// 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 strace implements the logic to print out the input and the return value // of each traced syscall. package strace import ( "fmt" "strconv" "strings" "time" "gvisor.dev/gvisor/pkg/abi" "gvisor.dev/gvisor/pkg/abi/linux" "gvisor.dev/gvisor/pkg/bits" "gvisor.dev/gvisor/pkg/eventchannel" "gvisor.dev/gvisor/pkg/marshal/primitive" "gvisor.dev/gvisor/pkg/seccomp" "gvisor.dev/gvisor/pkg/sentry/arch" "gvisor.dev/gvisor/pkg/sentry/kernel" pb "gvisor.dev/gvisor/pkg/sentry/strace/strace_go_proto" slinux "gvisor.dev/gvisor/pkg/sentry/syscalls/linux" "gvisor.dev/gvisor/pkg/usermem" ) // DefaultLogMaximumSize is the default LogMaximumSize. const DefaultLogMaximumSize = 1024 // LogMaximumSize determines the maximum display size for data blobs (read, // write, etc.). var LogMaximumSize uint = DefaultLogMaximumSize // EventMaximumSize determines the maximum size for data blobs (read, write, // etc.) sent over the event channel. Default is 0 because most clients cannot // do anything useful with binary text dump of byte array arguments. var EventMaximumSize uint // ItimerTypes are the possible itimer types. var ItimerTypes = abi.ValueSet{ linux.ITIMER_REAL: "ITIMER_REAL", linux.ITIMER_VIRTUAL: "ITIMER_VIRTUAL", linux.ITIMER_PROF: "ITIMER_PROF", } func hexNum(num uint64) string { return "0x" + strconv.FormatUint(num, 16) } func hexArg(arg arch.SyscallArgument) string { return hexNum(arg.Uint64()) } func iovecs(t *kernel.Task, addr usermem.Addr, iovcnt int, printContent bool, maxBytes uint64) string { if iovcnt < 0 || iovcnt > linux.UIO_MAXIOV { return fmt.Sprintf("%#x (error decoding iovecs: invalid iovcnt)", addr) } ars, err := t.CopyInIovecs(addr, iovcnt) if err != nil { return fmt.Sprintf("%#x (error decoding iovecs: %v)", addr, err) } var totalBytes uint64 var truncated bool iovs := make([]string, iovcnt) for i := 0; !ars.IsEmpty(); i, ars = i+1, ars.Tail() { ar := ars.Head() if ar.Length() == 0 || !printContent { iovs[i] = fmt.Sprintf("{base=%#x, len=%d}", ar.Start, ar.Length()) continue } size := uint64(ar.Length()) if truncated || totalBytes+size > maxBytes { truncated = true size = maxBytes - totalBytes } else { totalBytes += uint64(ar.Length()) } b := make([]byte, size) amt, err := t.CopyInBytes(ar.Start, b) if err != nil { iovs[i] = fmt.Sprintf("{base=%#x, len=%d, %q..., error decoding string: %v}", ar.Start, ar.Length(), b[:amt], err) continue } dot := "" if truncated { // Indicate truncation. dot = "..." } iovs[i] = fmt.Sprintf("{base=%#x, len=%d, %q%s}", ar.Start, ar.Length(), b[:amt], dot) } return fmt.Sprintf("%#x %s", addr, strings.Join(iovs, ", ")) } func dump(t *kernel.Task, addr usermem.Addr, size uint, maximumBlobSize uint) string { origSize := size if size > maximumBlobSize { size = maximumBlobSize } if size == 0 { return "" } b := make([]byte, size) amt, err := t.CopyInBytes(addr, b) if err != nil { return fmt.Sprintf("%#x (error decoding string: %s)", addr, err) } dot := "" if uint(amt) < origSize { // ... if we truncated the dump. dot = "..." } return fmt.Sprintf("%#x %q%s", addr, b[:amt], dot) } func path(t *kernel.Task, addr usermem.Addr) string { path, err := t.CopyInString(addr, linux.PATH_MAX) if err != nil { return fmt.Sprintf("%#x (error decoding path: %s)", addr, err) } return fmt.Sprintf("%#x %s", addr, path) } func fd(t *kernel.Task, fd int32) string { if kernel.VFS2Enabled { return fdVFS2(t, fd) } root := t.FSContext().RootDirectory() if root != nil { defer root.DecRef(t) } if fd == linux.AT_FDCWD { wd := t.FSContext().WorkingDirectory() var name string if wd != nil { defer wd.DecRef(t) name, _ = wd.FullName(root) } else { name = "(unknown cwd)" } return fmt.Sprintf("AT_FDCWD %s", name) } file := t.GetFile(fd) if file == nil { // Cast FD to uint64 to avoid printing negative hex. return fmt.Sprintf("%#x (bad FD)", uint64(fd)) } defer file.DecRef(t) name, _ := file.Dirent.FullName(root) return fmt.Sprintf("%#x %s", fd, name) } func fdVFS2(t *kernel.Task, fd int32) string { root := t.FSContext().RootDirectoryVFS2() defer root.DecRef(t) vfsObj := root.Mount().Filesystem().VirtualFilesystem() if fd == linux.AT_FDCWD { wd := t.FSContext().WorkingDirectoryVFS2() defer wd.DecRef(t) name, _ := vfsObj.PathnameWithDeleted(t, root, wd) return fmt.Sprintf("AT_FDCWD %s", name) } file := t.GetFileVFS2(fd) if file == nil { // Cast FD to uint64 to avoid printing negative hex. return fmt.Sprintf("%#x (bad FD)", uint64(fd)) } defer file.DecRef(t) name, _ := vfsObj.PathnameWithDeleted(t, root, file.VirtualDentry()) return fmt.Sprintf("%#x %s", fd, name) } func fdpair(t *kernel.Task, addr usermem.Addr) string { var fds [2]int32 _, err := primitive.CopyInt32SliceIn(t, addr, fds[:]) if err != nil { return fmt.Sprintf("%#x (error decoding fds: %s)", addr, err) } return fmt.Sprintf("%#x [%d %d]", addr, fds[0], fds[1]) } func uname(t *kernel.Task, addr usermem.Addr) string { var u linux.UtsName if _, err := u.CopyIn(t, addr); err != nil { return fmt.Sprintf("%#x (error decoding utsname: %s)", addr, err) } return fmt.Sprintf("%#x %s", addr, u) } func utimensTimespec(t *kernel.Task, addr usermem.Addr) string { if addr == 0 { return "null" } var tim linux.Timespec if _, err := tim.CopyIn(t, addr); err != nil { return fmt.Sprintf("%#x (error decoding timespec: %s)", addr, err) } var ns string switch tim.Nsec { case linux.UTIME_NOW: ns = "UTIME_NOW" case linux.UTIME_OMIT: ns = "UTIME_OMIT" default: ns = fmt.Sprintf("%v", tim.Nsec) } return fmt.Sprintf("%#x {sec=%v nsec=%s}", addr, tim.Sec, ns) } func timespec(t *kernel.Task, addr usermem.Addr) string { if addr == 0 { return "null" } var tim linux.Timespec if _, err := tim.CopyIn(t, addr); err != nil { return fmt.Sprintf("%#x (error decoding timespec: %s)", addr, err) } return fmt.Sprintf("%#x {sec=%v nsec=%v}", addr, tim.Sec, tim.Nsec) } func timeval(t *kernel.Task, addr usermem.Addr) string { if addr == 0 { return "null" } var tim linux.Timeval if _, err := tim.CopyIn(t, addr); err != nil { return fmt.Sprintf("%#x (error decoding timeval: %s)", addr, err) } return fmt.Sprintf("%#x {sec=%v usec=%v}", addr, tim.Sec, tim.Usec) } func utimbuf(t *kernel.Task, addr usermem.Addr) string { if addr == 0 { return "null" } var utim linux.Utime if _, err := utim.CopyIn(t, addr); err != nil { return fmt.Sprintf("%#x (error decoding utimbuf: %s)", addr, err) } return fmt.Sprintf("%#x {actime=%v, modtime=%v}", addr, utim.Actime, utim.Modtime) } func stat(t *kernel.Task, addr usermem.Addr) string { if addr == 0 { return "null" } var stat linux.Stat if _, err := stat.CopyIn(t, addr); err != nil { return fmt.Sprintf("%#x (error decoding stat: %s)", addr, err) } return fmt.Sprintf("%#x {dev=%d, ino=%d, mode=%s, nlink=%d, uid=%d, gid=%d, rdev=%d, size=%d, blksize=%d, blocks=%d, atime=%s, mtime=%s, ctime=%s}", addr, stat.Dev, stat.Ino, linux.FileMode(stat.Mode), stat.Nlink, stat.UID, stat.GID, stat.Rdev, stat.Size, stat.Blksize, stat.Blocks, time.Unix(stat.ATime.Sec, stat.ATime.Nsec), time.Unix(stat.MTime.Sec, stat.MTime.Nsec), time.Unix(stat.CTime.Sec, stat.CTime.Nsec)) } func