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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 (
"fmt"
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/context"
"gvisor.dev/gvisor/pkg/sentry/arch"
"gvisor.dev/gvisor/pkg/sentry/kernel/auth"
"gvisor.dev/gvisor/pkg/sentry/limits"
"gvisor.dev/gvisor/pkg/sentry/memmap"
"gvisor.dev/gvisor/pkg/syserror"
"gvisor.dev/gvisor/pkg/usermem"
)
// Preconditions: mm.mappingMu must be locked for writing. opts must be valid
// as defined by the checks in MMap.
func (mm *MemoryManager) createVMALocked(ctx context.Context, opts memmap.MMapOpts) (vmaIterator, usermem.AddrRange, error) {
if opts.MaxPerms != opts.MaxPerms.Effective() {
panic(fmt.Sprintf("Non-effective MaxPerms %s cannot be enforced", opts.MaxPerms))
}
// Find a usable range.
addr, err := mm.findAvailableLocked(opts.Length, findAvailableOpts{
Addr: opts.Addr,
Fixed: opts.Fixed,
Unmap: opts.Unmap,
Map32Bit: opts.Map32Bit,
})
if err != nil {
return vmaIterator{}, usermem.AddrRange{}, err
}
ar, _ := addr.ToRange(opts.Length)
// Check against RLIMIT_AS.
newUsageAS := mm.usageAS + opts.Length
if opts.Unmap {
newUsageAS -= uint64(mm.vmas.SpanRange(ar))
}
if limitAS := limits.FromContext(ctx).Get(limits.AS).Cur; newUsageAS > limitAS {
return vmaIterator{}, usermem.AddrRange{}, syserror.ENOMEM
}
if opts.MLockMode != memmap.MLockNone {
// Check against RLIMIT_MEMLOCK.
if creds := auth.CredentialsFromContext(ctx); !creds.HasCapabilityIn(linux.CAP_IPC_LOCK, creds.UserNamespace.Root()) {
mlockLimit := limits.FromContext(ctx).Get(limits.MemoryLocked).Cur
if mlockLimit == 0 {
return vmaIterator{}, usermem.AddrRange{}, syserror.EPERM
}
newLockedAS := mm.lockedAS + opts.Length
if opts.Unmap {
newLockedAS -= mm.mlockedBytesRangeLocked(ar)
}
if newLockedAS > mlockLimit {
return vmaIterator{}, usermem.AddrRange{}, syserror.EAGAIN
}
}
}
// Remove overwritten mappings. This ordering is consistent with Linux:
// compare Linux's mm/mmap.c:mmap_region() => do_munmap(),
// file->f_op->mmap().
var vgap vmaGapIterator
if opts.Unmap {
vgap = mm.unmapLocked(ctx, ar)
} else {
vgap = mm.vmas.FindGap(ar.Start)
}
// Inform the Mappable, if any, of the new mapping.
if opts.Mappable != nil {
// The expression for writable is vma.canWriteMappableLocked(), but we
// don't yet have a vma.
if err := opts.Mappable.AddMapping(ctx, mm, ar, opts.Offset, !opts.Private && opts.MaxPerms.Write); err != nil {
return vmaIterator{}, usermem.AddrRange{}, err
}
}
// Take a reference on opts.MappingIdentity before inserting the vma since
// vma merging can drop the reference.
if opts.MappingIdentity != nil {
opts.MappingIdentity.IncRef()
}
// Finally insert the vma.
v := vma{
mappable: opts.Mappable,
off: opts.Offset,
realPerms: opts.Perms,
effectivePerms: opts.Perms.Effective(),
maxPerms: opts.MaxPerms,
private: opts.Private,
growsDown: opts.GrowsDown,
mlockMode: opts.MLockMode,
numaPolicy: linux.MPOL_DEFAULT,
id: opts.MappingIdentity,
hint: opts.Hint,
}
vseg := mm.vmas.Insert(vgap, ar, v)
mm.usageAS += opts.Length
if v.isPrivateDataLocked() {
mm.dataAS += opts.Length
}
if opts.MLockMode != memmap.MLockNone {
mm.lockedAS += opts.Length
}
return vseg, ar, nil
}
type findAvailableOpts struct {
// These fields are equivalent to those in memmap.MMapOpts, except that:
//
// - Addr must be page-aligned.
