/**
* Copyright 2012 Google Inc.
*
* 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 com.google.devcoin.store;
import com.google.devcoin.core.*;
import com.google.devcoin.core.TransactionConfidence.ConfidenceType;
import com.google.devcoin.crypto.EncryptedPrivateKey;
import com.google.devcoin.crypto.KeyCrypter;
import com.google.devcoin.crypto.KeyCrypterScrypt;
import com.google.protobuf.ByteString;
import com.google.protobuf.TextFormat;
import org.devcoinj.wallet.Protos;
import org.devcoinj.wallet.Protos.Wallet.EncryptionType;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;
import java.io.IOException;
import java.io.InputStream;
import java.io.OutputStream;
import java.math.BigInteger;
import java.net.InetAddress;
import java.net.UnknownHostException;
import java.util.Date;
import java.util.HashMap;
import java.util.ListIterator;
import java.util.Map;
import static com.google.common.base.Preconditions.checkNotNull;
/**
* Serialize and de-serialize a wallet to a byte stream containing a
* <a href="http://code.google.com/apis/protocolbuffers/docs/overview.html">protocol buffer</a>. Protocol buffers are
* a data interchange format developed by Google with an efficient binary representation, a type safe specification
* language and compilers that generate code to work with those data structures for many languages. Protocol buffers
* can have their format evolved over time: conceptually they represent data using (tag, length, value) tuples. The
* format is defined by the <tt>bitcoin.proto</tt> file in the bitcoinj source distribution.<p>
*
* This class is used through its static methods. The most common operations are writeWallet and readWallet, which do
* the obvious operations on Output/InputStreams. You can use a {@link java.io.ByteArrayInputStream} and equivalent
* {@link java.io.ByteArrayOutputStream} if you'd like byte arrays instead. The protocol buffer can also be manipulated
* in its object form if you'd like to modify the flattened data structure before serialization to binary.<p>
*
* You can extend the wallet format with additional fields specific to your application if you want, but make sure
* to either put the extra data in the provided extension areas, or select tag numbers that are unlikely to be used
* by anyone else.<p>
*
* @author Miron Cuperman
*/
public class WalletProtobufSerializer {
private static final Logger log = LoggerFactory.getLogger(WalletProtobufSerializer.class);
// Used for de-serialization
protected Map<ByteString, Transaction> txMap;
public WalletProtobufSerializer() {
txMap = new HashMap<ByteString, Transaction>();
}
/**
* Formats the given wallet (transactions and keys) to the given output stream in protocol buffer format.<p>
*
* Equivalent to <tt>walletToProto(wallet).writeTo(output);</tt>
*/
public void writeWallet(Wallet wallet, OutputStream output) throws IOException {
Protos.Wallet walletProto = walletToProto(wallet);
walletProto.writeTo(output);
}
/**
* Returns the given wallet formatted as text. The text format is that used by protocol buffers and although it
* can also be parsed using {@link TextFormat#merge(CharSequence, com.google.protobuf.Message.Builder)},
* it is designed more for debugging than storage. It is not well specified and wallets are largely binary data
* structures anyway, consisting as they do of keys (large random numbers) and {@link Transaction}s which also
* mostly contain keys and hashes.
*/
public String walletToText(Wallet wallet) {
Protos.Wallet walletProto = walletToProto(wallet);
return TextFormat.printToString(walletProto);
}
/**
* Converts the given wallet to the object representation of the protocol buffers. This can be modified, or
* additional data fields set, before serialization takes place.
*/
public Protos.Wallet walletToProto(Wallet wallet) {
Protos.Wallet.Builder walletBuilder = Protos.Wallet.newBuilder();
walletBuilder.setNetworkIdentifier(wallet.getNetworkParameters().getId());
if (wallet.getDescription() != null) {
walletBuilder.setDescription(wallet.getDescription());
}
for (WalletTransaction wtx : wallet.getWalletTransactions()) {
Protos.Transaction txProto = makeTxProto(wtx);
walletBuilder.addTransaction(txProto);
}
for (ECKey key : wallet.getKeys()) {
Protos.Key.Builder keyBuilder = Protos.Key.newBuilder().setCreationTimestamp(key.getCreationTimeSeconds() * 1000)
// .setLabel() TODO
.setType(Protos.Key.Type.ORIGINAL);
if (key.getPrivKeyBytes() != null)
keyBuilder.setPrivateKey(ByteString.copyFrom(key.getPrivKeyBytes()));
EncryptedPrivateKey encryptedPrivateKey = key.getEncryptedPrivateKey();
if (encryptedPrivateKey != null) {
// Key is encrypted.
