ceph-csi/vendor/github.com/google/fscrypt/filesystem/filesystem.go
NymanRobin ca713945ad cephfs: upgrade fscrypt version to fix concurrency issue
In older versions of fscrypt there is a race condition
when multiple encrypted cephfs instances are deployed
simultaneously.

Signed-off-by: NymanRobin <robin.nyman@est.tech>
(cherry picked from commit 3073409695)
2024-05-15 07:59:38 +00:00

1090 lines
36 KiB
Go

/*
* filesystem.go - Contains the functionality for a specific filesystem. This
* includes the commands to setup the filesystem, apply policies, and locate
* metadata.
*
* Copyright 2017 Google Inc.
* Author: Joe Richey (joerichey@google.com)
*
* 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 filesystem deals with the structure of the files on disk used to
// store the metadata for fscrypt. Specifically, this package includes:
// 1. mountpoint management (mountpoint.go)
// - querying existing mounted filesystems
// - getting filesystems from a UUID
// - finding the filesystem for a specific path
// 2. metadata organization (filesystem.go)
// - setting up a mounted filesystem for use with fscrypt
// - adding/querying/deleting metadata
// - making links to other filesystems' metadata
// - following links to get data from other filesystems
package filesystem
import (
"fmt"
"io"
"log"
"os"
"os/user"
"path/filepath"
"sort"
"strings"
"syscall"
"time"
"github.com/pkg/errors"
"golang.org/x/sys/unix"
"google.golang.org/protobuf/proto"
"github.com/google/fscrypt/metadata"
"github.com/google/fscrypt/util"
)
// ErrAlreadySetup indicates that a filesystem is already setup for fscrypt.
type ErrAlreadySetup struct {
Mount *Mount
}
func (err *ErrAlreadySetup) Error() string {
return fmt.Sprintf("filesystem %s is already setup for use with fscrypt",
err.Mount.Path)
}
// ErrCorruptMetadata indicates that an fscrypt metadata file is corrupt.
type ErrCorruptMetadata struct {
Path string
UnderlyingError error
}
func (err *ErrCorruptMetadata) Error() string {
return fmt.Sprintf("fscrypt metadata file at %q is corrupt: %s",
err.Path, err.UnderlyingError)
}
// ErrFollowLink indicates that a protector link can't be followed.
type ErrFollowLink struct {
Link string
UnderlyingError error
}
func (err *ErrFollowLink) Error() string {
return fmt.Sprintf("cannot follow filesystem link %q: %s",
err.Link, err.UnderlyingError)
}
// ErrInsecurePermissions indicates that a filesystem is not considered to be
// setup for fscrypt because a metadata directory has insecure permissions.
type ErrInsecurePermissions struct {
Path string
}
func (err *ErrInsecurePermissions) Error() string {
return fmt.Sprintf("%q has insecure permissions (world-writable without sticky bit)",
err.Path)
}
// ErrMakeLink indicates that a protector link can't be created.
type ErrMakeLink struct {
Target *Mount
UnderlyingError error
}
func (err *ErrMakeLink) Error() string {
return fmt.Sprintf("cannot create filesystem link to %q: %s",
err.Target.Path, err.UnderlyingError)
}
// ErrMountOwnedByAnotherUser indicates that the mountpoint root directory is
// owned by a user that isn't trusted in the current context, so we don't
// consider fscrypt to be properly setup on the filesystem.
type ErrMountOwnedByAnotherUser struct {
Mount *Mount
}
func (err *ErrMountOwnedByAnotherUser) Error() string {
return fmt.Sprintf("another non-root user owns the root directory of %s", err.Mount.Path)
}
// ErrNoCreatePermission indicates that the current user lacks permission to
// create fscrypt metadata on the given filesystem.
type ErrNoCreatePermission struct {
Mount *Mount
}
func (err *ErrNoCreatePermission) Error() string {
return fmt.Sprintf("user lacks permission to create fscrypt metadata on %s", err.Mount.Path)
}
// ErrNotAMountpoint indicates that a path is not a mountpoint.
type ErrNotAMountpoint struct {
Path string
}
func (err *ErrNotAMountpoint) Error() string {
return fmt.Sprintf("%q is not a mountpoint", err.Path)
}
// ErrNotSetup indicates that a filesystem is not setup for fscrypt.
type ErrNotSetup struct {
Mount *Mount
}
func (err *ErrNotSetup) Error() string {
return fmt.Sprintf("filesystem %s is not setup for use with fscrypt", err.Mount.Path)
}
// ErrSetupByAnotherUser indicates that one or more of the fscrypt metadata
// directories is owned by a user that isn't trusted in the current context, so
// we don't consider fscrypt to be properly setup on the filesystem.
