Add CPartialMerkleTree

This adds a compact representation for a subset of a merkle tree's nodes.
12 years ago · 4bedfa9223
3 changed files with 309 additions and 0 deletions
--- a/src/main.cpp
+++ b/src/main.cpp
@ -2262,6 +2262,127 @@ CMerkleBlock::CMerkleBlock(const CBlock& block, CBloomFilter& filter)
 uint256 CPartialMerkleTree::CalcHash(int height, unsigned int pos, const std::vector<uint256> &vTxid) {
    if (height == 0) {
        // hash at height 0 is the txids themself
        return vTxid[pos];
    } else {
        // calculate left hash
        uint256 left = CalcHash(height-1, pos*2, vTxid), right;
        // calculate right hash if not beyong the end of the array - copy left hash otherwise1
        if (pos*2+1 < CalcTreeWidth(height-1))
            right = CalcHash(height-1, pos*2+1, vTxid);
        else
            right = left;
        // combine subhashes
        return Hash(BEGIN(left), END(left), BEGIN(right), END(right));
    }
 }
 void CPartialMerkleTree::TraverseAndBuild(int height, unsigned int pos, const std::vector<uint256> &vTxid, const std::vector<bool> &vMatch) {
    // determine whether this node is the parent of at least one matched txid
    bool fParentOfMatch = false;
    for (unsigned int p = pos << height; p < (pos+1) << height && p < nTransactions; p++)
        fParentOfMatch |= vMatch[p];
    // store as flag bit
    vBits.push_back(fParentOfMatch);
    if (height==0 || !fParentOfMatch) {
        // if at height 0, or nothing interesting below, store hash and stop
        vHash.push_back(CalcHash(height, pos, vTxid));
    } else {
        // otherwise, don't store any hash, but descend into the subtrees
        TraverseAndBuild(height-1, pos*2, vTxid, vMatch);
        if (pos*2+1 < CalcTreeWidth(height-1))
            TraverseAndBuild(height-1, pos*2+1, vTxid, vMatch);
    }
 }
 uint256 CPartialMerkleTree::TraverseAndExtract(int height, unsigned int pos, unsigned int &nBitsUsed, unsigned int &nHashUsed, std::vector<uint256> &vMatch) {
    if (nBitsUsed >= vBits.size()) {
        // overflowed the bits array - failure
        fBad = true;
        return 0;
    }
    bool fParentOfMatch = vBits[nBitsUsed++];
    if (height==0 || !fParentOfMatch) {
        // if at height 0, or nothing interesting below, use stored hash and do not descend
        if (nHashUsed >= vHash.size()) {
            // overflowed the hash array - failure
            fBad = true;
            return 0;
        }
        const uint256 &hash = vHash[nHashUsed++];
        if (height==0 && fParentOfMatch) // in case of height 0, we have a matched txid
            vMatch.push_back(hash);
        return hash;
    } else {
        // otherwise, descend into the subtrees to extract matched txids and hashes
        uint256 left = TraverseAndExtract(height-1, pos*2, nBitsUsed, nHashUsed, vMatch), right;
        if (pos*2+1 < CalcTreeWidth(height-1))
            right = TraverseAndExtract(height-1, pos*2+1, nBitsUsed, nHashUsed, vMatch);
        else
            right = left;
        // and combine them before returning
        return Hash(BEGIN(left), END(left), BEGIN(right), END(right));
    }
 }
 CPartialMerkleTree::CPartialMerkleTree(const std::vector<uint256> &vTxid, const std::vector<bool> &vMatch) : nTransactions(vTxid.size()), fBad(false) {
    // reset state
    vBits.clear();
    vHash.clear();
    // calculate height of tree
    int nHeight = 0;
    while (CalcTreeWidth(nHeight) > 1)
        nHeight++;
    // traverse the partial tree
    TraverseAndBuild(nHeight, 0, vTxid, vMatch);
 }
 CPartialMerkleTree::CPartialMerkleTree() : nTransactions(0), fBad(true) {}
 uint256 CPartialMerkleTree::ExtractMatches(std::vector<uint256> &vMatch) {
    vMatch.clear();
    // An empty set will not work
    if (nTransactions == 0)
        return 0;
    // check for excessively high numbers of transactions
    if (nTransactions > MAX_BLOCK_SIZE / 60) // 60 is the lower bound for the size of a serialized CTransaction
        return 0;
    // there can never be more hashes provided than one for every txid
    if (vHash.size() > nTransactions)
        return 0;
    // there must be at least one bit per node in the partial tree, and at least one node per hash
    if (vBits.size() < vHash.size())
        return 0;
    // calculate height of tree
    int nHeight = 0;
    while (CalcTreeWidth(nHeight) > 1)
        nHeight++;
    // traverse the partial tree
    unsigned int nBitsUsed = 0, nHashUsed = 0;
    uint256 hashMerkleRoot = TraverseAndExtract(nHeight, 0, nBitsUsed, nHashUsed, vMatch);
    // verify that no problems occured during the tree traversal
    if (fBad)
        return 0;
    // verify that all bits were consumed (except for the padding caused by serializing it as a byte sequence)
    if ((nBitsUsed+7)/8 != (vBits.size()+7)/8)
        return 0;
    // verify that all hashes were consumed
    if (nHashUsed != vHash.size())
        return 0;
    return hashMerkleRoot;
 }
 bool CheckDiskSpace(uint64 nAdditionalBytes)
 {
    uint64 nFreeBytesAvailable = filesystem::space(GetDataDir()).available;
--- a/src/main.h
+++ b/src/main.h
@ -1110,11 +1110,101 @@ public:
 /** Data structure that represents a partial merkle tree.
