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/*
 * 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 org.bitcoinj.core;

import org.bitcoinj.utils.*;

import javax.annotation.*;
import java.lang.ref.*;
import java.util.*;
import java.util.concurrent.locks.*;

import static com.google.common.base.Preconditions.checkNotNull;

/**
 * 

Tracks transactions that are being announced across the network. Typically one is created for you by a * {@link PeerGroup} and then given to each Peer to update. The current purpose is to let Peers update the confidence * (number of peers broadcasting). It helps address an attack scenario in which a malicious remote peer (or several) * feeds you invalid transactions, eg, ones that spend coins which don't exist. If you don't see most of the peers * announce the transaction within a reasonable time, it may be that the TX is not valid. Alternatively, an attacker * may control your entire internet connection: in this scenario counting broadcasting peers does not help you.

* *

It is not at this time directly equivalent to the Bitcoin Core memory pool, which tracks * all transactions not currently included in the best chain - it's simply a cache.

*/ public class TxConfidenceTable { protected ReentrantLock lock = Threading.lock("txconfidencetable"); private static class WeakConfidenceReference extends WeakReference { public Sha256Hash hash; public WeakConfidenceReference(TransactionConfidence confidence, ReferenceQueue queue) { super(confidence, queue); hash = confidence.getTransactionHash(); } } private LinkedHashMap table; // This ReferenceQueue gets entries added to it when they are only weakly reachable, ie, the TxConfidenceTable is the // only thing that is tracking the confidence data anymore. We check it from time to time and delete table entries // corresponding to expired transactions. In this way memory usage of the system is in line with however many // transactions you actually care to track the confidence of. We can still end up with lots of hashes being stored // if our peers flood us with invs but the MAX_SIZE param caps this. private ReferenceQueue referenceQueue; /** The max size of a table created with the no-args constructor. */ public static final int MAX_SIZE = 1000; /** * Creates a table that will track at most the given number of transactions (allowing you to bound memory * usage). * @param size Max number of transactions to track. The table will fill up to this size then stop growing. */ public TxConfidenceTable(final int size) { table = new LinkedHashMap() { @Override protected boolean removeEldestEntry(Map.Entry entry) { // An arbitrary choice to stop the memory used by tracked transactions getting too huge in the event // of some kind of DoS attack. return size() > size; } }; referenceQueue = new ReferenceQueue<>(); } /** * Creates a table that will track at most {@link TxConfidenceTable#MAX_SIZE} entries. You should normally use * this constructor. */ public TxConfidenceTable() { this(MAX_SIZE); } /** * If any transactions have expired due to being only weakly reachable through us, go ahead and delete their * table entries - it means we downloaded the transaction and sent it to various event listeners, none of * which bothered to keep a reference. Typically, this is because the transaction does not involve any keys that * are relevant to any of our wallets. */ private void cleanTable() { lock.lock(); try { Reference ref; while ((ref = referenceQueue.poll()) != null) { // Find which transaction got deleted by the GC. WeakConfidenceReference txRef = (WeakConfidenceReference) ref; // And remove the associated map entry so the other bits of memory can also be reclaimed. table.remove(txRef.hash); } } finally { lock.unlock(); } } /** * Returns the number of peers that have seen the given hash recently. */ public int numBroadcastPeers(Sha256Hash txHash) { lock.lock(); try { cleanTable(); WeakConfidenceReference entry = table.get(txHash); if (entry == null) { return 0; // No such TX known. } else { TransactionConfidence confidence = entry.get(); if (confidence == null) { // Such a TX hash was seen, but nothing seemed to care so we ended up throwing away the data. table.remove(txHash); return 0; } else { return confidence.numBroadcastPeers(); } } } finally { lock.unlock(); } } /** * Called by peers when they see a transaction advertised in an "inv" message. It passes the data on to the relevant * {@link org.bitcoinj.core.TransactionConfidence} object, creating it if needed. * * @return the number of peers that have now announced this hash (including the caller) */ public TransactionConfidence seen(Sha256Hash hash, PeerAddress byPeer) { TransactionConfidence confidence; boolean fresh = false; lock.lock(); { cleanTable(); confidence = getOrCreate(hash); fresh = confidence.markBroadcastBy(byPeer); } lock.unlock(); if (fresh) confidence.queueListeners(TransactionConfidence.Listener.ChangeReason.SEEN_PEERS); return confidence; } /** * Returns the {@link TransactionConfidence} for the given hash if we have downloaded it, or null if that tx hash * is unknown to the system at this time. */ public TransactionConfidence getOrCreate(Sha256Hash hash) { checkNotNull(hash); lock.lock(); try { WeakConfidenceReference reference = table.get(hash); if (reference != null) { TransactionConfidence confidence = reference.get(); if (confidence != null) return confidence; } TransactionConfidence newConfidence = new TransactionConfidence(hash); table.put(hash, new WeakConfidenceReference(newConfidence, referenceQueue)); return newConfidence; } finally { lock.unlock(); } } /** * Returns the {@link TransactionConfidence} for the given hash if we have downloaded it, or null if that tx hash * is unknown to the system at this time. */ @Nullable public TransactionConfidence get(Sha256Hash hash) { lock.lock(); try { WeakConfidenceReference ref = table.get(hash); if (ref == null) return null; TransactionConfidence confidence = ref.get(); if (confidence != null) return confidence; else return null; } finally { lock.unlock(); } } }




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