Protos.EncryptedPrivateKey.Builder encryptedKeyBuilder = Protos.EncryptedPrivateKey.newBuilder()
.setEncryptedPrivateKey(ByteString.copyFrom(encryptedPrivateKey.getEncryptedBytes()))
.setInitialisationVector(ByteString.copyFrom(encryptedPrivateKey.getInitialisationVector()));
if (key.getKeyCrypter() == null) {
throw new IllegalStateException("The encrypted key " + key.toString() + " has no KeyCrypter.");
} else {
// If it is a Scrypt + AES encrypted key, set the persisted key type.
if (key.getKeyCrypter().getUnderstoodEncryptionType() == Protos.Wallet.EncryptionType.ENCRYPTED_SCRYPT_AES) {
keyBuilder.setType(Protos.Key.Type.ENCRYPTED_SCRYPT_AES);
} else {
throw new IllegalArgumentException("The key " + key.toString() + " is encrypted with a KeyCrypter of type " + key.getKeyCrypter().getUnderstoodEncryptionType() +
". This WalletProtobufSerialiser does not understand that type of encryption.");
}
}
keyBuilder.setEncryptedPrivateKey(encryptedKeyBuilder);
}
// We serialize the public key even if the private key is present for speed reasons: we don't want to do
// lots of slow EC math to load the wallet, we prefer to store the redundant data instead. It matters more
// on mobile platforms.
keyBuilder.setPublicKey(ByteString.copyFrom(key.getPubKey()));
walletBuilder.addKey(keyBuilder);
}
// Populate the lastSeenBlockHash field.
Sha256Hash lastSeenBlockHash = wallet.getLastBlockSeenHash();
if (lastSeenBlockHash != null) {
walletBuilder.setLastSeenBlockHash(hashToByteString(lastSeenBlockHash));
walletBuilder.setLastSeenBlockHeight(wallet.getLastBlockSeenHeight());
}
// Populate the scrypt parameters.
KeyCrypter keyCrypter = wallet.getKeyCrypter();
if (keyCrypter == null) {
// The wallet is unencrypted.
walletBuilder.setEncryptionType(EncryptionType.UNENCRYPTED);
} else {
// The wallet is encrypted.
walletBuilder.setEncryptionType(keyCrypter.getUnderstoodEncryptionType());
if (keyCrypter instanceof KeyCrypterScrypt) {
KeyCrypterScrypt keyCrypterScrypt = (KeyCrypterScrypt) keyCrypter;
walletBuilder.setEncryptionParameters(keyCrypterScrypt.getScryptParameters());
} else {
// Some other form of encryption has been specified that we do not know how to persist.
throw new RuntimeException("The wallet has encryption of type '" + keyCrypter.getUnderstoodEncryptionType() + "' but this WalletProtobufSerializer does not know how to persist this.");
}
}
if (wallet.getKeyRotationTime() != null) {
long timeSecs = wallet.getKeyRotationTime().getTime() / 1000;
walletBuilder.setKeyRotationTime(timeSecs);
}
populateExtensions(wallet, walletBuilder);
// Populate the wallet version.
