gvisor.dev/gvisor@v0.0.0-20240520182842-f9d4d51c7e0f/pkg/sentry/platform/ptrace/subprocess_amd64.go (about)

     1  // Copyright 2018 The gVisor Authors.
     2  //
     3  // Licensed under the Apache License, Version 2.0 (the "License");
     4  // you may not use this file except in compliance with the License.
     5  // You may obtain a copy of the License at
     6  //
     7  //     http://www.apache.org/licenses/LICENSE-2.0
     8  //
     9  // Unless required by applicable law or agreed to in writing, software
    10  // distributed under the License is distributed on an "AS IS" BASIS,
    11  // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
    12  // See the License for the specific language governing permissions and
    13  // limitations under the License.
    14  
    15  //go:build amd64
    16  // +build amd64
    17  
    18  package ptrace
    19  
    20  import (
    21  	"fmt"
    22  	"strings"
    23  
    24  	"golang.org/x/sys/unix"
    25  	"gvisor.dev/gvisor/pkg/abi/linux"
    26  	"gvisor.dev/gvisor/pkg/seccomp"
    27  	"gvisor.dev/gvisor/pkg/sentry/arch"
    28  )
    29  
    30  const (
    31  	// initRegsRipAdjustment is the size of the syscall instruction.
    32  	initRegsRipAdjustment = 2
    33  )
    34  
    35  // resetSysemuRegs sets up emulation registers.
    36  //
    37  // This should be called prior to calling sysemu.
    38  func (t *thread) resetSysemuRegs(regs *arch.Registers) {
    39  	regs.Cs = t.initRegs.Cs
    40  	regs.Ss = t.initRegs.Ss
    41  	regs.Ds = t.initRegs.Ds
    42  	regs.Es = t.initRegs.Es
    43  	regs.Fs = t.initRegs.Fs
    44  	regs.Gs = t.initRegs.Gs
    45  }
    46  
    47  // createSyscallRegs sets up syscall registers.
    48  //
    49  // This should be called to generate registers for a system call.
    50  func createSyscallRegs(initRegs *arch.Registers, sysno uintptr, args ...arch.SyscallArgument) arch.Registers {
    51  	// Copy initial registers.
    52  	regs := *initRegs
    53  
    54  	// Set our syscall number.
    55  	regs.Rax = uint64(sysno)
    56  	if len(args) >= 1 {
    57  		regs.Rdi = args[0].Uint64()
    58  	}
    59  	if len(args) >= 2 {
    60  		regs.Rsi = args[1].Uint64()
    61  	}
    62  	if len(args) >= 3 {
    63  		regs.Rdx = args[2].Uint64()
    64  	}
    65  	if len(args) >= 4 {
    66  		regs.R10 = args[3].Uint64()
    67  	}
    68  	if len(args) >= 5 {
    69  		regs.R8 = args[4].Uint64()
    70  	}
    71  	if len(args) >= 6 {
    72  		regs.R9 = args[5].Uint64()
    73  	}
    74  
    75  	return regs
    76  }
    77  
    78  // isSingleStepping determines if the registers indicate single-stepping.
    79  func isSingleStepping(regs *arch.Registers) bool {
    80  	return (regs.Eflags & arch.X86TrapFlag) != 0
    81  }
    82  
    83  // updateSyscallRegs updates registers after finishing sysemu.
    84  func updateSyscallRegs(regs *arch.Registers) {
    85  	// Ptrace puts -ENOSYS in rax on syscall-enter-stop.
    86  	regs.Rax = regs.Orig_rax
    87  }
    88  
    89  // syscallReturnValue extracts a sensible return from registers.
