from Ethereum 2.0
def get_power_of_two_ceil(x: int) -> int:
"""
Get the power of 2 for given input, or the closest higher power of 2 if the input is not a power of 2.
Commonly used for "how many nodes do I need for a bottom tree layer fitting x elements?"
Example: 0->1, 1->1, 2->2, 3->4, 4->4, 5->8, 6->8, 7->8, 8->8, 9->16.
"""
if x <= 1:
return 1
elif x == 2:
return 2
else:
return 2 * get_power_of_two_ceil((x + 1) // 2)
def get_power_of_two_floor(x: int) -> int:
"""
Get the power of 2 for given input, or the closest lower power of 2 if the input is not a power of 2.
The zero case is a placeholder and not used for math with generalized indices.
Commonly used for "what power of two makes up the root bit of the generalized index?"
Example: 0->1, 1->1, 2->2, 3->2, 4->4, 5->4, 6->4, 7->4, 8->8, 9->8
"""
if x <= 1:
return 1
if x == 2:
return x
else:
return 2 * get_power_of_two_floor(x // 2)
In a binary Merkle tree, we define a "generalized index" of a node as 2**depth + index
. Visually, this looks as follows:
1
2 3
4 5 6 7
...
Note that the generalized index has the convenient property that the two children of node k
are 2k
and 2k+1
, and also that it equals the position of a node in the linear representation of the Merkle tree that's computed by this function:
def merkle_tree(leaves: Sequence[Bytes32]) -> Sequence[Bytes32]:
"""
Return an array representing the tree nodes by generalized index:
[0, 1, 2, 3, 4, 5, 6, 7], where each layer is a power of 2. The 0 index is ignored. The 1 index is the root.
The result will be twice the size as the padded bottom layer for the input leaves.
"""
bottom_length = get_power_of_two_ceil(len(leaves))
o = [Bytes32()] * bottom_length + list(leaves) + [Bytes32()] * (bottom_length - len(leaves))
for i in range(bottom_length - 1, 0, -1):
o[i] = hash(o[i * 2] + o[i * 2 + 1])
return o
We define a custom type GeneralizedIndex
as a Python integer type in this document. It can be represented as a Bitvector/Bitlist object as well.
We will define Merkle proofs in terms of generalized indices.
We can describe the hash tree of any SSZ object, rooted in hash_tree_root(object)
, as a binary Merkle tree whose depth may vary. For example, an object {x: bytes32, y: List[uint64]}
would look as follows:
root
/ \
x y_root
/ \
y_data_root len(y)
/ \
/\ /\
.......
We can now define a concept of a "path", a way of describing a function that takes as input an SSZ object and outputs some specific (possibly deeply nested) member. For example, foo -> foo.x
is a path, as are foo -> len(foo.y)
and foo -> foo.y[5].w
. We'll describe paths as lists, which can have two representations. In "human-readable form", they are ["x"]
, ["y", "__len__"]
and ["y", 5, "w"]
respectively. In "encoded form", they are lists of uint64
values, in these cases (assuming the fields of foo
in order are x
then y
, and w
is the first field of y[i]
) [0]
, [1, 2**64-1]
, [1, 5, 0]
. We define SSZVariableName
as the member variable name string, i.e., a path is presented as a sequence of integers and SSZVariableName
.
def item_length(typ: SSZType) -> int:
"""
Return the number of bytes in a basic type, or 32 (a full hash) for compound types.
"""
if issubclass(typ, BasicValue):
return typ.byte_len
else:
return 32
def get_elem_type(typ: Union[BaseBytes, BaseList, Container],
index_or_variable_name: Union[int, SSZVariableName]) -> SSZType:
"""
Return the type of the element of an object of the given type with the given index
or member variable name (eg. `7` for `x[7]`, `"foo"` for `x.foo`)
"""
return typ.get_fields()[index_or_variable_name] if issubclass(typ, Container) else typ.elem_type
def chunk_count(typ: SSZType) -> int:
"""
Return the number of hashes needed to represent the top-level elements in the given type
(eg. `x.foo` or `x[7]` but not `x[7].bar` or `x.foo.baz`). In all cases except lists/vectors
of basic types, this is simply the number of top-level elements, as each element gets one
hash. For lists/vectors of basic types, it is often fewer because multiple basic elements
can be packed into one 32-byte chunk.