type ErrSetupByAnotherUser struct {
Mount *Mount
}
func (err *ErrSetupByAnotherUser) Error() string {
return fmt.Sprintf("another non-root user owns fscrypt metadata directories on %s", err.Mount.Path)
}
// ErrSetupNotSupported indicates that the given filesystem type is not
// supported for fscrypt setup.
type ErrSetupNotSupported struct {
Mount *Mount
}
func (err *ErrSetupNotSupported) Error() string {
return fmt.Sprintf("filesystem type %s is not supported for fscrypt setup",
err.Mount.FilesystemType)
}
// ErrPolicyNotFound indicates that the policy metadata was not found.
type ErrPolicyNotFound struct {
Descriptor string
Mount *Mount
}
func (err *ErrPolicyNotFound) Error() string {
return fmt.Sprintf("policy metadata for %s not found on filesystem %s",
err.Descriptor, err.Mount.Path)
}
// ErrProtectorNotFound indicates that the protector metadata was not found.
type ErrProtectorNotFound struct {
Descriptor string
Mount *Mount
}
func (err *ErrProtectorNotFound) Error() string {
return fmt.Sprintf("protector metadata for %s not found on filesystem %s",
err.Descriptor, err.Mount.Path)
}
// SortDescriptorsByLastMtime indicates whether descriptors are sorted by last
// modification time when being listed. This can be set to true to get
// consistent output for testing.
var SortDescriptorsByLastMtime = false
// Mount contains information for a specific mounted filesystem.
//
// Path - Absolute path where the directory is mounted
// FilesystemType - Type of the mounted filesystem, e.g. "ext4"
// Device - Device for filesystem (empty string if we cannot find one)
// DeviceNumber - Device number of the filesystem. This is set even if
// Device isn't, since all filesystems have a device
// number assigned by the kernel, even pseudo-filesystems.
// Subtree - The mounted subtree of the filesystem. This is usually
// "/", meaning that the entire filesystem is mounted, but
// it can differ for bind mounts.
// ReadOnly - True if this is a read-only mount
//
// In order to use a Mount to store fscrypt metadata, some directories must be
// setup first. Specifically, the directories created look like:
// <mountpoint>
// └── .fscrypt
//
// ├── policies
// └── protectors
//
// These "policies" and "protectors" directories will contain files that are
// the corresponding metadata structures for policies and protectors. The public
// interface includes functions for setting up these directories and Adding,
// Getting, and Removing these files.
//
// There is also the ability to reference another filesystem's metadata. This is
// used when a Policy on filesystem A is protected with Protector on filesystem
// B. In this scenario, we store a "link file" in the protectors directory.
//
// We also allow ".fscrypt" to be a symlink which was previously created. This
// allows login protectors to be created when the root filesystem is read-only,
// provided that "/.fscrypt" is a symlink pointing to a writable location.
type Mount struct {
Path string
FilesystemType string
Device string
DeviceNumber DeviceNumber
Subtree string
ReadOnly bool
}
// PathSorter allows mounts to be sorted by Path.
type PathSorter []*Mount
func (p PathSorter) Len() int { return len(p) }
func (p PathSorter) Swap(i, j int) { p[i], p[j] = p[j], p[i] }
func (p PathSorter) Less(i, j int) bool { return p[i].Path < p[j].Path }
const (
// Names of the various directories used in fscrypt
baseDirName = ".fscrypt"
policyDirName = "policies"
protectorDirName = "protectors"
tempPrefix = ".tmp"
linkFileExtension = ".link"
// The base directory should be read-only (except for the creator)
basePermissions = 0755
// The metadata files shouldn't be readable or writable by other users.
// Having them be world-readable wouldn't necessarily be a huge issue,
// but given that some of these files contain (strong) password hashes,
// we error on the side of caution -- similar to /etc/shadow.
// Note: existing files on-disk might have mode 0644, as that was the
// mode used by fscrypt v0.3.2 and earlier.
filePermissions = os.FileMode(0600)
// Maximum size of a metadata file. This value is arbitrary, and it can
// be changed. We just set a reasonable limit that shouldn't be reached
// in practice, except by users trying to cause havoc by creating
// extremely large files in the metadata directories.
maxMetadataFileSize = 16384
)
// SetupMode is a mode for creating the fscrypt metadata directories.
type SetupMode int
const (
// SingleUserWritable specifies to make the fscrypt metadata directories
// writable by a single user (usually root) only.
SingleUserWritable SetupMode = iota
// WorldWritable specifies to make the fscrypt metadata directories
// world-writable (with the sticky bit set).