 *
 * It respresents a subset of the txid's of a known block, in a way that
 * allows recovery of the list of txid's and the merkle root, in an
 * authenticated way.
 *
 * The encoding works as follows: we traverse the tree in depth-first order,
 * storing a bit for each traversed node, signifying whether the node is the
 * parent of at least one matched leaf txid (or a matched txid itself). In
 * case we are at the leaf level, or this bit is 0, its merkle node hash is
 * stored, and its children are not explorer further. Otherwise, no hash is
 * stored, but we recurse into both (or the only) child branch. During
 * decoding, the same depth-first traversal is performed, consuming bits and
 * hashes as they written during encoding.
 *
 * The serialization is fixed and provides a hard guarantee about the
 * encoded size:
 *
 *   SIZE <= 10 + ceil(32.25*N)
 *
 * Where N represents the number of leaf nodes of the partial tree. N itself
 * is bounded by:
 *
 *   N <= total_transactions
 *   N <= 1 + matched_transactions*tree_height
 *
 * The serialization format:
 *  - uint32     total_transactions (4 bytes)
 *  - varint     number of hashes   (1-3 bytes)
 *  - uint256[]  hashes in depth-first order (<= 32*N bytes)
 *  - varint     number of bytes of flag bits (1-3 bytes)
 *  - byte[]     flag bits, packed per 8 in a byte, least significant bit first (<= 2*N-1 bits)
 * The size constraints follow from this.
 */
 class CPartialMerkleTree
 {
 protected:
    // the total number of transactions in the block
    unsigned int nTransactions;
    // node-is-parent-of-matched-txid bits
    std::vector<bool> vBits;
    // txids and internal hashes
    std::vector<uint256> vHash;
    // flag set when encountering invalid data
    bool fBad;
    // helper function to efficiently calculate the number of nodes at given height in the merkle tree
    unsigned int CalcTreeWidth(int height) {
        return (nTransactions+(1 << height)-1) >> height;
    }
    // calculate the hash of a node in the merkle tree (at leaf level: the txid's themself)
    uint256 CalcHash(int height, unsigned int pos, const std::vector<uint256> &vTxid);
    // recursive function that traverses tree nodes, storing the data as bits and hashes
    void TraverseAndBuild(int height, unsigned int pos, const std::vector<uint256> &vTxid, const std::vector<bool> &vMatch);
    // recursive function that traverses tree nodes, consuming the bits and hashes produced by TraverseAndBuild.
    // it returns the hash of the respective node.
    uint256 TraverseAndExtract(int height, unsigned int pos, unsigned int &nBitsUsed, unsigned int &nHashUsed, std::vector<uint256> &vMatch);
 public:
    // serialization implementation
    IMPLEMENT_SERIALIZE(
        READWRITE(nTransactions);
        READWRITE(vHash);
        std::vector<unsigned char> vBytes;
        if (fRead) {
            READWRITE(vBytes);
            CPartialMerkleTree &us = *(const_cast<CPartialMerkleTree*>(this));
            us.vBits.resize(vBytes.size() * 8);
            for (unsigned int p = 0; p < us.vBits.size(); p++)
                us.vBits[p] = (vBytes[p / 8] & (1 << (p % 8))) != 0;
            us.fBad = false;
        } else {
            vBytes.resize((vBits.size()+7)/8);
            for (unsigned int p = 0; p < vBits.size(); p++)
                vBytes[p / 8] |= vBits[p] << (p % 8);
            READWRITE(vBytes);
        }
    )
    // Construct a partial merkle tree from a list of transaction id's, and a mask that selects a subset of them
    CPartialMerkleTree(const std::vector<uint256> &vTxid, const std::vector<bool> &vMatch);
    CPartialMerkleTree();
    // extract the matching txid's represented by this partial merkle tree.
