// 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 mm import ( "fmt" mrand "math/rand" "gvisor.googlesource.com/gvisor/pkg/abi/linux" "gvisor.googlesource.com/gvisor/pkg/sentry/context" "gvisor.googlesource.com/gvisor/pkg/sentry/kernel/auth" "gvisor.googlesource.com/gvisor/pkg/sentry/kernel/futex" "gvisor.googlesource.com/gvisor/pkg/sentry/limits" "gvisor.googlesource.com/gvisor/pkg/sentry/memmap" "gvisor.googlesource.com/gvisor/pkg/sentry/platform" "gvisor.googlesource.com/gvisor/pkg/sentry/usermem" "gvisor.googlesource.com/gvisor/pkg/syserror" ) // HandleUserFault handles an application page fault. sp is the faulting // application thread's stack pointer. // // Preconditions: mm.as != nil. func (mm *MemoryManager) HandleUserFault(ctx context.Context, addr usermem.Addr, at usermem.AccessType, sp usermem.Addr) error { ar, ok := addr.RoundDown().ToRange(usermem.PageSize) if !ok { return syserror.EFAULT } // Don't bother trying existingPMAsLocked; in most cases, if we did have // existing pmas, we wouldn't have faulted. // Ensure that we have a usable vma. Here and below, since we are only // asking for a single page, there is no possibility of partial success, // and any error is immediately fatal. mm.mappingMu.RLock() vseg, _, err := mm.getVMAsLocked(ctx, ar, at, false) if err != nil { mm.mappingMu.RUnlock() return err } // Ensure that we have a usable pma. mm.activeMu.Lock() pseg, _, err := mm.getPMAsLocked(ctx, vseg, ar, pmaOpts{ breakCOW: at.Write, }) mm.mappingMu.RUnlock() if err != nil { mm.activeMu.Unlock() return err } // Downgrade to a read-lock on activeMu since we don't need to mutate pmas // anymore. mm.activeMu.DowngradeLock() // Map the faulted page into the active AddressSpace. err = mm.mapASLocked(pseg, ar, false) mm.activeMu.RUnlock() return err } // MMap establishes a memory mapping. func (mm *MemoryManager) MMap(ctx context.Context, opts memmap.MMapOpts) (usermem.Addr, error) { if opts.Length == 0 { return 0, syserror.EINVAL } length, ok := usermem.Addr(opts.Length).RoundUp() if !ok { return 0, syserror.ENOMEM } opts.Length = uint64(length) if opts.Mappable != nil { // Offset must be aligned. if usermem.Addr(opts.Offset).RoundDown() != usermem.Addr(opts.Offset) { return 0, syserror.EINVAL } // Offset + length must not overflow. if end := opts.Offset + opts.Length; end < opts.Offset { return 0, syserror.ENOMEM } } else { opts.Offset = 0 if !opts.Private { if opts.MappingIdentity != nil { return 0, syserror.EINVAL } m, err := NewSharedAnonMappable(opts.Length, platform.FromContext(ctx)) if err != nil { return 0, err } opts.MappingIdentity = m opts.Mappable = m } } if opts.Addr.RoundDown() != opts.Addr { // MAP_FIXED requires addr to be page-aligned; non-fixed mappings // don't. if opts.Fixed { return 0, syserror.EINVAL } opts.Addr = opts.Addr.RoundDown() } if !opts.MaxPerms.SupersetOf(opts.Perms) { return 0, syserror.EACCES } if opts.Unmap && !opts.Fixed { return 0, syserror.EINVAL } if opts.GrowsDown && opts.Mappable != nil { return 0, syserror.EINVAL } // Get the new vma. mm.mappingMu.Lock() if opts.MLockMode < mm.defMLockMode { opts.MLockMode = mm.defMLockMode } vseg, ar, err := mm.createVMALocked(ctx, opts) if err != nil { mm.mappingMu.Unlock() return 0, err } // TODO: In Linux, VM_LOCKONFAULT (which may be set on the new // vma by mlockall(MCL_FUTURE|MCL_ONFAULT) => mm_struct::def_flags) appears // to effectively disable MAP_POPULATE by unsetting FOLL_POPULATE in // mm/util.c:vm_mmap_pgoff() => mm/gup.c:__mm_populate() => // populate_vma_page_range(). Confirm this behavior. switch { case opts.Precommit || opts.MLockMode == memmap.MLockEager: // Get pmas and map with precommit as requested. mm.populateVMAAndUnlock(ctx, vseg, ar, true) case opts.Mappable == nil && length <= privateAllocUnit: // NOTE: Get pmas and map eagerly in the hope // that doing so will save on future page faults. We only do this for // anonymous mappings, since otherwise the cost of // memmap.Mappable.Translate