WorldWritable
)
func (m *Mount) String() string {
return fmt.Sprintf(`%s
FilesystemType: %s
Device: %s`, m.Path, m.FilesystemType, m.Device)
}
// BaseDir returns the path to the base fscrypt directory for this filesystem.
func (m *Mount) BaseDir() string {
rawBaseDir := filepath.Join(m.Path, baseDirName)
// We allow the base directory to be a symlink, but some callers need
// the real path, so dereference the symlink here if needed. Since the
// directory the symlink points to may not exist yet, we have to read
// the symlink manually rather than use filepath.EvalSymlinks.
target, err := os.Readlink(rawBaseDir)
if err != nil {
return rawBaseDir // not a symlink
}
if filepath.IsAbs(target) {
return target
}
return filepath.Join(m.Path, target)
}
// ProtectorDir returns the directory containing the protector metadata.
func (m *Mount) ProtectorDir() string {
return filepath.Join(m.BaseDir(), protectorDirName)
}
// protectorPath returns the full path to a regular protector file with the
// specified descriptor.
func (m *Mount) protectorPath(descriptor string) string {
return filepath.Join(m.ProtectorDir(), descriptor)
}
// linkedProtectorPath returns the full path to a linked protector file with the
// specified descriptor.
func (m *Mount) linkedProtectorPath(descriptor string) string {
return m.protectorPath(descriptor) + linkFileExtension
}
// PolicyDir returns the directory containing the policy metadata.
func (m *Mount) PolicyDir() string {
return filepath.Join(m.BaseDir(), policyDirName)
}
// PolicyPath returns the full path to a regular policy file with the
// specified descriptor.
func (m *Mount) PolicyPath(descriptor string) string {
return filepath.Join(m.PolicyDir(), descriptor)
}
// tempMount creates a temporary directory alongside this Mount's base fscrypt
// directory and returns a temporary Mount which represents this temporary
// directory. The caller is responsible for removing this temporary directory.
func (m *Mount) tempMount() (*Mount, error) {
tempDir, err := os.MkdirTemp(filepath.Dir(m.BaseDir()), tempPrefix)
return &Mount{Path: tempDir}, err
}
// ErrEncryptionNotEnabled indicates that encryption is not enabled on the given
// filesystem.
type ErrEncryptionNotEnabled struct {
Mount *Mount
}
func (err *ErrEncryptionNotEnabled) Error() string {
return fmt.Sprintf("encryption not enabled on filesystem %s (%s).",
err.Mount.Path, err.Mount.Device)
}
// ErrEncryptionNotSupported indicates that encryption is not supported on the
// given filesystem.
type ErrEncryptionNotSupported struct {
Mount *Mount
}
func (err *ErrEncryptionNotSupported) Error() string {
return fmt.Sprintf("This kernel doesn't support encryption on %s filesystems.",
err.Mount.FilesystemType)
}
// EncryptionSupportError adds filesystem-specific context to the
// ErrEncryptionNotEnabled and ErrEncryptionNotSupported errors from the
// metadata package.
func (m *Mount) EncryptionSupportError(err error) error {
switch err {
case metadata.ErrEncryptionNotEnabled:
return &ErrEncryptionNotEnabled{m}
case metadata.ErrEncryptionNotSupported:
return &ErrEncryptionNotSupported{m}
}
return err
}
// isFscryptSetupAllowed decides whether the given filesystem is allowed to be
// set up for fscrypt, without actually accessing it. This basically checks
// whether the filesystem type is one of the types that supports encryption, or
// at least is in some stage of planning for encrption support in the future.
//
// We need this list so that we can skip filesystems that are irrelevant for
// fscrypt without having to look for the fscrypt metadata directories on them,
// which can trigger errors, long delays, or side effects on some filesystems.
//
// Unfortunately, this means that if a completely new filesystem adds encryption
// support, then it will need to be manually added to this list. But it seems
// to be a worthwhile tradeoff to avoid the above issues.
func (m *Mount) isFscryptSetupAllowed() bool {
if m.Path == "/" {
// The root filesystem is always allowed, since it's where login
// protectors are stored.
return true
}
switch m.FilesystemType {
case "ext4", "f2fs", "ubifs", "btrfs", "ceph", "xfs", "lustre":
return true
default:
return false
}
}
// CheckSupport returns an error if this filesystem does not support encryption.
