syncthing/lib/protocol/encryption.go

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// Copyright (C) 2019 The Syncthing Authors.
//
// This Source Code Form is subject to the terms of the Mozilla Public
// License, v. 2.0. If a copy of the MPL was not distributed with this file,
// You can obtain one at https://mozilla.org/MPL/2.0/.
package protocol
import (
"context"
"encoding/base32"
"encoding/binary"
"errors"
"fmt"
"io"
"strings"
"sync"
"github.com/gogo/protobuf/proto"
lru "github.com/hashicorp/golang-lru/v2"
"github.com/miscreant/miscreant.go"
"github.com/syncthing/syncthing/lib/rand"
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"github.com/syncthing/syncthing/lib/sha256"
"golang.org/x/crypto/chacha20poly1305"
"golang.org/x/crypto/hkdf"
"golang.org/x/crypto/scrypt"
)
const (
nonceSize = 24 // chacha20poly1305.NonceSizeX
tagSize = 16 // chacha20poly1305.Overhead()
keySize = 32 // fits both chacha20poly1305 and AES-SIV
minPaddedSize = 1024 // smallest block we'll allow
blockOverhead = tagSize + nonceSize
maxPathComponent = 200 // characters
encryptedDirExtension = ".syncthing-enc" // for top level dirs
miscreantAlgo = "AES-SIV"
folderKeyCacheEntries = 1000
fileKeyCacheEntries = 5000
)
// The encryptedModel sits between the encrypted device and the model. It
// receives encrypted metadata and requests from the untrusted device, so it
// must decrypt those and answer requests by encrypting the data.
type encryptedModel struct {
model contextLessModel
folderKeys *folderKeyRegistry
keyGen *KeyGenerator
}
func newEncryptedModel(model contextLessModel, folderKeys *folderKeyRegistry, keyGen *KeyGenerator) encryptedModel {
return encryptedModel{
model: model,
folderKeys: folderKeys,
keyGen: keyGen,
}
}
func (e encryptedModel) Index(folder string, files []FileInfo) error {
if folderKey, ok := e.folderKeys.get(folder); ok {
// incoming index data to be decrypted
if err := decryptFileInfos(e.keyGen, files, folderKey); err != nil {
return err
}
}
return e.model.Index(folder, files)
}
func (e encryptedModel) IndexUpdate(folder string, files []FileInfo) error {
if folderKey, ok := e.folderKeys.get(folder); ok {
// incoming index data to be decrypted
if err := decryptFileInfos(e.keyGen, files, folderKey); err != nil {
return err
}
}
return e.model.IndexUpdate(folder, files)
}
func (e encryptedModel) Request(folder, name string, blockNo, size int32, offset int64, hash []byte, weakHash uint32, fromTemporary bool) (RequestResponse, error) {
folderKey, ok := e.folderKeys.get(folder)
if !ok {
return e.model.Request(folder, name, blockNo, size, offset, hash, weakHash, fromTemporary)
}
// Figure out the real file name, offset and size from the encrypted /
// tweaked values.
realName, err := decryptName(name, folderKey)
if err != nil {
return nil, fmt.Errorf("decrypting name: %w", err)
}
realSize := size - blockOverhead
realOffset := offset - int64(blockNo*blockOverhead)
if size < minPaddedSize {
return nil, errors.New("short request")
}
// Attempt to decrypt the block hash; it may be nil depending on what
// type of device the request comes from. Trusted devices with
// encryption enabled know the hash but don't bother to encrypt & send
// it to us. Untrusted devices have the hash from the encrypted index
// data and do send it. The model knows to only verify the hash if it
// actually gets one.
var realHash []byte
fileKey := e.keyGen.FileKey(realName, folderKey)
if len(hash) > 0 {
var additional [8]byte
binary.BigEndian.PutUint64(additional[:], uint64(realOffset))
realHash, err = decryptDeterministic(hash, fileKey, additional[:])
if err != nil {
// "Legacy", no offset additional data?
realHash, err = decryptDeterministic(hash, fileKey, nil)
}
if err != nil {
return nil, fmt.Errorf("decrypting block hash: %w", err)
}
}
// Perform that request and grab the data.
resp, err := e.model.Request(folder, realName, blockNo, realSize, realOffset, realHash, 0, false)
if err != nil {
return nil, err
}
// Encrypt the response. Blocks smaller than minPaddedSize are padded
// with random data.