    // returns the merkle root, or 0 in case of failure
    uint256 ExtractMatches(std::vector<uint256> &vMatch);
 };
 /** Nodes collect new transactions into a block, hash them into a hash tree,
--- a/src/test/pmt_tests.cpp
+++ b/src/test/pmt_tests.cpp
@ -0,0 +1,98 @@
 #include <boost/test/unit_test.hpp>
 #include "uint256.h"
 #include "main.h"
 using namespace std;
 class CPartialMerkleTreeTester : public CPartialMerkleTree
 {
 public:
    // flip one bit in one of the hashes - this should break the authentication
    void Damage() {
        unsigned int n = rand() % vHash.size();
        int bit = rand() % 256;
        uint256 &hash = vHash[n];
        hash ^= ((uint256)1 << bit);
    }
 };
 BOOST_AUTO_TEST_SUITE(pmt_tests)
 BOOST_AUTO_TEST_CASE(pmt_test1)
 {
    static const unsigned int nTxCounts[] = {1, 4, 7, 17, 56, 100, 127, 256, 312, 513, 1000, 4095};
    for (int n = 0; n < 12; n++) {
        unsigned int nTx = nTxCounts[n];
        // build a block with some dummy transactions
        CBlock block;
        for (unsigned int j=0; j<nTx; j++) {
            CTransaction tx;
            tx.nLockTime = rand(); // actual transaction data doesn't matter; just make the nLockTime's unique
            block.vtx.push_back(tx);
        }
        // calculate actual merkle root and height
        uint256 merkleRoot1 = block.BuildMerkleTree();
        std::vector<uint256> vTxid(nTx, 0);
        for (unsigned int j=0; j<nTx; j++)
            vTxid[j] = block.vtx[j].GetHash();
        int nHeight = 1, nTx_ = nTx;
        while (nTx_ > 1) {
            nTx_ = (nTx_+1)/2;
            nHeight++;
        }
        // check with random subsets with inclusion chances 1, 1/2, 1/4, ..., 1/128
        for (int att = 1; att < 15; att++) {
            // build random subset of txid's
            std::vector<bool> vMatch(nTx, false);
            std::vector<uint256> vMatchTxid1;
            for (unsigned int j=0; j<nTx; j++) {
                bool fInclude = (rand() & ((1 << (att/2)) - 1)) == 0;
                vMatch[j] = fInclude;
                if (fInclude)
                    vMatchTxid1.push_back(vTxid[j]);
            }
            // build the partial merkle tree
            CPartialMerkleTree pmt1(vTxid, vMatch);
            // serialize
            CDataStream ss(SER_NETWORK, PROTOCOL_VERSION);
            ss << pmt1;
            // verify CPartialMerkleTree's size guarantees
            unsigned int n = std::min<unsigned int>(nTx, 1 + vMatchTxid1.size()*nHeight);
            BOOST_CHECK(ss.size() <= 10 + (258*n+7)/8);
            // deserialize into a tester copy
            CPartialMerkleTreeTester pmt2;
            ss >> pmt2;
            // extract merkle root and matched txids from copy
            std::vector<uint256> vMatchTxid2;
            uint256 merkleRoot2 = pmt2.ExtractMatches(vMatchTxid2);
            // check that it has the same merkle root as the original, and a valid one
            BOOST_CHECK(merkleRoot1 == merkleRoot2);
            BOOST_CHECK(merkleRoot2 != 0);
            // check that it contains the matched transactions (in the same order!)
            BOOST_CHECK(vMatchTxid1 == vMatchTxid2);
            // check that random bit flips break the authentication
            for (int j=0; j<4; j++) {
                CPartialMerkleTreeTester pmt3(pmt2);
                pmt3.Damage();
                std::vector<uint256> vMatchTxid3;
                uint256 merkleRoot3 = pmt3.ExtractMatches(vMatchTxid3);
                BOOST_CHECK(merkleRoot3 != merkleRoot1);
            }
        }
    }
 }
 BOOST_AUTO_TEST_SUITE_END()