Pieter Wuille
9 years ago
3 changed files with 171 additions and 0 deletions
@ -0,0 +1,152 @@ |
|||||||
|
#include "merkle.h" |
||||||
|
#include "hash.h" |
||||||
|
#include "utilstrencodings.h" |
||||||
|
|
||||||
|
/* WARNING! If you're reading this because you're learning about crypto
|
||||||
|
and/or designing a new system that will use merkle trees, keep in mind |
||||||
|
that the following merkle tree algorithm has a serious flaw related to |
||||||
|
duplicate txids, resulting in a vulnerability (CVE-2012-2459). |
||||||
|
|
||||||
|
The reason is that if the number of hashes in the list at a given time |
||||||
|
is odd, the last one is duplicated before computing the next level (which |
||||||
|
is unusual in Merkle trees). This results in certain sequences of |
||||||
|
transactions leading to the same merkle root. For example, these two |
||||||
|
trees: |
||||||
|
|
||||||
|
A A |
||||||
|
/ \ / \ |
||||||
|
B C B C |
||||||
|
/ \ | / \ / \ |
||||||
|
D E F D E F F |
||||||
|
/ \ / \ / \ / \ / \ / \ / \ |
||||||
|
1 2 3 4 5 6 1 2 3 4 5 6 5 6 |
||||||
|
|
||||||
|
for transaction lists [1,2,3,4,5,6] and [1,2,3,4,5,6,5,6] (where 5 and |
||||||
|
6 are repeated) result in the same root hash A (because the hash of both |
||||||
|
of (F) and (F,F) is C). |
||||||
|
|
||||||
|
The vulnerability results from being able to send a block with such a |
||||||
|
transaction list, with the same merkle root, and the same block hash as |
||||||
|
the original without duplication, resulting in failed validation. If the |
||||||
|
receiving node proceeds to mark that block as permanently invalid |
||||||
|
however, it will fail to accept further unmodified (and thus potentially |
||||||
|
valid) versions of the same block. We defend against this by detecting |
||||||
|
the case where we would hash two identical hashes at the end of the list |
||||||
|
together, and treating that identically to the block having an invalid |
||||||
|
merkle root. Assuming no double-SHA256 collisions, this will detect all |
||||||
|
known ways of changing the transactions without affecting the merkle |
||||||
|
root. |
||||||
|
*/ |
||||||
|
|
||||||
|
/* 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); |
||||||
|
CHash256().Write(inner[level].begin(), 32).Write(h.begin(), 32).Finalize(h.begin()); |
||||||
|
} |
||||||
|
// 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); |
||||||
|
} |
||||||
|
CHash256().Write(h.begin(), 32).Write(h.begin(), 32).Finalize(h.begin()); |
||||||
|
// 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; |
||||||
|
} |
||||||
|
} |
||||||
|
CHash256().Write(inner[level].begin(), 32).Write(h.begin(), 32).Finalize(h.begin()); |
||||||
|
level++; |
||||||
|
} |
||||||
|
} |
||||||
|
// Return result.
|
||||||
|
if (pmutated) *pmutated = mutated; |
||||||
|
if (proot) *proot = h; |
||||||
|
} |
||||||
|
|
||||||
|
uint256 ComputeMerkleRoot(const std::vector<uint256>& leaves, bool* mutated) { |
||||||
|
uint256 hash; |
||||||
|
MerkleComputation(leaves, &hash, mutated, -1, NULL); |
||||||
|
return hash; |
||||||
|
} |
||||||
|
|
||||||
|
std::vector<uint256> ComputeMerkleBranch(const std::vector<uint256>& leaves, uint32_t position) { |
||||||
|
std::vector<uint256> ret; |
||||||
|
MerkleComputation(leaves, NULL, NULL, position, &ret); |
||||||
|
return ret; |
||||||
|
} |
||||||
|
|
||||||
|
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(BEGIN(*it), END(*it), BEGIN(hash), END(hash)); |
||||||
|
} else { |
||||||
|
hash = Hash(BEGIN(hash), END(hash), BEGIN(*it), END(*it)); |
||||||
|
} |
||||||
|
nIndex >>= 1; |
||||||
|
} |
||||||
|
return hash; |
||||||
|
} |
||||||
@ -0,0 +1,17 @@ |
|||||||
|
// Copyright (c) 2015 The Bitcoin Core developers
|
||||||
|
// Distributed under the MIT software license, see the accompanying
|
||||||
|
// file COPYING or http://www.opensource.org/licenses/mit-license.php.
|
||||||
|
|
||||||
|
#ifndef BITCOIN_MERKLE |
||||||
|
#define BITCOIN_MERKLE |
||||||
|
|
||||||
|
#include <stdint.h> |
||||||
|
#include <vector> |
||||||
|
|
||||||
|
#include "uint256.h" |
||||||
|
|
||||||
|
uint256 ComputeMerkleRoot(const std::vector<uint256>& leaves, bool* mutated = NULL); |
||||||
|
std::vector<uint256> ComputeMerkleBranch(const std::vector<uint256>& leaves, uint32_t position); |
||||||
|
uint256 ComputeMerkleRootFromBranch(const uint256& leaf, const std::vector<uint256>& branch, uint32_t position); |
||||||
|
|
||||||
|
#endif |
||||||
Loading…
Reference in new issue