// 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/context" "gvisor.dev/gvisor/pkg/safemem" "gvisor.dev/gvisor/pkg/sentry/platform" "gvisor.dev/gvisor/pkg/syserror" "gvisor.dev/gvisor/pkg/usermem" ) // There are two supported ways to copy data to/from application virtual // memory: // // 1. Internally-mapped copying: Determine the platform.File that backs the // copied-to/from virtual address, obtain a mapping of its pages, and read or // write to the mapping. // // 2. AddressSpace copying: If platform.Platform.SupportsAddressSpaceIO() is // true, AddressSpace permissions are applicable, and an AddressSpace is // available, copy directly through the AddressSpace, handling faults as // needed. // // (Given that internally-mapped copying requires that backing memory is always // implemented using a host file descriptor, we could also preadv/pwritev to it // instead. But this would incur a host syscall for each use of the mapped // page, whereas mmap is a one-time cost.) // // The fixed overhead of internally-mapped copying is expected to be higher // than that of AddressSpace copying since the former always needs to translate // addresses, whereas the latter only needs to do so when faults occur. // However, the throughput of internally-mapped copying is expected to be // somewhat higher than that of AddressSpace copying due to the high cost of // page faults and because implementations of the latter usually rely on // safecopy, which doesn't use AVX registers. So we prefer to use AddressSpace // copying (when available) for smaller copies, and switch to internally-mapped // copying once a size threshold is exceeded. const ( // copyMapMinBytes is the size threshold for switching to internally-mapped // copying in CopyOut, CopyIn, and ZeroOut. copyMapMinBytes = 32 << 10 // 32 KB // rwMapMinBytes is the size threshold for switching to internally-mapped // copying in CopyOutFrom and CopyInTo. It's lower than copyMapMinBytes // since AddressSpace copying in this case requires additional buffering; // see CopyOutFrom for details. rwMapMinBytes = 512 ) // CheckIORange is similar to usermem.Addr.ToRange, but applies bounds checks // consistent with Linux's arch/x86/include/asm/uaccess.h:access_ok(). // // Preconditions: length >= 0. func (mm *MemoryManager) CheckIORange(addr usermem.Addr, length int64) (usermem.AddrRange, bool) { // Note that access_ok() constrains end even if length == 0. ar, ok := addr.ToRange(uint64(length)) return ar, (ok && ar.End <= mm.layout.MaxAddr) } // checkIOVec applies bound checks consistent with Linux's // arch/x86/include/asm/uaccess.h:access_ok() to ars. func (mm *MemoryManager) checkIOVec(ars usermem.AddrRangeSeq) bool { for !ars.IsEmpty() { ar := ars.Head() if _, ok := mm.CheckIORange(ar.Start, int64(ar.Length())); !ok { return false } ars = ars.Tail() } return true } func (mm *MemoryManager) asioEnabled(opts usermem.IOOpts) bool { return mm.haveASIO && !opts.IgnorePermissions && opts.AddressSpaceActive } // translateIOError converts errors to EFAULT, as is usually reported for all // I/O errors originating from MM in Linux. func translateIOError(ctx context.Context, err error) error { if err == nil { return nil } if logIOErrors { ctx.Debugf("MM I/O error: %v", err) } return syserror.EFAULT } // CopyOut implements usermem.IO.CopyOut. func (mm *MemoryManager) CopyOut(ctx context.Context, addr usermem.Addr, src []byte, opts usermem.IOOpts) (int, error) { ar, ok := mm.CheckIORange(addr, int64(len(src))) if !ok { return 0, syserror.EFAULT } if len(src) == 0 { return 0, nil } // Do AddressSpace IO if applicable. if mm.asioEnabled(opts) && len(src) < copyMapMinBytes { return mm.asCopyOut(ctx, addr, src) } // Go through internal mappings. n64, err := mm.withInternalMappings(ctx, ar, usermem.Write, opts.IgnorePermissions, func(ims safemem.BlockSeq) (uint64, error) { n, err := safemem.CopySeq(ims, safemem.BlockSeqOf(safemem.BlockFromSafeSlice(src))) return n, translateIOError(ctx, err) }) return int(n64), err } func (mm *MemoryManager) asCopyOut(ctx context.Context, addr usermem.Addr, src []byte) (int, error) { var done int for { n, err := mm.as.CopyOut(addr+usermem.Addr(done), src[done:]) done += n if err == nil { return done, nil } if f, ok := err.