itimerval(t *kernel.Task, addr usermem.Addr) string { if addr == 0 { return "null" } interval := timeval(t, addr) value := timeval(t, addr+usermem.Addr((*linux.Timeval)(nil).SizeBytes())) return fmt.Sprintf("%#x {interval=%s, value=%s}", addr, interval, value) } func itimerspec(t *kernel.Task, addr usermem.Addr) string { if addr == 0 { return "null" } interval := timespec(t, addr) value := timespec(t, addr+usermem.Addr((*linux.Timespec)(nil).SizeBytes())) return fmt.Sprintf("%#x {interval=%s, value=%s}", addr, interval, value) } func stringVector(t *kernel.Task, addr usermem.Addr) string { vec, err := t.CopyInVector(addr, slinux.ExecMaxElemSize, slinux.ExecMaxTotalSize) if err != nil { return fmt.Sprintf("%#x {error copying vector: %v}", addr, err) } s := fmt.Sprintf("%#x [", addr) for i, v := range vec { if i != 0 { s += ", " } s += fmt.Sprintf("%q", v) } s += "]" return s } func rusage(t *kernel.Task, addr usermem.Addr) string { if addr == 0 { return "null" } var ru linux.Rusage if _, err := ru.CopyIn(t, addr); err != nil { return fmt.Sprintf("%#x (error decoding rusage: %s)", addr, err) } return fmt.Sprintf("%#x %+v", addr, ru) } func capHeader(t *kernel.Task, addr usermem.Addr) string { if addr == 0 { return "null" } var hdr linux.CapUserHeader if _, err := hdr.CopyIn(t, addr); err != nil { return fmt.Sprintf("%#x (error decoding header: %s)", addr, err) } var version string switch hdr.Version { case linux.LINUX_CAPABILITY_VERSION_1: version = "1" case linux.LINUX_CAPABILITY_VERSION_2: version = "2" case linux.LINUX_CAPABILITY_VERSION_3: version = "3" default: version = strconv.FormatUint(uint64(hdr.Version), 16) } return fmt.Sprintf("%#x {Version: %s, Pid: %d}", addr, version, hdr.Pid) } func capData(t *kernel.Task, hdrAddr, dataAddr usermem.Addr) string { if dataAddr == 0 { return "null" } var hdr linux.CapUserHeader if _, err := hdr.CopyIn(t, hdrAddr); err != nil { return fmt.Sprintf("%#x (error decoding header: %v)", dataAddr, err) } var p, i, e uint64 switch hdr.Version { case linux.LINUX_CAPABILITY_VERSION_1: var data linux.CapUserData if _, err := data.CopyIn(t, dataAddr); err != nil { return fmt.Sprintf("%#x (error decoding data: %v)", dataAddr, err) } p = uint64(data.Permitted) i = uint64(data.Inheritable) e = uint64(data.Effective) case linux.LINUX_CAPABILITY_VERSION_2, linux.LINUX_CAPABILITY_VERSION_3: var data [2]linux.CapUserData if _, err := linux.CopyCapUserDataSliceIn(t, dataAddr, data[:]); err != nil { return fmt.Sprintf("%#x (error decoding data: %v)", dataAddr, err) } p = uint64(data[0].Permitted) | (uint64(data[1].Permitted) << 32) i = uint64(data[0].Inheritable) | (uint64(data[1].Inheritable) << 32) e = uint64(data[0].Effective) | (uint64(data[1].Effective) << 32) default: return fmt.Sprintf("%#x (unknown version %d)", dataAddr, hdr.Version) } return fmt.Sprintf("%#x {Permitted: %s, Inheritable: %s, Effective: %s}", dataAddr, CapabilityBitset.Parse(p), CapabilityBitset.Parse(i), CapabilityBitset.Parse(e)) } // pre fills in the pre-execution arguments for a system call. If an argument // cannot be interpreted before the system call is executed, then a hex value // will be used. Note that a full output slice will always be provided, that is // len(return) == len(args). func (i *SyscallInfo) pre(t *kernel.Task, args arch.SyscallArguments, maximumBlobSize uint) []string { var output []string for arg := range args { if arg >= len(i.format) { break } switch i.format[arg] { case FD: output = append(output, fd(t, args[arg].Int())) case