コード例 #1
0
 // Derives the account path keys and inserts them into the basic key chain. This is important to
 // preserve their
 // order for serialization, amongst other things.
 private void initializeHierarchyUnencrypted(DeterministicKey baseKey) {
   if (baseKey.getPath().isEmpty()) {
     // baseKey is a master/root key derived directly from a seed.
     addToBasicChain(rootKey);
     hierarchy = new DeterministicHierarchy(rootKey);
     addToBasicChain(hierarchy.get(ACCOUNT_ZERO_PATH, false, true));
   } else if (baseKey.getPath().size() == 1) {
     // baseKey is a "watching key" that we were given so we could follow along with this account.
     rootKey = null;
     addToBasicChain(baseKey);
     hierarchy = new DeterministicHierarchy(baseKey);
   } else {
     throw new IllegalArgumentException();
   }
   externalKey = hierarchy.deriveChild(ACCOUNT_ZERO_PATH, false, false, ChildNumber.ZERO);
   internalKey = hierarchy.deriveChild(ACCOUNT_ZERO_PATH, false, false, ChildNumber.ONE);
   addToBasicChain(externalKey);
   addToBasicChain(internalKey);
 }
コード例 #2
0
  // For use in encryption.
  private DeterministicKeyChain(
      KeyCrypter crypter, KeyParameter aesKey, DeterministicKeyChain chain) {
    // Can't encrypt a watching chain.
    checkNotNull(chain.rootKey);
    checkNotNull(chain.seed);

    checkArgument(!chain.rootKey.isEncrypted(), "Chain already encrypted");

    this.issuedExternalKeys = chain.issuedExternalKeys;
    this.issuedInternalKeys = chain.issuedInternalKeys;

    this.lookaheadSize = chain.lookaheadSize;
    this.lookaheadThreshold = chain.lookaheadThreshold;

    this.seed = chain.seed.encrypt(crypter, aesKey);
    basicKeyChain = new BasicKeyChain(crypter);
    // The first number is the "account number" but we don't use that feature.
    rootKey = chain.rootKey.encrypt(crypter, aesKey, null);
    hierarchy = new DeterministicHierarchy(rootKey);
    basicKeyChain.importKey(rootKey);

    DeterministicKey account = encryptNonLeaf(aesKey, chain, rootKey, ACCOUNT_ZERO_PATH);
    externalKey = encryptNonLeaf(aesKey, chain, account, EXTERNAL_PATH);
    internalKey = encryptNonLeaf(aesKey, chain, account, INTERNAL_PATH);

    // Now copy the (pubkey only) leaf keys across to avoid rederiving them. The private key bytes
    // are missing
    // anyway so there's nothing to encrypt.
    for (ECKey eckey : chain.basicKeyChain.getKeys()) {
      DeterministicKey key = (DeterministicKey) eckey;
      if (key.getPath().size() != 3) continue; // Not a leaf key.
      DeterministicKey parent =
          hierarchy.get(checkNotNull(key.getParent()).getPath(), false, false);
      // Clone the key to the new encrypted hierarchy.
      key = new DeterministicKey(key.getPubOnly(), parent);
      hierarchy.putKey(key);
      basicKeyChain.importKey(key);
    }
  }
コード例 #3
0
 /**
  * Returns the deterministic key for the given absolute path in the hierarchy, optionally creating
  * it
  */
 public DeterministicKey getKeyByPath(List<ChildNumber> path, boolean create) {
   return hierarchy.get(path, false, create);
 }
コード例 #4
0
 /** Returns freshly derived key/s that have not been returned by this method before. */
 @Override
 public List<DeterministicKey> getKeys(KeyPurpose purpose, int numberOfKeys) {
   checkArgument(numberOfKeys > 0);
   lock.lock();
   try {
     DeterministicKey parentKey;
     int index;
     switch (purpose) {
         // Map both REFUND and RECEIVE_KEYS to the same branch for now. Refunds are a feature of
         // the BIP 70
         // payment protocol. Later we may wish to map it to a different branch (in a new wallet
         // version?).
         // This would allow a watching wallet to only be able to see inbound payments, but not
         // change
         // (i.e. spends) or refunds. Might be useful for auditing ...
       case RECEIVE_FUNDS:
       case REFUND:
         issuedExternalKeys += numberOfKeys;
         index = issuedExternalKeys;
         parentKey = externalKey;
         break;
       case AUTHENTICATION:
       case CHANGE:
         issuedInternalKeys += numberOfKeys;
         index = issuedInternalKeys;
         parentKey = internalKey;
         break;
       default:
         throw new UnsupportedOperationException();
     }
     // Optimization: potentially do a very quick key generation for just the number of keys we
     // need if we
     // didn't already create them, ignoring the configured lookahead size. This ensures we'll be
     // able to
     // retrieve the keys in the following loop, but if we're totally fresh and didn't get a chance
     // to
     // calculate the lookahead keys yet, this will not block waiting to calculate 100+ EC point
     // multiplies.
     // On slow/crappy Android phones looking ahead 100 keys can take ~5 seconds but the OS will
     // kill us
     // if we block for just one second on the UI thread. Because UI threads may need an address in
     // order
     // to render the screen, we need getKeys to be fast even if the wallet is totally brand new
     // and lookahead
     // didn't happen yet.
     //
     // It's safe to do this because when a network thread tries to calculate a Bloom filter, we'll
     // go ahead
     // and calculate the full lookahead zone there, so network requests will always use the right
     // amount.
     List<DeterministicKey> lookahead = maybeLookAhead(parentKey, index, 0, 0);
     basicKeyChain.importKeys(lookahead);
     List<DeterministicKey> keys = new ArrayList<DeterministicKey>(numberOfKeys);
     for (int i = 0; i < numberOfKeys; i++) {
       ImmutableList<ChildNumber> path =
           HDUtils.append(parentKey.getPath(), new ChildNumber(index - numberOfKeys + i, false));
       DeterministicKey k = hierarchy.get(path, false, false);
       // Just a last minute sanity check before we hand the key out to the app for usage. This
       // isn't inspired
       // by any real problem reports from bitcoinj users, but I've heard of cases via the
       // grapevine of
       // places that lost money due to bitflips causing addresses to not match keys. Of course in
       // an
       // environment with flaky RAM there's no real way to always win: bitflips could be
       // introduced at any
       // other layer. But as we're potentially retrieving from long term storage here, check
       // anyway.
       checkForBitFlip(k);
       keys.add(k);
     }
     return keys;
   } finally {
     lock.unlock();
   }
 }