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/*
* Copyright 2013 Google Inc.
* Copyright 2019 Andreas Schildbach
*
* 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 org.bitcoinj.wallet;
import org.bitcoinj.core.BloomFilter;
import org.bitcoinj.core.ECKey;
import org.bitcoinj.core.NetworkParameters;
import org.bitcoinj.crypto.*;
import org.bitcoinj.utils.ListenerRegistration;
import org.bitcoinj.utils.Threading;
import org.bitcoinj.wallet.listeners.KeyChainEventListener;
import com.google.common.collect.ImmutableList;
import com.google.common.collect.Lists;
import com.google.protobuf.ByteString;
import org.bouncycastle.crypto.params.KeyParameter;
import javax.annotation.Nullable;
import java.util.*;
import java.util.concurrent.CopyOnWriteArrayList;
import java.util.concurrent.Executor;
import java.util.concurrent.locks.ReentrantLock;
import static com.google.common.base.Preconditions.*;
/**
* A {@link KeyChain} that implements the simplest model possible: it can have keys imported into it, and just acts as
* a dumb bag of keys. It will, left to its own devices, always return the same key for usage by the wallet, although
* it will automatically add one to itself if it's empty or if encryption is requested.
*/
public class BasicKeyChain implements EncryptableKeyChain {
private final ReentrantLock lock = Threading.lock("BasicKeyChain");
// Maps used to let us quickly look up a key given data we find in transactions or the block chain.
private final LinkedHashMap hashToKeys;
private final LinkedHashMap pubkeyToKeys;
@Nullable private final KeyCrypter keyCrypter;
private boolean isWatching;
private final CopyOnWriteArrayList> listeners;
public BasicKeyChain() {
this(null);
}
public BasicKeyChain(@Nullable KeyCrypter crypter) {
this.keyCrypter = crypter;
hashToKeys = new LinkedHashMap<>();
pubkeyToKeys = new LinkedHashMap<>();
listeners = new CopyOnWriteArrayList<>();
}
/** Returns the {@link KeyCrypter} in use or null if the key chain is not encrypted. */
@Override
@Nullable
public KeyCrypter getKeyCrypter() {
lock.lock();
try {
return keyCrypter;
} finally {
lock.unlock();
}
}
@Override
public ECKey getKey(@Nullable KeyPurpose ignored) {
lock.lock();
try {
if (hashToKeys.isEmpty()) {
checkState(keyCrypter == null); // We will refuse to encrypt an empty key chain.
final ECKey key = new ECKey();
importKeyLocked(key);
queueOnKeysAdded(ImmutableList.of(key));
}
return hashToKeys.values().iterator().next();
} finally {
lock.unlock();
}
}
@Override
public List getKeys(@Nullable KeyPurpose purpose, int numberOfKeys) {
checkArgument(numberOfKeys > 0);
lock.lock();
try {
if (hashToKeys.size() < numberOfKeys) {
checkState(keyCrypter == null);
List keys = new ArrayList<>();
for (int i = 0; i < numberOfKeys - hashToKeys.size(); i++) {
keys.add(new ECKey());
}
ImmutableList immutableIKeys = ImmutableList.copyOf(keys);
ImmutableList immutableKeys = ImmutableList.copyOf(keys);
importKeysLocked(immutableKeys);
queueOnKeysAdded(immutableIKeys);
}
List keysToReturn = new ArrayList<>();
int count = 0;
while (hashToKeys.values().iterator().hasNext() && numberOfKeys != count) {
keysToReturn.add(hashToKeys.values().iterator().next());
count++;
}
return keysToReturn;
} finally {
lock.unlock();
}
}
/** Returns a copy of the list of keys that this chain is managing. */
public List getKeys() {
lock.lock();
try {
return new ArrayList<>(hashToKeys.values());
} finally {
lock.unlock();
}
}
public int importKeys(ECKey... keys) {
return importKeys(ImmutableList.copyOf(keys));
}
public int importKeys(List keys) {
lock.lock();
try {
// Check that if we're encrypted, the keys are all encrypted, and if we're not, that none are.