//
// - Unmap allows existing guard pages in the returned range.
Addr usermem.Addr
Fixed bool
Unmap bool
Map32Bit bool
}
// map32Start/End are the bounds to which MAP_32BIT mappings are constrained,
// and are equivalent to Linux's MAP32_BASE and MAP32_MAX respectively.
const (
map32Start = 0x40000000
map32End = 0x80000000
)
// findAvailableLocked finds an allocatable range.
//
// Preconditions: mm.mappingMu must be locked.
func (mm *MemoryManager) findAvailableLocked(length uint64, opts findAvailableOpts) (usermem.Addr, error) {
if opts.Fixed {
opts.Map32Bit = false
}
allowedAR := mm.applicationAddrRange()
if opts.Map32Bit {
allowedAR = allowedAR.Intersect(usermem.AddrRange{map32Start, map32End})
}
// Does the provided suggestion work?
if ar, ok := opts.Addr.ToRange(length); ok {
if allowedAR.IsSupersetOf(ar) {
if opts.Unmap {
return ar.Start, nil
}
// Check for the presence of an existing vma or guard page.
if vgap := mm.vmas.FindGap(ar.Start); vgap.Ok() && vgap.availableRange().IsSupersetOf(ar) {
return ar.Start, nil
}
}
}
// Fixed mappings accept only the requested address.
if opts.Fixed {
return 0, syserror.ENOMEM
}
// Prefer hugepage alignment if a hugepage or more is requested.
alignment := uint64(usermem.PageSize)
if length >= usermem.HugePageSize {
alignment = usermem.HugePageSize
}
if opts.Map32Bit {
return mm.findLowestAvailableLocked(length, alignment, allowedAR)
}
if mm.layout.DefaultDirection == arch.MmapBottomUp {
return mm.findLowestAvailableLocked(length, alignment, usermem.AddrRange{mm.layout.BottomUpBase, mm.layout.MaxAddr})
}
return mm.findHighestAvailableLocked(length, alignment, usermem.AddrRange{mm.layout.MinAddr, mm.layout.TopDownBase})
}
func (mm *MemoryManager) applicationAddrRange() usermem.AddrRange {
return usermem.AddrRange{mm.layout.MinAddr, mm.layout.MaxAddr}
}
// Preconditions: mm.mappingMu must be locked.
func (mm *MemoryManager) findLowestAvailableLocked(length, alignment uint64, bounds usermem.AddrRange) (usermem.Addr, error) {
for gap := mm.vmas.LowerBoundGap(bounds.Start); gap.Ok() && gap.Start() < bounds.End; gap = gap.NextLargeEnoughGap(usermem.Addr(length)) {
if gr := gap.availableRange().Intersect(bounds); uint64(gr.Length()) >= length {
// Can we shift up to match the alignment?
if offset := uint64(gr.Start) % alignment; offset != 0 {
if uint64(gr.Length()) >= length+alignment-offset {
// Yes, we're aligned.
return gr.Start + usermem.Addr(alignment-offset), nil
}
}
// Either aligned perfectly, or can't align it.
return gr.Start, nil
}
}
return 0, syserror.ENOMEM
}
// Preconditions: mm.mappingMu must be locked.
func (mm *MemoryManager) findHighestAvailableLocked(length, alignment uint64, bounds usermem.AddrRange) (usermem.Addr, error) {
for gap := mm.vmas.UpperBoundGap(bounds.End); gap.Ok() && gap.End() > bounds.Start; gap = gap.PrevLargeEnoughGap(usermem.Addr(length)) {
if gr := gap.availableRange().Intersect(bounds); uint64(gr.Length()) >= length {
// Can we shift down to match the alignment?
start := gr.End - usermem.Addr(length)
if offset := uint64(start) % alignment; offset != 0 {
if gr.Start <= start-usermem.Addr(offset) {
// Yes, we're aligned.
return start - usermem.Addr(offset), nil
}
}
// Either aligned perfectly, or can't align it.
return start, nil
}
}
return 0, syserror.ENOMEM
}
// Preconditions: mm.mappingMu must be locked.
func (mm *MemoryManager) mlockedBytesRangeLocked(ar usermem.AddrRange) uint64 {
var total uint64
for vseg := mm.vmas.LowerBoundSegment(ar.Start); vseg.Ok() && vseg.Start() < ar.End; vseg = vseg.NextSegment() {
if vseg.ValuePtr().mlockMode != memmap.MLockNone {
total += uint64(vseg.Range().Intersect(ar).Length())
}
}
return total
}
// getVMAsLocked ensures that vmas exist for all addresses in ar, and support
// access of type (at, ignorePermissions). It returns:
//
// - An iterator to the vma containing ar.Start. If no vma contains ar.Start,
// the iterator is unspecified.