func (m *Mount) CheckSupport() error {
if !m.isFscryptSetupAllowed() {
return &ErrEncryptionNotSupported{m}
}
return m.EncryptionSupportError(metadata.CheckSupport(m.Path))
}
func checkOwnership(path string, info os.FileInfo, trustedUser *user.User) bool {
if trustedUser == nil {
return true
}
trustedUID := uint32(util.AtoiOrPanic(trustedUser.Uid))
actualUID := info.Sys().(*syscall.Stat_t).Uid
if actualUID != 0 && actualUID != trustedUID {
log.Printf("WARNING: %q is owned by uid %d, but expected %d or 0",
path, actualUID, trustedUID)
return false
}
return true
}
// CheckSetup returns an error if any of the fscrypt metadata directories do not
// exist. Will log any unexpected errors or incorrect permissions.
func (m *Mount) CheckSetup(trustedUser *user.User) error {
if !m.isFscryptSetupAllowed() {
return &ErrNotSetup{m}
}
// Check that the mountpoint directory itself is not a symlink and has
// proper ownership, as otherwise we can't trust anything beneath it.
info, err := loggedLstat(m.Path)
if err != nil {
return &ErrNotSetup{m}
}
if (info.Mode() & os.ModeSymlink) != 0 {
log.Printf("mountpoint directory %q cannot be a symlink", m.Path)
return &ErrNotSetup{m}
}
if !info.IsDir() {
log.Printf("mountpoint %q is not a directory", m.Path)
return &ErrNotSetup{m}
}
if !checkOwnership(m.Path, info, trustedUser) {
return &ErrMountOwnedByAnotherUser{m}
}
// Check BaseDir similarly. However, unlike the other directories, we
// allow BaseDir to be a symlink, to support the use case of metadata
// for a read-only filesystem being redirected to a writable location.
info, err = loggedStat(m.BaseDir())
if err != nil {
return &ErrNotSetup{m}
}
if !info.IsDir() {
log.Printf("%q is not a directory", m.BaseDir())
return &ErrNotSetup{m}
}
if !checkOwnership(m.Path, info, trustedUser) {
return &ErrMountOwnedByAnotherUser{m}
}
// Check that the policies and protectors directories aren't symlinks and
// have proper ownership.
subdirs := []string{m.PolicyDir(), m.ProtectorDir()}
for _, path := range subdirs {
info, err := loggedLstat(path)
if err != nil {
return &ErrNotSetup{m}
}
if (info.Mode() & os.ModeSymlink) != 0 {
log.Printf("directory %q cannot be a symlink", path)
return &ErrNotSetup{m}
}
if !info.IsDir() {
log.Printf("%q is not a directory", path)
return &ErrNotSetup{m}
}
// We are no longer too picky about the mode, given that
// 'fscrypt setup' now offers a choice of two different modes,
// and system administrators could customize it further.
// However, we can at least verify that if the directory is
// world-writable, then the sticky bit is also set.
if info.Mode()&(os.ModeSticky|0002) == 0002 {
log.Printf("%q is world-writable but doesn't have sticky bit set", path)
return &ErrInsecurePermissions{path}
}
if !checkOwnership(path, info, trustedUser) {
return &ErrSetupByAnotherUser{m}
}
}
return nil
}
// makeDirectories creates the three metadata directories with the correct
// permissions. Note that this function overrides the umask.
func (m *Mount) makeDirectories(setupMode SetupMode) error {
// Zero the umask so we get the permissions we want
oldMask := unix.Umask(0)
defer func() {
unix.Umask(oldMask)
}()
if err := os.Mkdir(m.BaseDir(), basePermissions); err != nil {
return err
}
var dirMode os.FileMode
switch setupMode {
case SingleUserWritable:
dirMode = 0755
case WorldWritable:
dirMode = os.ModeSticky | 0777
}
if err := os.Mkdir(m.PolicyDir(), dirMode); err != nil {
return err
}
return os.Mkdir(m.ProtectorDir(), dirMode)
}
// GetSetupMode returns the current mode for fscrypt metadata creation on this
// filesystem.
func (m *Mount) GetSetupMode() (SetupMode, *user.User, error) {
info1, err1 := os.Stat(m.PolicyDir())
info2, err2 := os.Stat(m.ProtectorDir())
if err1 == nil && err2 == nil {
mask := os.ModeSticky | 0777
mode1 := info1.Mode() & mask
mode2 := info2.Mode() & mask
uid1 := info1.Sys().(*syscall.Stat_t).Uid
uid2 := info2.Sys().(*syscall.Stat_t).Uid
user, err := util.UserFromUID(int64(uid1))
if err == nil && mode1 == mode2 && uid1 == uid2 {
switch mode1 {
case mask:
return WorldWritable, nil, nil
case 0755:
return SingleUserWritable, user, nil
}
}
log.Printf("filesystem %s uses custom permissions on metadata directories", m.Path)
}
return -1, nil, errors.New("unable to determine setup mode")
}
// Setup sets up the filesystem for use with fscrypt. Note that this merely
// creates the appropriate files on the filesystem. It does not actually modify
// the filesystem's feature flags. This operation is atomic; it either succeeds
// or no files in the baseDir are created.