    90  func syscallReturnValue(regs *arch.Registers) (uintptr, error) {
    91  	rval := int64(regs.Rax)
    92  	if rval < 0 {
    93  		return 0, unix.Errno(-rval)
    94  	}
    95  	return uintptr(rval), nil
    96  }
    97  
    98  func dumpRegs(regs *arch.Registers) string {
    99  	var m strings.Builder
   100  
   101  	fmt.Fprintf(&m, "Registers:\n")
   102  	fmt.Fprintf(&m, "\tR15\t = %016x\n", regs.R15)
   103  	fmt.Fprintf(&m, "\tR14\t = %016x\n", regs.R14)
   104  	fmt.Fprintf(&m, "\tR13\t = %016x\n", regs.R13)
   105  	fmt.Fprintf(&m, "\tR12\t = %016x\n", regs.R12)
   106  	fmt.Fprintf(&m, "\tRbp\t = %016x\n", regs.Rbp)
   107  	fmt.Fprintf(&m, "\tRbx\t = %016x\n", regs.Rbx)
   108  	fmt.Fprintf(&m, "\tR11\t = %016x\n", regs.R11)
   109  	fmt.Fprintf(&m, "\tR10\t = %016x\n", regs.R10)
   110  	fmt.Fprintf(&m, "\tR9\t = %016x\n", regs.R9)
   111  	fmt.Fprintf(&m, "\tR8\t = %016x\n", regs.R8)
   112  	fmt.Fprintf(&m, "\tRax\t = %016x\n", regs.Rax)
   113  	fmt.Fprintf(&m, "\tRcx\t = %016x\n", regs.Rcx)
   114  	fmt.Fprintf(&m, "\tRdx\t = %016x\n", regs.Rdx)
   115  	fmt.Fprintf(&m, "\tRsi\t = %016x\n", regs.Rsi)
   116  	fmt.Fprintf(&m, "\tRdi\t = %016x\n", regs.Rdi)
   117  	fmt.Fprintf(&m, "\tOrig_rax = %016x\n", regs.Orig_rax)
   118  	fmt.Fprintf(&m, "\tRip\t = %016x\n", regs.Rip)
   119  	fmt.Fprintf(&m, "\tCs\t = %016x\n", regs.Cs)
   120  	fmt.Fprintf(&m, "\tEflags\t = %016x\n", regs.Eflags)
   121  	fmt.Fprintf(&m, "\tRsp\t = %016x\n", regs.Rsp)
   122  	fmt.Fprintf(&m, "\tSs\t = %016x\n", regs.Ss)
   123  	fmt.Fprintf(&m, "\tFs_base\t = %016x\n", regs.Fs_base)
   124  	fmt.Fprintf(&m, "\tGs_base\t = %016x\n", regs.Gs_base)
   125  	fmt.Fprintf(&m, "\tDs\t = %016x\n", regs.Ds)
   126  	fmt.Fprintf(&m, "\tEs\t = %016x\n", regs.Es)
   127  	fmt.Fprintf(&m, "\tFs\t = %016x\n", regs.Fs)
   128  	fmt.Fprintf(&m, "\tGs\t = %016x\n", regs.Gs)
   129  
   130  	return m.String()
   131  }
   132  
   133  // adjustInitregsRip adjust the current register RIP value to
   134  // be just before the system call instruction execution
   135  func (t *thread) adjustInitRegsRip() {
   136  	t.initRegs.Rip -= initRegsRipAdjustment
   137  }
   138  
   139  // Pass the expected PPID to the child via R15 when creating stub process.
   140  func initChildProcessPPID(initregs *arch.Registers, ppid int32) {
   141  	initregs.R15 = uint64(ppid)
   142  	// Rbx has to be set to 1 when creating stub process.
   143  	initregs.Rbx = 1
   144  }
   145  
   146  // patchSignalInfo patches the signal info to account for hitting the seccomp
   147  // filters from vsyscall emulation, specified below. We allow for SIGSYS as a
   148  // synchronous trap, but patch the structure to appear like a SIGSEGV with the
   149  // Rip as the faulting address.
   150  //
   151  // Note that this should only be called after verifying that the signalInfo has
   152  // been generated by the kernel.
   153  func patchSignalInfo(regs *arch.Registers, signalInfo *linux.SignalInfo) {
   154  	if linux.Signal(signalInfo.Signo) == linux.SIGSYS {
   155  		signalInfo.Signo = int32(linux.SIGSEGV)
   156  
   157  		// Unwind the kernel emulation, if any has occurred. A SIGSYS is delivered
   158  		// with the si_call_addr field pointing to the current RIP. This field
   159  		// aligns with the si_addr field for a SIGSEGV, so we don't need to touch
   160  		// anything there. We do need to unwind emulation however, so we set the
   161  		// instruction pointer to the faulting value, and "unpop" the stack.
   162  		regs.Rip = signalInfo.Addr()
   163  		regs.Rsp -= 8
   164  	}
   165  }
   166  
   167  // enableCpuidFault enables cpuid-faulting.
   168  //
   169  // This may fail on older kernels or hardware, so we just disregard the result.
