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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
import (
"bytes"
"debug/elf"
"fmt"
"io"
"gvisor.dev/gvisor/pkg/abi"
"gvisor.dev/gvisor/pkg/abi/linux"
"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/log"
"gvisor.dev/gvisor/pkg/sentry/arch"
"gvisor.dev/gvisor/pkg/sentry/fsbridge"
"gvisor.dev/gvisor/pkg/sentry/limits"
"gvisor.dev/gvisor/pkg/sentry/memmap"
"gvisor.dev/gvisor/pkg/sentry/mm"
"gvisor.dev/gvisor/pkg/syserror"
"gvisor.dev/gvisor/pkg/usermem"
)
const (
// elfMagic identifies an ELF file.
elfMagic = "\x7fELF"
// maxTotalPhdrSize is the maximum combined size of all program
// headers. Linux limits this to one page.
maxTotalPhdrSize = hostarch.PageSize
)
var (
// header64Size is the size of elf.Header64.
header64Size = (*linux.ElfHeader64)(nil).SizeBytes()
// Prog64Size is the size of elf.Prog64.
prog64Size = (*linux.ElfProg64)(nil).SizeBytes()
)
func progFlagsAsPerms(f elf.ProgFlag) hostarch.AccessType {
var p hostarch.AccessType
if f&elf.PF_R == elf.PF_R {
p.Read = true
}
if f&elf.PF_W == elf.PF_W {
p.Write = true
}
if f&elf.PF_X == elf.PF_X {
p.Execute = true
}
return p
}
// elfInfo contains the metadata needed to load an ELF binary.
type elfInfo struct {
// os is the target OS of the ELF.
os abi.OS
// arch is the target architecture of the ELF.
arch arch.Arch
// entry is the program entry point.
entry hostarch.Addr
// phdrs are the program headers.
phdrs []elf.ProgHeader
// phdrSize is the size of a single program header in the ELF.
phdrSize int
// phdrOff is the offset of the program headers in the file.
phdrOff uint64
// sharedObject is true if the ELF represents a shared object.
sharedObject bool
}
// fullReader interface extracts the ReadFull method from fsbridge.File so that
// client code does not need to define an entire fsbridge.File when only read
// functionality is needed.
//
// TODO(gvisor.dev/issue/1035): Once VFS2 ships, rewrite this to wrap
// vfs.FileDescription's PRead/Read instead.
type fullReader interface {
// ReadFull is the same as fsbridge.File.ReadFull.
ReadFull(ctx context.Context, dst usermem.IOSequence, offset int64) (int64, error)
}
// parseHeader parse the ELF header, verifying that this is a supported ELF
// file and returning the ELF program headers.
//
// This is similar to elf.NewFile, except that it is more strict about what it
// accepts from the ELF, and it doesn't parse unnecessary parts of the file.
func parseHeader(ctx context.Context, f fullReader) (elfInfo, error) {
// Check ident first; it will tell us the endianness of the rest of the
// structs.
var ident [elf.EI_NIDENT]byte
_, err := f.ReadFull(ctx, usermem.BytesIOSequence(ident[:]), 0)
if err != nil {
log.Infof("Error reading ELF ident: %v", err)
// The entire ident array always exists.
if err == io.EOF || err == io.ErrUnexpectedEOF {
err = syserror.ENOEXEC
}
return elfInfo{}, err
}
// Only some callers pre-check the ELF magic.
if !bytes.Equal(ident[:len(elfMagic)], []byte(elfMagic)) {
log.Infof("File is not an ELF")
return elfInfo{}, syserror.ENOEXEC
}
// We only support 64-bit, little endian binaries
if class := elf.Class(ident[elf.EI_CLASS]); class != elf.ELFCLASS64 {
log.Infof("Unsupported ELF class: %v", class)
return elfInfo{}, syserror.ENOEXEC
}
if endian := elf.Data(ident[elf.EI_DATA]); endian != elf.ELFDATA2LSB {
log.Infof("Unsupported ELF endianness: %v", endian)
return elfInfo{}, syserror.ENOEXEC
}
if version := elf.Version(ident[elf.EI_VERSION]); version != elf.EV_CURRENT {
log.Infof("Unsupported ELF version: %v", version)
return elfInfo{}, syserror.ENOEXEC
}
// EI_OSABI is ignored by Linux, which is the only OS supported.