walletBuilder.setVersion(wallet.getVersion());
return walletBuilder.build();
}
private static void populateExtensions(Wallet wallet, Protos.Wallet.Builder walletBuilder) {
for (WalletExtension extension : wallet.getExtensions().values()) {
Protos.Extension.Builder proto = Protos.Extension.newBuilder();
proto.setId(extension.getWalletExtensionID());
proto.setMandatory(extension.isWalletExtensionMandatory());
proto.setData(ByteString.copyFrom(extension.serializeWalletExtension()));
walletBuilder.addExtension(proto);
}
}
private static Protos.Transaction makeTxProto(WalletTransaction wtx) {
Transaction tx = wtx.getTransaction();
Protos.Transaction.Builder txBuilder = Protos.Transaction.newBuilder();
txBuilder.setPool(Protos.Transaction.Pool.valueOf(wtx.getPool().getValue()))
.setHash(hashToByteString(tx.getHash()))
.setVersion((int) tx.getVersion());
if (tx.getUpdateTime() != null) {
txBuilder.setUpdatedAt(tx.getUpdateTime().getTime());
}
if (tx.getLockTime() > 0) {
txBuilder.setLockTime((int)tx.getLockTime());
}
// Handle inputs.
for (TransactionInput input : tx.getInputs()) {
Protos.TransactionInput.Builder inputBuilder = Protos.TransactionInput.newBuilder()
.setScriptBytes(ByteString.copyFrom(input.getScriptBytes()))
.setTransactionOutPointHash(hashToByteString(input.getOutpoint().getHash()))
.setTransactionOutPointIndex((int) input.getOutpoint().getIndex());
if (input.hasSequence()) {
inputBuilder.setSequence((int)input.getSequenceNumber());
}
txBuilder.addTransactionInput(inputBuilder);
}
// Handle outputs.
for (TransactionOutput output : tx.getOutputs()) {
Protos.TransactionOutput.Builder outputBuilder = Protos.TransactionOutput.newBuilder()
.setScriptBytes(ByteString.copyFrom(output.getScriptBytes()))
.setValue(output.getValue().longValue());
final TransactionInput spentBy = output.getSpentBy();
if (spentBy != null) {
Sha256Hash spendingHash = spentBy.getParentTransaction().getHash();
int spentByTransactionIndex = spentBy.getParentTransaction().getInputs().indexOf(spentBy);
outputBuilder.setSpentByTransactionHash(hashToByteString(spendingHash))
.setSpentByTransactionIndex(spentByTransactionIndex);
}
txBuilder.addTransactionOutput(outputBuilder);
}
// Handle which blocks tx was seen in.
final Map<Sha256Hash, Integer> appearsInHashes = tx.getAppearsInHashes();
if (appearsInHashes != null) {
for (Map.Entry<Sha256Hash, Integer> entry : appearsInHashes.entrySet()) {
txBuilder.addBlockHash(hashToByteString(entry.getKey()));
txBuilder.addBlockRelativityOffsets(entry.getValue());
}
}
if (tx.hasConfidence()) {
TransactionConfidence confidence = tx.getConfidence();
Protos.TransactionConfidence.Builder confidenceBuilder = Protos.TransactionConfidence.newBuilder();
writeConfidence(txBuilder, confidence, confidenceBuilder);
}
Protos.Transaction.Purpose purpose;
switch (tx.getPurpose()) {
case UNKNOWN: purpose = Protos.Transaction.Purpose.UNKNOWN; break;
case USER_PAYMENT: purpose = Protos.Transaction.Purpose.USER_PAYMENT; break;
case KEY_ROTATION: purpose = Protos.Transaction.Purpose.KEY_ROTATION; break;
default:
throw new RuntimeException("New tx purpose serialization not implemented.");
}
txBuilder.setPurpose(purpose);
return txBuilder.build();
}
private static void writeConfidence(Protos.Transaction.Builder txBuilder,
TransactionConfidence confidence,
Protos.TransactionConfidence.Builder confidenceBuilder) {
synchronized (confidence) {
confidenceBuilder.setType(Protos.TransactionConfidence.Type.valueOf(confidence.getConfidenceType().getValue()));
if (confidence.getConfidenceType() == ConfidenceType.BUILDING) {
confidenceBuilder.setAppearedAtHeight(confidence.getAppearedAtChainHeight());
confidenceBuilder.setDepth(confidence.getDepthInBlocks());
if (confidence.getWorkDone() != null) {
confidenceBuilder.setWorkDone(confidence.getWorkDone().longValue());
}
}
if (confidence.getConfidenceType() == ConfidenceType.DEAD) {
// Copy in the overriding transaction, if available.
