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key_registry.go
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/
key_registry.go
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/*
* Copyright 2019 Dgraph Labs, Inc. and Contributors
*
* 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 badger
import (
"bytes"
"crypto/aes"
"crypto/rand"
"encoding/binary"
"hash/crc32"
"io"
"os"
"path/filepath"
"sync"
"time"
"github.com/dgraph-io/badger/v3/pb"
"github.com/dgraph-io/badger/v3/y"
)
const (
// KeyRegistryFileName is the file name for the key registry file.
KeyRegistryFileName = "KEYREGISTRY"
// KeyRegistryRewriteFileName is the file name for the rewrite key registry file.
KeyRegistryRewriteFileName = "REWRITE-KEYREGISTRY"
)
// SanityText is used to check whether the given user provided storage key is valid or not
var sanityText = []byte("Hello Badger")
// KeyRegistry used to maintain all the data keys.
type KeyRegistry struct {
sync.RWMutex
dataKeys map[uint64]*pb.DataKey
lastCreated int64 //lastCreated is the timestamp(seconds) of the last data key generated.
nextKeyID uint64
fp *os.File
opt KeyRegistryOptions
}
type KeyRegistryOptions struct {
Dir string
ReadOnly bool
EncryptionKey []byte
EncryptionKeyRotationDuration time.Duration
InMemory bool
}
// newKeyRegistry returns KeyRegistry.
func newKeyRegistry(opt KeyRegistryOptions) *KeyRegistry {
return &KeyRegistry{
dataKeys: make(map[uint64]*pb.DataKey),
nextKeyID: 0,
opt: opt,
}
}
// OpenKeyRegistry opens key registry if it exists, otherwise it'll create key registry
// and returns key registry.
func OpenKeyRegistry(opt KeyRegistryOptions) (*KeyRegistry, error) {
// sanity check the encryption key length.
if len(opt.EncryptionKey) > 0 {
switch len(opt.EncryptionKey) {
default:
return nil, y.Wrapf(ErrInvalidEncryptionKey, "During OpenKeyRegistry")
case 16, 24, 32:
break
}
}
// If db is opened in InMemory mode, we don't need to write key registry to the disk.
if opt.InMemory {
return newKeyRegistry(opt), nil
}
path := filepath.Join(opt.Dir, KeyRegistryFileName)
var flags y.Flags
if opt.ReadOnly {
flags |= y.ReadOnly
} else {
flags |= y.Sync
}
fp, err := y.OpenExistingFile(path, flags)
// OpenExistingFile just open file.
// So checking whether the file exist or not. If not
// We'll create new keyregistry.
if os.IsNotExist(err) {
// Creating new registry file if not exist.
kr := newKeyRegistry(opt)
if opt.ReadOnly {
return kr, nil
}
// Writing the key registry to the file.
if err := WriteKeyRegistry(kr, opt); err != nil {
return nil, y.Wrapf(err, "Error while writing key registry.")
}
fp, err = y.OpenExistingFile(path, flags)
if err != nil {
return nil, y.Wrapf(err, "Error while opening newly created key registry.")
}
} else if err != nil {
return nil, y.Wrapf(err, "Error while opening key registry.")
}
kr, err := readKeyRegistry(fp, opt)
if err != nil {
// This case happens only if the file is opened properly and
// not able to read.
fp.Close()
return nil, err
}
if opt.ReadOnly {
// We'll close the file in readonly mode.
return kr, fp.Close()
}
kr.fp = fp
return kr, nil
}
// keyRegistryIterator reads all the datakey from the key registry
type keyRegistryIterator struct {
encryptionKey []byte
fp *os.File
// lenCrcBuf contains crc buf and data length to move forward.
lenCrcBuf [8]byte
}
// newKeyRegistryIterator returns iterator which will allow you to iterate
// over the data key of the key registry.
func newKeyRegistryIterator(fp *os.File, encryptionKey []byte) (*keyRegistryIterator, error) {
return &keyRegistryIterator{
encryptionKey: encryptionKey,
fp: fp,
lenCrcBuf: [8]byte{},
}, validRegistry(fp, encryptionKey)
}
// validRegistry checks that given encryption key is valid or not.
func validRegistry(fp *os.File, encryptionKey []byte) error {
iv := make([]byte, aes.BlockSize)
var err error
if _, err = fp.Read(iv); err != nil {
return y.Wrapf(err, "Error while reading IV for key registry.")
}
eSanityText := make([]byte, len(sanityText))
if _, err = fp.Read(eSanityText); err != nil {
return y.Wrapf(err, "Error while reading sanity text.")