os := abi.Linux
var hdr linux.ElfHeader64
hdrBuf := make([]byte, header64Size)
_, err = f.ReadFull(ctx, usermem.BytesIOSequence(hdrBuf), 0)
if err != nil {
log.Infof("Error reading ELF header: %v", err)
// The entire header always exists.
if err == io.EOF || err == io.ErrUnexpectedEOF {
err = syserror.ENOEXEC
}
return elfInfo{}, err
}
hdr.UnmarshalUnsafe(hdrBuf)
// We support amd64 and arm64.
var a arch.Arch
switch machine := elf.Machine(hdr.Machine); machine {
case elf.EM_X86_64:
a = arch.AMD64
case elf.EM_AARCH64:
a = arch.ARM64
default:
log.Infof("Unsupported ELF machine %d", machine)
return elfInfo{}, syserror.ENOEXEC
}
var sharedObject bool
elfType := elf.Type(hdr.Type)
switch elfType {
case elf.ET_EXEC:
sharedObject = false
case elf.ET_DYN:
sharedObject = true
default:
log.Infof("Unsupported ELF type %v", elfType)
return elfInfo{}, syserror.ENOEXEC
}
if int(hdr.Phentsize) != prog64Size {
log.Infof("Unsupported phdr size %d", hdr.Phentsize)
return elfInfo{}, syserror.ENOEXEC
}
totalPhdrSize := prog64Size * int(hdr.Phnum)
if totalPhdrSize < prog64Size {
log.Warningf("No phdrs or total phdr size overflows: prog64Size: %d phnum: %d", prog64Size, int(hdr.Phnum))
return elfInfo{}, syserror.ENOEXEC
}
if totalPhdrSize > maxTotalPhdrSize {
log.Infof("Too many phdrs (%d): total size %d > %d", hdr.Phnum, totalPhdrSize, maxTotalPhdrSize)
return elfInfo{}, syserror.ENOEXEC
}
if int64(hdr.Phoff) < 0 || int64(hdr.Phoff+uint64(totalPhdrSize)) < 0 {
ctx.Infof("Unsupported phdr offset %d", hdr.Phoff)
return elfInfo{}, syserror.ENOEXEC
}
phdrBuf := make([]byte, totalPhdrSize)
_, err = f.ReadFull(ctx, usermem.BytesIOSequence(phdrBuf), int64(hdr.Phoff))
if err != nil {
log.Infof("Error reading ELF phdrs: %v", err)
// If phdrs were specified, they should all exist.
if err == io.EOF || err == io.ErrUnexpectedEOF {
err = syserror.ENOEXEC
}
return elfInfo{}, err
}
phdrs := make([]elf.ProgHeader, hdr.Phnum)
for i := range phdrs {
var prog64 linux.ElfProg64
prog64.UnmarshalUnsafe(phdrBuf[:prog64Size])
phdrBuf = phdrBuf[prog64Size:]
phdrs[i] = elf.ProgHeader{
Type: elf.ProgType(prog64.Type),
Flags: elf.ProgFlag(prog64.Flags),
Off: prog64.Off,
Vaddr: prog64.Vaddr,
Paddr: prog64.Paddr,
Filesz: prog64.Filesz,
Memsz: prog64.Memsz,
Align: prog64.Align,
}
}
return elfInfo{
os: os,
arch: a,
entry: hostarch.Addr(hdr.Entry),
phdrs: phdrs,
phdrOff: hdr.Phoff,
phdrSize: prog64Size,
sharedObject: sharedObject,
}, nil
}
// mapSegment maps a phdr into the Task. offset is the offset to apply to
// phdr.Vaddr.
