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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 mm
import (
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/context"
"gvisor.dev/gvisor/pkg/refs"
"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"
"gvisor.dev/gvisor/pkg/usermem"
)
// aioManager creates and manages asynchronous I/O contexts.
//
// +stateify savable
type aioManager struct {
// mu protects below.
mu sync.Mutex `state:"nosave"`
// aioContexts is the set of asynchronous I/O contexts.
contexts map[uint64]*AIOContext
}
func (a *aioManager) destroy() {
a.mu.Lock()
defer a.mu.Unlock()
for _, ctx := range a.contexts {
ctx.destroy()
}
}
// newAIOContext creates a new context for asynchronous I/O.
//
// Returns false if 'id' is currently in use.
func (a *aioManager) newAIOContext(events uint32, id uint64) bool {
a.mu.Lock()
defer a.mu.Unlock()
if _, ok := a.contexts[id]; ok {
return false
}
a.contexts[id] = &AIOContext{
requestReady: make(chan struct{}, 1),
maxOutstanding: events,
}
return true
}
// destroyAIOContext destroys an asynchronous I/O context. It doesn't wait for
// for pending requests to complete. Returns the destroyed AIOContext so it can
// be drained.
//
// Nil is returned if the context does not exist.
func (a *aioManager) destroyAIOContext(id uint64) *AIOContext {
a.mu.Lock()
defer a.mu.Unlock()
ctx, ok := a.contexts[id]
if !ok {
return nil
}
delete(a.contexts, id)
ctx.destroy()
return ctx
}
// lookupAIOContext looks up the given context.
//
// Returns false if context does not exist.
func (a *aioManager) lookupAIOContext(id uint64) (*AIOContext, bool) {
a.mu.Lock()
defer a.mu.Unlock()
ctx, ok := a.contexts[id]
return ctx, ok
}
// ioResult is a completed I/O operation.
//
// +stateify savable
type ioResult struct {
data interface{}
ioEntry
}
// AIOContext is a single asynchronous I/O context.
//
// +stateify savable
type AIOContext struct {
// requestReady is the notification channel used for all requests.
requestReady chan struct{} `state:"nosave"`
// mu protects below.
mu sync.Mutex `state:"nosave"`
// results is the set of completed requests.
results ioList
// maxOutstanding is the maximum number of outstanding entries; this value
// is immutable.
maxOutstanding uint32
// outstanding is the number of requests outstanding; this will effectively
// be the number of entries in the result list or that are expected to be
// added to the result list.
outstanding uint32
// dead is set when the context is destroyed.
dead bool `state:"zerovalue"`
}
// destroy marks the context dead.
func (ctx *AIOContext) destroy() {
ctx.mu.Lock()
defer ctx.mu.Unlock()
ctx.dead = true
ctx.checkForDone()
}
// Preconditions: ctx.mu must be held by caller.
func (ctx *AIOContext) checkForDone() {
if ctx.dead && ctx.outstanding == 0 {
close(ctx.requestReady)
ctx.requestReady = nil
}
}
// Prepare reserves space for a new request, returning true if available.
// Returns false if the context is busy.
func (ctx *AIOContext) Prepare() bool {
ctx.mu.Lock()
defer ctx.mu.Unlock()
if ctx.outstanding >= ctx.maxOutstanding {
return false
}
ctx.outstanding++
return true
}
// PopRequest pops a completed request if available, this function does not do
// any blocking. Returns false if no request is available.
func (ctx *AIOContext) PopRequest() (interface{}, bool) {
ctx.mu.Lock()
defer ctx.mu.Unlock()
// Is there anything ready?
if e := ctx.results.Front(); e != nil {
if ctx.outstanding == 0 {
panic("AIOContext outstanding is going negative")
}
ctx.outstanding--
ctx.results.Remove(e)
ctx.checkForDone()
return e.data, true
}
return nil, false
}
// FinishRequest finishes a pending request. It queues up the data
// and notifies listeners.
func (ctx *AIOContext) FinishRequest(data interface{}) {
ctx.mu.Lock()
defer ctx.mu.Unlock()
// Push to the list and notify opportunistically. The channel notify
// here is guaranteed to be safe because outstanding must be non-zero.