func (m *Mount) Setup(mode SetupMode) error {
if m.CheckSetup(nil) == nil {
return &ErrAlreadySetup{m}
}
if !m.isFscryptSetupAllowed() {
return &ErrSetupNotSupported{m}
}
// We build the directories under a temp Mount and then move into place.
temp, err := m.tempMount()
if err != nil {
return err
}
defer os.RemoveAll(temp.Path)
if err = temp.makeDirectories(mode); err != nil {
return err
}
// Atomically move directory into place.
return os.Rename(temp.BaseDir(), m.BaseDir())
}
// RemoveAllMetadata removes all the policy and protector metadata from the
// filesystem. This operation is atomic; it either succeeds or no files in the
// baseDir are removed.
// WARNING: Will cause data loss if the metadata is used to encrypt
// directories (this could include directories on other filesystems).
func (m *Mount) RemoveAllMetadata() error {
if err := m.CheckSetup(nil); err != nil {
return err
}
// temp will hold the old metadata temporarily
temp, err := m.tempMount()
if err != nil {
return err
}
defer os.RemoveAll(temp.Path)
// Move directory into temp (to be destroyed on defer)
return os.Rename(m.BaseDir(), temp.BaseDir())
}
func syncDirectory(dirPath string) error {
dirFile, err := os.Open(dirPath)
if err != nil {
return err
}
if err = dirFile.Sync(); err != nil {
dirFile.Close()
return err
}
return dirFile.Close()
}
func (m *Mount) overwriteDataNonAtomic(path string, data []byte) error {
file, err := os.OpenFile(path, os.O_WRONLY|os.O_TRUNC|unix.O_NOFOLLOW, 0)
if err != nil {
return err
}
if _, err = file.Write(data); err != nil {
log.Printf("WARNING: overwrite of %q failed; file will be corrupted!", path)
file.Close()
return err
}
if err = file.Sync(); err != nil {
file.Close()
return err
}
if err = file.Close(); err != nil {
return err
}
log.Printf("successfully overwrote %q non-atomically", path)
return nil
}
// writeData writes the given data to the given path such that, if possible, the
// data is either written to stable storage or an error is returned. If a file
// already exists at the path, it will be replaced.
//
// However, if the process doesn't have write permission to the directory but
// does have write permission to the file itself, then as a fallback the file is
// overwritten in-place rather than replaced. Note that this may be non-atomic.
func (m *Mount) writeData(path string, data []byte, owner *user.User, mode os.FileMode) error {
// Write the data to a temporary file, sync it, then rename into place
// so that the operation will be atomic.
dirPath := filepath.Dir(path)
tempFile, err := os.CreateTemp(dirPath, tempPrefix)
if err != nil {
log.Print(err)
if os.IsPermission(err) {
if _, err = os.Lstat(path); err == nil {
log.Printf("trying non-atomic overwrite of %q", path)
return m.overwriteDataNonAtomic(path, data)
}
return &ErrNoCreatePermission{m}
}
return err
}
defer os.Remove(tempFile.Name())
// Ensure the new file has the right permissions mask.
if err = tempFile.Chmod(mode); err != nil {
tempFile.Close()
return err
}
// Override the file owner if one was specified. This happens when root
// needs to create files owned by a particular user.
if owner != nil {
if err = util.Chown(tempFile, owner); err != nil {
log.Printf("could not set owner of %q to %v: %v",
path, owner.Username, err)
tempFile.Close()
return err
}
}
if _, err = tempFile.Write(data); err != nil {
tempFile.Close()
return err
}
if err = tempFile.Sync(); err != nil {
tempFile.Close()
return err
}
if err = tempFile.Close(); err != nil {
return err
}
if err = os.Rename(tempFile.Name(), path); err != nil {
return err
}
// Ensure the rename has been persisted before returning success.
return syncDirectory(dirPath)
}
// addMetadata writes the metadata structure to the file with the specified
// path. This will overwrite any existing data. The operation is atomic.
func (m *Mount) addMetadata(path string, md metadata.Metadata, owner *user.User) error {
if err := md.CheckValidity(); err != nil {
return errors.Wrap(err, "provided metadata is invalid")
}
data, err := proto.Marshal(md)
if err != nil {
return err
}
mode := filePermissions
// If the file already exists, then preserve its owner and mode if
// possible. This is necessary because by default, for atomicity
// reasons we'll replace the file rather than overwrite it.