func mapSegment(ctx context.Context, m *mm.MemoryManager, f fsbridge.File, phdr *elf.ProgHeader, offset hostarch.Addr) error {
// We must make a page-aligned mapping.
adjust := hostarch.Addr(phdr.Vaddr).PageOffset()
addr, ok := offset.AddLength(phdr.Vaddr)
if !ok {
// If offset != 0 we should have ensured this would fit.
ctx.Warningf("Computed segment load address overflows: %#x + %#x", phdr.Vaddr, offset)
return syserror.ENOEXEC
}
addr -= hostarch.Addr(adjust)
fileSize := phdr.Filesz + adjust
if fileSize < phdr.Filesz {
ctx.Infof("Computed segment file size overflows: %#x + %#x", phdr.Filesz, adjust)
return syserror.ENOEXEC
}
ms, ok := hostarch.Addr(fileSize).RoundUp()
if !ok {
ctx.Infof("fileSize %#x too large", fileSize)
return syserror.ENOEXEC
}
mapSize := uint64(ms)
if mapSize > 0 {
// This must result in a page-aligned offset. i.e., the original
// phdr.Off must have the same alignment as phdr.Vaddr. If that is not
// true, MMap will reject the mapping.
fileOffset := phdr.Off - adjust
prot := progFlagsAsPerms(phdr.Flags)
mopts := memmap.MMapOpts{
Length: mapSize,
Offset: fileOffset,
Addr: addr,
Fixed: true,
// Linux will happily allow conflicting segments to map over
// one another.
Unmap: true,
Private: true,
Perms: prot,
MaxPerms: hostarch.AnyAccess,
}
defer func() {
if mopts.MappingIdentity != nil {
mopts.MappingIdentity.DecRef(ctx)
}
}()
if err := f.ConfigureMMap(ctx, &mopts); err != nil {
ctx.Infof("File is not memory-mappable: %v", err)
return err
}
if _, err := m.MMap(ctx, mopts); err != nil {
ctx.Infof("Error mapping PT_LOAD segment %+v at %#x: %v", phdr, addr, err)
return err
}
// We need to clear the end of the last page that exceeds fileSize so
// we don't map part of the file beyond fileSize.
//
// Note that Linux *does not* clear the portion of the first page
// before phdr.Off.
if mapSize > fileSize {
zeroAddr, ok := addr.AddLength(fileSize)
if !ok {
panic(fmt.Sprintf("successfully mmaped address overflows? %#x + %#x", addr, fileSize))
}
zeroSize := int64(mapSize - fileSize)
if zeroSize < 0 {
panic(fmt.Sprintf("zeroSize too big? %#x", uint64(zeroSize)))
}
if _, err := m.ZeroOut(ctx, zeroAddr, zeroSize, usermem.IOOpts{IgnorePermissions: true}); err != nil {
ctx.Warningf("Failed to zero end of page [%#x, %#x): %v", zeroAddr, zeroAddr+hostarch.Addr(zeroSize), err)
return err
}
}
}
memSize := phdr.Memsz + adjust
if memSize < phdr.Memsz {
ctx.Infof("Computed segment mem size overflows: %#x + %#x", phdr.Memsz, adjust)
return syserror.ENOEXEC
}
// Allocate more anonymous pages if necessary.
if mapSize < memSize {
anonAddr, ok := addr.AddLength(mapSize)
if !ok {
panic(fmt.Sprintf("anonymous memory doesn't fit in pre-sized range? %#x + %#x", addr, mapSize))
}
anonSize, ok := hostarch.Addr(memSize - mapSize).RoundUp()
if !ok {
ctx.Infof("extra anon pages too large: %#x", memSize-mapSize)
return syserror.ENOEXEC
}
// N.B. Linux uses vm_brk_flags to map these pages, which only
// honors the X bit, always mapping at least RW. ignoring These
// pages are not included in the final brk region.
prot := hostarch.ReadWrite
if phdr.Flags&elf.PF_X == elf.PF_X {
prot.Execute = true
}
if _, err := m.MMap(ctx, memmap.MMapOpts{
Length: uint64(anonSize),
Addr: anonAddr,
// Fixed without Unmap will fail the mmap if something is
// already at addr.