is unknown; and only for small mappings, // to avoid needing to allocate large amounts of memory that we may // subsequently need to checkpoint. mm.populateVMAAndUnlock(ctx, vseg, ar, false) default: mm.mappingMu.Unlock() } return ar.Start, nil } // populateVMA obtains pmas for addresses in ar in the given vma, and maps them // into mm.as if it is active. // // Preconditions: mm.mappingMu must be locked. vseg.Range().IsSupersetOf(ar). func (mm *MemoryManager) populateVMA(ctx context.Context, vseg vmaIterator, ar usermem.AddrRange, precommit bool) { if !vseg.ValuePtr().effectivePerms.Any() { // Linux doesn't populate inaccessible pages. See // mm/gup.c:populate_vma_page_range. return } mm.activeMu.Lock() // Can't defer mm.activeMu.Unlock(); see below. // Even if we get new pmas, we can't actually map them if we don't have an // AddressSpace. if mm.as == nil { mm.activeMu.Unlock() return } // Ensure that we have usable pmas. pseg, _, err := mm.getPMAsLocked(ctx, vseg, ar, pmaOpts{}) if err != nil { // mm/util.c:vm_mmap_pgoff() ignores the error, if any, from // mm/gup.c:mm_populate(). If it matters, we'll get it again when // userspace actually tries to use the failing page. mm.activeMu.Unlock() return } // Downgrade to a read-lock on activeMu since we don't need to mutate pmas // anymore. mm.activeMu.DowngradeLock() // As above, errors are silently ignored. mm.mapASLocked(pseg, ar, precommit) mm.activeMu.RUnlock() } // populateVMAAndUnlock is equivalent to populateVMA, but also unconditionally // unlocks mm.mappingMu. In cases where populateVMAAndUnlock is usable, it is // preferable to populateVMA since it unlocks mm.mappingMu before performing // expensive operations that don't require it to be locked. // // Preconditions: mm.mappingMu must be locked for writing. // vseg.Range().IsSupersetOf(ar). // // Postconditions: mm.mappingMu will be unlocked. func (mm *MemoryManager) populateVMAAndUnlock(ctx context.Context, vseg vmaIterator, ar usermem.AddrRange, precommit bool) { // See populateVMA above for commentary. if !vseg.ValuePtr().effectivePerms.Any() { mm.mappingMu.Unlock() return } mm.activeMu.Lock() if mm.as == nil { mm.activeMu.Unlock() mm.mappingMu.Unlock() return } // mm.mappingMu doesn't need to be write-locked for getPMAsLocked, and it // isn't needed at all for mapASLocked. mm.mappingMu.DowngradeLock() pseg, _, err := mm.getPMAsLocked(ctx, vseg, ar, pmaOpts{}) mm.mappingMu.RUnlock() if err != nil { mm.activeMu.Unlock() return } mm.activeMu.DowngradeLock() mm.mapASLocked(pseg, ar, precommit) mm.activeMu.RUnlock() } // MapStack allocates the initial process stack. func (mm *MemoryManager) MapStack(ctx context.Context) (usermem.AddrRange, error) { // maxStackSize is the maximum supported process stack size in bytes. // // This limit exists because stack growing isn't implemented, so the entire // process stack must be mapped up-front. const maxStackSize = 128 << 20 stackSize := limits.FromContext(ctx).Get(limits.Stack) r, ok := usermem.Addr(stackSize.Cur).RoundUp() sz := uint64(r) if !ok { // RLIM_INFINITY rounds up to 0. sz = linux.DefaultStackSoftLimit } else if sz > maxStackSize { ctx.Warningf("Capping stack size from RLIMIT_STACK of %v down to %v.", sz, maxStackSize) sz = maxStackSize } else if sz == 0 { return usermem.AddrRange{}, syserror.ENOMEM } szaddr := usermem.Addr(sz) ctx.Debugf("Allocating stack with size of %v bytes", sz) // Determine the stack's desired location. Unlike Linux, address // randomization can't be disabled. stackEnd := mm.layout.MaxAddr - usermem.Addr(mrand.Int63n(int64(mm.layout.MaxStackRand))).RoundDown() if stackEnd < szaddr { return usermem.AddrRange{}, syserror.ENOMEM } stackStart := stackEnd - szaddr mm.mappingMu.Lock() defer mm.mappingMu.Unlock() _, ar, err := mm.createVMALocked(ctx, memmap.MMapOpts{ Length: sz, Addr: stackStart, Perms: usermem.ReadWrite, MaxPerms: usermem.AnyAccess, Private: true, GrowsDown: true, MLockMode: mm.defMLockMode, Hint: "[stack]", }) return ar, err } // MUnmap implements the semantics of Linux's munmap(2). func (mm *MemoryManager) MUnmap(ctx context.Context, addr usermem.Addr, length uint64) error { if addr != addr.RoundDown() { return syserror.EINVAL } if length == 0 { return syserror.EINVAL } la, ok := usermem.Addr(length).RoundUp() if !ok { return syserror.EINVAL } ar, ok := addr.ToRange(uint64(la)) if !ok { return syserror.EINVAL } mm.mappingMu.Lock() defer mm.mappingMu.Unlock() mm.unmapLocked(ctx, ar) return nil } // MRemapOpts specifies options to MRemap. type MRemapOpts struct { // Move controls whether MRemap moves the remapped mapping to a new address. Move MRemapMoveMode // NewAddr is the new address for the remapping. NewAddr is ignored unless // Move is MMRemapMustMove. NewAddr usermem.Addr } // MRemapMoveMode controls MRemap's moving behavior. type MRemapMoveMode int const ( // MRemapNoMove prevents MRemap from moving the remapped mapping. MRemapNoMove MRemapMoveMode = iota // MRemapMayMove allows MRemap to move the remapped mapping. MRemapMayMove // MRemapMustMove requires MRemap to move the remapped mapping to // MRemapOpts.NewAddr, replacing any existing mappings in the remapped // range. MRemapMustMove ) // MRemap implements the semantics of Linux's mremap(2). func (mm *MemoryManager) MRemap(ctx context.Context, oldAddr usermem.Addr, oldSize uint64, newSize uint64, opts MRemapOpts) (usermem.Addr, error) { // "Note that old_address has to be page aligned." - mremap(2) if oldAddr.RoundDown() != oldAddr { return 0, syserror.EINVAL } // Linux treats an old_size that rounds up to 0 as 0, which is otherwise a // valid size. However, new_size can't be 0 after rounding. oldSizeAddr, _ := usermem.Addr(oldSize).RoundUp() oldSize = uint64(oldSizeAddr) newSizeAddr, ok := usermem.Addr(newSize).RoundUp() if !ok || newSizeAddr == 0 { return 0, syserror.EINVAL } newSize = uint64(newSizeAddr) oldEnd, ok := oldAddr.AddLength(oldSize) if !ok { return 0, syserror.EINVAL } mm.mappingMu.Lock() defer mm.mappingMu.Unlock() // All cases require that a vma exists at oldAddr. vseg := mm.vmas.FindSegment(oldAddr) if !vseg.Ok() { return 0, syserror.EFAULT } // Behavior matrix: // // Move | oldSize = 0 | oldSize < newSize | oldSize = newSize | oldSize > newSize // ---------+-------------+-------------------+-------------------+------------------ // NoMove | ENOMEM [1] | Grow in-place | No-op | Shrink in-place // MayMove | Copy [1] | Grow in-place or | No-op | Shrink in-place // | | move | | // MustMove | Copy | Move and grow | Move | Shrink and move // // [1] In-place growth is impossible because the vma at oldAddr already // occupies at least part of the destination. Thus the NoMove case always // fails and the MayMove case always falls back to copying. if vma := vseg.ValuePtr(); newSize > oldSize && vma.mlockMode != memmap.MLockNone { // Check against RLIMIT_MEMLOCK. Unlike mmap, mlock, and mlockall, // mremap in Linux does not check mm/mlock.c:can_do_mlock() and // therefore does not return EPERM if RLIMIT_MEMLOCK is 0 and // !CAP_IPC_LOCK. mlockLimit := limits.FromContext(ctx).Get(limits.MemoryLocked).Cur if creds := auth.CredentialsFromContext(ctx); !creds.HasCapabilityIn(linux.CAP_IPC_LOCK, creds.UserNamespace.Root()) { if newLockedAS := mm.lockedAS - oldSize + newSize; newLockedAS > mlockLimit { return 0, syserror.EAGAIN } } } if opts.Move != MRemapMustMove { // Handle no-ops and in-place shrinking. These cases don't care if // [oldAddr, oldEnd) maps to a single vma, or is even mapped at all // (aside from oldAddr). if newSize <= oldSize { if newSize < oldSize { // If oldAddr+oldSize didn't overflow, oldAddr+newSize can't // either. newEnd := oldAddr + usermem.Addr(newSize) mm.unmapLocked(ctx, usermem.AddrRange{newEnd, oldEnd}) } return oldAddr, nil } // Handle in-place growing. // Check that oldEnd maps to the same vma as oldAddr. if vseg.End() < oldEnd { return 0, syserror.EFAULT } // "Grow" the existing vma by creating a