has observed a
// connection error while receiving from conn, and all goroutines in
// handleRequests() should exit immediately. recvShutdown is protected by
// recvMu.
recvShutdown bool
// sendMu serializes sending to conn.
sendMu sync.Mutex
// conn is the connection used by the legacy transport.
conn *unet.Socket
// -- below relates to the flipcall handler --
// channelMu protects below.
channelMu sync.Mutex
// channelWg represents active workers.
channelWg sync.WaitGroup
// channelAlloc allocates channel memory.
channelAlloc *flipcall.PacketWindowAllocator
// channels are the set of initialized channels.
channels []*channel
}
// fidRef wraps a node and tracks references.
type fidRef struct {
// server is the associated server.
server *Server
// file is the associated File.
file File
// refs is an active refence count.
//
// The node above will be closed only when refs reaches zero.
refs int64
// opened indicates whether this has been opened already.
//
// This is updated in handlers.go.
//
// opened is protected by pathNode.opMu or renameMu (for write).
opened bool
// mode is the fidRef's mode from the walk. Only the type bits are
// valid, the permissions may change. This is used to sanity check
// operations on this element, and prevent walks across
// non-directories.
mode FileMode
// openFlags is the mode used in the open.
//
// This is updated in handlers.go.
//
// openFlags is protected by pathNode.opMu or renameMu (for write).
openFlags OpenFlags
// pathNode is the current pathNode for this FID.
pathNode *pathNode
// parent is the parent fidRef. We hold on to a parent reference to
// ensure that hooks, such as Renamed, can be executed safely by the
// server code.
//
// Note that parent cannot be changed without holding both the global
// rename lock and a writable lock on the associated pathNode for this
// fidRef. Holding either of these locks is sufficient to examine
// parent safely.
//
// The parent will be nil for root fidRefs, and non-nil otherwise. The
// method maybeParent can be used to return a cyclical reference, and
// isRoot should be used to check for root over looking at parent
// directly.
parent *fidRef
// deleted indicates that the backing file has been deleted. We stop
// many operations at the API level if they are incompatible with a
// file that has already been unlinked.
deleted uint32
}
// IncRef increases the references on a fid.
func (f *fidRef) IncRef() {
atomic.AddInt64(&f.refs, 1)
}
// DecRef should be called when you're finished with a fid.
func (f *fidRef) DecRef() {
if atomic.AddInt64(&f.refs, -1) == 0 {
f.file.Close()
// Drop the parent reference.
//
// Since this fidRef is guaranteed to be non-discoverable when
// the references reach zero, we don't need to worry about
// clearing the parent.
if f.parent != nil {
// If we've been previously deleted, this removing this
// ref is a no-op. That's expected.
f.parent.pathNode.removeChild(f)
f.parent.DecRef()
}
}
}
// isDeleted returns true if this fidRef has been deleted.
func (f *fidRef) isDeleted() bool {
return atomic.LoadUint32(&f.deleted) != 0
}
// isRoot indicates whether this is a root fid.
func (f *fidRef) isRoot() bool {
return f.parent == nil
}
// maybeParent returns a cyclic reference for roots, and the parent otherwise.
func (f *fidRef) maybeParent() *fidRef {
if f.parent != nil {
return f.parent
}
return f // Root has itself.
}
// notifyDelete marks all fidRefs as deleted.
//
// Precondition: this must be called via safelyWrite or safelyGlobal.
func notifyDelete(pn *pathNode) {
// Call on all local references.
pn.forEachChildRef(func(ref *fidRef, _ string) {
atomic.StoreUint32(&ref.deleted, 1)
})
// Call on all subtrees.
pn.forEachChildNode(func(pn *pathNode) {
notifyDelete(pn)
})
}
// markChildDeleted marks all children below the given name as deleted.
