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sparseMerkleTree.ts
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sparseMerkleTree.ts
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/// @dev The Fuel testing Merkle trees.
/// A set of useful helper methods for testing and deploying Merkle trees.
import { hash } from '@fuel-ts/merkle-shared';
import { compactProof } from './proofs';
import { isLeaf, hashLeaf, hashNode, parseLeaf, parseNode } from './treeHasher';
import type SparseCompactMerkleProof from './types/sparseCompactMerkleProof';
import SparseMerkleProof from './types/sparseMerkleProof';
import type { MapStore } from './utils';
import { ZERO, MAX_HEIGHT, getBitAtFromMSB, reverseSideNodes, countCommonPrefix } from './utils';
class SparseMerkleTree {
ms: MapStore;
root: string;
constructor() {
const ms: MapStore = {};
this.ms = ms;
this.root = ZERO;
this.ms[this.root] = ZERO;
}
get(key: string): string {
return this.ms[key];
}
set(key: string, value: string): void {
this.ms[key] = value;
}
setRoot(root: string): void {
this.root = root;
}
sideNodesForRoot(key: string, root: string): [string[], string, string, string] {
const sideNodes: string[] = [];
// If the root is a placeholder, there are no sidenodes to return.
// The data is nil, and the sibling is nil
if (root === ZERO) {
return [sideNodes, ZERO, '', ''];
}
let currentData = this.get(root);
// If the root is a leaf, there are also no sidenodes to return.
// The data is the leaf data, and the sibling is nil
if (isLeaf(currentData)) {
return [sideNodes, root, currentData, ''];
}
let leftNode;
let rightNode;
let nodeHash = '';
let sideNode = '';
for (let i = 0; i < MAX_HEIGHT; i += 1) {
[leftNode, rightNode] = parseNode(currentData);
if (getBitAtFromMSB(key, i) === 1) {
sideNode = leftNode;
nodeHash = rightNode;
} else {
sideNode = rightNode;
nodeHash = leftNode;
}
sideNodes.push(sideNode);
// If the node is a placeholder, we've reached the end.
if (nodeHash === ZERO) {
currentData = '';
break;
}
currentData = this.get(nodeHash);
// If the node is a leaf, we've reached the end.
if (isLeaf(currentData)) {
break;
}
}
const siblingData = this.get(sideNode);
return [reverseSideNodes(sideNodes), nodeHash, currentData, siblingData];
}
deleteWithSideNodes(
key: string,
sideNodes: string[],
oldLeafHash: string,
oldLeafData: string
): string {
// If value already zero, deletion changes nothing. Just return current root
if (oldLeafHash === ZERO) {
return this.root;
}
// If key is already empty (different key found in its place), deletion changed nothing. Just return current root
const [actualPath] = parseLeaf(oldLeafData);
if (actualPath !== key) {
return this.root;
}
let currentHash = '';
let currentData = '';
let sideNode = '';
let sideNodeValue = '';
let nonPlaceholderReached = false;
for (let i = 0; i < sideNodes.length; i += 1) {
if (sideNodes[i] === '') {
// eslint-disable-next-line no-continue
continue;
}
sideNode = sideNodes[i];
if (currentData === '') {
sideNodeValue = this.get(sideNode);
if (isLeaf(sideNodeValue)) {
// This is the leaf sibling that needs to be percolated up the tree.
currentHash = sideNode;
currentData = sideNode;
// eslint-disable-next-line no-continue
continue;
} else {
// This is the node sibling that needs to be left in its place.
currentData = ZERO;
nonPlaceholderReached = true;
}
}
if (!nonPlaceholderReached && sideNode === ZERO) {
// We found another placeholder sibling node, keep going up the
// tree until we find the first sibling that is not a placeholder.
// eslint-disable-next-line no-continue
continue;
} else if (!nonPlaceholderReached) {
// We found the first sibling node that is not a placeholder, it is
// time to insert our leaf sibling node here.
nonPlaceholderReached = true;
}
if (getBitAtFromMSB(key, sideNodes.length - 1 - i) === 1) {
[currentHash, currentData] = hashNode(sideNode, currentData);
} else {
[currentHash, currentData] = hashNode(currentData, sideNode);
}
this.set(currentHash, currentData);
currentData = currentHash;
}
// The tree is empty; return placeholder value as root.