WriteBuffer: output = append(output, dump(t, args[arg].Pointer(), args[arg+1].SizeT(), maximumBlobSize)) case WriteIOVec: output = append(output, iovecs(t, args[arg].Pointer(), int(args[arg+1].Int()), true /* content */, uint64(maximumBlobSize))) case IOVec: output = append(output, iovecs(t, args[arg].Pointer(), int(args[arg+1].Int()), false /* content */, uint64(maximumBlobSize))) case SendMsgHdr: output = append(output, msghdr(t, args[arg].Pointer(), true /* content */, uint64(maximumBlobSize))) case RecvMsgHdr: output = append(output, msghdr(t, args[arg].Pointer(), false /* content */, uint64(maximumBlobSize))) case Path: output = append(output, path(t, args[arg].Pointer())) case ExecveStringVector: output = append(output, stringVector(t, args[arg].Pointer())) case SetSockOptVal: output = append(output, sockOptVal(t, args[arg-2].Uint64() /* level */, args[arg-1].Uint64() /* optName */, args[arg].Pointer() /* optVal */, args[arg+1].Uint64() /* optLen */, maximumBlobSize)) case SockOptLevel: output = append(output, sockOptLevels.Parse(args[arg].Uint64())) case SockOptName: output = append(output, sockOptNames[args[arg-1].Uint64() /* level */].Parse(args[arg].Uint64())) case SockAddr: output = append(output, sockAddr(t, args[arg].Pointer(), uint32(args[arg+1].Uint64()))) case SockLen: output = append(output, sockLenPointer(t, args[arg].Pointer())) case SockFamily: output = append(output, SocketFamily.Parse(uint64(args[arg].Int()))) case SockType: output = append(output, sockType(args[arg].Int())) case SockProtocol: output = append(output, sockProtocol(args[arg-2].Int(), args[arg].Int())) case SockFlags: output = append(output, sockFlags(args[arg].Int())) case Timespec: output = append(output, timespec(t, args[arg].Pointer())) case UTimeTimespec: output = append(output, utimensTimespec(t, args[arg].Pointer())) case ItimerVal: output = append(output, itimerval(t, args[arg].Pointer())) case ItimerSpec: output = append(output, itimerspec(t, args[arg].Pointer())) case Timeval: output = append(output, timeval(t, args[arg].Pointer())) case Utimbuf: output = append(output, utimbuf(t, args[arg].Pointer())) case CloneFlags: output = append(output, CloneFlagSet.Parse(uint64(args[arg].Uint()))) case OpenFlags: output = append(output, open(uint64(args[arg].Uint()))) case Mode: output = append(output, linux.FileMode(args[arg].ModeT()).String()) case FutexOp: output = append(output, futex(uint64(args[arg].Uint()))) case PtraceRequest: output = append(output, PtraceRequestSet.Parse(args[arg].Uint64())) case ItimerType: output = append(output, ItimerTypes.Parse(uint64(args[arg].Int()))) case Signal: output = append(output, signalNames.ParseDecimal(args[arg].Uint64())) case SignalMaskAction: output = append(output, signalMaskActions.Parse(uint64(args[arg].Int()))) case SigSet: output = append(output, sigSet(t, args[arg].Pointer())) case SigAction: output = append(output, sigAction(t, args[arg].Pointer())) case CapHeader: output = append(output, capHeader(t, args[arg].Pointer())) case CapData: output = append(output, capData(t, args[arg-1].Pointer(), args[arg].Pointer())) case PollFDs: output = append(output, pollFDs(t, args[arg].Pointer(), uint(args[arg+1].Uint()), false)) case EpollCtlOp: output = append(output, epollCtlOps.Parse(uint64(args[arg].Int()))) case EpollEvent: output = append(output, epollEvent(t, args[arg].Pointer())) case EpollEvents: output = append(output, epollEvents(t, args[arg].Pointer(), 0 /* numEvents */, uint64(maximumBlobSize))) case SelectFDSet: output = append(output, fdSet(t, int(args[0].Int()), args[arg].Pointer())) case Oct: output = append(output, "0o"+strconv.FormatUint(args[arg].Uint64(), 8)) case Hex: fallthrough default: output = append(output, hexArg(args[arg])) } } return output } // post fills in the post-execution arguments for a system call. This modifies // the given output slice in place with arguments that may only be interpreted // after the system call has been executed. func (i *SyscallInfo) post(t *kernel.Task, args arch.SyscallArguments, rval uintptr, output []string, maximumBlobSize uint) { for arg := range output { if arg >= len(i.format) { break } switch i.format[arg] { case ReadBuffer: output[arg] = dump(t, args[arg].Pointer(), uint(rval), maximumBlobSize) case ReadIOVec: printLength := uint64(rval) if printLength > uint64(maximumBlobSize) { printLength = uint64(maximumBlobSize) } output[arg] = iovecs(t, args[arg].Pointer(), int(args[arg+1].Int()), true /* content */, printLength) case WriteIOVec, IOVec, WriteBuffer: // We already have a big blast from write. output[arg] = "..." case SendMsgHdr: output[arg] = msghdr(t, args[arg].Pointer(), false /* content */, uint64(maximumBlobSize)) case RecvMsgHdr: output[arg] = msghdr(t, args[arg].Pointer(), true /* content */, uint64(maximumBlobSize)) case PostPath: output[arg] = path(t, args[arg].Pointer()) case PipeFDs: output[arg] = fdpair(t, args[arg].Pointer()) case Uname: output[arg] = uname(t, args[arg].Pointer()) case Stat: output[arg] = stat(t, args[arg].Pointer()) case PostSockAddr: output[arg] = postSockAddr(t, args[arg].Pointer(), args[arg+1].Pointer()) case SockLen: output[arg] = sockLenPointer(t, args[arg].Pointer()) case PostTimespec: output[arg] = timespec(t, args[arg].Pointer()) case PostItimerVal: output[arg] = itimerval(t, args[arg].Pointer()) case PostItimerSpec: output[arg] = itimerspec(t, args[arg].Pointer()) case Timeval: output[arg] = timeval(t, args[arg].Pointer()) case Rusage: output[arg] = rusage(t, args[arg].Pointer()) case PostSigSet: output[arg] = sigSet(t, args[arg].Pointer()) case PostSigAction: output[arg] = sigAction(t, args[arg].Pointer()) case PostCapData: output[arg] = capData(t, args[arg-1].Pointer(), args[arg].Pointer()) case PollFDs: output[arg] = pollFDs(t, args[arg].Pointer(), uint(args[arg+1].Uint()), true) case EpollEvents: output[arg] = epollEvents(t, args[arg].Pointer(), uint64(rval), uint64(maximumBlobSize)) case GetSockOptVal: output[arg] = getSockOptVal(t, args[arg-2].Uint64() /* level */, args[arg-1].Uint64() /* optName */, args[arg].Pointer() /* optVal */, args[arg+1].Pointer() /* optLen */, maximumBlobSize, rval) case SetSockOptVal: // No need to print the value again. While it usually // isn't, the string version of this arg can be long. output[arg] = hexArg(args[arg]) } } } // printEntry prints the given system call entry. func (i *SyscallInfo) printEnter(t *kernel.Task, args arch.SyscallArguments) []string { output := i.pre(t, args, LogMaximumSize) switch len(output) { case 0: t.Infof("%s E %s()", t.Name(), i.name) case 1: t.Infof("%s E %s(%s)", t.Name(), i.name, output[0]) case 2: t.Infof("%s E %s(%s, %s)", t.Name(), i.name, output[0], output[1]) case 3: t.Infof("%s E %s(%s, %s, %s)", t.Name(), i.name, output[0], output[1], output[2]) case 4: t.Infof("%s E %s(%s, %s, %s, %s)", t.Name(), i.name, output[0], output[1], output[2], output[3]) case 5: t.Infof("%s E %s(%s, %s, %s, %s, %s)", t.Name(), i.name, output[0], output[1], output[2], output[3], output[4]) case 6: t.Infof("%s E %s(%s, %s, %s, %s, %s, %s)", t.Name(), i.name, output[0], output[1], output[2], output[3], output[4], output[5]) } return output } // printExit prints the given system call exit. func (i *SyscallInfo) printExit(t *kernel.Task, elapsed time.Duration, output []string, args arch.SyscallArguments, retval uintptr, err error, errno int) { var rval string if err == nil { // Fill in the output after successful execution. i.post(t, args, retval, output, LogMaximumSize) rval = fmt.Sprintf("%#x (%v)", retval, elapsed) } else { rval = fmt.Sprintf("%#x errno=%d (%s) (%v)", retval, errno, err, elapsed) } switch len(output) { case 0: t.Infof("%s X %s() = %s", t.Name(), i.name, rval) case 1: t.Infof("%s X %s(%s) = %s", t.Name(), i.name, output[0], rval) case 2: t.Infof("%s X %s(%s, %s) = %s", t.Name(), i.name, output[0], output[1], rval) case 3: t.Infof("%s X %s(%s, %s, %s) = %s", t.Name(), i.name, output[0], output[1], output[2], rval) case 4: t.Infof("%s X %s(%s, %s, %s, %s) = %s", t.Name(), i.name, output[0], output[1], output[2], output[3], rval) case 5: t.Infof("%s X %s(%s, %s, %s, %s, %s) = %s", t.Name(), i.name, output[0], output[1], output[2], output[3], output[4], rval) case 6: t.Infof("%s X %s(%s, %s, %s, %s, %s, %s) = %s", t.Name(), i.name, output[0], output[1], output[2], output[3], output[4], output[5], rval) } } // sendEnter sends the syscall enter to event log. func (i *SyscallInfo) sendEnter(t *kernel.Task, args arch.SyscallArguments) []string { output := i.pre(t, args, EventMaximumSize) event := pb.Strace{ Process: t.Name(), Function: i.name, Info: &pb.Strace_Enter{ Enter: &pb.StraceEnter{}, }, } for _, arg := range output { event.Args = append(event.Args, arg) } eventchannel.Emit(&event) return output } // sendExit sends the syscall exit to event log. func (i *SyscallInfo) sendExit(t *kernel.Task, elapsed time.Duration, output []string, args arch.SyscallArguments, rval uintptr, err error, errno int) { if err == nil { // Fill in the output after successful execution. i.post(t, args, rval, output, EventMaximumSize) } exit := &pb.StraceExit{ Return: fmt.Sprintf("%#x", rval), ElapsedNs: elapsed.Nanoseconds(), } if err != nil { exit.Error = err.Error() exit.ErrNo = int64(errno) } event := pb.Strace{ Process: t.Name(), Function: i.name, Info: &pb.Strace_Exit{Exit: exit}, } for _, arg := range output { event.Args = append(event.Args, arg) } eventchannel.Emit(&event) } type syscallContext struct { info SyscallInfo args arch.SyscallArguments start time.Time logOutput []string eventOutput []string flags uint32 } // SyscallEnter implements kernel.Stracer.SyscallEnter. It logs the syscall // entry trace. func (s SyscallMap) SyscallEnter(t *kernel.Task, sysno uintptr, args arch.SyscallArguments, flags uint32) interface{} { info, ok := s[sysno] if !ok { info = SyscallInfo{ name: fmt.Sprintf("sys_%d", sysno), format: defaultFormat, } } var output, eventOutput []string if bits.IsOn32(flags, kernel.StraceEnableLog) { output = info.printEnter(t, args) } if bits.IsOn32(flags, kernel.StraceEnableEvent) { eventOutput = info.sendEnter(t, args) } return &syscallContext{ info: info, args: args, start: time.Now(), logOutput: output, eventOutput: eventOutput, flags: flags, } } // SyscallExit implements kernel.Stracer.SyscallExit. It logs the syscall // exit trace. func (s SyscallMap) SyscallExit(context interface{}, t *kernel.Task, sysno, rval uintptr, err error) { errno := kernel.ExtractErrno(err, int(sysno)) c := context.