info, err := os.Lstat(path)
if err == nil {
if owner == nil && util.IsUserRoot() {
uid := info.Sys().(*syscall.Stat_t).Uid
if owner, err = util.UserFromUID(int64(uid)); err != nil {
log.Print(err)
}
}
mode = info.Mode() & 0777
} else if !os.IsNotExist(err) {
log.Print(err)
}
if owner != nil {
log.Printf("writing metadata to %q and setting owner to %s", path, owner.Username)
} else {
log.Printf("writing metadata to %q", path)
}
return m.writeData(path, data, owner, mode)
}
// readMetadataFileSafe gets the contents of a metadata file extra-carefully,
// considering that it could be a malicious file created to cause a
// denial-of-service. Specifically, the following checks are done:
//
// - It must be a regular file, not another type of file like a symlink or FIFO.
// (Symlinks aren't bad by themselves, but given that a malicious user could
// point one to absolutely anywhere, and there is no known use case for the
// metadata files themselves being symlinks, it seems best to disallow them.)
// - It must have a reasonable size (<= maxMetadataFileSize).
// - If trustedUser is non-nil, then the file must be owned by the given user
// or by root.
//
// Take care to avoid TOCTOU (time-of-check-time-of-use) bugs when doing these
// tests. Notably, we must open the file before checking the file type, as the
// file type could change between any previous checks and the open. When doing
// this, O_NOFOLLOW is needed to avoid following a symlink (this applies to the
// last path component only), and O_NONBLOCK is needed to avoid blocking if the
// file is a FIFO.
//
// This function returns the data read as well as the UID of the user who owns
// the file. The returned UID is needed for login protectors, where the UID
// needs to be cross-checked with the UID stored in the file itself.
func readMetadataFileSafe(path string, trustedUser *user.User) ([]byte, int64, error) {
file, err := os.OpenFile(path, os.O_RDONLY|unix.O_NOFOLLOW|unix.O_NONBLOCK, 0)
if err != nil {
return nil, -1, err
}
defer file.Close()
info, err := file.Stat()
if err != nil {
return nil, -1, err
}
if !info.Mode().IsRegular() {
return nil, -1, &ErrCorruptMetadata{path, errors.New("not a regular file")}
}
if !checkOwnership(path, info, trustedUser) {
return nil, -1, &ErrCorruptMetadata{path, errors.New("metadata file belongs to another user")}
}
// Clear O_NONBLOCK, since it has served its purpose when opening the
// file, and the behavior of reading from a regular file with O_NONBLOCK
// is technically unspecified.
if _, err = unix.FcntlInt(file.Fd(), unix.F_SETFL, 0); err != nil {
return nil, -1, &os.PathError{Op: "clearing O_NONBLOCK", Path: path, Err: err}
}
// Read the file contents, allowing at most maxMetadataFileSize bytes.
reader := &io.LimitedReader{R: file, N: maxMetadataFileSize + 1}
data, err := io.ReadAll(reader)
if err != nil {
return nil, -1, err
}
if reader.N == 0 {
return nil, -1, &ErrCorruptMetadata{path, errors.New("metadata file size limit exceeded")}
}
return data, int64(info.Sys().(*syscall.Stat_t).Uid), nil
}
// getMetadata reads the metadata structure from the file with the specified
// path. Only reads normal metadata files, not linked metadata.
func (m *Mount) getMetadata(path string, trustedUser *user.User, md metadata.Metadata) (int64, error) {
data, owner, err := readMetadataFileSafe(path, trustedUser)
if err != nil {
log.Printf("could not read metadata from %q: %v", path, err)
return -1, err
}
if err := proto.Unmarshal(data, md); err != nil {
return -1, &ErrCorruptMetadata{path, err}
}
if err := md.CheckValidity(); err != nil {
return -1, &ErrCorruptMetadata{path, err}
}
log.Printf("successfully read metadata from %q", path)
return owner, nil
}
// removeMetadata deletes the metadata struct from the file with the specified
// path. Works with regular or linked metadata.
func (m *Mount) removeMetadata(path string) error {
if err := os.Remove(path); err != nil {
log.Printf("could not remove metadata file at %q: %v", path, err)
return err
}
log.Printf("successfully removed metadata file at %q", path)
return nil
}
// AddProtector adds the protector metadata to this filesystem's storage. This
// will overwrite the value of an existing protector with this descriptor. This
// will fail with ErrLinkedProtector if a linked protector with this descriptor
// already exists on the filesystem.