new mergeable one. vma := vseg.ValuePtr() var newOffset uint64 if vma.mappable != nil { newOffset = vseg.mappableRange().End } vseg, ar, err := mm.createVMALocked(ctx, memmap.MMapOpts{ Length: newSize - oldSize, MappingIdentity: vma.id, Mappable: vma.mappable, Offset: newOffset, Addr: oldEnd, Fixed: true, Perms: vma.realPerms, MaxPerms: vma.maxPerms, Private: vma.private, GrowsDown: vma.growsDown, MLockMode: vma.mlockMode, Hint: vma.hint, }) if err == nil { if vma.mlockMode == memmap.MLockEager { mm.populateVMA(ctx, vseg, ar, true) } return oldAddr, nil } // In-place growth failed. In the MRemapMayMove case, fall through to // copying/moving below. if opts.Move == MRemapNoMove { return 0, err } } // Find a location for the new mapping. var newAR usermem.AddrRange switch opts.Move { case MRemapMayMove: newAddr, err := mm.findAvailableLocked(newSize, findAvailableOpts{}) if err != nil { return 0, err } newAR, _ = newAddr.ToRange(newSize) case MRemapMustMove: newAddr := opts.NewAddr if newAddr.RoundDown() != newAddr { return 0, syserror.EINVAL } var ok bool newAR, ok = newAddr.ToRange(newSize) if !ok { return 0, syserror.EINVAL } if (usermem.AddrRange{oldAddr, oldEnd}).Overlaps(newAR) { return 0, syserror.EINVAL } // Unmap any mappings at the destination. mm.unmapLocked(ctx, newAR) // If the sizes specify shrinking, unmap everything between the new and // old sizes at the source. Unmapping before the following checks is // correct: compare Linux's mm/mremap.c:mremap_to() => do_munmap(), // vma_to_resize(). if newSize < oldSize { oldNewEnd := oldAddr + usermem.Addr(newSize) mm.unmapLocked(ctx, usermem.AddrRange{oldNewEnd, oldEnd}) oldEnd = oldNewEnd } // unmapLocked may have invalidated vseg; look it up again. vseg = mm.vmas.FindSegment(oldAddr) } oldAR := usermem.AddrRange{oldAddr, oldEnd} // Check that oldEnd maps to the same vma as oldAddr. if vseg.End() < oldEnd { return 0, syserror.EFAULT } // Check against RLIMIT_AS. newUsageAS := mm.usageAS - uint64(oldAR.Length()) + uint64(newAR.Length()) if limitAS := limits.FromContext(ctx).Get(limits.AS).Cur; newUsageAS > limitAS { return 0, syserror.ENOMEM } if vma := vseg.ValuePtr(); vma.mappable != nil { // Check that offset+length does not overflow. if vma.off+uint64(newAR.Length()) < vma.off { return 0, syserror.EINVAL } // Inform the Mappable, if any, of the new mapping. if err := vma.mappable.CopyMapping(ctx, mm, oldAR, newAR, vseg.mappableOffsetAt(oldAR.Start), vma.canWriteMappableLocked()); err != nil { return 0, err } } if oldSize == 0 { // Handle copying. // // We can't use createVMALocked because it calls Mappable.AddMapping, // whereas we've already called Mappable.CopyMapping (which is // consistent with Linux). Call vseg.Value() (rather than // vseg.ValuePtr()) to make a copy of the vma. vma := vseg.Value() if vma.mappable != nil { vma.off = vseg.mappableOffsetAt(oldAR.Start) } if vma.id != nil { vma.id.IncRef() } vseg := mm.vmas.Insert(mm.vmas.FindGap(newAR.Start), newAR, vma) mm.usageAS += uint64(newAR.Length()) if vma.mlockMode != memmap.MLockNone { mm.lockedAS += uint64(newAR.Length()) if vma.mlockMode == memmap.MLockEager { mm.populateVMA(ctx, vseg, newAR, true) } } return newAR.Start, nil } // Handle moving. // // Remove the existing vma before inserting the new one to minimize // iterator invalidation. We do this directly (instead of calling // removeVMAsLocked) because: // // 1. We can't drop the reference on vma.id, which will be transferred to // the new vma. // // 2. We can't call vma.mappable.RemoveMapping, because pmas are still at // oldAR, so calling RemoveMapping could cause us to miss an invalidation // overlapping oldAR. // // Call vseg.Value() (rather than vseg.ValuePtr()) to make a copy of the // vma. vseg = mm.vmas.Isolate(vseg, oldAR) vma := vseg.Value() mm.vmas.Remove(vseg) vseg = mm.vmas.Insert(mm.vmas.FindGap(newAR.Start), newAR, vma) mm.usageAS = mm.usageAS - uint64(oldAR.Length()) + uint64(newAR.Length()) if vma.mlockMode != memmap.MLockNone { mm.lockedAS = mm.lockedAS - uint64(oldAR.Length()) + uint64(newAR.Length()) } // Move pmas. This is technically optional for non-private pmas, which // could just go through memmap.Mappable.Translate again, but it's required // for private pmas. mm.activeMu.Lock() mm.movePMAsLocked(oldAR, newAR) mm.activeMu.Unlock() // Now that pmas have been moved to newAR, we can notify vma.mappable that // oldAR is no longer mapped. if vma.mappable != nil { vma.mappable.RemoveMapping(ctx, mm, oldAR, vma.off, vma.canWriteMappableLocked()) } if vma.mlockMode == memmap.MLockEager { mm.populateVMA(ctx, vseg, newAR, true) } return newAR.Start, nil } // MProtect implements the semantics of Linux's mprotect(2). func (mm *MemoryManager) MProtect(addr usermem.Addr, length uint64, realPerms usermem.AccessType, growsDown bool) error { if addr.RoundDown() != addr { return syserror.EINVAL } if length == 0 { return nil } rlength, ok := usermem.Addr(length).RoundUp() if !ok { return syserror.ENOMEM } ar, ok := addr.ToRange(uint64(rlength)) if !ok { return syserror.ENOMEM } effectivePerms := realPerms.Effective() mm.mappingMu.Lock() defer mm.mappingMu.Unlock() // Non-growsDown mprotect requires that all of ar is mapped, and stops at // the first non-empty gap. growsDown mprotect requires that the first vma // be growsDown, but does not require it to extend all the way to ar.Start; // vmas after the first must be contiguous but need not be growsDown, like // the non-growsDown case. vseg := mm.vmas.LowerBoundSegment(ar.Start) if !vseg.Ok() { return syserror.ENOMEM } if growsDown { if !vseg.ValuePtr().growsDown { return syserror.EINVAL } if ar.End <= vseg.Start() { return syserror.ENOMEM } ar.Start = vseg.Start() } else { if ar.Start < vseg.Start() { return syserror.ENOMEM } } mm.activeMu.Lock() defer mm.activeMu.Unlock() defer func() { mm.vmas.MergeRange(ar) mm.vmas.MergeAdjacent(ar) mm.pmas.MergeRange(ar) mm.pmas.MergeAdjacent(ar) }() pseg := mm.pmas.LowerBoundSegment(ar.Start) var didUnmapAS bool for { // Check for permission validity before splitting vmas, for consistency // with Linux. if !vseg.ValuePtr().maxPerms.SupersetOf(effectivePerms) { return syserror.EACCES } vseg = mm.vmas.Isolate(vseg, ar) // Update vma permissions. vma := vseg.ValuePtr() vma.realPerms = realPerms vma.effectivePerms = effectivePerms // Propagate vma permission changes to pmas. for pseg.Ok() && pseg.Start() < vseg.End() { if pseg.Range().Overlaps(vseg.Range()) { pseg = mm.pmas.Isolate(pseg, vseg.Range()) if !effectivePerms.SupersetOf(pseg.ValuePtr().vmaEffectivePerms) && !didUnmapAS { // Unmap all of ar, not just vseg.Range(), to minimize host // syscalls. mm.unmapASLocked(ar) didUnmapAS = true } pseg.ValuePtr().vmaEffectivePerms = effectivePerms } pseg = pseg.NextSegment() } // Continue to the next vma. if ar.End <= vseg.End() { return nil } vseg, _ = vseg.NextNonEmpty() if !vseg.Ok() { return syserror.ENOMEM } } } // BrkSetup sets mm's brk address to addr and its brk size to 0. func (mm *MemoryManager) BrkSetup(ctx context.Context, addr usermem.Addr) { mm.mappingMu.Lock() defer mm.mappingMu.Unlock() // Unmap the existing brk. if mm.brk.Length() != 0 { mm.unmapLocked(ctx, mm.brk) } mm.brk = usermem.AddrRange{addr, addr} } // Brk implements the semantics of Linux's brk(2), except that it returns an // error on failure. func (mm *MemoryManager) Brk(ctx context.Context, addr usermem.Addr) (usermem.Addr, error) { mm.mappingMu.Lock() // Can't defer mm.mappingMu.Unlock(); see below. if addr < mm.brk.Start { mm.mappingMu.Unlock() return mm.brk.End, syserror.EINVAL } // TODO: This enforces RLIMIT_DATA, but is slightly more // permissive than the usual data limit. In particular, this only // limits the size of the heap; a true RLIMIT_DATA limits the size of // heap + data + bss. The segment sizes need to be plumbed from the // loader package to fully enforce RLIMIT_DATA. if uint64(addr-mm.brk.Start) > limits.FromContext(ctx).Get(limits.Data).Cur { mm.mappingMu.Unlock() return mm.brk.End, syserror.ENOMEM } oldbrkpg, _ := mm.brk.End.RoundUp() newbrkpg, ok := addr.RoundUp() if !ok { mm.mappingMu.Unlock() return mm.brk.End, syserror.EFAULT } switch { case newbrkpg < oldbrkpg: mm.unmapLocked(ctx, usermem.AddrRange{newbrkpg, oldbrkpg}) mm.mappingMu.Unlock() case oldbrkpg < newbrkpg: vseg, ar, err := mm.createVMALocked(ctx, memmap.MMapOpts{ Length: uint64(newbrkpg - oldbrkpg), Addr: oldbrkpg, Fixed: true, // Compare Linux's // arch/x86/include/asm/page_types.h:VM_DATA_DEFAULT_FLAGS. Perms: usermem.ReadWrite, MaxPerms: usermem.AnyAccess, Private: true, // Linux: mm/mmap.c:sys_brk() => do_brk_flags() includes // mm->def_flags. MLockMode: mm.defMLockMode, Hint: "[heap]", }) if err != nil { mm.mappingMu.Unlock() return mm.brk.End, err } if mm.defMLockMode == memmap.MLockEager { mm.populateVMAAndUnlock(ctx, vseg, ar, true) } else { mm.mappingMu.Unlock() } default: // Nothing to do. mm.mappingMu.Unlock() } mm.brk.End = addr return addr, nil } // MLock implements the semantics of Linux's mlock()/mlock2()/munlock(), // depending on mode. func (mm *MemoryManager) MLock(ctx context.Context, addr usermem.Addr, length uint64, mode memmap.MLockMode) error { // Linux allows this to overflow. la, _ := usermem.Addr(length + addr.PageOffset()).RoundUp() ar, ok := addr.RoundDown().ToRange(uint64(la)) if !ok { return syserror.EINVAL } mm.mappingMu.Lock() // Can't defer mm.mappingMu.Unlock(); see below. if mode != 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 { mm.mappingMu.Unlock() return syserror.EPERM } if newLockedAS := mm.lockedAS + uint64(ar.Length()) - mm.mlockedBytesRangeLocked(ar); newLockedAS > mlockLimit { mm.mappingMu.Unlock() return syserror.ENOMEM } } } // Check this after RLIMIT_MEMLOCK for consistency with Linux. if ar.Length() == 0 { mm.mappingMu.Unlock() return nil } // Apply the new mlock mode to vmas. var unmapped bool vseg := mm.vmas.FindSegment(ar.Start) for { if !vseg.Ok() { unmapped = true break } vseg = mm.vmas.Isolate(vseg, ar) vma := vseg.ValuePtr() prevMode := vma.mlockMode vma.mlockMode = mode if mode != memmap.MLockNone && prevMode == memmap.MLockNone { mm.lockedAS += uint64(vseg.Range().Length()) } else if mode == memmap.MLockNone && prevMode != memmap.MLockNone { mm.lockedAS -= uint64(vseg.Range().Length()) } if ar.End <= vseg.End() { break } vseg, _ = vseg.NextNonEmpty() } mm.vmas.MergeRange(ar) mm.vmas.MergeAdjacent(ar) if unmapped { mm.mappingMu.Unlock() return syserror.ENOMEM } if mode == memmap.MLockEager { // Ensure that we have usable pmas. Since we didn't return ENOMEM // above, ar must be fully covered by vmas, so we can just use // NextSegment below. mm.activeMu.Lock() mm.mappingMu.DowngradeLock() for vseg := mm.vmas.FindSegment(ar.Start); vseg.Ok() && vseg.Start() < ar.End; vseg = vseg.NextSegment() { if !vseg.ValuePtr().effectivePerms.Any() { // Linux: mm/gup.c:__get_user_pages() returns EFAULT in this // case, which is converted to ENOMEM by mlock. mm.activeMu.Unlock() mm.mappingMu.RUnlock() return syserror.ENOMEM } _, _, err := mm.getPMAsLocked(ctx, vseg, vseg.Range().Intersect(ar), pmaOpts{}) if err != nil { mm.activeMu.Unlock() mm.mappingMu.RUnlock() // Linux: mm/mlock.c:__mlock_posix_error_return() if err == syserror.EFAULT { return syserror.ENOMEM } if err == syserror.ENOMEM { return syserror.EAGAIN } return err } } // Map pmas into the active AddressSpace, if we have one. mm.mappingMu.RUnlock() if mm.as != nil { mm.activeMu.DowngradeLock() err := mm.mapASLocked(mm.pmas.LowerBoundSegment(ar.Start), ar, true /* precommit */) mm.activeMu.RUnlock() if err != nil { return err } } else { mm.activeMu.Unlock() } } else { mm.mappingMu.Unlock() } return nil } // MLockAllOpts holds options to MLockAll. type MLockAllOpts struct { // If Current is true, change the memory-locking behavior of all mappings // to Mode. If Future is true, upgrade the memory-locking behavior of all // future mappings to Mode. At least one