"""
# typ.length describes the limit for list types, or the length for vector types.
if issubclass(typ, BasicValue):
return 1
elif issubclass(typ, Bits):
return (typ.length + 255) // 256
elif issubclass(typ, Elements):
return (typ.length * item_length(typ.elem_type) + 31) // 32
elif issubclass(typ, Container):
return len(typ.get_fields())
else:
raise Exception(f"Type not supported: {typ}")
def get_item_position(typ: SSZType, index_or_variable_name: Union[int, SSZVariableName]) -> Tuple[int, int, int]:
"""
Return three variables:
(i) the index of the chunk in which the given element of the item is represented;
(ii) the starting byte position within the chunk;
(iii) the ending byte position within the chunk.
For example: for a 6-item list of uint64 values, index=2 will return (0, 16, 24), index=5 will return (1, 8, 16)
"""
if issubclass(typ, Elements):
index = int(index_or_variable_name)
start = index * item_length(typ.elem_type)
return start // 32, start % 32, start % 32 + item_length(typ.elem_type)
elif issubclass(typ, Container):
variable_name = index_or_variable_name
return typ.get_field_names().index(variable_name), 0, item_length(get_elem_type(typ, variable_name))
else:
raise Exception("Only lists/vectors/containers supported")
def get_generalized_index(typ: SSZType, path: Sequence[Union[int, SSZVariableName]]) -> GeneralizedIndex:
"""
Converts a path (eg. `[7, "foo", 3]` for `x[7].foo[3]`, `[12, "bar", "__len__"]` for
`len(x[12].bar)`) into the generalized index representing its position in the Merkle tree.
"""
root = GeneralizedIndex(1)
for p in path:
assert not issubclass(typ, BasicValue) # If we descend to a basic type, the path cannot continue further
if p == '__len__':
typ = uint64
assert issubclass(typ, (List, ByteList))
root = GeneralizedIndex(root * 2 + 1)
else:
pos, _, _ = get_item_position(typ, p)
base_index = (GeneralizedIndex(2) if issubclass(typ, (List, ByteList)) else GeneralizedIndex(1))
root = GeneralizedIndex(root * base_index * get_power_of_two_ceil(chunk_count(typ)) + pos)
typ = get_elem_type(typ, p)
return root
Usage note: functions outside this section should manipulate generalized indices using only functions inside this section. This is to make it easier for developers to implement generalized indices with underlying representations other than bigints.
concat_generalized_indices
def concat_generalized_indices(*indices: GeneralizedIndex) -> GeneralizedIndex:
"""
Given generalized indices i1 for A -> B, i2 for B -> C .... i_n for Y -> Z, returns
the generalized index for A -> Z.
"""
o = GeneralizedIndex(1)
for i in indices:
o = GeneralizedIndex(o * get_power_of_two_floor(i) + (i - get_power_of_two_floor(i)))
return o
get_generalized_index_length
def get_generalized_index_length(index: GeneralizedIndex) -> int:
"""
Return the length of a path represented by a generalized index.
"""
return int(log2(index))
get_generalized_index_bit
def get_generalized_index_bit(index: GeneralizedIndex, position: int) -> bool:
"""
Return the given bit of a generalized index.
"""
return (index & (1 << position)) > 0
generalized_index_sibling
def generalized_index_sibling(index: GeneralizedIndex) -> GeneralizedIndex:
return GeneralizedIndex(index ^ 1)
generalized_index_child
def generalized_index_child(index: GeneralizedIndex, right_side: bool) -> GeneralizedIndex:
return GeneralizedIndex(index * 2 + right_side)
generalized_index_parent
def generalized_index_parent(index: GeneralizedIndex) -> GeneralizedIndex:
return GeneralizedIndex(index // 2)
We define a Merkle multiproof as a minimal subset of nodes in a Merkle tree needed to fully authenticate that a set of nodes actually are part of a Merkle tree with some specified root, at a particular set of generalized indices. For example, here is the Merkle multiproof for positions 0, 1, 6 in an 8-node Merkle tree (i.e. generalized indices 8, 9, 14):
.
