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// Copyright (c) 2015-2020 The Bitcoin Core developers
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.
#include <consensus/merkle.h>
#include <test/util/random.h>
#include <test/util/setup_common.h>
#include <boost/test/unit_test.hpp>
BOOST_FIXTURE_TEST_SUITE(merkle_tests, TestingSetup)
static uint256 ComputeMerkleRootFromBranch(const uint256& leaf, const std::vector<uint256>& vMerkleBranch, uint32_t nIndex) {
uint256 hash = leaf;
for (std::vector<uint256>::const_iterator it = vMerkleBranch.begin(); it != vMerkleBranch.end(); ++it) {
if (nIndex & 1) {
hash = Hash(*it, hash);
} else {
hash = Hash(hash, *it);
}
nIndex >>= 1;
}
return hash;
}
/* This implements a constant-space merkle root/path calculator, limited to 2^32 leaves. */
static void MerkleComputation(const std::vector<uint256>& leaves, uint256* proot, bool* pmutated, uint32_t branchpos, std::vector<uint256>* pbranch) {
if (pbranch) pbranch->clear();
if (leaves.size() == 0) {
if (pmutated) *pmutated = false;
if (proot) *proot = uint256();
return;
}
bool mutated = false;
// count is the number of leaves processed so far.
uint32_t count = 0;
// inner is an array of eagerly computed subtree hashes, indexed by tree
// level (0 being the leaves).
// For example, when count is 25 (11001 in binary), inner[4] is the hash of
// the first 16 leaves, inner[3] of the next 8 leaves, and inner[0] equal to
// the last leaf. The other inner entries are undefined.
uint256 inner[32];
// Which position in inner is a hash that depends on the matching leaf.
int matchlevel = -1;
// First process all leaves into 'inner' values.
while (count < leaves.size()) {
uint256 h = leaves[count];
bool matchh = count == branchpos;
count++;
int level;
// For each of the lower bits in count that are 0, do 1 step. Each
// corresponds to an inner value that existed before processing the
// current leaf, and each needs a hash to combine it.
for (level = 0; !(count & ((uint32_t{1}) << level)); level++) {
if (pbranch) {
if (matchh) {
pbranch->push_back(inner[level]);
} else if (matchlevel == level) {
pbranch->push_back(h);
matchh = true;
}
}
mutated |= (inner[level] == h);
h = Hash(inner[level], h);
}
// Store the resulting hash at inner position level.
inner[level] = h;
if (matchh) {
matchlevel = level;
}
}
// Do a final 'sweep' over the rightmost branch of the tree to process
// odd levels, and reduce everything to a single top value.
// Level is the level (counted from the bottom) up to which we've sweeped.
int level = 0;
// As long as bit number level in count is zero, skip it. It means there
// is nothing left at this level.
while (!(count & ((uint32_t{1}) << level))) {
level++;
}
uint256 h = inner[level];
bool matchh = matchlevel == level;
while (count != ((uint32_t{1}) << level)) {
// If we reach this point, h is an inner value that is not the top.
// We combine it with itself (Bitcoin's special rule for odd levels in
// the tree) to produce a higher level one.
if (pbranch && matchh) {
pbranch->push_back(h);
}
h = Hash(h, h);
// Increment count to the value it would have if two entries at this
// level had existed.
count += ((uint32_t{1}) << level);
level++;
// And propagate the result upwards accordingly.
while (!(count & ((uint32_t{1}) << level))) {
if (pbranch) {
if (matchh) {
pbranch->push_back(inner[level]);
} else if (matchlevel == level) {
pbranch->push_back(h);
matchh = true;
}
}
h = Hash(inner[level], h);
level++;
}
}
// Return result.
if (pmutated) *pmutated = mutated;
if (proot) *proot = h;
}
static std::vector<uint256> ComputeMerkleBranch(const std::vector<uint256>& leaves, uint32_t position) {
std::vector<uint256> ret;
MerkleComputation(leaves, nullptr, nullptr, position, &ret);
return ret;
}
static std::vector<uint256> BlockMerkleBranch(const CBlock& block, uint32_t position)
{
std::vector<uint256> leaves;
leaves.resize(block.vtx.size());
for (size_t s = 0; s < block.vtx.size(); s++) {
leaves[s] = block.vtx[s]->GetHash();
}
return ComputeMerkleBranch(leaves, position);
}
// Older version of the merkle root computation code, for comparison.
static uint256 BlockBuildMerkleTree(const CBlock& block, bool* fMutated, std::vector<uint256>& vMerkleTree)
{
vMerkleTree.clear();
vMerkleTree.reserve(block.vtx.size() * 2 + 16); // Safe upper bound for the number of total nodes.
