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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 loader loads an executable file into a MemoryManager.
package loader
import (
"bytes"
"fmt"
"io"
"path"
"gvisor.dev/gvisor/pkg/abi"
"gvisor.dev/gvisor/pkg/abi/linux"
"gvisor.dev/gvisor/pkg/abi/linux/errno"
"gvisor.dev/gvisor/pkg/context"
"gvisor.dev/gvisor/pkg/cpuid"
"gvisor.dev/gvisor/pkg/errors/linuxerr"
"gvisor.dev/gvisor/pkg/hostarch"
"gvisor.dev/gvisor/pkg/rand"
"gvisor.dev/gvisor/pkg/sentry/arch"
"gvisor.dev/gvisor/pkg/sentry/fsbridge"
"gvisor.dev/gvisor/pkg/sentry/kernel/auth"
"gvisor.dev/gvisor/pkg/sentry/mm"
"gvisor.dev/gvisor/pkg/sentry/vfs"
"gvisor.dev/gvisor/pkg/syserr"
"gvisor.dev/gvisor/pkg/usermem"
)
// LoadArgs holds specifications for an executable file to be loaded.
type LoadArgs struct {
// MemoryManager is the memory manager to load the executable into.
MemoryManager *mm.MemoryManager
// RemainingTraversals is the maximum number of symlinks to follow to
// resolve Filename. This counter is passed by reference to keep it
// updated throughout the call stack.
RemainingTraversals *uint
// ResolveFinal indicates whether the final link of Filename should be
// resolved, if it is a symlink.
ResolveFinal bool
// Filename is the path for the executable.
Filename string
// File is an open fs.File object of the executable. If File is not
// nil, then File will be loaded and Filename will be ignored.
//
// The caller is responsible for checking that the user can execute this file.
File fsbridge.File
// Opener is used to open the executable file when 'File' is nil.
Opener fsbridge.Lookup
// CloseOnExec indicates that the executable (or one of its parent
// directories) was opened with O_CLOEXEC. If the executable is an
// interpreter script, then cause an ENOENT error to occur, since the
// script would otherwise be inaccessible to the interpreter.
CloseOnExec bool
// Argv is the vector of arguments to pass to the executable.
Argv []string
// Envv is the vector of environment variables to pass to the
// executable.
Envv []string
// Features specifies the CPU feature set for the executable.
Features *cpuid.FeatureSet
}
// openPath opens args.Filename and checks that it is valid for loading.
//
// openPath returns an *fs.Dirent and *fs.File for args.Filename, which is not
// installed in the Task FDTable. The caller takes ownership of both.
//
// args.Filename must be a readable, executable, regular file.
func openPath(ctx context.Context, args LoadArgs) (fsbridge.File, error) {
if args.Filename == "" {
ctx.Infof("cannot open empty name")
return nil, linuxerr.ENOENT
}
// TODO(gvisor.dev/issue/160): Linux requires only execute permission,
// not read. However, our backing filesystems may prevent us from reading
// the file without read permission. Additionally, a task with a
// non-readable executable has additional constraints on access via
// ptrace and procfs.
opts := vfs.OpenOptions{
Flags: linux.O_RDONLY,
FileExec: true,
}
return args.Opener.OpenPath(ctx, args.Filename, opts, args.RemainingTraversals, args.ResolveFinal)
}
// checkIsRegularFile prevents us from trying to execute a directory, pipe, etc.
func checkIsRegularFile(ctx context.Context, file fsbridge.File, filename string) error {
t, err := file.Type(ctx)
if err != nil {
return err
}
if t != linux.ModeRegular {
ctx.Infof("%q is not a regular file: %v", filename, t)
return linuxerr.EACCES
}
return nil
}
// allocStack allocates and maps a stack in to any available part of the address space.
func allocStack(ctx context.Context, m *mm.MemoryManager, a arch.Context) (*arch.Stack, error) {
ar, err := m.MapStack(ctx)
if err != nil {
return nil, err
}
return &arch.Stack{Arch: a, IO: m, Bottom: ar.End}, nil
}
const (
// maxLoaderAttempts is the maximum number of attempts to try to load
// an interpreter scripts, to prevent loops. 6 (initial + 5 changes) is
// what the Linux kernel allows (fs/exec.c:search_binary_handler).
maxLoaderAttempts = 6
)
// loadExecutable loads an executable that is pointed to by args.File. The
// caller is responsible for checking that the user can execute this file.