(*syscallContext) elapsed := time.Since(c.start) if bits.IsOn32(c.flags, kernel.StraceEnableLog) { c.info.printExit(t, elapsed, c.logOutput, c.args, rval, err, errno) } if bits.IsOn32(c.flags, kernel.StraceEnableEvent) { c.info.sendExit(t, elapsed, c.eventOutput, c.args, rval, err, errno) } } // ConvertToSysnoMap converts the names to a map keyed on the syscall number // and value set to true. // // The map is in a convenient format to pass to SyscallFlagsTable.Enable(). func (s SyscallMap) ConvertToSysnoMap(syscalls []string) (map[uintptr]bool, error) { if syscalls == nil { // Sentinel: no list. return nil, nil } l := make(map[uintptr]bool) for _, sc := range syscalls { // Try to match this system call. sysno, ok := s.ConvertToSysno(sc) if !ok { return nil, fmt.Errorf("syscall %q not found", sc) } l[sysno] = true } // Success. return l, nil } // ConvertToSysno converts the name to system call number. Returns false // if syscall with same name is not found. func (s SyscallMap) ConvertToSysno(syscall string) (uintptr, bool) { for sysno, info := range s { if info.name != "" && info.name == syscall { return sysno, true } } return 0, false } // Name returns the syscall name. func (s SyscallMap) Name(sysno uintptr) string { if info, ok := s[sysno]; ok { return info.name } return fmt.Sprintf("sys_%d", sysno) } // Initialize prepares all syscall tables for use by this package. // // N.B. This is not in an init function because we can't be sure all syscall // tables are registered with the kernel when init runs. func Initialize() { for _, table := range kernel.SyscallTables() { // Is this known? sys, ok := Lookup(table.OS, table.Arch) if !ok { continue } table.Stracer = sys } } // SinkType defines where to send straces to. type SinkType uint32 const ( // SinkTypeLog sends straces to text log SinkTypeLog SinkType = 1 << iota // SinkTypeEvent sends strace to event log SinkTypeEvent ) func convertToSyscallFlag(sinks SinkType) uint32 { ret := uint32(0) if bits.IsOn32(uint32(sinks), uint32(SinkTypeLog)) { ret |= kernel.StraceEnableLog } if bits.IsOn32(uint32(sinks), uint32(SinkTypeEvent)) { ret |= kernel.StraceEnableEvent } return ret } // Enable enables the syscalls in whitelist in all syscall tables. // // Preconditions: Initialize has been called. func Enable(whitelist []string, sinks SinkType) error { flags := convertToSyscallFlag(sinks) for _, table := range kernel.SyscallTables() { // Is this known? sys, ok := Lookup(table.OS, table.Arch) if !ok { continue } // Convert to a set of system calls numbers. wl, err := sys.ConvertToSysnoMap(whitelist) if err != nil { return err } table.FeatureEnable.Enable(flags, wl, true) } // Done. return nil } // Disable will disable Strace for all system calls and missing syscalls. // // Preconditions: Initialize has been called. func Disable(sinks SinkType) { flags := convertToSyscallFlag(sinks) for _, table := range kernel.SyscallTables() { // Strace will be disabled for all syscalls including missing. table.FeatureEnable.Enable(flags, nil, false) } } // EnableAll enables all syscalls in all syscall tables. // // Preconditions: Initialize has been called. func EnableAll(sinks SinkType) { flags := convertToSyscallFlag(sinks) for _, table := range kernel.SyscallTables() { // Is this known? if _, ok := Lookup(table.OS, table.Arch); !ok { continue } table.FeatureEnable.EnableAll(flags) } } func init() { t, ok := Lookup(abi.Host, arch.Host) if ok { // Provide the native table as the lookup for seccomp // debugging. This is best-effort. This is provided this way to // avoid dependencies from seccomp to this package. seccomp.SyscallName = t.Name } }