. .
. * * .
x x . . . . x *
. are unused nodes, _ are used nodes, x are the values we are trying to prove. Notice how despite being a multiproof for 3 values, it requires only 3 auxiliary nodes, only one node more than would be required to prove a single value. Normally the efficiency gains are not quite that extreme, but the savings relative to individual Merkle proofs are still significant. As a rule of thumb, a multiproof for k nodes at the same level of an n-node tree has size k _ (n/k + log(n/k))
.
First, we provide a method for computing the generalized indices of the auxiliary tree nodes that a proof of a given set of generalized indices will require:
def get_branch_indices(tree_index: GeneralizedIndex) -> Sequence[GeneralizedIndex]:
"""
Get the generalized indices of the sister chunks along the path from the chunk with the
given tree index to the root.
"""
o = [generalized_index_sibling(tree_index)]
while o[-1] > 1:
o.append(generalized_index_sibling(generalized_index_parent(o[-1])))
return o[:-1]
def get_path_indices(tree_index: GeneralizedIndex) -> Sequence[GeneralizedIndex]:
"""
Get the generalized indices of the chunks along the path from the chunk with the
given tree index to the root.
"""
o = [tree_index]
while o[-1] > 1:
o.append(generalized_index_parent(o[-1]))
return o[:-1]
def get_helper_indices(indices: Sequence[GeneralizedIndex]) -> Sequence[GeneralizedIndex]:
"""
Get the generalized indices of all "extra" chunks in the tree needed to prove the chunks with the given
generalized indices. Note that the decreasing order is chosen deliberately to ensure equivalence to the
order of hashes in a regular single-item Merkle proof in the single-item case.
"""
all_helper_indices: Set[GeneralizedIndex] = set()
all_path_indices: Set[GeneralizedIndex] = set()
for index in indices:
all_helper_indices = all_helper_indices.union(set(get_branch_indices(index)))
all_path_indices = all_path_indices.union(set(get_path_indices(index)))
return sorted(all_helper_indices.difference(all_path_indices), reverse=True)
Now we provide the Merkle proof verification functions. First, for single item proofs:
def calculate_merkle_root(leaf: Bytes32, proof: Sequence[Bytes32], index: GeneralizedIndex) -> Root:
assert len(proof) == get_generalized_index_length(index)
for i, h in enumerate(proof):
if get_generalized_index_bit(index, i):
leaf = hash(h + leaf)
else:
leaf = hash(leaf + h)
return leaf
def verify_merkle_proof(leaf: Bytes32, proof: Sequence[Bytes32], index: GeneralizedIndex, root: Root) -> bool:
return calculate_merkle_root(leaf, proof, index) == root
Now for multi-item proofs:
def calculate_multi_merkle_root(leaves: Sequence[Bytes32],
proof: Sequence[Bytes32],
indices: Sequence[GeneralizedIndex]) -> Root:
assert len(leaves) == len(indices)
helper_indices = get_helper_indices(indices)
assert len(proof) == len(helper_indices)
objects = {
**{index: node for index, node in zip(indices, leaves)},
**{index: node for index, node in zip(helper_indices, proof)}
}
keys = sorted(objects.keys(), reverse=True)
pos = 0
while pos < len(keys):
k = keys[pos]
if k in objects and k ^ 1 in objects and k // 2 not in objects:
objects[GeneralizedIndex(k // 2)] = hash(
objects[GeneralizedIndex((k | 1) ^ 1)] +
objects[GeneralizedIndex(k | 1)]
)
keys.append(GeneralizedIndex(k // 2))
pos += 1
return objects[GeneralizedIndex(1)]
def verify_merkle_multiproof(leaves: Sequence[Bytes32],
proof: Sequence[Bytes32],
indices: Sequence[GeneralizedIndex],
root: Root) -> bool:
return calculate_multi_merkle_root(leaves, proof, indices) == root
Note that the single-item proof is a special case of a multi-item proof; a valid single-item proof verifies correctly when put into the multi-item verification function (making the natural trivial changes to input arguments, index -> [index]
and leaf -> [leaf]
). Note also that calculate_merkle_root
and calculate_multi_merkle_root
can be used independently to compute the new Merkle root of a proof with leaves updated.