//
// Precondition: this must be called via safelyWrite or safelyGlobal.
func (f *fidRef) markChildDeleted(name string) {
origPathNode := f.pathNode.removeWithName(name, func(ref *fidRef) {
atomic.StoreUint32(&ref.deleted, 1)
})
if origPathNode != nil {
// Mark all children as deleted.
notifyDelete(origPathNode)
}
}
// notifyNameChange calls the relevant Renamed method on all nodes in the path,
// recursively. Note that this applies only for subtrees, as these
// notifications do not apply to the actual file whose name has changed.
//
// Precondition: this must be called via safelyGlobal.
func notifyNameChange(pn *pathNode) {
// Call on all local references.
pn.forEachChildRef(func(ref *fidRef, name string) {
ref.file.Renamed(ref.parent.file, name)
})
// Call on all subtrees.
pn.forEachChildNode(func(pn *pathNode) {
notifyNameChange(pn)
})
}
// renameChildTo renames the given child to the target.
//
// Precondition: this must be called via safelyGlobal.
func (f *fidRef) renameChildTo(oldName string, target *fidRef, newName string) {
target.markChildDeleted(newName)
origPathNode := f.pathNode.removeWithName(oldName, func(ref *fidRef) {
// N.B. DecRef can take f.pathNode's parent's childMu. This is
// allowed because renameMu is held for write via safelyGlobal.
ref.parent.DecRef() // Drop original reference.
ref.parent = target // Change parent.
ref.parent.IncRef() // Acquire new one.
if f.pathNode == target.pathNode {
target.pathNode.addChildLocked(ref, newName)
} else {
target.pathNode.addChild(ref, newName)
}
ref.file.Renamed(target.file, newName)
})
if origPathNode != nil {
// Replace the previous (now deleted) path node.
target.pathNode.addPathNodeFor(newName, origPathNode)
// Call Renamed on all children.
notifyNameChange(origPathNode)
}
}
// safelyRead executes the given operation with the local path node locked.
// This implies that paths will not change during the operation.
func (f *fidRef) safelyRead(fn func() error) (err error) {
f.server.renameMu.RLock()
defer f.server.renameMu.RUnlock()
f.pathNode.opMu.RLock()
defer f.pathNode.opMu.RUnlock()
return fn()
}
// safelyWrite executes the given operation with the local path node locked in
// a writable fashion. This implies some paths may change.
func (f *fidRef) safelyWrite(fn func() error) (err error) {
f.server.renameMu.RLock()
defer f.server.renameMu.RUnlock()
f.pathNode.opMu.Lock()
defer f.pathNode.opMu.Unlock()
return fn()
}
// safelyGlobal executes the given operation with the global path lock held.
func (f *fidRef) safelyGlobal(fn func() error) (err error) {
f.server.renameMu.Lock()
defer f.server.renameMu.Unlock()
return fn()
}
// LookupFID finds the given FID.
//
// You should call fid.DecRef when you are finished using the fid.
func (cs *connState) LookupFID(fid FID) (*fidRef, bool) {
cs.fidMu.Lock()
defer cs.fidMu.Unlock()
fidRef, ok := cs.fids[fid]
if ok {
fidRef.IncRef()
return fidRef, true
}
return nil, false
}
// InsertFID installs the given FID.
//
// This fid starts with a reference count of one. If a FID exists in
// the slot already it is closed, per the specification.
func (cs *connState) InsertFID(fid FID, newRef *fidRef) {
cs.fidMu.Lock()
defer cs.fidMu.Unlock()
origRef, ok := cs.fids[fid]
if ok {
defer origRef.DecRef()
}
newRef.IncRef()
cs.fids[fid] = newRef
}
// DeleteFID removes the given FID.
//
// This simply removes it from the map and drops a reference.
func (cs *connState) DeleteFID(fid FID) bool {
cs.fidMu.Lock()
defer cs.fidMu.Unlock()
fidRef, ok := cs.fids[fid]
if !ok {
return false
}
delete(cs.fids, fid)
fidRef.DecRef()
return true
}
// StartTag starts handling the tag.