// If nil, the path args.Filename is resolved and loaded (check that the user
// can execute this file is done here in this case). If the executable is an
// interpreter script rather than an ELF, the binary of the corresponding
// interpreter will be loaded.
//
// It returns:
// * loadedELF, description of the loaded binary
// * arch.Context matching the binary arch
// * fs.Dirent of the binary file
// * Possibly updated args.Argv
func loadExecutable(ctx context.Context, args LoadArgs) (loadedELF, arch.Context, fsbridge.File, []string, error) {
for i := 0; i < maxLoaderAttempts; i++ {
if args.File == nil {
var err error
args.File, err = openPath(ctx, args)
if err != nil {
ctx.Infof("Error opening %s: %v", args.Filename, err)
return loadedELF{}, nil, nil, nil, err
}
// Ensure file is release in case the code loops or errors out.
defer args.File.DecRef(ctx)
} else {
if err := checkIsRegularFile(ctx, args.File, args.Filename); err != nil {
return loadedELF{}, nil, nil, nil, err
}
}
// Check the header. Is this an ELF or interpreter script?
var hdr [4]uint8
// N.B. We assume that reading from a regular file cannot block.
_, err := args.File.ReadFull(ctx, usermem.BytesIOSequence(hdr[:]), 0)
// Allow unexpected EOF, as a valid executable could be only three bytes
// (e.g., #!a).
if err != nil && err != io.ErrUnexpectedEOF {
if err == io.EOF {
err = linuxerr.ENOEXEC
}
return loadedELF{}, nil, nil, nil, err
}
switch {
case bytes.Equal(hdr[:], []byte(elfMagic)):
loaded, ac, err := loadELF(ctx, args)
if err != nil {
ctx.Infof("Error loading ELF: %v", err)
return loadedELF{}, nil, nil, nil, err
}
// An ELF is always terminal. Hold on to file.
args.File.IncRef()
return loaded, ac, args.File, args.Argv, err
case bytes.Equal(hdr[:2], []byte(interpreterScriptMagic)):
if args.CloseOnExec {
return loadedELF{}, nil, nil, nil, linuxerr.ENOENT
}
args.Filename, args.Argv, err = parseInterpreterScript(ctx, args.Filename, args.File, args.Argv)
if err != nil {
ctx.Infof("Error loading interpreter script: %v", err)
return loadedELF{}, nil, nil, nil, err
}
// Refresh the traversal limit for the interpreter.
*args.RemainingTraversals = linux.MaxSymlinkTraversals
default:
ctx.Infof("Unknown magic: %v", hdr)
return loadedELF{}, nil, nil, nil, linuxerr.ENOEXEC
}
// Set to nil in case we loop on a Interpreter Script.
args.File = nil
}
return loadedELF{}, nil, nil, nil, linuxerr.ELOOP
}
// Load loads args.File into a MemoryManager. If args.File is nil, the path
// args.Filename is resolved and loaded instead.
//
// If Load returns ErrSwitchFile it should be called again with the returned
// path and argv.
//
// Preconditions:
// * The Task MemoryManager is empty.
// * Load is called on the Task goroutine.
func Load(ctx context.Context, args LoadArgs, extraAuxv []arch.AuxEntry, vdso *VDSO) (abi.OS, arch.Context, string, *syserr.Error) {
// Load the executable itself.
loaded, ac, file, newArgv, err := loadExecutable(ctx, args)
if err != nil {
return 0, nil, "", syserr.NewDynamic(fmt.Sprintf("failed to load %s: %v", args.Filename, err), syserr.FromError(err).ToLinux())
}
defer file.DecRef(ctx)
// Load the VDSO.
vdsoAddr, err := loadVDSO(ctx, args.MemoryManager, vdso, loaded)
if err != nil {
return 0, nil, "", syserr.NewDynamic(fmt.Sprintf("error loading VDSO: %v", err), syserr.FromError(err).ToLinux())
}
// Setup the heap. brk starts at the next page after the end of the
// executable. Userspace can assume that the remainer of the page after
// loaded.end is available for its use.