}
if len(encryptionKey) > 0 {
// Decrypting sanity text.
if eSanityText, err = y.XORBlockAllocate(eSanityText, encryptionKey, iv); err != nil {
return y.Wrapf(err, "During validRegistry")
}
}
// Check the given key is valid or not.
if !bytes.Equal(eSanityText, sanityText) {
return ErrEncryptionKeyMismatch
}
return nil
}
func (kri *keyRegistryIterator) next() (*pb.DataKey, error) {
var err error
// Read crc buf and data length.
if _, err = kri.fp.Read(kri.lenCrcBuf[:]); err != nil {
// EOF means end of the iteration.
if err != io.EOF {
return nil, y.Wrapf(err, "While reading crc in keyRegistryIterator.next")
}
return nil, err
}
l := int64(binary.BigEndian.Uint32(kri.lenCrcBuf[0:4]))
// Read protobuf data.
data := make([]byte, l)
if _, err = kri.fp.Read(data); err != nil {
// EOF means end of the iteration.
if err != io.EOF {
return nil, y.Wrapf(err, "While reading protobuf in keyRegistryIterator.next")
}
return nil, err
}
// Check checksum.
if crc32.Checksum(data, y.CastagnoliCrcTable) != binary.BigEndian.Uint32(kri.lenCrcBuf[4:]) {
return nil, y.Wrapf(y.ErrChecksumMismatch, "Error while checking checksum for data key.")
}
dataKey := &pb.DataKey{}
if err = dataKey.Unmarshal(data); err != nil {
return nil, y.Wrapf(err, "While unmarshal of datakey in keyRegistryIterator.next")
}
if len(kri.encryptionKey) > 0 {
// Decrypt the key if the storage key exists.
if dataKey.Data, err = y.XORBlockAllocate(dataKey.Data, kri.encryptionKey, dataKey.Iv); err != nil {
return nil, y.Wrapf(err, "While decrypting datakey in keyRegistryIterator.next")
}
}
return dataKey, nil
}
// readKeyRegistry will read the key registry file and build the key registry struct.
func readKeyRegistry(fp *os.File, opt KeyRegistryOptions) (*KeyRegistry, error) {
itr, err := newKeyRegistryIterator(fp, opt.EncryptionKey)
if err != nil {
return nil, err
}
kr := newKeyRegistry(opt)
var dk *pb.DataKey
dk, err = itr.next()
for err == nil && dk != nil {
if dk.KeyId > kr.nextKeyID {
// Set the maximum key ID for next key ID generation.
kr.nextKeyID = dk.KeyId
}
if dk.CreatedAt > kr.lastCreated {
// Set the last generated key timestamp.
kr.lastCreated = dk.CreatedAt
}
// No need to lock since we are building the initial state.
kr.dataKeys[dk.KeyId] = dk
// Forward the iterator.
dk, err = itr.next()
}
// We read all the key. So, Ignoring this error.
if err == io.EOF {
err = nil
}
return kr, err
}
/*
Structure of Key Registry.
+-------------------+---------------------+--------------------+--------------+------------------+
| IV | Sanity Text | DataKey1 | DataKey2 | ... |
+-------------------+---------------------+--------------------+--------------+------------------+
*/
// WriteKeyRegistry will rewrite the existing key registry file with new one.
// It is okay to give closed key registry. Since, it's using only the datakey.
func WriteKeyRegistry(reg *KeyRegistry, opt KeyRegistryOptions) error {
buf := &bytes.Buffer{}
iv, err := y.GenerateIV()
y.Check(err)
// Encrypt sanity text if the encryption key is presents.
eSanity := sanityText
if len(opt.EncryptionKey) > 0 {
var err error
eSanity, err = y.XORBlockAllocate(eSanity, opt.EncryptionKey, iv)
if err != nil {
return y.Wrapf(err, "Error while encrpting sanity text in WriteKeyRegistry")
}
}
y.Check2(buf.Write(iv))
y.Check2(buf.Write(eSanity))
// Write all the datakeys to the buf.
for _, k := range reg.dataKeys {
// Writing the datakey to the given buffer.
if err := storeDataKey(buf, opt.EncryptionKey, k); err != nil {
return y.Wrapf(err, "Error while storing datakey in WriteKeyRegistry")
}
}
tmpPath := filepath.Join(opt.Dir, KeyRegistryRewriteFileName)
// Open temporary file to write the data and do atomic rename.
fp, err := y.OpenTruncFile(tmpPath, true)
if err != nil {
return y.Wrapf(err, "Error while opening tmp file in WriteKeyRegistry")
}
// Write buf to the disk.
if _, err = fp.Write(buf.Bytes()); err != nil {
// close the fd before returning error. We're not using defer
// because, for windows we need to close the fd explicitly before
// renaming.
fp.Close()
return y.Wrapf(err, "Error while writing buf in WriteKeyRegistry")
}
// In Windows the files should be closed before doing a Rename.