// We are NOT checking that the actual password matches here because we don't have access to the password at
// this point: if you screw up and import keys with mismatched passwords, you lose! So make sure the
// password is checked first.
for (ECKey key : keys) {
checkKeyEncryptionStateMatches(key);
}
List actuallyAdded = new ArrayList<>(keys.size());
for (final ECKey key : keys) {
if (hasKey(key)) continue;
actuallyAdded.add(key);
importKeyLocked(key);
}
if (actuallyAdded.size() > 0)
queueOnKeysAdded(ImmutableList.copyOf(actuallyAdded));
return actuallyAdded.size();
} finally {
lock.unlock();
}
}
private void checkKeyEncryptionStateMatches(ECKey key) {
if (keyCrypter == null && key.isEncrypted())
throw new KeyCrypterException("Key is encrypted but chain is not");
else if (keyCrypter != null && !key.isEncrypted())
throw new KeyCrypterException("Key is not encrypted but chain is");
else if (keyCrypter != null && key.getKeyCrypter() != null && !key.getKeyCrypter().equals(keyCrypter))
throw new KeyCrypterException("Key encrypted under different parameters to chain");
}
private void importKeyLocked(ECKey key) {
if (hashToKeys.isEmpty()) {
isWatching = key.isWatching();
} else {
if (key.isWatching() && !isWatching)
throw new IllegalArgumentException("Key is watching but chain is not");
if (!key.isWatching() && isWatching)
throw new IllegalArgumentException("Key is not watching but chain is");
}
ECKey previousKey = pubkeyToKeys.put(ByteString.copyFrom(key.getPubKey()), key);
hashToKeys.put(ByteString.copyFrom(key.getPubKeyHash()), key);
checkState(previousKey == null);
}
private void importKeysLocked(List keys) {
for (ECKey key : keys) {
importKeyLocked(key);
}
}
/**
* Imports a key to the key chain. If key is present in the key chain, ignore it.
*/
public void importKey(ECKey key) {
lock.lock();
try {
checkKeyEncryptionStateMatches(key);
if (hasKey(key)) return;
importKeyLocked(key);
queueOnKeysAdded(ImmutableList.of(key));
} finally {
lock.unlock();
}
}
public ECKey findKeyFromPubHash(byte[] pubKeyHash) {
lock.lock();
try {
return hashToKeys.get(ByteString.copyFrom(pubKeyHash));
} finally {
lock.unlock();
}
}
public ECKey findKeyFromPubKey(byte[] pubKey) {
lock.lock();
try {
return pubkeyToKeys.get(ByteString.copyFrom(pubKey));
} finally {
lock.unlock();
}
}
@Override
public boolean hasKey(ECKey key) {
return findKeyFromPubKey(key.getPubKey()) != null;
}
@Override
public int numKeys() {
return pubkeyToKeys.size();
}
/** Whether this basic key chain is empty, full of regular (usable for signing) keys, or full of watching keys. */
public enum State {
EMPTY,
WATCHING,
REGULAR
}
/**
* Returns whether this chain consists of pubkey only (watching) keys, regular keys (usable for signing), or
* has no keys in it yet at all (thus we cannot tell).
*/
public State isWatching() {
lock.lock();
try {
if (hashToKeys.isEmpty())
return State.EMPTY;
return isWatching ? State.WATCHING : State.REGULAR;
} finally {
lock.unlock();
}
}
/**
* Removes the given key from the keychain. Be very careful with this - losing a private key destroys the
* money associated with it.
* @return Whether the key was removed or not.
