nim-eth/eth/ssz/merkle_tree.nim

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{.push raises: [Defect].}
import
math, sequtils, ssz_serialization, options, algorithm,
nimcrypto/hash,
../common/eth_types, ./types, ./merkleization
const maxTreeDepth: uint64 = 32
const empty: seq[Digest] = @[]
type
MerkleNodeType = enum
LeafType,
NodeType,
ZeroType
MerkleNode = ref object
case kind: MerkleNodeType
of LeafType:
digest: Digest
of NodeType:
innerDigest: Digest
left: MerkleNode
right: MerkleNode
of ZeroType:
depth: uint64
func zeroNodes(): seq[MerkleNode] =
var nodes = newSeq[MerkleNode]()
for i in 0..maxTreeDepth:
nodes.add(MerkleNode(kind: ZeroType, depth: i))
return nodes
let zNodes = zeroNodes()
# This look like something that should be in standard lib.
func splitAt[T](s: openArray[T], idx: uint64): (seq[T], seq[T]) =
var lSeq = newSeq[T]()
var rSeq = newSeq[T]()
for i, e in s:
if (uint64(i) < idx):
lSeq.add(e)
else:
rSeq.add(e)
(lSeq, rSeq)
func splitLeaves(l: openArray[Digest], cap: uint64): (seq[Digest], seq[Digest]) =
if (uint64(len(l)) <= cap):
(l.toSeq(), empty)
else:
splitAt(l, cap)
proc getSubTrees(node: MerkleNode): Option[(MerkleNode, MerkleNode)] =
case node.kind
of LeafType:
return none[(MerkleNode, MerkleNode)]()
of NodeType:
return some((node.left, node.right))
of ZeroType:
if node.depth == 0:
return none[(MerkleNode, MerkleNode)]()
else:
return some((zNodes[node.depth - 1], zNodes[node.depth - 1]))
func hash*(node: MerkleNode): Digest =
case node.kind
of LeafType:
node.digest
of NodeType:
node.innerDigest
of ZeroType:
zeroHashes[node.depth]
func getCapacityAtDepth(depth: uint64): uint64 =
uint64 math.pow(2'f64, float64 depth)
func createTree*(leaves: openArray[Digest], depth: uint64): MerkleNode =
if len(leaves) == 0:
return MerkleNode(kind: ZeroType, depth: depth)
elif depth == 0:
return MerkleNode(kind: LeafType, digest: leaves[0])
else:
let nexLevelDepth = depth - 1
let subCap = getCapacityAtDepth(nexLevelDepth)
let (left, right) = splitLeaves(leaves, subCap)
let leftTree = createTree(left, nexLevelDepth)
let rightTree = createTree(right, nexLevelDepth)
let finalHash = mergeBranches(leftTree.hash(), rightTree.hash())
return MerkleNode(kind: NodeType, innerDigest: finalHash, left: leftTree, right: rightTree)
proc genProof*(tree: MerkleNode, idx: uint64, treeDepth: uint64): seq[Digest] =
var proof = newSeq[Digest]()
var currNode = tree
var currDepth = treeDepth
while currDepth > 0:
let ithBit = (idx shr (currDepth - 1)) and 1
# should be safe to call unsafeGet() as leaves are on lowest level, and depth is
# always larger than 0
let (left, right) = getSubTrees(currNode).unsafeGet()
if ithBit == 1:
proof.add(left.hash())
currNode = right
else:
proof.add(right.hash())
currNode = left
currDepth = currDepth - 1
proof.reverse()
proof
# TODO add method to add leaf to the exisiting tree