// Copyright (c) 2009-2010 Satoshi Nakamoto // Copyright (c) 2009-2014 The Bitcoin Core developers // Copyright (c) 2016-2024 The Hush developers // Distributed under the GPLv3 software license, see the accompanying // file COPYING or https://www.gnu.org/licenses/gpl-3.0.en.html /****************************************************************************** * Copyright © 2014-2019 The SuperNET Developers. * * * * See the AUTHORS, DEVELOPER-AGREEMENT and LICENSE files at * * the top-level directory of this distribution for the individual copyright * * holder information and the developer policies on copyright and licensing. * * * * Unless otherwise agreed in a custom licensing agreement, no part of the * * SuperNET software, including this file may be copied, modified, propagated * * or distributed except according to the terms contained in the LICENSE file * * * * Removal or modification of this copyright notice is prohibited. * * * ******************************************************************************/ #ifndef HUSH_MERKLEBLOCK_H #define HUSH_MERKLEBLOCK_H #include "serialize.h" #include "uint256.h" #include "primitives/block.h" #include "bloom.h" #include /** Data structure that represents a partial merkle tree. * * It represents 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 vBits; /** txids and internal hashes */ std::vector 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 itself) */ uint256 CalcHash(int height, unsigned int pos, const std::vector &vTxid); /** recursive function that traverses tree nodes, storing the data as bits and hashes */ void TraverseAndBuild(int height, unsigned int pos, const std::vector &vTxid, const std::vector &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 &vMatch); public: /** serialization implementation */ ADD_SERIALIZE_METHODS; template inline void SerializationOp(Stream& s, Operation ser_action) { READWRITE(nTransactions); READWRITE(vHash); std::vector vBytes; if (ser_action.ForRead()) { READWRITE(vBytes); CPartialMerkleTree &us = *(const_cast(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 ids, and a mask that selects a subset of them */ CPartialMerkleTree(const std::vector &vTxid, const std::vector &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 &vMatch); }; /** * Used to relay blocks as header + vector * to filtered nodes. */ class CMerkleBlock { public: /** Public only for unit testing */ CBlockHeader header; CPartialMerkleTree txn; public: /** Public only for unit testing and relay testing (not relayed) */ std::vector > vMatchedTxn; /** * Create from a CBlock, filtering transactions according to filter * Note that this will call IsRelevantAndUpdate on the filter for each transaction, * thus the filter will likely be modified. */ CMerkleBlock(const CBlock& block, CBloomFilter& filter); // Create from a CBlock, matching the txids in the set CMerkleBlock(const CBlock& block, const std::set& txids); CMerkleBlock() {} ADD_SERIALIZE_METHODS; template inline void SerializationOp(Stream& s, Operation ser_action) { READWRITE(header); READWRITE(txn); } }; #endif // HUSH_MERKLEBLOCK_H