Fixed: true,
Private: true,
Perms: prot,
MaxPerms: hostarch.AnyAccess,
}); err != nil {
ctx.Infof("Error mapping PT_LOAD segment %v anonymous memory: %v", phdr, err)
return err
}
}
return nil
}
// loadedELF describes an ELF that has been successfully loaded.
type loadedELF struct {
// os is the target OS of the ELF.
os abi.OS
// arch is the target architecture of the ELF.
arch arch.Arch
// entry is the entry point of the ELF.
entry hostarch.Addr
// start is the end of the ELF.
start hostarch.Addr
// end is the end of the ELF.
end hostarch.Addr
// interpter is the path to the ELF interpreter.
interpreter string
// phdrAddr is the address of the ELF program headers.
phdrAddr hostarch.Addr
// phdrSize is the size of a single program header in the ELF.
phdrSize int
// phdrNum is the number of program headers.
phdrNum int
// auxv contains a subset of ELF-specific auxiliary vector entries:
// * AT_PHDR
// * AT_PHENT
// * AT_PHNUM
// * AT_BASE
// * AT_ENTRY
auxv arch.Auxv
}
// loadParsedELF loads f into mm.
//
// info is the parsed elfInfo from the header.
//
// It does not load the ELF interpreter, or return any auxv entries.
//
// Preconditions: f is an ELF file.
func loadParsedELF(ctx context.Context, m *mm.MemoryManager, f fsbridge.File, info elfInfo, sharedLoadOffset hostarch.Addr) (loadedELF, error) {
first := true
var start, end hostarch.Addr
var interpreter string
for _, phdr := range info.phdrs {
switch phdr.Type {
case elf.PT_LOAD:
vaddr := hostarch.Addr(phdr.Vaddr)
if first {
first = false
start = vaddr
}
if vaddr < end {
// NOTE(b/37474556): Linux allows out-of-order
// segments, in violation of the spec.
ctx.Infof("PT_LOAD headers out-of-order. %#x < %#x", vaddr, end)
return loadedELF{}, syserror.ENOEXEC
}
var ok bool
end, ok = vaddr.AddLength(phdr.Memsz)
if !ok {
ctx.Infof("PT_LOAD header size overflows. %#x + %#x", vaddr, phdr.Memsz)
return loadedELF{}, syserror.ENOEXEC
}
case elf.PT_INTERP:
if phdr.Filesz < 2 {
ctx.Infof("PT_INTERP path too small: %v", phdr.Filesz)
return loadedELF{}, syserror.ENOEXEC
}
if phdr.Filesz > linux.PATH_MAX {
ctx.Infof("PT_INTERP path too big: %v", phdr.Filesz)
return loadedELF{}, syserror.ENOEXEC
}
if int64(phdr.Off) < 0 || int64(phdr.Off+phdr.Filesz) < 0 {
ctx.Infof("Unsupported PT_INTERP offset %d", phdr.Off)
return loadedELF{}, syserror.ENOEXEC
}
path := make([]byte, phdr.Filesz)
_, err := f.ReadFull(ctx, usermem.BytesIOSequence(path), int64(phdr.Off))
if err != nil {
// If an interpreter was specified, it should exist.
ctx.Infof("Error reading PT_INTERP path: %v", err)
return loadedELF{}, syserror.ENOEXEC
}
if path[len(path)-1] != 0 {
ctx.Infof("PT_INTERP path not NUL-terminated: %v", path)
return loadedELF{}, syserror.ENOEXEC
}
// Strip NUL-terminator and everything beyond from
// string. Note that there may be a NUL-terminator
// before len(path)-1.
interpreter = string(path[:bytes.IndexByte(path, '\x00')])
if interpreter == "" {
// Linux actually attempts to open_exec("\0").
// open_exec -> do_open_execat fails to check
// that name != '\0' before calling
// do_filp_open, which thus opens the working
// directory. do_open_execat returns EACCES
// because the directory is not a regular file.