(platform.SegmentationFault); ok { ar, _ := addr.ToRange(uint64(len(src))) if err := mm.handleASIOFault(ctx, f.Addr, ar, usermem.Write); err != nil { return done, err } continue } return done, translateIOError(ctx, err) } } // CopyIn implements usermem.IO.CopyIn. func (mm *MemoryManager) CopyIn(ctx context.Context, addr usermem.Addr, dst []byte, opts usermem.IOOpts) (int, error) { ar, ok := mm.CheckIORange(addr, int64(len(dst))) if !ok { return 0, syserror.EFAULT } if len(dst) == 0 { return 0, nil } // Do AddressSpace IO if applicable. if mm.asioEnabled(opts) && len(dst) < copyMapMinBytes { return mm.asCopyIn(ctx, addr, dst) } // Go through internal mappings. n64, err := mm.withInternalMappings(ctx, ar, usermem.Read, opts.IgnorePermissions, func(ims safemem.BlockSeq) (uint64, error) { n, err := safemem.CopySeq(safemem.BlockSeqOf(safemem.BlockFromSafeSlice(dst)), ims) return n, translateIOError(ctx, err) }) return int(n64), err } func (mm *MemoryManager) asCopyIn(ctx context.Context, addr usermem.Addr, dst []byte) (int, error) { var done int for { n, err := mm.as.CopyIn(addr+usermem.Addr(done), dst[done:]) done += n if err == nil { return done, nil } if f, ok := err.(platform.SegmentationFault); ok { ar, _ := addr.ToRange(uint64(len(dst))) if err := mm.handleASIOFault(ctx, f.Addr, ar, usermem.Read); err != nil { return done, err } continue } return done, translateIOError(ctx, err) } } // ZeroOut implements usermem.IO.ZeroOut. func (mm *MemoryManager) ZeroOut(ctx context.Context, addr usermem.Addr, toZero int64, opts usermem.IOOpts) (int64, error) { ar, ok := mm.CheckIORange(addr, toZero) if !ok { return 0, syserror.EFAULT } if toZero == 0 { return 0, nil } // Do AddressSpace IO if applicable. if mm.asioEnabled(opts) && toZero < copyMapMinBytes { return mm.asZeroOut(ctx, addr, toZero) } // Go through internal mappings. return mm.withInternalMappings(ctx, ar, usermem.Write, opts.IgnorePermissions, func(dsts safemem.BlockSeq) (uint64, error) { n, err := safemem.ZeroSeq(dsts) return n, translateIOError(ctx, err) }) } func (mm *MemoryManager) asZeroOut(ctx context.Context, addr usermem.Addr, toZero int64) (int64, error) { var done int64 for { n, err := mm.as.ZeroOut(addr+usermem.Addr(done), uintptr(toZero-done)) done += int64(n) if err == nil { return done, nil } if f, ok := err.(platform.SegmentationFault); ok { ar, _ := addr.ToRange(uint64(toZero)) if err := mm.handleASIOFault(ctx, f.Addr, ar, usermem.Write); err != nil { return done, err } continue } return done, translateIOError(ctx, err) } } // CopyOutFrom implements usermem.IO.CopyOutFrom. func (mm *MemoryManager) CopyOutFrom(ctx context.Context, ars usermem.AddrRangeSeq, src safemem.Reader, opts usermem.IOOpts) (int64, error) { if !mm.checkIOVec(ars) { return 0, syserror.EFAULT } if ars.NumBytes() == 0 { return 0, nil } // Do AddressSpace IO if applicable. if mm.asioEnabled(opts) && ars.NumBytes() < rwMapMinBytes { // We have to introduce a buffered copy, instead of just passing a // safemem.BlockSeq representing addresses in the AddressSpace to src. // This is because usermem.IO.CopyOutFrom() guarantees that it calls // src.ReadToBlocks() at most once, which is incompatible with handling // faults between calls. In the future, this is probably best resolved // by introducing a CopyOutFrom variant or option that allows it to // call src.ReadToBlocks() any number of times. // // This issue applies to CopyInTo as well. buf := make([]byte, int(ars.NumBytes())) bufN, bufErr := src.ReadToBlocks(safemem.BlockSeqOf(safemem.BlockFromSafeSlice(buf))) var done int64 for done < int64(bufN) { ar := ars.Head() cplen := int64(ar.Length()) if cplen > int64(bufN)-done { cplen = int64(bufN) - done } n, err := mm.asCopyOut(ctx, ar.Start, buf[int(done):int(done+cplen)]) done += int64(n) if err != nil { return done, err } ars = ars.Tail() } // Do not convert errors returned by src to EFAULT. return done, bufErr } // Go through internal mappings. return mm.withVecInternalMappings(ctx, ars, usermem.Write, opts.IgnorePermissions, src.ReadToBlocks) } // CopyInTo implements usermem.IO.CopyInTo. func (mm *MemoryManager) CopyInTo(ctx context.Context, ars usermem.AddrRangeSeq, dst safemem.Writer, opts usermem.IOOpts) (int64, error) { if !mm.checkIOVec(ars) { return 0, syserror.EFAULT } if ars.NumBytes() == 0 { return 0, nil } // Do AddressSpace IO if applicable. if mm.asioEnabled(opts) && ars.NumBytes() < rwMapMinBytes { buf := make([]byte, int(ars.NumBytes())) var done int var bufErr error for !ars.IsEmpty() { ar := ars.Head() var n int n, bufErr = mm.asCopyIn(ctx, ar.Start, buf[done:done+int(ar.Length())]) done += n if bufErr != nil { break } ars = ars.Tail() } n, err := dst.WriteFromBlocks(safemem.BlockSeqOf(safemem.BlockFromSafeSlice(buf[:done]))) if err != nil { return int64(n), err } // Do not convert errors returned by dst to EFAULT. return int64(n), bufErr } // Go through internal mappings. return mm.withVecInternalMappings(ctx, ars, usermem.Read, opts.IgnorePermissions, dst.WriteFromBlocks) } // SwapUint32 implements usermem.IO.SwapUint32. func (mm *MemoryManager) SwapUint32(ctx context.Context, addr usermem.Addr, new uint32, opts usermem.IOOpts) (uint32, error) { ar, ok := mm.CheckIORange(addr, 4) if !ok { return 0, syserror.EFAULT } // Do AddressSpace IO if applicable. if mm.haveASIO && opts.AddressSpaceActive && !opts.IgnorePermissions { for { old, err := mm.as.SwapUint32(addr, new) if err == nil { return old, nil } if f, ok := err.(platform.SegmentationFault); ok { if err := mm.handleASIOFault(ctx, f.Addr, ar, usermem.ReadWrite); err != nil { return 0, err } continue } return 0, translateIOError(ctx, err) } } // Go through internal mappings. var old uint32 _, err := mm.withInternalMappings(ctx, ar, usermem.ReadWrite, opts.IgnorePermissions, func(ims safemem.BlockSeq) (uint64, error) { if ims.NumBlocks() != 1 || ims.NumBytes() != 4 { // Atomicity is unachievable across mappings. return 0, syserror.EFAULT } im := ims.Head() var err error old, err = safemem.SwapUint32(im, new) if err != nil { return 0, translateIOError(ctx, err) } // Return the number of bytes read. return 4, nil }) return old, err } // CompareAndSwapUint32 implements usermem.IO.CompareAndSwapUint32. func (mm *MemoryManager) CompareAndSwapUint32(ctx context.Context, addr usermem.Addr, old, new uint32, opts usermem.IOOpts) (uint32, error) { ar, ok := mm.CheckIORange(addr, 4) if !ok { return 0, syserror.EFAULT } // Do AddressSpace IO if applicable. if mm.haveASIO && opts.AddressSpaceActive && !opts.IgnorePermissions { for { prev, err := mm.as.CompareAndSwapUint32(addr, old, new) if err == nil { return prev, nil } if f, ok := err.(platform.SegmentationFault); ok { if err := mm.handleASIOFault(ctx, f.Addr, ar, usermem.ReadWrite); err != nil { return 0, err } continue } return 0, translateIOError(ctx, err) } } // Go through internal mappings. var prev uint32 _, err := mm.withInternalMappings(ctx, ar, usermem.ReadWrite, opts.IgnorePermissions, func(ims safemem.BlockSeq) (uint64, error) { if ims.NumBlocks() != 1 || ims.NumBytes() != 4 { // Atomicity is unachievable across mappings. return 0, syserror.EFAULT } im := ims.Head() var err error prev, err = safemem.CompareAndSwapUint32(im, old, new) if err != nil { return 0, translateIOError(ctx, err) } // Return the number of bytes read. return 4, nil }) return prev, err } // LoadUint32 implements usermem.IO.LoadUint32. func (mm *MemoryManager) LoadUint32(ctx context.Context, addr usermem.Addr, opts usermem.IOOpts) (uint32, error) { ar, ok := mm.CheckIORange(addr, 4) if !ok { return 0, syserror.EFAULT } // Do AddressSpace IO if applicable. if mm.haveASIO && opts.AddressSpaceActive && !opts.IgnorePermissions { for { val, err := mm.as.LoadUint32(addr) if err == nil { return val, nil } if f, ok := err.