//
// False is returned if this tag is already active.
func (cs *connState) StartTag(t Tag) bool {
cs.tagMu.Lock()
defer cs.tagMu.Unlock()
_, ok := cs.tags[t]
if ok {
return false
}
cs.tags[t] = make(chan struct{})
return true
}
// ClearTag finishes handling a tag.
func (cs *connState) ClearTag(t Tag) {
cs.tagMu.Lock()
defer cs.tagMu.Unlock()
ch, ok := cs.tags[t]
if !ok {
// Should never happen.
panic("unused tag cleared")
}
delete(cs.tags, t)
// Notify.
close(ch)
}
// WaitTag waits for a tag to finish.
func (cs *connState) WaitTag(t Tag) {
cs.tagMu.Lock()
ch, ok := cs.tags[t]
cs.tagMu.Unlock()
if !ok {
return
}
// Wait for close.
<-ch
}
// initializeChannels initializes all channels.
//
// This is a no-op if channels are already initialized.
func (cs *connState) initializeChannels() (err error) {
cs.channelMu.Lock()
defer cs.channelMu.Unlock()
// Initialize our channel allocator.
if cs.channelAlloc == nil {
alloc, err := flipcall.NewPacketWindowAllocator()
if err != nil {
return err
}
cs.channelAlloc = alloc
}
// Create all the channels.
for len(cs.channels) < channelsPerClient {
res := &channel{
done: make(chan struct{}),
}
res.desc, err = cs.channelAlloc.Allocate(channelSize)
if err != nil {
return err
}
if err := res.data.Init(flipcall.ServerSide, res.desc); err != nil {
return err
}
socks, err := fdchannel.NewConnectedSockets()
if err != nil {
res.data.Destroy() // Cleanup.
return err
}
res.fds.Init(socks[0])
res.client = fd.New(socks[1])
cs.channels = append(cs.channels, res)
// Start servicing the channel.
//
// When we call stop, we will close all the channels and these
// routines should finish. We need the wait group to ensure
// that active handlers are actually finished before cleanup.
cs.channelWg.Add(1)
go func() { // S/R-SAFE: Server side.
defer cs.channelWg.Done()
if err := res.service(cs); err != nil {
// Don't log flipcall.ShutdownErrors, which we expect to be
// returned during server shutdown.
if _, ok := err.(flipcall.ShutdownError); !ok {
log.Warningf("p9.channel.service: %v", err)
}
}
}()
}
return nil
}
// lookupChannel looks up the channel with given id.
//
// The function returns nil if no such channel is available.
func (cs *connState) lookupChannel(id uint32) *channel {
cs.channelMu.Lock()
defer cs.channelMu.Unlock()
if id >= uint32(len(cs.channels)) {
return nil
}
return cs.channels[id]
}
// handle handles a single message.
func (cs *connState) handle(m message) (r message) {
if !cs.reqGate.Enter() {
// connState.stop() has been called; the connection is shutting down.
r = newErrFromLinuxerr(linuxerr.ECONNRESET)
return
}
defer func() {
cs.reqGate.Leave()
if r == nil {
// Don't allow a panic to propagate.
err := recover()
// Include a useful log message.
log.Warningf("panic in handler: %v\n%s", err, debug.Stack())
// Wrap in an EFAULT error; we don't really have a
// better way to describe this kind of error. It will
// usually manifest as a result of the test framework.
r = newErrFromLinuxerr(linuxerr.EFAULT)
}
}()
if handler, ok := m.(handler); ok {
// Call the message handler.
r = handler.handle(cs)
// TODO(b/34162363):This is only here to make sure the server works with
// only linuxerr Errors, as the handlers work with both client and server.