if err = fp.Close(); err != nil {
return y.Wrapf(err, "Error while closing tmp file in WriteKeyRegistry")
}
// Rename to the original file.
if err = os.Rename(tmpPath, filepath.Join(opt.Dir, KeyRegistryFileName)); err != nil {
return y.Wrapf(err, "Error while renaming file in WriteKeyRegistry")
}
// Sync Dir.
return syncDir(opt.Dir)
}
// DataKey returns datakey of the given key id.
func (kr *KeyRegistry) DataKey(id uint64) (*pb.DataKey, error) {
kr.RLock()
defer kr.RUnlock()
if id == 0 {
// nil represent plain text.
return nil, nil
}
dk, ok := kr.dataKeys[id]
if !ok {
return nil, y.Wrapf(ErrInvalidDataKeyID, "Error for the KEY ID %d", id)
}
return dk, nil
}
// LatestDataKey will give you the latest generated datakey based on the rotation
// period. If the last generated datakey lifetime exceeds the rotation period.
// It'll create new datakey.
func (kr *KeyRegistry) LatestDataKey() (*pb.DataKey, error) {
if len(kr.opt.EncryptionKey) == 0 {
// nil is for no encryption.
return nil, nil
}
// validKey return datakey if the last generated key duration less than
// rotation duration.
validKey := func() (*pb.DataKey, bool) {
// Time diffrence from the last generated time.
diff := time.Since(time.Unix(kr.lastCreated, 0))
if diff < kr.opt.EncryptionKeyRotationDuration {
return kr.dataKeys[kr.nextKeyID], true
}
return nil, false
}
kr.RLock()
key, valid := validKey()
kr.RUnlock()
if valid {
// If less than EncryptionKeyRotationDuration, returns the last generated key.
return key, nil
}
kr.Lock()
defer kr.Unlock()
// Key might have generated by another go routine. So,
// checking once again.
key, valid = validKey()
if valid {
return key, nil
}
k := make([]byte, len(kr.opt.EncryptionKey))
iv, err := y.GenerateIV()
if err != nil {
return nil, err
}
_, err = rand.Read(k)
if err != nil {
return nil, err
}
// Otherwise Increment the KeyID and generate new datakey.
kr.nextKeyID++
dk := &pb.DataKey{
KeyId: kr.nextKeyID,
Data: k,
CreatedAt: time.Now().Unix(),
Iv: iv,
}
// Don't store the datakey on file if badger is running in InMemory mode.
if !kr.opt.InMemory {
// Store the datekey.
buf := &bytes.Buffer{}
if err = storeDataKey(buf, kr.opt.EncryptionKey, dk); err != nil {
return nil, err
}
// Persist the datakey to the disk
if _, err = kr.fp.Write(buf.Bytes()); err != nil {
return nil, err
}
}
// storeDatakey encrypts the datakey So, placing un-encrypted key in the memory.
dk.Data = k
kr.lastCreated = dk.CreatedAt
kr.dataKeys[kr.nextKeyID] = dk
return dk, nil
}
// Close closes the key registry.
func (kr *KeyRegistry) Close() error {
if !(kr.opt.ReadOnly || kr.opt.InMemory) {
return kr.fp.Close()
}
return nil
}
// storeDataKey stores datakey in an encrypted format in the given buffer. If storage key preset.
func storeDataKey(buf *bytes.Buffer, storageKey []byte, k *pb.DataKey) error {
// xor will encrypt the IV and xor with the given data.
// It'll used for both encryption and decryption.
xor := func() error {
if len(storageKey) == 0 {
return nil
}
var err error
k.Data, err = y.XORBlockAllocate(k.Data, storageKey, k.Iv)
return err
}
// In memory datakey will be plain text so encrypting before storing to the disk.
var err error
if err = xor(); err != nil {
return y.Wrapf(err, "Error while encrypting datakey in storeDataKey")
}
var data []byte
if data, err = k.Marshal(); err != nil {
err = y.Wrapf(err, "Error while marshaling datakey in storeDataKey")
var err2 error
// decrypting the datakey back.
if err2 = xor(); err2 != nil {
return y.Wrapf(err,
y.Wrapf(err2, "Error while decrypting datakey in storeDataKey").Error())
}
return err
}
var lenCrcBuf [8]byte
binary.BigEndian.PutUint32(lenCrcBuf[0:4], uint32(len(data)))
binary.BigEndian.PutUint32(lenCrcBuf[4:8], crc32.Checksum(data, y.CastagnoliCrcTable))
y.Check2(buf.Write(lenCrcBuf[:]))
y.Check2(buf.Write(data))
// Decrypting the datakey back since we're using the pointer.
return xor()
}