   170  // Host CPUID will be enabled.
   171  //
   172  // This is safe to call in an afterFork context.
   173  //
   174  //go:norace
   175  //go:nosplit
   176  func enableCpuidFault() {
   177  	unix.RawSyscall6(unix.SYS_ARCH_PRCTL, linux.ARCH_SET_CPUID, 0, 0, 0, 0, 0)
   178  }
   179  
   180  // appendArchSeccompRules append architecture specific seccomp rules when creating BPF program.
   181  // Ref attachedThread() for more detail.
   182  func appendArchSeccompRules(rules []seccomp.RuleSet, defaultAction linux.BPFAction) []seccomp.RuleSet {
   183  	rules = append(rules,
   184  		// Rules for trapping vsyscall access.
   185  		seccomp.RuleSet{
   186  			Rules: seccomp.MakeSyscallRules(map[uintptr]seccomp.SyscallRule{
   187  				unix.SYS_GETTIMEOFDAY: seccomp.MatchAll{},
   188  				unix.SYS_TIME:         seccomp.MatchAll{},
   189  				unix.SYS_GETCPU:       seccomp.MatchAll{}, // SYS_GETCPU was not defined in package syscall on amd64.
   190  			}),
   191  			Action:   linux.SECCOMP_RET_TRAP,
   192  			Vsyscall: true,
   193  		})
   194  	if defaultAction != linux.SECCOMP_RET_ALLOW {
   195  		rules = append(rules,
   196  			seccomp.RuleSet{
   197  				Rules: seccomp.MakeSyscallRules(map[uintptr]seccomp.SyscallRule{
   198  					unix.SYS_ARCH_PRCTL: seccomp.PerArg{
   199  						seccomp.EqualTo(linux.ARCH_SET_CPUID),
   200  						seccomp.EqualTo(0),
   201  					},
   202  				}),
   203  				Action: linux.SECCOMP_RET_ALLOW,
   204  			})
   205  	}
   206  	return rules
   207  }
   208  
   209  // probeSeccomp returns true iff seccomp is run after ptrace notifications,
   210  // which is generally the case for kernel version >= 4.8. This check is dynamic
   211  // because kernels have be backported behavior.
   212  //
   213  // See createStub for more information.
   214  //
   215  // Precondition: the runtime OS thread must be locked.
   216  func probeSeccomp() bool {
   217  	// Create a completely new, destroyable process.
   218  	t, err := attachedThread(0, linux.SECCOMP_RET_ERRNO)
   219  	if err != nil {
   220  		panic(fmt.Sprintf("seccomp probe failed: %v", err))
   221  	}
   222  	defer t.destroy()
   223  
   224  	// Set registers to the yield system call. This call is not allowed
   225  	// by the filters specified in the attachThread function.
   226  	regs := createSyscallRegs(&t.initRegs, unix.SYS_SCHED_YIELD)
   227  	if err := t.setRegs(&regs); err != nil {
   228  		panic(fmt.Sprintf("ptrace set regs failed: %v", err))
   229  	}
   230  
   231  	for {
   232  		// Attempt an emulation.
   233  		if _, _, errno := unix.RawSyscall6(unix.SYS_PTRACE, unix.PTRACE_SYSEMU, uintptr(t.tid), 0, 0, 0, 0); errno != 0 {
   234  			panic(fmt.Sprintf("ptrace syscall-enter failed: %v", errno))
   235  		}
   236  
   237  		sig := t.wait(stopped)
   238  		if sig == (syscallEvent | unix.SIGTRAP) {
   239  			// Did the seccomp errno hook already run? This would
   240  			// indicate that seccomp is first in line and we're
   241  			// less than 4.8.
   242  			if err := t.getRegs(&regs); err != nil {
   243  				panic(fmt.Sprintf("ptrace get-regs failed: %v", err))
   244  			}
   245  			if _, err := syscallReturnValue(&regs); err == nil {
   246  				// The seccomp errno mode ran first, and reset
   247  				// the error in the registers.
   248  				return false
   249  			}
   250  			// The seccomp hook did not run yet, and therefore it
   251  			// is safe to use RET_KILL mode for dispatched calls.
   252  			return true
   253  		}
   254  	}
   255  }
   256  
   257  func (s *subprocess) arm64SyscallWorkaround(t *thread, regs *arch.Registers) {
   258  }