(platform.SegmentationFault); ok { if err := mm.handleASIOFault(ctx, f.Addr, ar, usermem.Read); err != nil { return 0, err } continue } return 0, translateIOError(ctx, err) } } // Go through internal mappings. var val uint32 _, err := mm.withInternalMappings(ctx, ar, usermem.Read, opts.IgnorePermissions, func(ims safemem.BlockSeq) (uint64, error) { if ims.NumBlocks() != 1 || ims.NumBytes() != 4 { // Atomicity is unachievable across mappings. return 0, syserror.EFAULT } im := ims.Head() var err error val, err = safemem.LoadUint32(im) if err != nil { return 0, translateIOError(ctx, err) } // Return the number of bytes read. return 4, nil }) return val, err } // handleASIOFault handles a page fault at address addr for an AddressSpaceIO // operation spanning ioar. // // Preconditions: // * mm.as != nil. // * ioar.Length() != 0. // * ioar.Contains(addr). func (mm *MemoryManager) handleASIOFault(ctx context.Context, addr usermem.Addr, ioar usermem.AddrRange, at usermem.AccessType) error { // Try to map all remaining pages in the I/O operation. This RoundUp can't // overflow because otherwise it would have been caught by CheckIORange. end, _ := ioar.End.RoundUp() ar := usermem.AddrRange{addr.RoundDown(), end} // Don't bother trying existingPMAsLocked; in most cases, if we did have // existing pmas, we wouldn't have faulted. // Ensure that we have usable vmas. Here and below, only return early if we // can't map the first (faulting) page; failure to map later pages are // silently ignored. This maximizes partial success. mm.mappingMu.RLock() vseg, vend, err := mm.getVMAsLocked(ctx, ar, at, false) if vendaddr := vend.Start(); vendaddr < ar.End { if vendaddr <= ar.Start { mm.mappingMu.RUnlock() return translateIOError(ctx, err) } ar.End = vendaddr } // Ensure that we have usable pmas. mm.activeMu.Lock() pseg, pend, err := mm.getPMAsLocked(ctx, vseg, ar, at) mm.mappingMu.RUnlock() if pendaddr := pend.Start(); pendaddr < ar.End { if pendaddr <= ar.Start { mm.activeMu.Unlock() return translateIOError(ctx, err) } ar.End = pendaddr } // Downgrade to a read-lock on activeMu since we don't need to mutate pmas // anymore. mm.activeMu.DowngradeLock() err = mm.mapASLocked(pseg, ar, false) mm.activeMu.RUnlock() return translateIOError(ctx, err) } // withInternalMappings ensures that pmas exist for all addresses in ar, // support access of type (at, ignorePermissions), and have internal mappings // cached. It then calls f with mm.activeMu locked for reading, passing // internal mappings for the subrange of ar for which this property holds. // // withInternalMappings takes a function returning uint64 since many safemem // functions have this property, but returns an int64 since this is usually // more useful for usermem.IO methods. // // Preconditions: 0 < ar.Length() <= math.MaxInt64. func (mm *MemoryManager) withInternalMappings(ctx context.Context, ar usermem.AddrRange, at usermem.AccessType, ignorePermissions bool, f func(safemem.BlockSeq) (uint64, error)) (int64, error) { // If pmas are already available, we can do IO without touching mm.vmas or // mm.mappingMu. mm.activeMu.RLock() if pseg := mm.existingPMAsLocked(ar, at, ignorePermissions, true /* needInternalMappings */); pseg.Ok() { n, err := f(mm.internalMappingsLocked(pseg, ar)) mm.activeMu.RUnlock() // Do not convert errors returned by f to EFAULT. return int64(n), err } mm.activeMu.RUnlock() // Ensure that we have usable vmas. mm.mappingMu.RLock() vseg, vend, verr := mm.getVMAsLocked(ctx, ar, at, ignorePermissions) if