*/
public boolean removeKey(ECKey key) {
lock.lock();
try {
boolean a = hashToKeys.remove(ByteString.copyFrom(key.getPubKeyHash())) != null;
boolean b = pubkeyToKeys.remove(ByteString.copyFrom(key.getPubKey())) != null;
checkState(a == b); // Should be in both maps or neither.
return a;
} finally {
lock.unlock();
}
}
@Override
public long getEarliestKeyCreationTime() {
lock.lock();
try {
long time = Long.MAX_VALUE;
for (ECKey key : hashToKeys.values())
time = Math.min(key.getCreationTimeSeconds(), time);
return time;
} finally {
lock.unlock();
}
}
public List> getListeners() {
return new ArrayList<>(listeners);
}
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// Serialization support
//
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////
Map serializeToEditableProtobufs() {
Map result = new LinkedHashMap<>();
for (ECKey ecKey : hashToKeys.values()) {
Protos.Key.Builder protoKey = serializeEncryptableItem(ecKey);
protoKey.setPublicKey(ByteString.copyFrom(ecKey.getPubKey()));
result.put(ecKey, protoKey);
}
return result;
}
@Override
public List serializeToProtobuf() {
Collection builders = serializeToEditableProtobufs().values();
List result = new ArrayList<>(builders.size());
for (Protos.Key.Builder builder : builders) result.add(builder.build());
return result;
}
/*package*/ static Protos.Key.Builder serializeEncryptableItem(EncryptableItem item) {
Protos.Key.Builder proto = Protos.Key.newBuilder();
proto.setCreationTimestamp(item.getCreationTimeSeconds() * 1000);
if (item.isEncrypted() && item.getEncryptedData() != null) {
// The encrypted data can be missing for an "encrypted" key in the case of a deterministic wallet for
// which the leaf keys chain to an encrypted parent and rederive their private keys on the fly. In that
// case the caller in DeterministicKeyChain will take care of setting the type.
EncryptedData data = item.getEncryptedData();
proto.setEncryptedData(proto.getEncryptedData().toBuilder()
.setEncryptedPrivateKey(ByteString.copyFrom(data.encryptedBytes))
.setInitialisationVector(ByteString.copyFrom(data.initialisationVector)));
// We don't allow mixing of encryption types at the moment.
checkState(item.getEncryptionType() == Protos.Wallet.EncryptionType.ENCRYPTED_SCRYPT_AES);
proto.setType(Protos.Key.Type.ENCRYPTED_SCRYPT_AES);
} else {
final byte[] secret = item.getSecretBytes();
// The secret might be missing in the case of a watching wallet, or a key for which the private key
// is expected to be rederived on the fly from its parent.
if (secret != null)
proto.setSecretBytes(ByteString.copyFrom(secret));
proto.setType(Protos.Key.Type.ORIGINAL);
}
return proto;
}
/**
* Returns a new BasicKeyChain that contains all basic, ORIGINAL type keys extracted from the list. Unrecognised
* key types are ignored.
*/
public static BasicKeyChain fromProtobufUnencrypted(List keys) throws UnreadableWalletException {
BasicKeyChain chain = new BasicKeyChain();
chain.deserializeFromProtobuf(keys);
return chain;
}
/**
* Returns a new BasicKeyChain that contains all basic, ORIGINAL type keys and also any encrypted keys extracted
* from the list. Unrecognised key types are ignored.