for (std::vector<CTransactionRef>::const_iterator it(block.vtx.begin()); it != block.vtx.end(); ++it)
vMerkleTree.push_back((*it)->GetHash());
int j = 0;
bool mutated = false;
for (int nSize = block.vtx.size(); nSize > 1; nSize = (nSize + 1) / 2)
{
for (int i = 0; i < nSize; i += 2)
{
int i2 = std::min(i+1, nSize-1);
if (i2 == i + 1 && i2 + 1 == nSize && vMerkleTree[j+i] == vMerkleTree[j+i2]) {
// Two identical hashes at the end of the list at a particular level.
mutated = true;
}
vMerkleTree.push_back(Hash(vMerkleTree[j+i], vMerkleTree[j+i2]));
}
j += nSize;
}
if (fMutated) {
*fMutated = mutated;
}
return (vMerkleTree.empty() ? uint256() : vMerkleTree.back());
}
// Older version of the merkle branch computation code, for comparison.
static std::vector<uint256> BlockGetMerkleBranch(const CBlock& block, const std::vector<uint256>& vMerkleTree, int nIndex)
{
std::vector<uint256> vMerkleBranch;
int j = 0;
for (int nSize = block.vtx.size(); nSize > 1; nSize = (nSize + 1) / 2)
{
int i = std::min(nIndex^1, nSize-1);
vMerkleBranch.push_back(vMerkleTree[j+i]);
nIndex >>= 1;
j += nSize;
}
return vMerkleBranch;
}
static inline int ctz(uint32_t i) {
if (i == 0) return 0;
int j = 0;
while (!(i & 1)) {
j++;
i >>= 1;
}
return j;
}
BOOST_AUTO_TEST_CASE(merkle_test)
{
for (int i = 0; i < 32; i++) {
// Try 32 block sizes: all sizes from 0 to 16 inclusive, and then 15 random sizes.
int ntx = (i <= 16) ? i : 17 + (m_rng.randrange(4000));
// Try up to 3 mutations.
for (int mutate = 0; mutate <= 3; mutate++) {
int duplicate1 = mutate >= 1 ? 1 << ctz(ntx) : 0; // The last how many transactions to duplicate first.
if (duplicate1 >= ntx) break; // Duplication of the entire tree results in a different root (it adds a level).
int ntx1 = ntx + duplicate1; // The resulting number of transactions after the first duplication.
int duplicate2 = mutate >= 2 ? 1 << ctz(ntx1) : 0; // Likewise for the second mutation.
if (duplicate2 >= ntx1) break;
int ntx2 = ntx1 + duplicate2;
int duplicate3 = mutate >= 3 ? 1 << ctz(ntx2) : 0; // And for the third mutation.
if (duplicate3 >= ntx2) break;
int ntx3 = ntx2 + duplicate3;
// Build a block with ntx different transactions.
CBlock block;
block.vtx.resize(ntx);
for (int j = 0; j < ntx; j++) {
CMutableTransaction mtx;
mtx.nLockTime = j;
block.vtx[j] = MakeTransactionRef(std::move(mtx));
}
// Compute the root of the block before mutating it.
bool unmutatedMutated = false;
uint256 unmutatedRoot = BlockMerkleRoot(block, &unmutatedMutated);
BOOST_CHECK(unmutatedMutated == false);
// Optionally mutate by duplicating the last transactions, resulting in the same merkle root.
block.vtx.resize(ntx3);
for (int j = 0; j < duplicate1; j++) {
block.vtx[ntx + j] = block.vtx[ntx + j - duplicate1];
}
for (int j = 0; j < duplicate2; j++) {
block.vtx[ntx1 + j] = block.vtx[ntx1 + j - duplicate2];
}
for (int j = 0; j < duplicate3; j++) {
block.vtx[ntx2 + j] = block.vtx[ntx2 + j - duplicate3];
}
// Compute the merkle root and merkle tree using the old mechanism.
bool oldMutated = false;
std::vector<uint256> merkleTree;
uint256 oldRoot = BlockBuildMerkleTree(block, &oldMutated, merkleTree);
// Compute the merkle root using the new mechanism.
bool newMutated = false;
uint256 newRoot = BlockMerkleRoot(block, &newMutated);
BOOST_CHECK(oldRoot == newRoot);
BOOST_CHECK(newRoot == unmutatedRoot);
BOOST_CHECK((newRoot == uint256()) == (ntx == 0));
BOOST_CHECK(oldMutated == newMutated);
BOOST_CHECK(newMutated == !!mutate);
// If no mutation was done (once for every ntx value), try up to 16 branches.