//
// We bypass that nonsense and simply
// short-circuit with EACCES. Those this does
// mean that there may be some edge cases where
// the open path would return a different
// error.
ctx.Infof("PT_INTERP path is empty: %v", path)
return loadedELF{}, linuxerr.EACCES
}
}
}
// Shared objects don't have fixed load addresses. We need to pick a
// base address big enough to fit all segments, so we first create a
// mapping for the total size just to find a region that is big enough.
//
// It is safe to unmap it immediately without racing with another mapping
// because we are the only one in control of the MemoryManager.
//
// Note that the vaddr of the first PT_LOAD segment is ignored when
// choosing the load address (even if it is non-zero). The vaddr does
// become an offset from that load address.
var offset hostarch.Addr
if info.sharedObject {
totalSize := end - start
totalSize, ok := totalSize.RoundUp()
if !ok {
ctx.Infof("ELF PT_LOAD segments too big")
return loadedELF{}, syserror.ENOEXEC
}
var err error
offset, err = m.MMap(ctx, memmap.MMapOpts{
Length: uint64(totalSize),
Addr: sharedLoadOffset,
Private: true,
})
if err != nil {
ctx.Infof("Error allocating address space for shared object: %v", err)
return loadedELF{}, err
}
if err := m.MUnmap(ctx, offset, uint64(totalSize)); err != nil {
panic(fmt.Sprintf("Failed to unmap base address: %v", err))
}
start, ok = start.AddLength(uint64(offset))
if !ok {
ctx.Infof(fmt.Sprintf("Start %#x + offset %#x overflows?", start, offset))
return loadedELF{}, linuxerr.EINVAL
}
end, ok = end.AddLength(uint64(offset))
if !ok {
ctx.Infof(fmt.Sprintf("End %#x + offset %#x overflows?", end, offset))
return loadedELF{}, linuxerr.EINVAL
}
info.entry, ok = info.entry.AddLength(uint64(offset))
if !ok {
ctx.Infof("Entrypoint %#x + offset %#x overflows? Is the entrypoint within a segment?", info.entry, offset)
return loadedELF{}, err
}
}
// Map PT_LOAD segments.
for _, phdr := range info.phdrs {
switch phdr.Type {
case elf.PT_LOAD:
if phdr.Memsz == 0 {
// No need to load segments with size 0, but
// they exist in some binaries.
continue
}
if err := mapSegment(ctx, m, f, &phdr, offset); err != nil {
ctx.Infof("Failed to map PT_LOAD segment: %+v", phdr)
return loadedELF{}, err
}
}
}
// This assumes that the first segment contains the ELF headers. This
// may not be true in a malformed ELF, but Linux makes the same
// assumption.
phdrAddr, ok := start.AddLength(info.phdrOff)
if !ok {
ctx.Warningf("ELF start address %#x + phdr offset %#x overflows", start, info.phdrOff)
phdrAddr = 0
}
return loadedELF{
os: info.os,
arch: info.arch,
entry: info.entry,
start: start,
end: end,
interpreter: interpreter,
phdrAddr: phdrAddr,
phdrSize: info.phdrSize,
phdrNum: len(info.phdrs),
}, nil
}
// loadInitialELF loads f into mm.
//
// It creates an arch.Context for the ELF and prepares the mm for this arch.
//
// It does not load the ELF interpreter, or return any auxv entries.
//
// Preconditions:
// * f is an ELF file.
// * f is the first ELF loaded into m.
func loadInitialELF(ctx context.Context, m *mm.MemoryManager, fs *cpuid.FeatureSet, f fsbridge.File) (loadedELF, arch.Context, error) {
info, err := parseHeader(ctx, f)
if err != nil {
ctx.Infof("Failed to parse initial ELF: %v", err)
return loadedELF{}, nil, err
}
// Check Image Compatibility.
if arch.Host != info.arch {
ctx.Warningf("Found mismatch for platform %s with ELF type %s", arch.Host.String(), info.arch.String())
return loadedELF{}, nil, syserror.ENOEXEC
}
// Create the arch.Context now so we can prepare the mmap layout before
// mapping anything.