e, ok := loaded.end.RoundUp()
if !ok {
return 0, nil, "", syserr.NewDynamic(fmt.Sprintf("brk overflows: %#x", loaded.end), errno.ENOEXEC)
}
args.MemoryManager.BrkSetup(ctx, e)
// Allocate our stack.
stack, err := allocStack(ctx, args.MemoryManager, ac)
if err != nil {
return 0, nil, "", syserr.NewDynamic(fmt.Sprintf("Failed to allocate stack: %v", err), syserr.FromError(err).ToLinux())
}
// Push the original filename to the stack, for AT_EXECFN.
if _, err := stack.PushNullTerminatedByteSlice([]byte(args.Filename)); err != nil {
return 0, nil, "", syserr.NewDynamic(fmt.Sprintf("Failed to push exec filename: %v", err), syserr.FromError(err).ToLinux())
}
execfn := stack.Bottom
// Push 16 random bytes on the stack which AT_RANDOM will point to.
var b [16]byte
if _, err := rand.Read(b[:]); err != nil {
return 0, nil, "", syserr.NewDynamic(fmt.Sprintf("Failed to read random bytes: %v", err), syserr.FromError(err).ToLinux())
}
if _, err = stack.PushNullTerminatedByteSlice(b[:]); err != nil {
return 0, nil, "", syserr.NewDynamic(fmt.Sprintf("Failed to push random bytes: %v", err), syserr.FromError(err).ToLinux())
}
random := stack.Bottom
c := auth.CredentialsFromContext(ctx)
// Add generic auxv entries.
auxv := append(loaded.auxv, arch.Auxv{
arch.AuxEntry{linux.AT_UID, hostarch.Addr(c.RealKUID.In(c.UserNamespace).OrOverflow())},
arch.AuxEntry{linux.AT_EUID, hostarch.Addr(c.EffectiveKUID.In(c.UserNamespace).OrOverflow())},
arch.AuxEntry{linux.AT_GID, hostarch.Addr(c.RealKGID.In(c.UserNamespace).OrOverflow())},
arch.AuxEntry{linux.AT_EGID, hostarch.Addr(c.EffectiveKGID.In(c.UserNamespace).OrOverflow())},
// The conditions that require AT_SECURE = 1 never arise. See
// kernel.Task.updateCredsForExecLocked.
arch.AuxEntry{linux.AT_SECURE, 0},
arch.AuxEntry{linux.AT_CLKTCK, linux.CLOCKS_PER_SEC},
arch.AuxEntry{linux.AT_EXECFN, execfn},
arch.AuxEntry{linux.AT_RANDOM, random},
arch.AuxEntry{linux.AT_PAGESZ, hostarch.PageSize},
arch.AuxEntry{linux.AT_SYSINFO_EHDR, vdsoAddr},
}...)
auxv = append(auxv, extraAuxv...)
sl, err := stack.Load(newArgv, args.Envv, auxv)
if err != nil {
return 0, nil, "", syserr.NewDynamic(fmt.Sprintf("Failed to load stack: %v", err), syserr.FromError(err).ToLinux())
}
m := args.MemoryManager
m.SetArgvStart(sl.ArgvStart)
m.SetArgvEnd(sl.ArgvEnd)
m.SetEnvvStart(sl.EnvvStart)
m.SetEnvvEnd(sl.EnvvEnd)
m.SetAuxv(auxv)
m.SetExecutable(ctx, file)
symbolValue, err := getSymbolValueFromVDSO("rt_sigreturn")
if err != nil {
return 0, nil, "", syserr.NewDynamic(fmt.Sprintf("Failed to find rt_sigreturn in vdso: %v", err), syserr.FromError(err).ToLinux())
}
// Found rt_sigretrun.
addr := uint64(vdsoAddr) + symbolValue - vdsoPrelink
m.SetVDSOSigReturn(addr)
ac.SetIP(uintptr(loaded.entry))
ac.SetStack(uintptr(stack.Bottom))
name := path.Base(args.Filename)
if len(name) > linux.TASK_COMM_LEN-1 {
name = name[:linux.TASK_COMM_LEN-1]
}
return loaded.os, ac, name, nil
}
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