// (A dead coinbase transaction has no overriding transaction).
if (confidence.getOverridingTransaction() != null) {
Sha256Hash overridingHash = confidence.getOverridingTransaction().getHash();
confidenceBuilder.setOverridingTransaction(hashToByteString(overridingHash));
}
}
TransactionConfidence.Source source = confidence.getSource();
switch (source) {
case SELF: confidenceBuilder.setSource(Protos.TransactionConfidence.Source.SOURCE_SELF); break;
case NETWORK: confidenceBuilder.setSource(Protos.TransactionConfidence.Source.SOURCE_NETWORK); break;
case UNKNOWN:
// Fall through.
default:
confidenceBuilder.setSource(Protos.TransactionConfidence.Source.SOURCE_UNKNOWN); break;
}
}
for (ListIterator<PeerAddress> it = confidence.getBroadcastBy(); it.hasNext();) {
PeerAddress address = it.next();
Protos.PeerAddress proto = Protos.PeerAddress.newBuilder()
.setIpAddress(ByteString.copyFrom(address.getAddr().getAddress()))
.setPort(address.getPort())
.setServices(address.getServices().longValue())
.build();
confidenceBuilder.addBroadcastBy(proto);
}
txBuilder.setConfidence(confidenceBuilder);
}
public static ByteString hashToByteString(Sha256Hash hash) {
return ByteString.copyFrom(hash.getBytes());
}
public static Sha256Hash byteStringToHash(ByteString bs) {
return new Sha256Hash(bs.toByteArray());
}
/**
* <p>Parses a wallet from the given stream, using the provided Wallet instance to load data into. This is primarily
* used when you want to register extensions. Data in the proto will be added into the wallet where applicable and
* overwrite where not.</p>
*
* <p>A wallet can be unreadable for various reasons, such as inability to open the file, corrupt data, internally
* inconsistent data, a wallet extension marked as mandatory that cannot be handled and so on. You should always
* handle {@link UnreadableWalletException} and communicate failure to the user in an appropriate manner.</p>
*
* @throws UnreadableWalletException thrown in various error conditions (see description).
*/
public Wallet readWallet(InputStream input) throws UnreadableWalletException {
Protos.Wallet walletProto = null;
try {
walletProto = parseToProto(input);
} catch (IOException e) {
throw new UnreadableWalletException("Could not load wallet file", e);
}
// System.out.println(TextFormat.printToString(walletProto));
NetworkParameters params = NetworkParameters.fromID(walletProto.getNetworkIdentifier());
Wallet wallet = new Wallet(params);
readWallet(walletProto, wallet);
return wallet;
}
/**
* <p>Loads wallet data from the given protocol buffer and inserts it into the given Wallet object. This is primarily
* useful when you wish to pre-register extension objects. Note that if loading fails the provided Wallet object
* may be in an indeterminate state and should be thrown away.</p>
*
* <p>A wallet can be unreadable for various reasons, such as inability to open the file, corrupt data, internally
* inconsistent data, a wallet extension marked as mandatory that cannot be handled and so on. You should always
* handle {@link UnreadableWalletException} and communicate failure to the user in an appropriate manner.</p>
*
* @throws UnreadableWalletException thrown in various error conditions (see description).
*/
public void readWallet(Protos.Wallet walletProto, Wallet wallet) throws UnreadableWalletException {
// Read the scrypt parameters that specify how encryption and decryption is performed.