//
// - An iterator to the gap after the last vma containing an address in ar. If
// vmas exist for no addresses in ar, the iterator is to a gap that begins
// before ar.Start.
//
// - An error that is non-nil if vmas exist for only a subset of ar.
//
// Preconditions: mm.mappingMu must be locked for reading; it may be
// temporarily unlocked. ar.Length() != 0.
func (mm *MemoryManager) getVMAsLocked(ctx context.Context, ar usermem.AddrRange, at usermem.AccessType, ignorePermissions bool) (vmaIterator, vmaGapIterator, error) {
if checkInvariants {
if !ar.WellFormed() || ar.Length() <= 0 {
panic(fmt.Sprintf("invalid ar: %v", ar))
}
}
// Inline mm.vmas.LowerBoundSegment so that we have the preceding gap if
// !vbegin.Ok().
vbegin, vgap := mm.vmas.Find(ar.Start)
if !vbegin.Ok() {
vbegin = vgap.NextSegment()
// vseg.Ok() is checked before entering the following loop.
} else {
vgap = vbegin.PrevGap()
}
addr := ar.Start
vseg := vbegin
for vseg.Ok() {
// Loop invariants: vgap = vseg.PrevGap(); addr < vseg.End().
vma := vseg.ValuePtr()
if addr < vseg.Start() {
// TODO(jamieliu): Implement vma.growsDown here.
return vbegin, vgap, syserror.EFAULT
}
perms := vma.effectivePerms
if ignorePermissions {
perms = vma.maxPerms
}
if !perms.SupersetOf(at) {
return vbegin, vgap, syserror.EPERM
}
addr = vseg.End()
vgap = vseg.NextGap()
if addr >= ar.End {
return vbegin, vgap, nil
}
vseg = vgap.NextSegment()
}
// Ran out of vmas before ar.End.
return vbegin, vgap, syserror.EFAULT
}
// getVecVMAsLocked ensures that vmas exist for all addresses in ars, and
// support access to type of (at, ignorePermissions). It returns the subset of
// ars for which vmas exist. If this is not equal to ars, it returns a non-nil
// error explaining why.
//
// Preconditions: mm.mappingMu must be locked for reading; it may be
// temporarily unlocked.
//
// Postconditions: ars is not mutated.
func (mm *MemoryManager) getVecVMAsLocked(ctx context.Context, ars usermem.AddrRangeSeq, at usermem.AccessType, ignorePermissions bool) (usermem.AddrRangeSeq, error) {
for arsit := ars; !arsit.IsEmpty(); arsit = arsit.Tail() {
ar := arsit.Head()
if ar.Length() == 0 {
continue
}
if _, vend, err := mm.getVMAsLocked(ctx, ar, at, ignorePermissions); err != nil {
return truncatedAddrRangeSeq(ars, arsit, vend.Start()), err
}
}
return ars, nil
}
// vma extension will not shrink the number of unmapped bytes between the start
// of a growsDown vma and the end of its predecessor non-growsDown vma below
// guardBytes.
//
// guardBytes is equivalent to Linux's stack_guard_gap after upstream
// 1be7107fbe18 "mm: larger stack guard gap, between vmas".
const guardBytes = 256 * usermem.PageSize
// unmapLocked unmaps all addresses in ar and returns the resulting gap in
// mm.vmas.
//
// Preconditions: mm.mappingMu must be locked for writing. ar.Length() != 0.