of Current or Future must be true. Current bool Future bool Mode memmap.MLockMode } // MLockAll implements the semantics of Linux's mlockall()/munlockall(), // depending on opts. func (mm *MemoryManager) MLockAll(ctx context.Context, opts MLockAllOpts) error { if !opts.Current && !opts.Future { return syserror.EINVAL } mm.mappingMu.Lock() // Can't defer mm.mappingMu.Unlock(); see below. if opts.Current { if opts.Mode != 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 { mm.mappingMu.Unlock() return syserror.EPERM } if uint64(mm.vmas.Span()) > mlockLimit { mm.mappingMu.Unlock() return syserror.ENOMEM } } } for vseg := mm.vmas.FirstSegment(); vseg.Ok(); vseg = vseg.NextSegment() { vma := vseg.ValuePtr() prevMode := vma.mlockMode vma.mlockMode = opts.Mode if opts.Mode != memmap.MLockNone && prevMode == memmap.MLockNone { mm.lockedAS += uint64(vseg.Range().Length()) } else if opts.Mode == memmap.MLockNone && prevMode != memmap.MLockNone { mm.lockedAS -= uint64(vseg.Range().Length()) } } } if opts.Future { mm.defMLockMode = opts.Mode } if opts.Current && opts.Mode == memmap.MLockEager { // Linux: mm/mlock.c:sys_mlockall() => include/linux/mm.h:mm_populate() // ignores the return value of __mm_populate(), so all errors below are // ignored. // // Try to get usable pmas. mm.activeMu.Lock() mm.mappingMu.DowngradeLock() for vseg := mm.vmas.FirstSegment(); vseg.Ok(); vseg = vseg.NextSegment() { if vseg.ValuePtr().effectivePerms.Any() { mm.getPMAsLocked(ctx, vseg, vseg.Range(), pmaOpts{}) } } // Map all pmas into the active AddressSpace, if we have one. mm.mappingMu.RUnlock() if mm.as != nil { mm.activeMu.DowngradeLock() mm.mapASLocked(mm.pmas.FirstSegment(), mm.applicationAddrRange(), true /* precommit */) mm.activeMu.RUnlock() } else { mm.activeMu.Unlock() } } else { mm.mappingMu.Unlock() } return nil } // Decommit implements the semantics of Linux's madvise(MADV_DONTNEED). func (mm *MemoryManager) Decommit(addr usermem.Addr, length uint64) error { ar, ok := addr.ToRange(length) if !ok { return syserror.EINVAL } mm.mappingMu.RLock() defer mm.mappingMu.RUnlock() mm.activeMu.Lock() defer mm.activeMu.Unlock() // Linux's mm/madvise.c:madvise_dontneed() => mm/memory.c:zap_page_range() // is analogous to our mm.invalidateLocked(ar, true, true). We inline this // here, with the special case that we synchronously decommit // uniquely-owned (non-copy-on-write) pages for private anonymous vma, // which is the common case for MADV_DONTNEED. Invalidating these pmas, and // allowing them to be reallocated when touched again, increases pma // fragmentation, which may significantly reduce performance for // non-vectored I/O implementations. Also, decommitting synchronously // ensures that Decommit immediately reduces host memory usage. var didUnmapAS bool pseg := mm.pmas.LowerBoundSegment(ar.Start) mem := mm.p.Memory() for vseg := mm.vmas.LowerBoundSegment(ar.Start); vseg.Ok() && vseg.Start() < ar.End; vseg = vseg.NextSegment() { vma := vseg.ValuePtr() if vma.mlockMode != memmap.MLockNone { return syserror.EINVAL } vsegAR := vseg.Range().Intersect(ar) // pseg should already correspond to either this vma or a later one, // since there can't be a pma without a corresponding vma. if checkInvariants { if pseg.Ok() && pseg.End() <= vsegAR.Start { panic(fmt.Sprintf("pma %v precedes vma %v", pseg.Range(), vsegAR)) } } for pseg.Ok() && pseg.Start() < vsegAR.End { pma := pseg.ValuePtr() if pma.private && !mm.isPMACopyOnWriteLocked(pseg) { psegAR := pseg.Range().Intersect(ar) if vsegAR.IsSupersetOf(psegAR) && vma.mappable == nil { if err := mem.Decommit(pseg.fileRangeOf(psegAR)); err == nil { pseg = pseg.NextSegment() continue } // If an error occurs, fall through to the general // invalidation case below. } } pseg = mm.pmas.Isolate(pseg, vsegAR) pma = pseg.ValuePtr() if !didUnmapAS { // Unmap all of ar, not just pseg.Range(), to minimize host // syscalls. AddressSpace mappings must be removed before // mm.decPrivateRef(). mm.unmapASLocked(ar) didUnmapAS = true } if pma.private { mm.decPrivateRef(pseg.fileRange()) } pma.file.DecRef(pseg.fileRange()) mm.removeRSSLocked(pseg.Range()) pseg = mm.pmas.Remove(pseg).NextSegment() } } // "If there are some parts of the specified address space that are not // mapped, the Linux version of madvise() ignores them and applies the call // to the rest (but returns ENOMEM from the system call, as it should)." - // madvise(2) if mm.vmas.SpanRange(ar) != ar.Length() { return syserror.ENOMEM } return nil } // MSyncOpts holds options to MSync. type MSyncOpts struct { // Sync has the semantics of MS_SYNC. Sync bool // Invalidate has the semantics of MS_INVALIDATE. Invalidate bool } // MSync implements the semantics of Linux's msync(). func (mm *MemoryManager) MSync(ctx context.Context, addr usermem.Addr, length uint64, opts MSyncOpts) error { if addr != addr.RoundDown() { return syserror.EINVAL } if length == 0 { return nil } la, ok := usermem.Addr(length).RoundUp() if !ok { return syserror.ENOMEM } ar, ok := addr.ToRange(uint64(la)) if !ok { return syserror.ENOMEM } mm.mappingMu.RLock() // Can't defer mm.mappingMu.RUnlock(); see below. vseg := mm.vmas.LowerBoundSegment(ar.Start) if !vseg.Ok() { mm.mappingMu.RUnlock() return syserror.ENOMEM } var unmapped bool lastEnd := ar.Start for { if !vseg.Ok() { mm.mappingMu.RUnlock() unmapped = true break } if lastEnd < vseg.Start() { unmapped = true } lastEnd = vseg.End() vma := vseg.ValuePtr() if opts.Invalidate && vma.mlockMode != memmap.MLockNone { mm.mappingMu.RUnlock() return syserror.EBUSY } // It's only possible to have dirtied the Mappable through a shared // mapping. Don't check if the mapping is writable, because mprotect // may have changed this, and also because Linux doesn't. if id := vma.id; opts.Sync && id != nil && vma.mappable != nil && !vma.private { // We can't call memmap.MappingIdentity.Msync while holding // mm.mappingMu since it may take fs locks that precede it in the // lock order. id.IncRef() mr := vseg.mappableRangeOf(vseg.Range().Intersect(ar)) mm.mappingMu.RUnlock() err := id.Msync(ctx, mr) id.DecRef() if err != nil { return err } if lastEnd >= ar.End { break } mm.mappingMu.RLock() vseg = mm.vmas.LowerBoundSegment(lastEnd) } else { if lastEnd >= ar.End { mm.mappingMu.RUnlock() break } vseg = vseg.NextSegment() } } if unmapped { return syserror.ENOMEM } return nil } // GetSharedFutexKey is used by kernel.Task.GetSharedKey. func (mm *MemoryManager) GetSharedFutexKey(ctx context.Context, addr usermem.Addr) (futex.Key, error) { ar, ok := addr.ToRange(4) // sizeof(int32). if !ok { return futex.Key{}, syserror.EFAULT } mm.mappingMu.RLock() defer mm.mappingMu.RUnlock() vseg, _, err := mm.getVMAsLocked(ctx, ar, usermem.Read, false) if err != nil { return futex.Key{}, err } vma := vseg.ValuePtr() if vma.private { return futex.Key{ Kind: futex.KindSharedPrivate, Offset: uint64(addr), }, nil } if vma.id != nil { vma.id.IncRef() } return futex.Key{ Kind: futex.KindSharedMappable, Mappable: vma.mappable, MappingIdentity: vma.id, Offset: vseg.mappableOffsetAt(addr), }, nil } // VirtualMemorySize returns the combined length in bytes of all mappings in // mm. func (mm *MemoryManager) VirtualMemorySize() uint64 { mm.mappingMu.RLock() defer mm.mappingMu.RUnlock() return uint64(mm.usageAS) } // VirtualMemorySizeRange returns the combined length in bytes of all mappings // in ar in mm. func (mm *MemoryManager) VirtualMemorySizeRange(ar usermem.AddrRange) uint64 { mm.mappingMu.RLock() defer mm.mappingMu.RUnlock() return uint64(mm.vmas.SpanRange(ar)) } // ResidentSetSize returns the value advertised as mm's RSS in bytes. func (mm *MemoryManager) ResidentSetSize() uint64 { mm.activeMu.RLock() defer mm.activeMu.RUnlock() return uint64(mm.curRSS) } // MaxResidentSetSize returns the value advertised as mm's max RSS in bytes. func (mm *MemoryManager) MaxResidentSetSize() uint64 { mm.activeMu.RLock() defer mm.activeMu.RUnlock() return uint64(mm.maxRSS) }