if (walletProto.hasEncryptionParameters()) {
Protos.ScryptParameters encryptionParameters = walletProto.getEncryptionParameters();
wallet.setKeyCrypter(new KeyCrypterScrypt(encryptionParameters));
}
if (walletProto.hasDescription()) {
wallet.setDescription(walletProto.getDescription());
}
// Read all keys
for (Protos.Key keyProto : walletProto.getKeyList()) {
if (!(keyProto.getType() == Protos.Key.Type.ORIGINAL || keyProto.getType() == Protos.Key.Type.ENCRYPTED_SCRYPT_AES)) {
throw new UnreadableWalletException("Unknown key type in wallet, type = " + keyProto.getType());
}
byte[] privKey = keyProto.hasPrivateKey() ? keyProto.getPrivateKey().toByteArray() : null;
EncryptedPrivateKey encryptedPrivateKey = null;
if (keyProto.hasEncryptedPrivateKey()) {
Protos.EncryptedPrivateKey encryptedPrivateKeyProto = keyProto.getEncryptedPrivateKey();
encryptedPrivateKey = new EncryptedPrivateKey(encryptedPrivateKeyProto.getInitialisationVector().toByteArray(),
encryptedPrivateKeyProto.getEncryptedPrivateKey().toByteArray());
}
byte[] pubKey = keyProto.hasPublicKey() ? keyProto.getPublicKey().toByteArray() : null;
ECKey ecKey;
final KeyCrypter keyCrypter = wallet.getKeyCrypter();
if (keyCrypter != null && keyCrypter.getUnderstoodEncryptionType() != EncryptionType.UNENCRYPTED) {
// If the key is encrypted construct an ECKey using the encrypted private key bytes.
ecKey = new ECKey(encryptedPrivateKey, pubKey, keyCrypter);
} else {
// Construct an unencrypted private key.
ecKey = new ECKey(privKey, pubKey);
}
ecKey.setCreationTimeSeconds((keyProto.getCreationTimestamp() + 500) / 1000);
wallet.addKey(ecKey);
}
// Read all transactions and insert into the txMap.
for (Protos.Transaction txProto : walletProto.getTransactionList()) {
readTransaction(txProto, wallet.getParams());
}
// Update transaction outputs to point to inputs that spend them
for (Protos.Transaction txProto : walletProto.getTransactionList()) {
WalletTransaction wtx = connectTransactionOutputs(txProto);
wallet.addWalletTransaction(wtx);
}
// Update the lastBlockSeenHash.
if (!walletProto.hasLastSeenBlockHash()) {
wallet.setLastBlockSeenHash(null);
} else {
wallet.setLastBlockSeenHash(byteStringToHash(walletProto.getLastSeenBlockHash()));
}
if (!walletProto.hasLastSeenBlockHeight()) {
wallet.setLastBlockSeenHeight(-1);
} else {
wallet.setLastBlockSeenHeight(walletProto.getLastSeenBlockHeight());
}
if (walletProto.hasKeyRotationTime()) {
wallet.setKeyRotationTime(new Date(walletProto.getKeyRotationTime() * 1000));
}
loadExtensions(wallet, walletProto);
if (walletProto.hasVersion()) {
wallet.setVersion(walletProto.getVersion());
}
// Make sure the object can be re-used to read another wallet without corruption.
txMap.clear();
}
private static void loadExtensions(Wallet wallet, Protos.Wallet walletProto) throws UnreadableWalletException {
final Map<String, WalletExtension> extensions = wallet.getExtensions();
for (Protos.Extension extProto : walletProto.getExtensionList()) {
String id = extProto.getId();
WalletExtension extension = extensions.get(id);
if (extension == null) {
if (extProto.getMandatory()) {
throw new UnreadableWalletException("Unknown mandatory extension in wallet: " + id);
}
} else {
log.info("Loading wallet extension {}", id);
try {
extension.deserializeWalletExtension(wallet, extProto.getData().toByteArray());
} catch (Exception e) {
if (extProto.getMandatory())
throw new UnreadableWalletException("Could not parse mandatory extension in wallet: " + id);
}
}
}
}
/**
* Returns the loaded protocol buffer from the given byte stream. You normally want
* {@link Wallet#loadFromFile(java.io.File)} instead - this method is designed for low level work involving the
* wallet file format itself.