// How can currentHash be '' / nil if it's a hash ?
if (currentHash === '') {
currentHash = ZERO;
}
return currentHash;
}
updateWithSideNodes(
key: string,
value: string,
sideNodes: string[],
oldLeafHash: string,
oldLeafData: string
): string {
let currentHash;
let currentData;
this.set(hash(value), value);
[currentHash, currentData] = hashLeaf(key, value);
this.set(currentHash, currentData);
currentData = currentHash;
// If the leaf node that sibling nodes lead to has a different actual path
// than the leaf node being updated, we need to create an intermediate node
// with this leaf node and the new leaf node as children.
//
// First, get the number of bits that the paths of the two leaf nodes share
// in common as a prefix.
let commonPrefixCount;
if (oldLeafHash === ZERO) {
commonPrefixCount = MAX_HEIGHT;
} else {
const [actualPath] = parseLeaf(oldLeafData);
commonPrefixCount = countCommonPrefix(key, actualPath);
}
if (commonPrefixCount !== MAX_HEIGHT) {
if (getBitAtFromMSB(key, commonPrefixCount) === 1) {
[currentHash, currentData] = hashNode(oldLeafHash, currentData);
} else {
[currentHash, currentData] = hashNode(currentData, oldLeafHash);
}
this.set(currentHash, currentData);
currentData = currentHash;
}
for (let i = 0; i < MAX_HEIGHT; i += 1) {
let sideNode;
const offsetOfSideNodes = MAX_HEIGHT - sideNodes.length;
// If there are no sidenodes at this height, but the number of
// bits that the paths of the two leaf nodes share in common is
// greater than this height, then we need to build up the tree
// to this height with placeholder values at siblings.
if (i - offsetOfSideNodes < 0 || sideNodes[i - offsetOfSideNodes] === '') {
if (commonPrefixCount !== MAX_HEIGHT && commonPrefixCount > MAX_HEIGHT - 1 - i) {
sideNode = ZERO;
} else {
// eslint-disable-next-line no-continue
continue;
}
} else {
sideNode = sideNodes[i - offsetOfSideNodes];
}
if (getBitAtFromMSB(key, MAX_HEIGHT - 1 - i) === 1) {
[currentHash, currentData] = hashNode(sideNode, currentData);
} else {
[currentHash, currentData] = hashNode(currentData, sideNode);
}
this.set(currentHash, currentData);
currentData = currentHash;
}
return currentHash;
}
update(key: string, value: string): void {
const [sideNodes, oldLeafHash, oldLeafData] = this.sideNodesForRoot(key, this.root);
let newRoot;
if (value === ZERO) {
newRoot = this.deleteWithSideNodes(key, sideNodes, oldLeafHash, oldLeafData);
} else {
newRoot = this.updateWithSideNodes(key, value, sideNodes, oldLeafHash, oldLeafData);
}
this.setRoot(newRoot);
}
delete(key: string): void {
this.update(key, ZERO);
}
prove(key: string): SparseMerkleProof {
const [sideNodes, leafHash, leafData, siblingData] = this.sideNodesForRoot(key, this.root);
const nonEmptySideNodes: string[] = [];
for (let i = 0; i < sideNodes.length; i += 1) {
if (sideNodes[i] !== '') {
nonEmptySideNodes.push(sideNodes[i]);
}
}
// Deal with non-membership proofs. If the leaf hash is the placeholder
// value, we do not need to add anything else to the proof.
let nonMembershipLeafData = '';
if (leafHash !== ZERO) {
const [actualPath] = parseLeaf(leafData);
if (actualPath !== key) {
// This is a non-membership proof that involves showing a different leaf.
// Add the leaf data to the proof.
nonMembershipLeafData = leafData;
}
}
const proof = new SparseMerkleProof(nonEmptySideNodes, nonMembershipLeafData, siblingData);
return proof;
}
proveCompacted(key: string): SparseCompactMerkleProof {
const proof = this.prove(key);
const compactedProof = compactProof(proof);
return compactedProof;
}
}
export default SparseMerkleTree;