func (m *Mount) AddProtector(data *metadata.ProtectorData, owner *user.User) error {
var err error
if err = m.CheckSetup(nil); err != nil {
return err
}
if isRegularFile(m.linkedProtectorPath(data.ProtectorDescriptor)) {
return errors.Errorf("cannot modify linked protector %s on filesystem %s",
data.ProtectorDescriptor, m.Path)
}
path := m.protectorPath(data.ProtectorDescriptor)
return m.addMetadata(path, data, owner)
}
// AddLinkedProtector adds a link in this filesystem to the protector metadata
// in the dest filesystem, if one doesn't already exist. On success, the return
// value is a nil error and a bool that is true iff the link is newly created.
func (m *Mount) AddLinkedProtector(descriptor string, dest *Mount, trustedUser *user.User,
ownerIfCreating *user.User) (bool, error) {
if err := m.CheckSetup(trustedUser); err != nil {
return false, err
}
// Check that the link is good (descriptor exists, filesystem has UUID).
if _, err := dest.GetRegularProtector(descriptor, trustedUser); err != nil {
return false, err
}
linkPath := m.linkedProtectorPath(descriptor)
// Check whether the link already exists.
existingLink, _, err := readMetadataFileSafe(linkPath, trustedUser)
if err == nil {
existingLinkedMnt, err := getMountFromLink(string(existingLink))
if err != nil {
return false, errors.Wrap(err, linkPath)
}
if existingLinkedMnt != dest {
return false, errors.Errorf("link %q points to %q, but expected %q",
linkPath, existingLinkedMnt.Path, dest.Path)
}
return false, nil
}
if !os.IsNotExist(err) {
return false, err
}
var newLink string
newLink, err = makeLink(dest)
if err != nil {
return false, err
}
return true, m.writeData(linkPath, []byte(newLink), ownerIfCreating, filePermissions)
}
// GetRegularProtector looks up the protector metadata by descriptor. This will
// fail with ErrProtectorNotFound if the descriptor is a linked protector.
func (m *Mount) GetRegularProtector(descriptor string, trustedUser *user.User) (*metadata.ProtectorData, error) {
if err := m.CheckSetup(trustedUser); err != nil {
return nil, err
}
data := new(metadata.ProtectorData)
path := m.protectorPath(descriptor)
owner, err := m.getMetadata(path, trustedUser, data)
if os.IsNotExist(err) {
err = &ErrProtectorNotFound{descriptor, m}
}
if err != nil {
return nil, err
}
// Login protectors have their UID stored in the file. Since normally
// any user can create files in the fscrypt metadata directories, for a
// login protector to be considered valid it *must* be owned by the
// claimed user or by root. Note: fscrypt v0.3.2 and later always makes
// login protectors owned by the user, but previous versions could
// create them owned by root -- that is the main reason we allow root.
if data.Source == metadata.SourceType_pam_passphrase && owner != 0 && owner != data.Uid {
log.Printf("WARNING: %q claims to be the login protector for uid %d, but it is owned by uid %d. Needs to be %d or 0.",
path, data.Uid, owner, data.Uid)
return nil, &ErrCorruptMetadata{path, errors.New("login protector belongs to wrong user")}
}
return data, nil
}
// GetProtector returns the Mount of the filesystem containing the information
// and that protector's data. If the descriptor is a regular (not linked)
// protector, the mount will return itself.
func (m *Mount) GetProtector(descriptor string, trustedUser *user.User) (*Mount, *metadata.ProtectorData, error) {
if err := m.CheckSetup(trustedUser); err != nil {
return nil, nil, err
}
// Get the link data from the link file
path := m.linkedProtectorPath(descriptor)
link, _, err := readMetadataFileSafe(path, trustedUser)
if err != nil {
// If the link doesn't exist, try for a regular protector.
if os.IsNotExist(err) {
data, err := m.GetRegularProtector(descriptor, trustedUser)
return m, data, err
}
return nil, nil, err
}
log.Printf("following protector link %s", path)
linkedMnt, err := getMountFromLink(string(link))
if err != nil {
return nil, nil, errors.Wrap(err, path)
}
data, err := linkedMnt.GetRegularProtector(descriptor, trustedUser)
if err != nil {
return nil, nil, &ErrFollowLink{string(link), err}
}
return linkedMnt, data, nil
}
// RemoveProtector deletes the protector metadata (or a link to another
// filesystem's metadata) from the filesystem storage.
func (m *Mount) RemoveProtector(descriptor string) error {
if err := m.CheckSetup(nil); err != nil {
return err
}
// We first try to remove the linkedProtector. If that metadata does not
// exist, we try to remove the normal protector.
err := m.removeMetadata(m.linkedProtectorPath(descriptor))
if os.IsNotExist(err) {
err = m.removeMetadata(m.protectorPath(descriptor))
if os.IsNotExist(err) {
err = &ErrProtectorNotFound{descriptor, m}
}
}
return err
}
// ListProtectors lists the descriptors of all protectors on this filesystem.