*/
public static Protos.Wallet parseToProto(InputStream input) throws IOException {
return Protos.Wallet.parseFrom(input);
}
private void readTransaction(Protos.Transaction txProto, NetworkParameters params) throws UnreadableWalletException {
Transaction tx = new Transaction(params);
if (txProto.hasUpdatedAt()) {
tx.setUpdateTime(new Date(txProto.getUpdatedAt()));
}
for (Protos.TransactionOutput outputProto : txProto.getTransactionOutputList()) {
BigInteger value = BigInteger.valueOf(outputProto.getValue());
byte[] scriptBytes = outputProto.getScriptBytes().toByteArray();
TransactionOutput output = new TransactionOutput(params, tx, value, scriptBytes);
tx.addOutput(output);
}
for (Protos.TransactionInput transactionInput : txProto.getTransactionInputList()) {
byte[] scriptBytes = transactionInput.getScriptBytes().toByteArray();
TransactionOutPoint outpoint = new TransactionOutPoint(params,
transactionInput.getTransactionOutPointIndex() & 0xFFFFFFFFL,
byteStringToHash(transactionInput.getTransactionOutPointHash())
);
TransactionInput input = new TransactionInput(params, tx, scriptBytes, outpoint);
if (transactionInput.hasSequence()) {
input.setSequenceNumber(transactionInput.getSequence());
}
tx.addInput(input);
}
for (int i = 0; i < txProto.getBlockHashCount(); i++) {
ByteString blockHash = txProto.getBlockHash(i);
int relativityOffset = 0;
if (txProto.getBlockRelativityOffsetsCount() > 0)
relativityOffset = txProto.getBlockRelativityOffsets(i);
tx.addBlockAppearance(byteStringToHash(blockHash), relativityOffset);
}
if (txProto.hasLockTime()) {
tx.setLockTime(0xffffffffL & txProto.getLockTime());
}
if (txProto.hasPurpose()) {
switch (txProto.getPurpose()) {
case UNKNOWN: tx.setPurpose(Transaction.Purpose.UNKNOWN); break;
case USER_PAYMENT: tx.setPurpose(Transaction.Purpose.USER_PAYMENT); break;
case KEY_ROTATION: tx.setPurpose(Transaction.Purpose.KEY_ROTATION); break;
default: throw new RuntimeException("New purpose serialization not implemented");
}
} else {
// Old wallet: assume a user payment as that's the only reason a new tx would have been created back then.
tx.setPurpose(Transaction.Purpose.USER_PAYMENT);
}
// Transaction should now be complete.
Sha256Hash protoHash = byteStringToHash(txProto.getHash());
if (!tx.getHash().equals(protoHash))
throw new UnreadableWalletException(String.format("Transaction did not deserialize completely: %s vs %s", tx.getHash(), protoHash));
if (txMap.containsKey(txProto.getHash()))
throw new UnreadableWalletException("Wallet contained duplicate transaction " + byteStringToHash(txProto.getHash()));
txMap.put(txProto.getHash(), tx);
}
private WalletTransaction connectTransactionOutputs(org.devcoinj.wallet.Protos.Transaction txProto) throws UnreadableWalletException {
Transaction tx = txMap.get(txProto.getHash());
WalletTransaction.Pool pool = WalletTransaction.Pool.valueOf(txProto.getPool().getNumber());
if (pool == WalletTransaction.Pool.INACTIVE || pool == WalletTransaction.Pool.PENDING_INACTIVE) {
// Upgrade old wallets: inactive pool has been merged with the pending pool.
// Remove this some time after 0.9 is old and everyone has upgraded.
// There should not be any spent outputs in this tx as old wallets would not allow them to be spent
// in this state.