ac := arch.New(info.arch, fs)
l, err := m.SetMmapLayout(ac, limits.FromContext(ctx))
if err != nil {
ctx.Warningf("Failed to set mmap layout: %v", err)
return loadedELF{}, nil, err
}
// PIELoadAddress tries to move the ELF out of the way of the default
// mmap base to ensure that the initial brk has sufficient space to
// grow.
le, err := loadParsedELF(ctx, m, f, info, ac.PIELoadAddress(l))
return le, ac, err
}
// loadInterpreterELF loads f into mm.
//
// The interpreter must be for the same OS/Arch as the initial ELF.
//
// It does not return any auxv entries.
//
// Preconditions: f is an ELF file.
func loadInterpreterELF(ctx context.Context, m *mm.MemoryManager, f fsbridge.File, initial loadedELF) (loadedELF, error) {
info, err := parseHeader(ctx, f)
if err != nil {
if linuxerr.Equals(linuxerr.ENOEXEC, err) {
// Bad interpreter.
err = syserror.ELIBBAD
}
return loadedELF{}, err
}
if info.os != initial.os {
ctx.Infof("Initial ELF OS %v and interpreter ELF OS %v differ", initial.os, info.os)
return loadedELF{}, syserror.ELIBBAD
}
if info.arch != initial.arch {
ctx.Infof("Initial ELF arch %v and interpreter ELF arch %v differ", initial.arch, info.arch)
return loadedELF{}, syserror.ELIBBAD
}
// The interpreter is not given a load offset, as its location does not
// affect brk.
return loadParsedELF(ctx, m, f, info, 0)
}
// loadELF loads args.File into the Task address space.
//
// If loadELF returns ErrSwitchFile it should be called again with the returned
// path and argv.
//
// Preconditions: args.File is an ELF file.
func loadELF(ctx context.Context, args LoadArgs) (loadedELF, arch.Context, error) {
bin, ac, err := loadInitialELF(ctx, args.MemoryManager, args.Features, args.File)
if err != nil {
ctx.Infof("Error loading binary: %v", err)
return loadedELF{}, nil, err
}
var interp loadedELF
if bin.interpreter != "" {
// Even if we do not allow the final link of the script to be
// resolved, the interpreter should still be resolved if it is
// a symlink.
args.ResolveFinal = true
// Refresh the traversal limit.
*args.RemainingTraversals = linux.MaxSymlinkTraversals
args.Filename = bin.interpreter
intFile, err := openPath(ctx, args)
if err != nil {
ctx.Infof("Error opening interpreter %s: %v", bin.interpreter, err)
return loadedELF{}, nil, err
}
defer intFile.DecRef(ctx)
interp, err = loadInterpreterELF(ctx, args.MemoryManager, intFile, bin)
if err != nil {
ctx.Infof("Error loading interpreter: %v", err)
return loadedELF{}, nil, err
}
if interp.interpreter != "" {
// No recursive interpreters!
ctx.Infof("Interpreter requires an interpreter")
return loadedELF{}, nil, syserror.ENOEXEC
}
}
// ELF-specific auxv entries.
bin.auxv = arch.Auxv{
arch.AuxEntry{linux.AT_PHDR, bin.phdrAddr},
arch.AuxEntry{linux.AT_PHENT, hostarch.Addr(bin.phdrSize)},
arch.AuxEntry{linux.AT_PHNUM, hostarch.Addr(bin.phdrNum)},
arch.AuxEntry{linux.AT_ENTRY, bin.entry},
}
if bin.interpreter != "" {
bin.auxv = append(bin.auxv, arch.AuxEntry{linux.AT_BASE, interp.start})
// Start in the interpreter.
// N.B. AT_ENTRY above contains the *original* entry point.
bin.entry = interp.entry
} else {
// Always add AT_BASE even if there is no interpreter.
bin.auxv = append(bin.auxv, arch.AuxEntry{linux.AT_BASE, 0})
}
return bin, ac, nil
}
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