// It will be removed a followup, when all the unix.Errno errors are
// replaced with linuxerr.
if rlError, ok := r.(*Rlerror); ok {
e := linuxerr.ErrorFromUnix(unix.Errno(rlError.Error))
r = newErrFromLinuxerr(e)
}
} else {
// Produce an ENOSYS error.
r = newErrFromLinuxerr(linuxerr.ENOSYS)
}
return
}
// handleRequest handles a single request. It returns true if the caller should
// continue handling requests and false if it should terminate.
func (cs *connState) handleRequest() bool {
// Obtain the right to receive a message from cs.conn.
atomic.AddInt32(&cs.recvIdle, 1)
cs.recvMu.Lock()
atomic.AddInt32(&cs.recvIdle, -1)
if cs.recvShutdown {
// Another goroutine already detected a connection problem; exit
// immediately.
cs.recvMu.Unlock()
return false
}
messageSize := atomic.LoadUint32(&cs.messageSize)
if messageSize == 0 {
// Default or not yet negotiated.
messageSize = maximumLength
}
// Receive a message.
tag, m, err := recv(cs.conn, messageSize, msgRegistry.get)
if errSocket, ok := err.(ErrSocket); ok {
// Connection problem; stop serving.
log.Debugf("p9.recv: %v", errSocket.error)
cs.recvShutdown = true
cs.recvMu.Unlock()
return false
}
// Ensure that another goroutine is available to receive from cs.conn.
if atomic.LoadInt32(&cs.recvIdle) == 0 {
go cs.handleRequests() // S/R-SAFE: Irrelevant.
}
cs.recvMu.Unlock()
// Deal with other errors.
if err != nil && err != io.EOF {
// If it's not a connection error, but some other protocol error,
// we can send a response immediately.
cs.sendMu.Lock()
err := send(cs.conn, tag, newErrFromLinuxerr(err))
cs.sendMu.Unlock()
if err != nil {
log.Debugf("p9.send: %v", err)
}
return true
}
// Try to start the tag.
if !cs.StartTag(tag) {
// Nothing we can do at this point; client is bogus.
log.Debugf("no valid tag [%05d]", tag)
return true
}
// Handle the message.
r := cs.handle(m)
// Clear the tag before sending. That's because as soon as this hits
// the wire, the client can legally send the same tag.
cs.ClearTag(tag)
// Send back the result.
cs.sendMu.Lock()
err = send(cs.conn, tag, r)
cs.sendMu.Unlock()
if err != nil {
log.Debugf("p9.send: %v", err)
}
// Return the message to the cache.
msgRegistry.put(m)
return true
}
func (cs *connState) handleRequests() {
for {
if !cs.handleRequest() {
return
}
}
}
func (cs *connState) stop() {
// Stop new requests from proceeding, and wait for completion of all
// inflight requests. This is mostly so that if a request is stuck, the
// sandbox supervisor has the opportunity to kill us with SIGABRT to get a
// stack dump of the offending handler.
cs.reqGate.Close()
// Free the channels.
cs.channelMu.Lock()
for _, ch := range cs.channels {
ch.Shutdown()
}
cs.channelWg.Wait()
for _, ch := range cs.channels {
ch.Close()
}
cs.channels = nil // Clear.
cs.channelMu.Unlock()
// Free the channel memory.
if cs.channelAlloc != nil {
cs.channelAlloc.Destroy()
}
// Ensure the connection is closed.
cs.conn.Close()
// Close all remaining fids.
for fid, fidRef := range cs.fids {
delete(cs.fids, fid)
// Drop final reference in the FID table. Note this should
// always close the file, since we've ensured that there are no
// handlers running via the wait for Pending => 0 below.
fidRef.DecRef()
}
}
// Handle handles a single connection.
func (s *Server) Handle(conn *unet.Socket) error {
cs := &connState{
server: s,
fids: make(map[FID]*fidRef),
tags: make(map[Tag]chan struct{}),
conn: conn,
}
defer cs.stop()
// Serve requests from conn in the current goroutine; handleRequests() will
// create more goroutines as needed.
cs.handleRequests()
return nil
}
// Serve handles requests from the bound socket.
//
// The passed serverSocket _must_ be created in packet mode.
func (s *Server) Serve(serverSocket *unet.ServerSocket) error {
var wg sync.WaitGroup
defer wg.Wait()
for {
conn, err := serverSocket.Accept()
if err != nil {
// Something went wrong.
//
// Socket closed?
return err
}
wg.Add(1)
go func(conn *unet.Socket) { // S/R-SAFE: Irrelevant.
s.Handle(conn)
wg.Done()
}(conn)
}
}
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