* @throws org.bitcoinj.wallet.UnreadableWalletException.BadPassword if the password doesn't seem to match
* @throws org.bitcoinj.wallet.UnreadableWalletException if the data structures are corrupted/inconsistent
*/
public static BasicKeyChain fromProtobufEncrypted(List keys, KeyCrypter crypter) throws UnreadableWalletException {
BasicKeyChain chain = new BasicKeyChain(checkNotNull(crypter));
chain.deserializeFromProtobuf(keys);
return chain;
}
private void deserializeFromProtobuf(List keys) throws UnreadableWalletException {
lock.lock();
try {
checkState(hashToKeys.isEmpty(), "Tried to deserialize into a non-empty chain");
for (Protos.Key key : keys) {
if (key.getType() != Protos.Key.Type.ORIGINAL && key.getType() != Protos.Key.Type.ENCRYPTED_SCRYPT_AES)
continue;
boolean encrypted = key.getType() == Protos.Key.Type.ENCRYPTED_SCRYPT_AES;
byte[] priv = key.hasSecretBytes() ? key.getSecretBytes().toByteArray() : null;
if (!key.hasPublicKey())
throw new UnreadableWalletException("Public key missing");
byte[] pub = key.getPublicKey().toByteArray();
ECKey ecKey;
if (encrypted) {
checkState(keyCrypter != null, "This wallet is encrypted but encrypt() was not called prior to deserialization");
if (!key.hasEncryptedData())
throw new UnreadableWalletException("Encrypted private key data missing");
Protos.EncryptedData proto = key.getEncryptedData();
EncryptedData e = new EncryptedData(proto.getInitialisationVector().toByteArray(),
proto.getEncryptedPrivateKey().toByteArray());
ecKey = ECKey.fromEncrypted(e, keyCrypter, pub);
} else {
if (priv != null)
ecKey = ECKey.fromPrivateAndPrecalculatedPublic(priv, pub);
else
ecKey = ECKey.fromPublicOnly(pub);
}
ecKey.setCreationTimeSeconds(key.getCreationTimestamp() / 1000);
importKeyLocked(ecKey);
}
} finally {
lock.unlock();
}
}
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// Event listener support
//
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////
@Override
public void addEventListener(KeyChainEventListener listener) {
addEventListener(listener, Threading.USER_THREAD);
}
@Override
public void addEventListener(KeyChainEventListener listener, Executor executor) {
addEventListener(new ListenerRegistration<>(listener, executor));
}
/* package private */ void addEventListener(ListenerRegistration listener) {
listeners.add(listener);
}
@Override
public boolean removeEventListener(KeyChainEventListener listener) {
return ListenerRegistration.removeFromList(listener, listeners);
}
private void queueOnKeysAdded(final List keys) {
checkState(lock.isHeldByCurrentThread());
for (final ListenerRegistration registration : listeners) {
registration.executor.execute(new Runnable() {
@Override
public void run() {
registration.listener.onKeysAdded(keys);
}
});
}
}
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// Encryption support
//
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////
/**
* Convenience wrapper around {@link #toEncrypted(KeyCrypter,
* org.bouncycastle.crypto.params.KeyParameter)} which uses the default Scrypt key derivation algorithm and
* parameters, derives a key from the given password and returns the created key.
*/
@Override
public BasicKeyChain toEncrypted(CharSequence password) {
checkNotNull(password);
checkArgument(password.length() > 0);
KeyCrypter scrypt = new KeyCrypterScrypt();
KeyParameter derivedKey = scrypt.deriveKey(password);
return toEncrypted(scrypt, derivedKey);
}
/**
* Encrypt the wallet using the KeyCrypter and the AES key. A good default KeyCrypter to use is
* {@link KeyCrypterScrypt}.
*
* @param keyCrypter The KeyCrypter that specifies how to encrypt/ decrypt a key
* @param aesKey AES key to use (normally created using KeyCrypter#deriveKey and cached as it is time consuming
* to create from a password)
* @throws KeyCrypterException Thrown if the wallet encryption fails. If so, the wallet state is unchanged.
*/
@Override
public BasicKeyChain toEncrypted(KeyCrypter keyCrypter, KeyParameter aesKey) {
lock.lock();
try {
checkNotNull(keyCrypter);
checkState(this.keyCrypter == null, "Key chain is already encrypted");
BasicKeyChain encrypted = new BasicKeyChain(keyCrypter);
for (ECKey key : hashToKeys.values()) {
ECKey encryptedKey = key.encrypt(keyCrypter, aesKey);
// Check that the encrypted key can be successfully decrypted.
// This is done as it is a critical failure if the private key cannot be decrypted successfully
// (all bitcoin controlled by that private key is lost forever).