data := resp.Data()
if len(data) < minPaddedSize {
nd := make([]byte, minPaddedSize)
copy(nd, data)
if _, err := rand.Read(nd[len(data):]); err != nil {
panic("catastrophic randomness failure")
}
data = nd
}
enc := encryptBytes(data, fileKey)
resp.Close()
return rawResponse{enc}, nil
}
func (e encryptedModel) DownloadProgress(folder string, updates []FileDownloadProgressUpdate) error {
if _, ok := e.folderKeys.get(folder); !ok {
return e.model.DownloadProgress(folder, updates)
}
// Encrypted devices shouldn't send these - ignore them.
return nil
}
func (e encryptedModel) ClusterConfig(config ClusterConfig) error {
return e.model.ClusterConfig(config)
}
func (e encryptedModel) Closed(err error) {
e.model.Closed(err)
}
// The encryptedConnection sits between the model and the encrypted device. It
// encrypts outgoing metadata and decrypts incoming responses.
type encryptedConnection struct {
ConnectionInfo
conn *rawConnection
folderKeys *folderKeyRegistry
keyGen *KeyGenerator
}
func newEncryptedConnection(ci ConnectionInfo, conn *rawConnection, folderKeys *folderKeyRegistry, keyGen *KeyGenerator) encryptedConnection {
return encryptedConnection{
ConnectionInfo: ci,
conn: conn,
folderKeys: folderKeys,
keyGen: keyGen,
}
}
func (e encryptedConnection) Start() {
e.conn.Start()
}
func (e encryptedConnection) SetFolderPasswords(passwords map[string]string) {
e.folderKeys.setPasswords(passwords)
}
func (e encryptedConnection) DeviceID() DeviceID {
return e.conn.DeviceID()
}
func (e encryptedConnection) Index(ctx context.Context, folder string, files []FileInfo) error {
if folderKey, ok := e.folderKeys.get(folder); ok {
encryptFileInfos(e.keyGen, files, folderKey)
}
return e.conn.Index(ctx, folder, files)
}
func (e encryptedConnection) IndexUpdate(ctx context.Context, folder string, files []FileInfo) error {
if folderKey, ok := e.folderKeys.get(folder); ok {
encryptFileInfos(e.keyGen, files, folderKey)
}
return e.conn.IndexUpdate(ctx, folder, files)
}
func (e encryptedConnection) Request(ctx context.Context, folder string, name string, blockNo int, offset int64, size int, hash []byte, weakHash uint32, fromTemporary bool) ([]byte, error) {
folderKey, ok := e.folderKeys.get(folder)
if !ok {
return e.conn.Request(ctx, folder, name, blockNo, offset, size, hash, weakHash, fromTemporary)
}
// Encrypt / adjust the request parameters.
origSize := size
if size < minPaddedSize {
// Make a request for minPaddedSize data instead of the smaller
// block. We'll chop of the extra data later.
size = minPaddedSize
}
encName := encryptName(name, folderKey)
encOffset := offset + int64(blockNo*blockOverhead)
encSize := size + blockOverhead
// Perform that request, getting back and encrypted block.
bs, err := e.conn.Request(ctx, folder, encName, blockNo, encOffset, encSize, nil, 0, false)
if err != nil {
return nil, err
}
// Return the decrypted block (or an error if it fails decryption)
fileKey := e.keyGen.FileKey(name, folderKey)
bs, err = DecryptBytes(bs, fileKey)
if err != nil {
return nil, err
}
return bs[:origSize], nil
}
func (e encryptedConnection) DownloadProgress(ctx context.Context, folder string, updates []FileDownloadProgressUpdate) {
if _, ok := e.folderKeys.get(folder); !ok {
e.conn.DownloadProgress(ctx, folder, updates)
}
// No need to send these
}
func (e encryptedConnection) ClusterConfig(config ClusterConfig) {
e.conn.ClusterConfig(config)
}
func (e encryptedConnection) Close(err error) {
e.conn.Close(err)
}
func (e encryptedConnection) Closed() <-chan struct{} {
return e.conn.Closed()
}
func (e encryptedConnection) Statistics() Statistics {
return e.conn.Statistics()
}
func encryptFileInfos(keyGen *KeyGenerator, files []FileInfo, folderKey *[keySize]byte) {
for i, fi := range files {
files[i] = encryptFileInfo(keyGen, fi, folderKey)
}
}
// encryptFileInfo encrypts a FileInfo and wraps it into a new fake FileInfo
// with an encrypted name.