pool = WalletTransaction.Pool.PENDING;
}
for (int i = 0 ; i < tx.getOutputs().size() ; i++) {
TransactionOutput output = tx.getOutputs().get(i);
final Protos.TransactionOutput transactionOutput = txProto.getTransactionOutput(i);
if (transactionOutput.hasSpentByTransactionHash()) {
final ByteString spentByTransactionHash = transactionOutput.getSpentByTransactionHash();
Transaction spendingTx = txMap.get(spentByTransactionHash);
if (spendingTx == null) {
throw new UnreadableWalletException(String.format("Could not connect %s to %s",
tx.getHashAsString(), byteStringToHash(spentByTransactionHash)));
}
final int spendingIndex = transactionOutput.getSpentByTransactionIndex();
TransactionInput input = checkNotNull(spendingTx.getInput(spendingIndex));
input.connect(output);
}
}
if (txProto.hasConfidence()) {
Protos.TransactionConfidence confidenceProto = txProto.getConfidence();
TransactionConfidence confidence = tx.getConfidence();
readConfidence(tx, confidenceProto, confidence);
}
return new WalletTransaction(pool, tx);
}
private void readConfidence(Transaction tx, Protos.TransactionConfidence confidenceProto,
TransactionConfidence confidence) throws UnreadableWalletException {
// We are lenient here because tx confidence is not an essential part of the wallet.
// If the tx has an unknown type of confidence, ignore.
if (!confidenceProto.hasType()) {
log.warn("Unknown confidence type for tx {}", tx.getHashAsString());
return;
}
ConfidenceType confidenceType;
switch (confidenceProto.getType()) {
case BUILDING: confidenceType = ConfidenceType.BUILDING; break;
case DEAD: confidenceType = ConfidenceType.DEAD; break;
// These two are equivalent (must be able to read old wallets).
case NOT_IN_BEST_CHAIN: confidenceType = ConfidenceType.PENDING; break;
case PENDING: confidenceType = ConfidenceType.PENDING; break;
case UNKNOWN:
// Fall through.
default:
confidenceType = ConfidenceType.UNKNOWN; break;
}
confidence.setConfidenceType(confidenceType);
if (confidenceProto.hasAppearedAtHeight()) {
if (confidence.getConfidenceType() != ConfidenceType.BUILDING) {
log.warn("Have appearedAtHeight but not BUILDING for tx {}", tx.getHashAsString());
return;
}
confidence.setAppearedAtChainHeight(confidenceProto.getAppearedAtHeight());
}
if (confidenceProto.hasDepth()) {
if (confidence.getConfidenceType() != ConfidenceType.BUILDING) {
log.warn("Have depth but not BUILDING for tx {}", tx.getHashAsString());
return;
}
confidence.setDepthInBlocks(confidenceProto.getDepth());
}
if (confidenceProto.hasWorkDone()) {
if (confidence.getConfidenceType() != ConfidenceType.BUILDING) {
log.warn("Have workDone but not BUILDING for tx {}", tx.getHashAsString());
return;
}
confidence.setWorkDone(BigInteger.valueOf(confidenceProto.getWorkDone()));
}
if (confidenceProto.hasOverridingTransaction()) {
if (confidence.getConfidenceType() != ConfidenceType.DEAD) {
log.warn("Have overridingTransaction but not OVERRIDDEN for tx {}", tx.getHashAsString());
return;
}
Transaction overridingTransaction =
txMap.get(confidenceProto.getOverridingTransaction());
if (overridingTransaction == null) {
log.warn("Have overridingTransaction that is not in wallet for tx {}", tx.getHashAsString());
return;
}
confidence.setOverridingTransaction(overridingTransaction);
}
for (Protos.PeerAddress proto : confidenceProto.getBroadcastByList()) {
InetAddress ip;
try {
ip = InetAddress.getByAddress(proto.getIpAddress().toByteArray());
} catch (UnknownHostException e) {
throw new UnreadableWalletException("Peer IP address does not have the right length", e);
}
int port = proto.getPort();
PeerAddress address = new PeerAddress(ip, port);
address.setServices(BigInteger.valueOf(proto.getServices()));
confidence.markBroadcastBy(address);
}
switch (confidenceProto.getSource()) {
case SOURCE_SELF: confidence.setSource(TransactionConfidence.Source.SELF); break;
case SOURCE_NETWORK: confidence.setSource(TransactionConfidence.Source.NETWORK); break;
case SOURCE_UNKNOWN:
// Fall through.
default: confidence.setSource(TransactionConfidence.Source.UNKNOWN); break;
}
}
}