// The requestReady channel is only closed when outstanding reaches zero.
ctx.results.PushBack(&ioResult{data: data})
select {
case ctx.requestReady <- struct{}{}:
default:
}
}
// WaitChannel returns a channel that is notified when an AIO request is
// completed. Returns nil if the context is destroyed and there are no more
// outstanding requests.
func (ctx *AIOContext) WaitChannel() chan struct{} {
ctx.mu.Lock()
defer ctx.mu.Unlock()
return ctx.requestReady
}
// Dead returns true if the context has been destroyed.
func (ctx *AIOContext) Dead() bool {
ctx.mu.Lock()
defer ctx.mu.Unlock()
return ctx.dead
}
// CancelPendingRequest forgets about a request that hasn't yet completed.
func (ctx *AIOContext) CancelPendingRequest() {
ctx.mu.Lock()
defer ctx.mu.Unlock()
if ctx.outstanding == 0 {
panic("AIOContext outstanding is going negative")
}
ctx.outstanding--
ctx.checkForDone()
}
// Drain drops all completed requests. Pending requests remain untouched.
func (ctx *AIOContext) Drain() {
ctx.mu.Lock()
defer ctx.mu.Unlock()
if ctx.outstanding == 0 {
return
}
size := uint32(ctx.results.Len())
if ctx.outstanding < size {
panic("AIOContext outstanding is going negative")
}
ctx.outstanding -= size
ctx.results.Reset()
ctx.checkForDone()
}
// aioMappable implements memmap.MappingIdentity and memmap.Mappable for AIO
// ring buffers.
//
// +stateify savable
type aioMappable struct {
refs.AtomicRefCount
mfp pgalloc.MemoryFileProvider
fr memmap.FileRange
}
var aioRingBufferSize = uint64(usermem.Addr(linux.AIORingSize).MustRoundUp())
func newAIOMappable(mfp pgalloc.MemoryFileProvider) (*aioMappable, error) {
fr, err := mfp.MemoryFile().Allocate(aioRingBufferSize, usage.Anonymous)
if err != nil {
return nil, err
}
m := aioMappable{mfp: mfp, fr: fr}
m.EnableLeakCheck("mm.aioMappable")
return &m, nil
}
// DecRef implements refs.RefCounter.DecRef.
func (m *aioMappable) DecRef(ctx context.Context) {
m.AtomicRefCount.DecRefWithDestructor(ctx, func(context.Context) {
m.mfp.MemoryFile().DecRef(m.fr)
})
}
// MappedName implements memmap.MappingIdentity.MappedName.
func (m *aioMappable) MappedName(ctx context.Context) string {
return "[aio]"
}
// DeviceID implements memmap.MappingIdentity.DeviceID.
func (m *aioMappable) DeviceID() uint64 {
return 0
}
// InodeID implements memmap.MappingIdentity.InodeID.
func (m *aioMappable) InodeID() uint64 {
return 0
}
// Msync implements memmap.MappingIdentity.Msync.
func (m *aioMappable) Msync(ctx context.Context, mr memmap.MappableRange) error {
// Linux: aio_ring_fops.fsync == NULL
return syserror.EINVAL
}
// AddMapping implements memmap.Mappable.AddMapping.
func (m *aioMappable) AddMapping(_ context.Context, _ memmap.MappingSpace, ar usermem.AddrRange, offset uint64, _ bool) error {
// Don't allow mappings to be expanded (in Linux, fs/aio.c:aio_ring_mmap()
// sets VM_DONTEXPAND).
if offset != 0 || uint64(ar.Length()) != aioRingBufferSize {
return syserror.EFAULT
}
return nil
}
// RemoveMapping implements memmap.Mappable.RemoveMapping.
func (m *aioMappable) RemoveMapping(context.Context, memmap.MappingSpace, usermem.AddrRange, uint64, bool) {
}
// CopyMapping implements memmap.Mappable.CopyMapping.
func (m *aioMappable) CopyMapping(ctx context.Context, ms memmap.MappingSpace, srcAR, dstAR usermem.AddrRange, offset uint64, _ bool) error {
// Don't allow mappings to be expanded (in Linux, fs/aio.c:aio_ring_mmap()
// sets VM_DONTEXPAND).
if offset != 0 || uint64(dstAR.Length()) != aioRingBufferSize {
return syserror.EFAULT
}
// Require that the mapping correspond to a live AIOContext. Compare
// Linux's fs/aio.c:aio_ring_mremap().