vendaddr := vend.Start(); vendaddr < ar.End { if vendaddr <= ar.Start { mm.mappingMu.RUnlock() return 0, translateIOError(ctx, verr) } ar.End = vendaddr } // Ensure that we have usable pmas. mm.activeMu.Lock() pseg, pend, perr := mm.getPMAsLocked(ctx, vseg, ar, at) mm.mappingMu.RUnlock() if pendaddr := pend.Start(); pendaddr < ar.End { if pendaddr <= ar.Start { mm.activeMu.Unlock() return 0, translateIOError(ctx, perr) } ar.End = pendaddr } imend, imerr := mm.getPMAInternalMappingsLocked(pseg, ar) mm.activeMu.DowngradeLock() if imendaddr := imend.Start(); imendaddr < ar.End { if imendaddr <= ar.Start { mm.activeMu.RUnlock() return 0, translateIOError(ctx, imerr) } ar.End = imendaddr } // Do I/O. un, err := f(mm.internalMappingsLocked(pseg, ar)) mm.activeMu.RUnlock() n := int64(un) // Return the first error in order of progress through ar. if err != nil { // Do not convert errors returned by f to EFAULT. return n, err } if imerr != nil { return n, translateIOError(ctx, imerr) } if perr != nil { return n, translateIOError(ctx, perr) } return n, translateIOError(ctx, verr) } // withVecInternalMappings ensures that pmas exist for all addresses in ars, // support access of type (at, ignorePermissions), and have internal mappings // cached. It then calls f with mm.activeMu locked for reading, passing // internal mappings for the subset of ars for which this property holds. // // Preconditions: !ars.IsEmpty(). func (mm *MemoryManager) withVecInternalMappings(ctx context.Context, ars usermem.AddrRangeSeq, at usermem.AccessType, ignorePermissions bool, f func(safemem.BlockSeq) (uint64, error)) (int64, error) { // withInternalMappings is faster than withVecInternalMappings because of // iterator plumbing (this isn't generally practical in the vector case due // to iterator invalidation between AddrRanges). Use it if possible. if ars.NumRanges() == 1 { return mm.withInternalMappings(ctx, ars.Head(), at, ignorePermissions, f) } // If pmas are already available, we can do IO without touching mm.vmas or // mm.mappingMu. mm.activeMu.RLock() if mm.existingVecPMAsLocked(ars, at, ignorePermissions, true /* needInternalMappings */) { n, err := f(mm.vecInternalMappingsLocked(ars)) mm.activeMu.RUnlock() // Do not convert errors returned by f to EFAULT. return int64(n), err } mm.activeMu.RUnlock() // Ensure that we have usable vmas. mm.mappingMu.RLock() vars, verr := mm.getVecVMAsLocked(ctx, ars, at, ignorePermissions) if vars.NumBytes() == 0 { mm.mappingMu.RUnlock() return 0, translateIOError(ctx, verr) } // Ensure that we have usable pmas. mm.activeMu.Lock() pars, perr := mm.getVecPMAsLocked(ctx, vars, at) mm.mappingMu.RUnlock() if pars.NumBytes() == 0 { mm.activeMu.Unlock() return 0, translateIOError(ctx, perr) } imars, imerr := mm.getVecPMAInternalMappingsLocked(pars) mm.activeMu.DowngradeLock() if imars.NumBytes() == 0 { mm.activeMu.RUnlock() return 0, translateIOError(ctx, imerr) } // Do I/O. un, err := f(mm.vecInternalMappingsLocked(imars)) mm.activeMu.RUnlock() n := int64(un) // Return the first error in order of progress through ars. if err != nil { // Do not convert errors from f to EFAULT. return n, err } if imerr != nil { return n, translateIOError(ctx, imerr) } if perr != nil { return n, translateIOError(ctx, perr) } return n, translateIOError(ctx, verr) } // truncatedAddrRangeSeq returns a copy of ars, but with the end truncated to // at most address end on AddrRange arsit.Head(). It is used in vector I/O paths to // truncate usermem.AddrRangeSeq when errors occur. // // Preconditions: // * !arsit.IsEmpty(). // * end <= arsit.Head().End. func truncatedAddrRangeSeq(ars, arsit usermem.AddrRangeSeq, end usermem.Addr) usermem.AddrRangeSeq { ar := arsit.Head() if end <= ar.Start { return ars.TakeFirst64(ars.NumBytes() - arsit.NumBytes()) } return ars.TakeFirst64(ars.NumBytes() - arsit.NumBytes() + int64(end-ar.Start)) }