// ar must be page-aligned.
func (mm *MemoryManager) unmapLocked(ctx context.Context, ar usermem.AddrRange) vmaGapIterator {
if checkInvariants {
if !ar.WellFormed() || ar.Length() <= 0 || !ar.IsPageAligned() {
panic(fmt.Sprintf("invalid ar: %v", ar))
}
}
// AddressSpace mappings and pmas must be invalidated before
// mm.removeVMAsLocked() => memmap.Mappable.RemoveMapping().
mm.Invalidate(ar, memmap.InvalidateOpts{InvalidatePrivate: true})
return mm.removeVMAsLocked(ctx, ar)
}
// removeVMAsLocked removes vmas for addresses in ar and returns the resulting
// gap in mm.vmas. It does not remove pmas or AddressSpace mappings; clients
// must do so before calling removeVMAsLocked.
//
// Preconditions: mm.mappingMu must be locked for writing. ar.Length() != 0. ar
// must be page-aligned.
func (mm *MemoryManager) removeVMAsLocked(ctx context.Context, ar usermem.AddrRange) vmaGapIterator {
if checkInvariants {
if !ar.WellFormed() || ar.Length() <= 0 || !ar.IsPageAligned() {
panic(fmt.Sprintf("invalid ar: %v", ar))
}
}
vseg, vgap := mm.vmas.Find(ar.Start)
if vgap.Ok() {
vseg = vgap.NextSegment()
}
for vseg.Ok() && vseg.Start() < ar.End {
vseg = mm.vmas.Isolate(vseg, ar)
vmaAR := vseg.Range()
vma := vseg.ValuePtr()
if vma.mappable != nil {
vma.mappable.RemoveMapping(ctx, mm, vmaAR, vma.off, vma.canWriteMappableLocked())
}
if vma.id != nil {
vma.id.DecRef(ctx)
}
mm.usageAS -= uint64(vmaAR.Length())
if vma.isPrivateDataLocked() {
mm.dataAS -= uint64(vmaAR.Length())
}
if vma.mlockMode != memmap.MLockNone {
mm.lockedAS -= uint64(vmaAR.Length())
}
vgap = mm.vmas.Remove(vseg)
vseg = vgap.NextSegment()
}
return vgap
}
// canWriteMappableLocked returns true if it is possible for vma.mappable to be
// written to via this vma, i.e. if it is possible that
// vma.mappable.Translate(at.Write=true) may be called as a result of this vma.
// This includes via I/O with usermem.IOOpts.IgnorePermissions = true, such as
// PTRACE_POKEDATA.
//
// canWriteMappableLocked is equivalent to Linux's VM_SHARED.
//
// Preconditions: mm.mappingMu must be locked.
func (vma *vma) canWriteMappableLocked() bool {
return !vma.private && vma.maxPerms.Write
}
// isPrivateDataLocked identify the data segments - private, writable, not stack
//
// Preconditions: mm.mappingMu must be locked.
func (vma *vma) isPrivateDataLocked() bool {
return vma.realPerms.Write && vma.private && !vma.growsDown
}
// vmaSetFunctions implements segment.Functions for vmaSet.
type vmaSetFunctions struct{}
func (vmaSetFunctions) MinKey() usermem.Addr {
return 0
}
func (vmaSetFunctions) MaxKey() usermem.Addr {
return ^usermem.Addr(0)
}
func (vmaSetFunctions) ClearValue(vma *vma) {
vma.mappable = nil
vma.id = nil
vma.hint = ""
}
func (vmaSetFunctions) Merge(ar1 usermem.AddrRange, vma1 vma, ar2 usermem.AddrRange, vma2 vma) (vma, bool) {
if vma1.mappable != vma2.mappable ||
(vma1.mappable != nil && vma1.off+uint64(ar1.Length()) != vma2.off) ||
vma1.realPerms != vma2.realPerms ||
vma1.maxPerms != vma2.maxPerms ||
vma1.private != vma2.private ||
vma1.growsDown != vma2.growsDown ||
vma1.mlockMode != vma2.mlockMode ||
vma1.numaPolicy != vma2.numaPolicy ||
vma1.numaNodemask != vma2.numaNodemask ||
vma1.dontfork != vma2.dontfork ||
vma1.id != vma2.id ||
vma1.hint != vma2.hint {
return vma{}, false
}
if vma2.id != nil {
vma2.id.DecRef(context.Background())
}
return vma1, true
}
func (vmaSetFunctions) Split(ar usermem.AddrRange, v vma, split usermem.Addr) (vma, vma) {
v2 := v
if v2.mappable != nil {
v2.off += uint64(split - ar.Start)
}
if v2.id != nil {
v2.id.IncRef()
}
return v, v2
}
// Preconditions: vseg.ValuePtr().mappable != nil. vseg.Range().Contains(addr).