func encryptFileInfo(keyGen *KeyGenerator, fi FileInfo, folderKey *[keySize]byte) FileInfo {
fileKey := keyGen.FileKey(fi.Name, folderKey)
// The entire FileInfo is encrypted with a random nonce, and concatenated
// with that nonce.
bs, err := proto.Marshal(&fi)
if err != nil {
panic("impossible serialization mishap: " + err.Error())
}
encryptedFI := encryptBytes(bs, fileKey)
// The vector is set to something that is higher than any other version sent
// previously. We do this because
// there is no way for the insecure device on the other end to do proper
// conflict resolution, so they will simply accept and keep whatever is the
// latest version they see. The secure devices will decrypt the real
// FileInfo, see the real Version, and act appropriately regardless of what
// this fake version happens to be.
// The vector also needs to be deterministic/the same among all trusted
// devices with the same vector, such that the pulling/remote completion
// works correctly on the untrusted device(s).
version := Vector{
Counters: []Counter{
{
ID: 1,
},
},
}
for _, counter := range fi.Version.Counters {
version.Counters[0].Value += counter.Value
}
// Construct the fake block list. Each block will be blockOverhead bytes
// larger than the corresponding real one and have an encrypted hash.
// Very small blocks will be padded upwards to minPaddedSize.
//
// The encrypted hash becomes just a "token" for the data -- it doesn't
// help verifying it, but it lets the encrypted device do block level
// diffs and data reuse properly when it gets a new version of a file.
var offset int64
blocks := make([]BlockInfo, len(fi.Blocks))
for i, b := range fi.Blocks {
if b.Size < minPaddedSize {
b.Size = minPaddedSize
}
size := b.Size + blockOverhead
// The offset goes into the encrypted block hash as additional data,
// essentially mixing in with the nonce. This means a block hash
// remains stable for the same data at the same offset, but doesn't
// reveal the existence of identical data blocks at other offsets.
var additional [8]byte
binary.BigEndian.PutUint64(additional[:], uint64(b.Offset))
hash := encryptDeterministic(b.Hash, fileKey, additional[:])
blocks[i] = BlockInfo{
Hash: hash,
Offset: offset,
Size: size,
}
offset += int64(size)
}
// Construct the fake FileInfo. This is mostly just a wrapper around the
// encrypted FileInfo and fake block list. We'll represent symlinks as
// directories, because they need some sort of on disk representation
// but have no data outside of the metadata. Deletion and sequence
// numbering are handled as usual.
typ := FileInfoTypeFile
if fi.Type != FileInfoTypeFile {
typ = FileInfoTypeDirectory
}
enc := FileInfo{
Name: encryptName(fi.Name, folderKey),
Type: typ,
Permissions: 0o644,
ModifiedS: 1234567890, // Sat Feb 14 00:31:30 CET 2009
Deleted: fi.Deleted,
RawInvalid: fi.IsInvalid(),
Version: version,
Sequence: fi.Sequence,
Encrypted: encryptedFI,
}
if typ == FileInfoTypeFile {
enc.Size = offset // new total file size
enc.Blocks = blocks
enc.RawBlockSize = fi.BlockSize() + blockOverhead
}
return enc
}
func decryptFileInfos(keyGen *KeyGenerator, files []FileInfo, folderKey *[keySize]byte) error {
for i, fi := range files {
decFI, err := DecryptFileInfo(keyGen, fi, folderKey)
if err != nil {
return err
}
files[i] = decFI
}
return nil
}
// DecryptFileInfo extracts the encrypted portion of a FileInfo, decrypts it
// and returns that.
func DecryptFileInfo(keyGen *KeyGenerator, fi FileInfo, folderKey *[keySize]byte) (FileInfo, error) {
realName, err := decryptName(fi.Name, folderKey)
if err != nil {
return FileInfo{}, err
}
fileKey := keyGen.FileKey(realName, folderKey)
dec, err := DecryptBytes(fi.Encrypted, fileKey)
if err != nil {
return FileInfo{}, err
}
var decFI FileInfo
if err := proto.Unmarshal(dec, &decFI); err != nil {
return FileInfo{}, err
}
// Preserve sequence, which is legitimately controlled by the untrusted device
decFI.Sequence = fi.Sequence
return decFI, nil
}
var base32Hex = base32.HexEncoding.WithPadding(base32.NoPadding)
// encryptName encrypts the given string in a deterministic manner (the
// result is always the same for any given string) and encodes it in a
// filesystem-friendly manner.