mm, ok := ms.(*MemoryManager)
if !ok {
return syserror.EINVAL
}
am := &mm.aioManager
am.mu.Lock()
defer am.mu.Unlock()
oldID := uint64(srcAR.Start)
aioCtx, ok := am.contexts[oldID]
if !ok {
return syserror.EINVAL
}
aioCtx.mu.Lock()
defer aioCtx.mu.Unlock()
if aioCtx.dead {
return syserror.EINVAL
}
// Use the new ID for the AIOContext.
am.contexts[uint64(dstAR.Start)] = aioCtx
delete(am.contexts, oldID)
return nil
}
// Translate implements memmap.Mappable.Translate.
func (m *aioMappable) Translate(ctx context.Context, required, optional memmap.MappableRange, at usermem.AccessType) ([]memmap.Translation, error) {
var err error
if required.End > m.fr.Length() {
err = &memmap.BusError{syserror.EFAULT}
}
if source := optional.Intersect(memmap.MappableRange{0, m.fr.Length()}); source.Length() != 0 {
return []memmap.Translation{
{
Source: source,
File: m.mfp.MemoryFile(),
Offset: m.fr.Start + source.Start,
Perms: usermem.AnyAccess,
},
}, err
}
return nil, err
}
// InvalidateUnsavable implements memmap.Mappable.InvalidateUnsavable.
func (m *aioMappable) InvalidateUnsavable(ctx context.Context) error {
return nil
}
// NewAIOContext creates a new context for asynchronous I/O.
//
// NewAIOContext is analogous to Linux's fs/aio.c:ioctx_alloc().
func (mm *MemoryManager) NewAIOContext(ctx context.Context, events uint32) (uint64, error) {
// libaio get_ioevents() expects context "handle" to be a valid address.
// libaio peeks inside looking for a magic number. This function allocates
// a page per context and keeps it set to zeroes to ensure it will not
// match AIO_RING_MAGIC and make libaio happy.
m, err := newAIOMappable(mm.mfp)
if err != nil {
return 0, err
}
defer m.DecRef(ctx)
addr, err := mm.MMap(ctx, memmap.MMapOpts{
Length: aioRingBufferSize,
MappingIdentity: m,
Mappable: m,
// Linux uses "do_mmap_pgoff(..., PROT_READ | PROT_WRITE, ...)" in
// fs/aio.c:aio_setup_ring(). Since we don't implement AIO_RING_MAGIC,
// user mode should not write to this page.
Perms: usermem.Read,
MaxPerms: usermem.Read,
})
if err != nil {
return 0, err
}
id := uint64(addr)
if !mm.aioManager.newAIOContext(events, id) {
mm.MUnmap(ctx, addr, aioRingBufferSize)
return 0, syserror.EINVAL
}
return id, nil
}
// DestroyAIOContext destroys an asynchronous I/O context. It returns the
// destroyed context. nil if the context does not exist.
func (mm *MemoryManager) DestroyAIOContext(ctx context.Context, id uint64) *AIOContext {
if _, ok := mm.LookupAIOContext(ctx, id); !ok {
return nil
}
// Only unmaps after it assured that the address is a valid aio context to
// prevent random memory from been unmapped.
//
// Note: It's possible to unmap this address and map something else into
// the same address. Then it would be unmapping memory that it doesn't own.
// This is, however, the way Linux implements AIO. Keeps the same [weird]
// semantics in case anyone relies on it.
mm.MUnmap(ctx, usermem.Addr(id), aioRingBufferSize)
return mm.aioManager.destroyAIOContext(id)
}
// LookupAIOContext looks up the given context. It returns false if the context
// does not exist.
func (mm *MemoryManager) LookupAIOContext(ctx context.Context, id uint64) (*AIOContext, bool) {
aioCtx, ok := mm.aioManager.lookupAIOContext(id)
if !ok {
return nil, false
}
// Protect against 'ids' that are inaccessible (Linux also reads 4 bytes
// from id).
var buf [4]byte
_, err := mm.CopyIn(ctx, usermem.Addr(id), buf[:], usermem.IOOpts{})
if err != nil {
return nil, false
}
return aioCtx, true
}
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