func (vseg vmaIterator) mappableOffsetAt(addr usermem.Addr) uint64 {
if checkInvariants {
if !vseg.Ok() {
panic("terminal vma iterator")
}
if vseg.ValuePtr().mappable == nil {
panic("Mappable offset is meaningless for anonymous vma")
}
if !vseg.Range().Contains(addr) {
panic(fmt.Sprintf("addr %v out of bounds %v", addr, vseg.Range()))
}
}
vma := vseg.ValuePtr()
vstart := vseg.Start()
return vma.off + uint64(addr-vstart)
}
// Preconditions: vseg.ValuePtr().mappable != nil.
func (vseg vmaIterator) mappableRange() memmap.MappableRange {
return vseg.mappableRangeOf(vseg.Range())
}
// Preconditions: vseg.ValuePtr().mappable != nil.
// vseg.Range().IsSupersetOf(ar). ar.Length() != 0.
func (vseg vmaIterator) mappableRangeOf(ar usermem.AddrRange) memmap.MappableRange {
if checkInvariants {
if !vseg.Ok() {
panic("terminal vma iterator")
}
if vseg.ValuePtr().mappable == nil {
panic("MappableRange is meaningless for anonymous vma")
}
if !ar.WellFormed() || ar.Length() <= 0 {
panic(fmt.Sprintf("invalid ar: %v", ar))
}
if !vseg.Range().IsSupersetOf(ar) {
panic(fmt.Sprintf("ar %v out of bounds %v", ar, vseg.Range()))
}
}
vma := vseg.ValuePtr()
vstart := vseg.Start()
return memmap.MappableRange{vma.off + uint64(ar.Start-vstart), vma.off + uint64(ar.End-vstart)}
}
// Preconditions: vseg.ValuePtr().mappable != nil.
// vseg.mappableRange().IsSupersetOf(mr). mr.Length() != 0.
func (vseg vmaIterator) addrRangeOf(mr memmap.MappableRange) usermem.AddrRange {
if checkInvariants {
if !vseg.Ok() {
panic("terminal vma iterator")
}
if vseg.ValuePtr().mappable == nil {
panic("MappableRange is meaningless for anonymous vma")
}
if !mr.WellFormed() || mr.Length() <= 0 {
panic(fmt.Sprintf("invalid mr: %v", mr))
}
if !vseg.mappableRange().IsSupersetOf(mr) {
panic(fmt.Sprintf("mr %v out of bounds %v", mr, vseg.mappableRange()))
}
}
vma := vseg.ValuePtr()
vstart := vseg.Start()
return usermem.AddrRange{vstart + usermem.Addr(mr.Start-vma.off), vstart + usermem.Addr(mr.End-vma.off)}
}
// seekNextLowerBound returns mm.vmas.LowerBoundSegment(addr), but does so by
// scanning linearly forward from vseg.
//
// Preconditions: mm.mappingMu must be locked. addr >= vseg.Start().
func (vseg vmaIterator) seekNextLowerBound(addr usermem.Addr) vmaIterator {
if checkInvariants {
if !vseg.Ok() {
panic("terminal vma iterator")
}
if addr < vseg.Start() {
panic(fmt.Sprintf("can't seek forward to %#x from %#x", addr, vseg.Start()))
}
}
for vseg.Ok() && addr >= vseg.End() {
vseg = vseg.NextSegment()
}
return vseg
}
// availableRange returns the subset of vgap.Range() in which new vmas may be
// created without MMapOpts.Unmap == true.
func (vgap vmaGapIterator) availableRange() usermem.AddrRange {
ar := vgap.Range()
next := vgap.NextSegment()
if !next.Ok() || !next.ValuePtr().growsDown {
return ar
}
// Exclude guard pages.
if ar.Length() < guardBytes {
return usermem.AddrRange{ar.Start, ar.Start}
}
ar.End -= guardBytes
return ar
}
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