func encryptName(name string, key *[keySize]byte) string {
enc := encryptDeterministic([]byte(name), key, nil)
return slashify(base32Hex.EncodeToString(enc))
}
// decryptName decrypts a string from encryptName
func decryptName(name string, key *[keySize]byte) (string, error) {
name, err := deslashify(name)
if err != nil {
return "", err
}
bs, err := base32Hex.DecodeString(name)
if err != nil {
return "", err
}
dec, err := decryptDeterministic(bs, key, nil)
if err != nil {
return "", err
}
return string(dec), nil
}
// encryptBytes encrypts bytes with a random nonce
func encryptBytes(data []byte, key *[keySize]byte) []byte {
nonce := randomNonce()
return encrypt(data, nonce, key)
}
// encryptDeterministic encrypts bytes using AES-SIV
func encryptDeterministic(data []byte, key *[keySize]byte, additionalData []byte) []byte {
aead, err := miscreant.NewAEAD(miscreantAlgo, key[:], 0)
if err != nil {
panic("cipher failure: " + err.Error())
}
return aead.Seal(nil, nil, data, additionalData)
}
// decryptDeterministic decrypts bytes using AES-SIV
func decryptDeterministic(data []byte, key *[keySize]byte, additionalData []byte) ([]byte, error) {
aead, err := miscreant.NewAEAD(miscreantAlgo, key[:], 0)
if err != nil {
panic("cipher failure: " + err.Error())
}
return aead.Open(nil, nil, data, additionalData)
}
func encrypt(data []byte, nonce *[nonceSize]byte, key *[keySize]byte) []byte {
aead, err := chacha20poly1305.NewX(key[:])
if err != nil {
// Can only fail if the key is the wrong length
panic("cipher failure: " + err.Error())
}
if aead.NonceSize() != nonceSize || aead.Overhead() != tagSize {
// We want these values to be constant for our type declarations so
// we don't use the values returned by the GCM, but we verify them
// here.
panic("crypto parameter mismatch")
}
// Data is appended to the nonce
return aead.Seal(nonce[:], nonce[:], data, nil)
}
// DecryptBytes returns the decrypted bytes, or an error if decryption
// failed.
func DecryptBytes(data []byte, key *[keySize]byte) ([]byte, error) {
if len(data) < blockOverhead {
return nil, errors.New("data too short")
}
aead, err := chacha20poly1305.NewX(key[:])
if err != nil {
// Can only fail if the key is the wrong length
panic("cipher failure: " + err.Error())
}
if aead.NonceSize() != nonceSize || aead.Overhead() != tagSize {
// We want these values to be constant for our type declarations so
// we don't use the values returned by the GCM, but we verify them
// here.
panic("crypto parameter mismatch")
}
return aead.Open(nil, data[:nonceSize], data[nonceSize:], nil)
}
// randomNonce is a normal, cryptographically random nonce
func randomNonce() *[nonceSize]byte {
var nonce [nonceSize]byte
if _, err := rand.Read(nonce[:]); err != nil {
panic("catastrophic randomness failure: " + err.Error())
}
return &nonce
}
// keysFromPasswords converts a set of folder ID to password into a set of
// folder ID to encryption key, using our key derivation function.
func keysFromPasswords(keyGen *KeyGenerator, passwords map[string]string) map[string]*[keySize]byte {
res := make(map[string]*[keySize]byte, len(passwords))
for folder, password := range passwords {
res[folder] = keyGen.KeyFromPassword(folder, password)
}
return res
}
func knownBytes(folderID string) []byte {
return []byte("syncthing" + folderID)
}
type KeyGenerator struct {
mut sync.Mutex
folderKeys *lru.TwoQueueCache[folderKeyCacheKey, *[keySize]byte]
fileKeys *lru.TwoQueueCache[fileKeyCacheKey, *[keySize]byte]
}
func NewKeyGenerator() *KeyGenerator {
folderKeys, _ := lru.New2Q[folderKeyCacheKey, *[keySize]byte](folderKeyCacheEntries)
fileKeys, _ := lru.New2Q[fileKeyCacheKey, *[keySize]byte](fileKeyCacheEntries)
return &KeyGenerator{
folderKeys: folderKeys,
fileKeys: fileKeys,
}
}
type folderKeyCacheKey struct {
folderID string
password string
}
// KeyFromPassword uses key derivation to generate a stronger key from a
// probably weak password.
