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trezor-firmware/python/src/trezorlib/merkle_tree.py
2023-03-24 13:24:46 +01:00

179 lines
6.2 KiB
Python
Executable File

# This file is part of the Trezor project.
#
# Copyright (C) 2012-2022 SatoshiLabs and contributors
#
# This library is free software: you can redistribute it and/or modify
# it under the terms of the GNU Lesser General Public License version 3
# as published by the Free Software Foundation.
#
# This library is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU Lesser General Public License for more details.
#
# You should have received a copy of the License along with this library.
# If not, see <https://www.gnu.org/licenses/lgpl-3.0.html>.
import typing as t
from hashlib import sha256
from typing_extensions import Protocol
def leaf_hash(value: bytes) -> bytes:
"""Calculate a hash of a leaf node based on its value.
See documentation for `MerkleTree` for details.
"""
return sha256(b"\x00" + value).digest()
def internal_hash(left: bytes, right: bytes) -> bytes:
"""Calculate a hash of an internal node based on its child nodes.
See documentation for `MerkleTree` for details.
"""
hash_a = min(left, right)
hash_b = max(left, right)
return sha256(b"\x01" + hash_a + hash_b).digest()
class NodeType(Protocol):
"""Merkle tree node."""
tree_hash: bytes
"""Merkle root hash of the subtree rooted at this node."""
def add_to_proof_list(self, proof_entry: bytes) -> None:
"""Add a proof entry to the proof list of this node."""
...
class Leaf:
"""Leaf of a Merkle tree."""
def __init__(self, value: bytes) -> None:
self.tree_hash = leaf_hash(value)
self.proof: t.List[bytes] = []
def add_to_proof_list(self, proof_entry: bytes) -> None:
self.proof.append(proof_entry)
class Node:
"""Internal node of a Merkle tree.
Does not have its own proof, but helps to build the proof of its children by passing
the respective proof entries to them.
"""
def __init__(self, left: NodeType, right: NodeType) -> None:
self.left = left
self.right = right
self.left.add_to_proof_list(self.right.tree_hash)
self.right.add_to_proof_list(self.left.tree_hash)
self.tree_hash = internal_hash(self.left.tree_hash, self.right.tree_hash)
def add_to_proof_list(self, proof_entry: bytes) -> None:
self.left.add_to_proof_list(proof_entry)
self.right.add_to_proof_list(proof_entry)
class MerkleTree:
"""Merkle tree for a list of byte values.
The tree is built up as follows:
1. Order the leaves by their hash.
2. Build up the next level up by pairing the leaves in the current level from left
to right.
3. Any left-over odd node at the current level gets pushed to the next level.
4. Repeat until there is only one node left.
Values are not saved in the tree, only their hashes. This allows us to construct a
tree with very large values without having to keep them in memory.
Semantically, the tree operates as a set, but this implementation does not check for
duplicates. If the same value is added multiple times, the resulting tree will be
different from a tree with only one instance of the value. In addition, only one of
the several possible proofs for the repeated value is retrievable.
Proof hashes are constructed as follows:
- Leaf node entries are hashes of b"\x00" + value.
- Internal node entries are hashes of b"\x01" + min(left, right) + max(left, right).
The prefixes function to distinguish leaf nodes from internal nodes. This prevents
two attacks:
(a) An attacker cannot misuse a proof for an internal node to claim that
<internal-node-entry> is a member of the tree.
(b) An attacker cannot insert a leaf node in the format of <internal-node-entry>
that is itself an internal node of a different tree. This would allow the
attacker to expand the tree with their own subtree.
Ordering the internal node entry as min(left, right) + max(left, right) simplifies
the proof format and verifier code: when constructing the internal entry, the
verifier does not need to distinguish between left and right subtree.
"""
entries: t.Dict[bytes, Leaf]
"""Map of leaf hash -> leaf node.
Use `leaf_hash` to calculate the hash of a value, or use `get_proof(value)`
to access the proof directly.
"""
root: NodeType
"""Root node of the tree."""
def __init__(self, values: t.Iterable[bytes]) -> None:
leaves = [Leaf(value) for value in values]
leaves.sort(key=lambda leaf: leaf.tree_hash)
if not leaves:
raise ValueError("Merkle tree must have at least one value")
self.entries = {leaf.tree_hash: leaf for leaf in leaves}
# build the tree
current_level = leaves
while len(current_level) > 1:
# build one level of the tree
next_level = []
while len(current_level) >= 2:
left, right, *current_level = current_level
next_level.append(Node(left, right))
# add the remaining one or zero nodes to the next level
next_level.extend(current_level)
# switch levels and continue
current_level = next_level
assert len(current_level) == 1, "Tree must have exactly one root node"
# save the root
self.root = current_level[0]
def get_root_hash(self) -> bytes:
return self.root.tree_hash
def get_proof(self, value: bytes) -> t.List[bytes]:
"""Get the proof for a given value."""
try:
return self.entries[leaf_hash(value)].proof
except KeyError:
raise KeyError("Value not found in Merkle tree") from None
def evaluate_proof(value: bytes, proof: t.List[bytes]) -> bytes:
"""Evaluate the provided proof of membership.
Reconstructs the Merkle root hash for a tree that contains `value` as a leaf node,
proving membership in a Merkle tree with the given root hash. The result can be
compared to a statically known root hash, or a signature of it can be verified.
"""
hash = leaf_hash(value)
for proof_entry in proof:
hash = internal_hash(hash, proof_entry)
return hash