org.bitcoinj.crypto.DeterministicHierarchy Maven / Gradle / Ivy
/*
* Copyright 2013 Matija Mazi.
*
* 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.crypto;
import com.google.common.collect.ImmutableList;
import com.google.common.collect.Maps;
import java.util.List;
import java.util.Locale;
import java.util.Map;
import static com.google.common.base.Preconditions.checkArgument;
// TODO: This whole API feels a bit object heavy. Do we really need ChildNumber and so many maps, etc?
// TODO: Should we be representing this using an actual tree arrangement in memory instead of a bunch of hashmaps?
/**
* A DeterministicHierarchy calculates and keeps a whole tree (hierarchy) of keys originating from a single
* root key. This implements part of the BIP 32 specification. A deterministic key tree is useful because
* Bitcoin's privacy system require new keys to be created for each transaction, but managing all these
* keys quickly becomes unwieldy. In particular it becomes hard to back up and distribute them. By having
* a way to derive random-looking but deterministic keys we can make wallet backup simpler and gain the
* ability to hand out {@link DeterministicKey}s to other people who can then create new addresses
* on the fly, without having to contact us.
*
* The hierarchy is started from a single root key, and a location in the tree is given by a path which
* is a list of {@link ChildNumber}s.
*/
public class DeterministicHierarchy {
private final Map, DeterministicKey> keys = Maps.newHashMap();
private final ImmutableList rootPath;
// Keep track of how many child keys each node has. This is kind of weak.
private final Map, ChildNumber> lastChildNumbers = Maps.newHashMap();
public static final int BIP32_STANDARDISATION_TIME_SECS = 1369267200;
/**
* Constructs a new hierarchy rooted at the given key. Note that this does not have to be the top of the tree.
* You can construct a DeterministicHierarchy for a subtree of a larger tree that you may not own.
*/
public DeterministicHierarchy(DeterministicKey rootKey) {
putKey(rootKey);
rootPath = rootKey.getPath();
}
/**
* Inserts a key into the hierarchy. Used during deserialization: you normally don't need this. Keys must be
* inserted in order.
*/
public final void putKey(DeterministicKey key) {
ImmutableList path = key.getPath();
// Update our tracking of what the next child in each branch of the tree should be. Just assume that keys are
// inserted in order here.
final DeterministicKey parent = key.getParent();
if (parent != null)
lastChildNumbers.put(parent.getPath(), key.getChildNumber());
keys.put(path, key);
}
/**
* Returns a key for the given path, optionally creating it.
*
* @param path the path to the key
* @param relativePath whether the path is relative to the root path
* @param create whether the key corresponding to path should be created (with any necessary ancestors) if it doesn't exist already
* @return next newly created key using the child derivation function
* @throws IllegalArgumentException if create is false and the path was not found.
*/
public DeterministicKey get(List path, boolean relativePath, boolean create) {
ImmutableList absolutePath = relativePath
? ImmutableList.builder().addAll(rootPath).addAll(path).build()
: ImmutableList.copyOf(path);
if (!keys.containsKey(absolutePath)) {
if (!create)
throw new IllegalArgumentException(String.format(Locale.US, "No key found for %s path %s.",
relativePath ? "relative" : "absolute", HDUtils.formatPath(path)));
checkArgument(absolutePath.size() > 0, "Can't derive the master key: nothing to derive from.");
DeterministicKey parent = get(absolutePath.subList(0, absolutePath.size() - 1), false, true);
putKey(HDKeyDerivation.deriveChildKey(parent, absolutePath.get(absolutePath.size() - 1)));
}
return keys.get(absolutePath);
}
/**
* Extends the tree by calculating the next key that hangs off the given parent path. For example, if you pass a
* path of 1/2 here and there are already keys 1/2/1 and 1/2/2 then it will derive 1/2/3.
*
* @param parentPath the path to the parent
* @param relative whether the path is relative to the root path
* @param createParent whether the parent corresponding to path should be created (with any necessary ancestors) if it doesn't exist already
* @param privateDerivation whether to use private or public derivation
* @return next newly created key using the child derivation funtcion
* @throws IllegalArgumentException if the parent doesn't exist and createParent is false.
*/
public DeterministicKey deriveNextChild(ImmutableList parentPath, boolean relative, boolean createParent, boolean privateDerivation) {
DeterministicKey parent = get(parentPath, relative, createParent);
int nAttempts = 0;
while (nAttempts++ < HDKeyDerivation.MAX_CHILD_DERIVATION_ATTEMPTS) {
try {
ChildNumber createChildNumber = getNextChildNumberToDerive(parent.getPath(), privateDerivation);
return deriveChild(parent, createChildNumber);
} catch (HDDerivationException ignore) { }
}
throw new HDDerivationException("Maximum number of child derivation attempts reached, this is probably an indication of a bug.");
}
private ChildNumber getNextChildNumberToDerive(ImmutableList path, boolean privateDerivation) {
ChildNumber lastChildNumber = lastChildNumbers.get(path);
ChildNumber nextChildNumber = new ChildNumber(lastChildNumber != null ? lastChildNumber.num() + 1 : 0, privateDerivation);
lastChildNumbers.put(path, nextChildNumber);
return nextChildNumber;
}
public int getNumChildren(ImmutableList path) {
final ChildNumber cn = lastChildNumbers.get(path);
if (cn == null)
return 0;
else
return cn.num() + 1; // children start with zero based childnumbers
}
/**
* Extends the tree by calculating the requested child for the given path. For example, to get the key at position
* 1/2/3 you would pass 1/2 as the parent path and 3 as the child number.
*
* @param parentPath the path to the parent
* @param relative whether the path is relative to the root path
* @param createParent whether the parent corresponding to path should be created (with any necessary ancestors) if it doesn't exist already
* @return the requested key.
* @throws IllegalArgumentException if the parent doesn't exist and createParent is false.
*/
public DeterministicKey deriveChild(List parentPath, boolean relative, boolean createParent, ChildNumber createChildNumber) {
return deriveChild(get(parentPath, relative, createParent), createChildNumber);
}
private DeterministicKey deriveChild(DeterministicKey parent, ChildNumber createChildNumber) {
DeterministicKey childKey = HDKeyDerivation.deriveChildKey(parent, createChildNumber);
putKey(childKey);
return childKey;
}
/**
* Returns the root key that the {@link DeterministicHierarchy} was created with.
*/
public DeterministicKey getRootKey() {
return get(rootPath, false, false);
}
}