// For a correctly constructed keyCrypter the encryption should always be reversible so it is just
// being as cautious as possible.
if (!ECKey.encryptionIsReversible(key, encryptedKey, keyCrypter, aesKey))
throw new KeyCrypterException("The key " + key.toString() + " cannot be successfully decrypted after encryption so aborting wallet encryption.");
encrypted.importKeyLocked(encryptedKey);
}
for (ListenerRegistration listener : listeners) {
encrypted.addEventListener(listener);
}
return encrypted;
} finally {
lock.unlock();
}
}
@Override
public BasicKeyChain toDecrypted(CharSequence password) {
checkNotNull(keyCrypter, "Wallet is already decrypted");
KeyParameter aesKey = keyCrypter.deriveKey(password);
return toDecrypted(aesKey);
}
@Override
public BasicKeyChain toDecrypted(KeyParameter aesKey) {
lock.lock();
try {
checkState(keyCrypter != null, "Wallet is already decrypted");
// Do an up-front check.
if (numKeys() > 0 && !checkAESKey(aesKey))
throw new KeyCrypterException("Password/key was incorrect.");
BasicKeyChain decrypted = new BasicKeyChain();
for (ECKey key : hashToKeys.values()) {
decrypted.importKeyLocked(key.decrypt(aesKey));
}
for (ListenerRegistration listener : listeners) {
decrypted.addEventListener(listener);
}
return decrypted;
} finally {
lock.unlock();
}
}
/**
* Returns whether the given password is correct for this key chain.
* @throws IllegalStateException if the chain is not encrypted at all.
*/
@Override
public boolean checkPassword(CharSequence password) {
checkNotNull(password);
checkState(keyCrypter != null, "Key chain not encrypted");
return checkAESKey(keyCrypter.deriveKey(password));
}
/**
* Check whether the AES key can decrypt the first encrypted key in the wallet.
*
* @return true if AES key supplied can decrypt the first encrypted private key in the wallet, false otherwise.
*/
@Override
public boolean checkAESKey(KeyParameter aesKey) {
lock.lock();
try {
// If no keys then cannot decrypt.
if (hashToKeys.isEmpty()) return false;
checkState(keyCrypter != null, "Key chain is not encrypted");
// Find the first encrypted key in the wallet.
ECKey first = null;
for (ECKey key : hashToKeys.values()) {
if (key.isEncrypted()) {
first = key;
break;
}
}
checkState(first != null, "No encrypted keys in the wallet");
try {
ECKey rebornKey = first.decrypt(aesKey);
return Arrays.equals(first.getPubKey(), rebornKey.getPubKey());
} catch (KeyCrypterException e) {
// The AES key supplied is incorrect.
return false;
}
} finally {
lock.unlock();
}
}
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// Bloom filtering support
//
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////
@Override
public BloomFilter getFilter(int size, double falsePositiveRate, long tweak) {
lock.lock();
try {
BloomFilter filter = new BloomFilter(size, falsePositiveRate, tweak);
for (ECKey key : hashToKeys.values())
filter.insert(key);
return filter;
} finally {
lock.unlock();
}
}
@Override
public int numBloomFilterEntries() {
return numKeys() * 2;
}
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////
//
// Key rotation support
//
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////
/** Returns the first ECKey created after the given UNIX time, or null if there is none. */
@Nullable
public ECKey findOldestKeyAfter(long timeSecs) {
lock.lock();
try {
ECKey oldest = null;
for (ECKey key : hashToKeys.values()) {
final long keyTime = key.getCreationTimeSeconds();
if (keyTime > timeSecs) {
if (oldest == null || oldest.getCreationTimeSeconds() > keyTime)
oldest = key;
}
}
return oldest;
} finally {
lock.unlock();
}
}
/** Returns a list of all ECKeys created after the given UNIX time. */
public List findKeysBefore(long timeSecs) {
lock.lock();
try {
List results = Lists.newLinkedList();
for (ECKey key : hashToKeys.values()) {
final long keyTime = key.getCreationTimeSeconds();
if (keyTime < timeSecs) {
results.add(key);
}
}
return results;
} finally {
lock.unlock();
}
}
public String toString(boolean includePrivateKeys, @Nullable KeyParameter aesKey, NetworkParameters params) {
final StringBuilder builder = new StringBuilder();
List keys = getKeys();
Collections.sort(keys, ECKey.AGE_COMPARATOR);
for (ECKey key : keys)
key.formatKeyWithAddress(includePrivateKeys, aesKey, builder, params, null, "imported");
return builder.toString();
}
}