// This does not include linked protectors. If trustedUser is non-nil, then
// the protectors are restricted to those owned by the given user or by root.
func (m *Mount) ListProtectors(trustedUser *user.User) ([]string, error) {
return m.listMetadata(m.ProtectorDir(), "protectors", trustedUser)
}
// AddPolicy adds the policy metadata to the filesystem storage.
func (m *Mount) AddPolicy(data *metadata.PolicyData, owner *user.User) error {
if err := m.CheckSetup(nil); err != nil {
return err
}
return m.addMetadata(m.PolicyPath(data.KeyDescriptor), data, owner)
}
// GetPolicy looks up the policy metadata by descriptor.
func (m *Mount) GetPolicy(descriptor string, trustedUser *user.User) (*metadata.PolicyData, error) {
if err := m.CheckSetup(trustedUser); err != nil {
return nil, err
}
data := new(metadata.PolicyData)
_, err := m.getMetadata(m.PolicyPath(descriptor), trustedUser, data)
if os.IsNotExist(err) {
err = &ErrPolicyNotFound{descriptor, m}
}
return data, err
}
// RemovePolicy deletes the policy metadata from the filesystem storage.
func (m *Mount) RemovePolicy(descriptor string) error {
if err := m.CheckSetup(nil); err != nil {
return err
}
err := m.removeMetadata(m.PolicyPath(descriptor))
if os.IsNotExist(err) {
err = &ErrPolicyNotFound{descriptor, m}
}
return err
}
// ListPolicies lists the descriptors of all policies on this filesystem. If
// trustedUser is non-nil, then the policies are restricted to those owned by
// the given user or by root.
func (m *Mount) ListPolicies(trustedUser *user.User) ([]string, error) {
return m.listMetadata(m.PolicyDir(), "policies", trustedUser)
}
type namesAndTimes struct {
names []string
times []time.Time
}
func (c namesAndTimes) Len() int {
return len(c.names)
}
func (c namesAndTimes) Less(i, j int) bool {
return c.times[i].Before(c.times[j])
}
func (c namesAndTimes) Swap(i, j int) {
c.names[i], c.names[j] = c.names[j], c.names[i]
c.times[i], c.times[j] = c.times[j], c.times[i]
}
func sortFileListByLastMtime(directoryPath string, names []string) error {
c := namesAndTimes{names: names, times: make([]time.Time, len(names))}
for i, name := range names {
fi, err := os.Lstat(filepath.Join(directoryPath, name))
if err != nil {
return err
}
c.times[i] = fi.ModTime()
}
sort.Sort(c)
return nil
}
// listDirectory returns a list of descriptors for a metadata directory,
// including files which are links to other filesystem's metadata.
func (m *Mount) listDirectory(directoryPath string) ([]string, error) {
dir, err := os.Open(directoryPath)
if err != nil {
return nil, err
}
defer dir.Close()
names, err := dir.Readdirnames(-1)
if err != nil {
return nil, err
}
if SortDescriptorsByLastMtime {
if err := sortFileListByLastMtime(directoryPath, names); err != nil {
return nil, err
}
}
descriptors := make([]string, 0, len(names))
for _, name := range names {
// Be sure to include links as well
descriptors = append(descriptors, strings.TrimSuffix(name, linkFileExtension))
}
return descriptors, nil
}
func (m *Mount) listMetadata(dirPath string, metadataType string, owner *user.User) ([]string, error) {
log.Printf("listing %s in %q", metadataType, dirPath)
if err := m.CheckSetup(owner); err != nil {
return nil, err
}
names, err := m.listDirectory(dirPath)
if err != nil {
return nil, err
}
filesIgnoredDescription := ""
if owner != nil {
filteredNames := make([]string, 0, len(names))
uid := uint32(util.AtoiOrPanic(owner.Uid))
for _, name := range names {
info, err := os.Lstat(filepath.Join(dirPath, name))
if err != nil {
continue
}
fileUID := info.Sys().(*syscall.Stat_t).Uid
if fileUID != uid && fileUID != 0 {
continue
}
filteredNames = append(filteredNames, name)
}
numIgnored := len(names) - len(filteredNames)
if numIgnored != 0 {
filesIgnoredDescription =
fmt.Sprintf(" (ignored %d %s not owned by %s or root)",
numIgnored, metadataType, owner.Username)
}
names = filteredNames
}
log.Printf("found %d %s%s", len(names), metadataType, filesIgnoredDescription)
return names, nil
}