if (mutate == 0) {
for (int loop = 0; loop < std::min(ntx, 16); loop++) {
// If ntx <= 16, try all branches. Otherwise, try 16 random ones.
int mtx = loop;
if (ntx > 16) {
mtx = m_rng.randrange(ntx);
}
std::vector<uint256> newBranch = BlockMerkleBranch(block, mtx);
std::vector<uint256> oldBranch = BlockGetMerkleBranch(block, merkleTree, mtx);
BOOST_CHECK(oldBranch == newBranch);
BOOST_CHECK(ComputeMerkleRootFromBranch(block.vtx[mtx]->GetHash(), newBranch, mtx) == oldRoot);
}
}
}
}
}
BOOST_AUTO_TEST_CASE(merkle_test_empty_block)
{
bool mutated = false;
CBlock block;
uint256 root = BlockMerkleRoot(block, &mutated);
BOOST_CHECK_EQUAL(root.IsNull(), true);
BOOST_CHECK_EQUAL(mutated, false);
}
BOOST_AUTO_TEST_CASE(merkle_test_oneTx_block)
{
bool mutated = false;
CBlock block;
block.vtx.resize(1);
CMutableTransaction mtx;
mtx.nLockTime = 0;
block.vtx[0] = MakeTransactionRef(std::move(mtx));
uint256 root = BlockMerkleRoot(block, &mutated);
BOOST_CHECK_EQUAL(root, block.vtx[0]->GetHash());
BOOST_CHECK_EQUAL(mutated, false);
}
BOOST_AUTO_TEST_CASE(merkle_test_OddTxWithRepeatedLastTx_block)
{
bool mutated;
CBlock block, blockWithRepeatedLastTx;
block.vtx.resize(3);
for (std::size_t pos = 0; pos < block.vtx.size(); pos++) {
CMutableTransaction mtx;
mtx.nLockTime = pos;
block.vtx[pos] = MakeTransactionRef(std::move(mtx));
}
blockWithRepeatedLastTx = block;
blockWithRepeatedLastTx.vtx.push_back(blockWithRepeatedLastTx.vtx.back());
uint256 rootofBlock = BlockMerkleRoot(block, &mutated);
BOOST_CHECK_EQUAL(mutated, false);
uint256 rootofBlockWithRepeatedLastTx = BlockMerkleRoot(blockWithRepeatedLastTx, &mutated);
BOOST_CHECK_EQUAL(rootofBlock, rootofBlockWithRepeatedLastTx);
BOOST_CHECK_EQUAL(mutated, true);
}
BOOST_AUTO_TEST_CASE(merkle_test_LeftSubtreeRightSubtree)
{
CBlock block, leftSubtreeBlock, rightSubtreeBlock;
block.vtx.resize(4);
std::size_t pos;
for (pos = 0; pos < block.vtx.size(); pos++) {
CMutableTransaction mtx;
mtx.nLockTime = pos;
block.vtx[pos] = MakeTransactionRef(std::move(mtx));
}
for (pos = 0; pos < block.vtx.size() / 2; pos++)
leftSubtreeBlock.vtx.push_back(block.vtx[pos]);
for (pos = block.vtx.size() / 2; pos < block.vtx.size(); pos++)
rightSubtreeBlock.vtx.push_back(block.vtx[pos]);
uint256 root = BlockMerkleRoot(block);
uint256 rootOfLeftSubtree = BlockMerkleRoot(leftSubtreeBlock);
uint256 rootOfRightSubtree = BlockMerkleRoot(rightSubtreeBlock);
std::vector<uint256> leftRight;
leftRight.push_back(rootOfLeftSubtree);
leftRight.push_back(rootOfRightSubtree);
uint256 rootOfLR = ComputeMerkleRoot(leftRight);
BOOST_CHECK_EQUAL(root, rootOfLR);
}
BOOST_AUTO_TEST_CASE(merkle_test_BlockWitness)
{
CBlock block;
block.vtx.resize(2);
for (std::size_t pos = 0; pos < block.vtx.size(); pos++) {
CMutableTransaction mtx;
mtx.nLockTime = pos;
block.vtx[pos] = MakeTransactionRef(std::move(mtx));
}
uint256 blockWitness = BlockWitnessMerkleRoot(block);
std::vector<uint256> hashes;
hashes.resize(block.vtx.size());
hashes[0].SetNull();
hashes[1] = block.vtx[1]->GetHash();
uint256 merkleRootofHashes = ComputeMerkleRoot(hashes);
BOOST_CHECK_EQUAL(merkleRootofHashes, blockWitness);
}
BOOST_AUTO_TEST_SUITE_END()
|