func (g *KeyGenerator) KeyFromPassword(folderID, password string) *[keySize]byte {
cacheKey := folderKeyCacheKey{folderID, password}
g.mut.Lock()
defer g.mut.Unlock()
if key, ok := g.folderKeys.Get(cacheKey); ok {
return key
}
bs, err := scrypt.Key([]byte(password), knownBytes(folderID), 32768, 8, 1, keySize)
if err != nil {
panic("key derivation failure: " + err.Error())
}
if len(bs) != keySize {
panic("key derivation failure: wrong number of bytes")
}
var key [keySize]byte
copy(key[:], bs)
g.folderKeys.Add(cacheKey, &key)
return &key
}
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var hkdfSalt = []byte("syncthing")
type fileKeyCacheKey struct {
file string
key [keySize]byte
}
func (g *KeyGenerator) FileKey(filename string, folderKey *[keySize]byte) *[keySize]byte {
g.mut.Lock()
defer g.mut.Unlock()
cacheKey := fileKeyCacheKey{filename, *folderKey}
if key, ok := g.fileKeys.Get(cacheKey); ok {
return key
}
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kdf := hkdf.New(sha256.New, append(folderKey[:], filename...), hkdfSalt, nil)
var fileKey [keySize]byte
n, err := io.ReadFull(kdf, fileKey[:])
if err != nil || n != keySize {
panic("hkdf failure")
}
g.fileKeys.Add(cacheKey, &fileKey)
return &fileKey
}
func PasswordToken(keyGen *KeyGenerator, folderID, password string) []byte {
return encryptDeterministic(knownBytes(folderID), keyGen.KeyFromPassword(folderID, password), nil)
}
// slashify inserts slashes (and file extension) in the string to create an
// appropriate tree. ABCDEFGH... => A.syncthing-enc/BC/DEFGH... We can use
// forward slashes here because we're on the outside of native path formats,
// the slash is the wire format.
func slashify(s string) string {
// We somewhat sloppily assume bytes == characters here, but the only
// file names we should deal with are those that come from our base32
// encoding.
comps := make([]string, 0, len(s)/maxPathComponent+3)
comps = append(comps, s[:1]+encryptedDirExtension)
s = s[1:]
comps = append(comps, s[:2])
s = s[2:]
for len(s) > maxPathComponent {
comps = append(comps, s[:maxPathComponent])
s = s[maxPathComponent:]
}
if len(s) > 0 {
comps = append(comps, s)
}
return strings.Join(comps, "/")
}
// deslashify removes slashes and encrypted file extensions from the string.
// This is the inverse of slashify().
func deslashify(s string) (string, error) {
if s == "" || !strings.HasPrefix(s[1:], encryptedDirExtension) {
return "", fmt.Errorf("invalid encrypted path: %q", s)
}
s = s[:1] + s[1+len(encryptedDirExtension):]
return strings.ReplaceAll(s, "/", ""), nil
}
type rawResponse struct {
data []byte
}
func (r rawResponse) Data() []byte {
return r.data
}
func (rawResponse) Close() {}
func (rawResponse) Wait() {}
// IsEncryptedParent returns true if the path points at a parent directory of
// encrypted data, i.e. is not a "real" directory. This is determined by
// checking for a sentinel string in the path.
func IsEncryptedParent(pathComponents []string) bool {
l := len(pathComponents)
if l == 2 && len(pathComponents[1]) != 2 {
return false
} else if l == 0 {
return false
}
if pathComponents[0] == "" {
return false
}
if pathComponents[0][1:] != encryptedDirExtension {
return false
}
if l < 2 {
return true
}
for _, comp := range pathComponents[2:] {
if len(comp) != maxPathComponent {
return false
}
}
return true
}
type folderKeyRegistry struct {
keyGen *KeyGenerator
keys map[string]*[keySize]byte // folder ID -> key
mut sync.RWMutex
}
func newFolderKeyRegistry(keyGen *KeyGenerator, passwords map[string]string) *folderKeyRegistry {
return &folderKeyRegistry{
keyGen: keyGen,
keys: keysFromPasswords(keyGen, passwords),
}
}
func (r *folderKeyRegistry) get(folder string) (*[keySize]byte, bool) {
r.mut.RLock()
key, ok := r.keys[folder]
r.mut.RUnlock()
return key, ok
}
func (r *folderKeyRegistry) setPasswords(passwords map[string]string) {
r.mut.Lock()
r.keys = keysFromPasswords(r.keyGen, passwords)
r.mut.Unlock()
}