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46 Commits

Author SHA1 Message Date
0045ef85b1 Prepare package to self-host in Gitea npm registry 2023-09-12 02:33:39 -07:00
smart_ex
3da67b29ed update lib es2020 2022-04-04 18:44:15 +10:00
Alexey Pertsev
73b4b68c9d
Merge pull request #3 from tornadocash/typescript
Migration to Typescript, add partial tree implementation
2022-04-04 10:32:36 +02:00
smart_ex
22e923c469 update Readme 2022-03-29 18:37:37 +10:00
smart_ex
ec56e449f7 update Readme 2022-03-29 18:36:05 +10:00
smart_ex
0efd9caee8 update Readme 2022-03-29 18:33:56 +10:00
smart_ex
a29aa84450 implement indexOf with fromIndex param 2022-03-28 18:21:32 +10:00
smart_ex
7d439740b1 fix deserialize method 2022-03-28 17:44:50 +10:00
smart_ex
cc33277ba1 more test. fix nullish alloc 2022-03-25 15:12:06 +10:00
smart_ex
c1c6972a4b fix partial tree path 2022-03-25 00:41:06 +10:00
Sergei SMART
1f02fd3f45 0.7.1 2022-03-14 20:20:28 +10:00
Sergei SMART
b92ee38355 0.7.1 2022-03-14 20:14:01 +10:00
Sergei SMART
2e65f7cac0 upload lib files 2022-03-14 19:42:36 +10:00
Sergei SMART
1f34fa69fa update tsconfig 2022-03-14 19:41:45 +10:00
Sergei SMART
d72b2b91be update tsc 2022-03-14 18:34:59 +10:00
Sergei SMART
3ddaca5ff5 update tsconfig.json 2022-03-14 18:01:12 +10:00
Sergei SMART
5cf73384dd update package.json 2022-03-14 17:21:38 +10:00
Sergei SMART
2a2dd204c0 code duplication reduced 2022-03-13 15:28:37 +10:00
Sergei SMART
d11c5c168a implementing getTreeSlices types 2022-03-13 14:45:13 +10:00
smart_ex
bc533ede2d check elements length in constructor 2022-03-11 15:37:20 +10:00
smart_ex
6df03ab139 fix tree slices order 2022-03-11 11:38:51 +10:00
smart_ex
e9f123a8b2 use mimc from circomlibjs 2022-03-11 00:12:55 +10:00
Sergei SMART
ad634a6b3a implementing getTreeSlices 2022-03-10 19:41:32 +10:00
Sergei SMART
8e2b0a2dbc implementing tree slicing 2022-03-10 18:29:31 +10:00
Sergei SMART
6439775e37 final buildHashes algorithm 2022-03-10 18:00:26 +10:00
Sergei SMART
623cef3da2 wip 2022-03-09 20:35:34 +10:00
Sergei SMART
1015f72954 test with timing, fix constructor 2022-03-09 20:00:00 +10:00
Sergei SMART
2dc7b4b5b3 wip 2022-03-09 16:25:49 +10:00
Sergei SMART
ed4e372c93 clean up 2022-03-02 15:13:27 +10:00
Sergei SMART
5ebbf81959 add shiftEdge method 2022-03-02 14:33:04 +10:00
Sergei SMART
e0817b8389 add proof leaf method 2022-03-02 13:22:54 +10:00
Sergei SMART
12f95d97ee added serialize / deserialize / proof / toString, coverage increase 2022-03-02 12:03:16 +10:00
Smart
fba9bab7a8 fix imports 2022-03-01 19:46:29 +10:00
Sergei SMART
6173676074 100% coverage of fixed tree 2022-03-01 16:02:45 +10:00
Sergei SMART
21e673a659 implementing features and cover it by tests 2022-03-01 15:33:46 +10:00
Sergei SMART
9536889468 add test coverage. more tests 2022-03-01 11:16:52 +10:00
Smart
95ac6e0f55 wip. 2022-02-28 17:00:28 +10:00
Smart
f2697487c8 add simpleHash function & tests, add coverage 2022-02-26 22:50:08 +10:00
Smart
744438ceba add simpleHash function & tests, add coverage 2022-02-26 22:50:08 +10:00
Sergei SMART
e6a1ce979c init partial tree 2022-02-26 19:13:09 +10:00
Sergei SMART
5f036748a9 remove deps, add simple hashFunction for example and tests. 2022-02-24 13:21:14 +10:00
Sergei SMART
107217f74d add getters 2022-02-22 20:41:26 +10:00
Sergei SMART
3d6356b596 add getTreeEdge method 2022-02-22 19:42:49 +10:00
Sergei SMART
4501cae4d6 initial typescript edit 2022-02-22 18:45:31 +10:00
Danil Kovtonyuk
e3c54ea818
fix: bulk insert empty elements 2022-02-17 01:05:45 +10:00
Roman Semenov
d5816e7cf4
Merge pull request #1 from tornadocash/bulk-insert
Bulk insert
2021-09-15 20:09:08 +03:00
29 changed files with 4600 additions and 5535 deletions

@ -1,26 +1,57 @@
{
"env": {
"node": true,
"browser": true,
"es6": true,
"mocha": true
},
"extends": "eslint:recommended",
"globals": {
"Atomics": "readonly",
"SharedArrayBuffer": "readonly"
},
"parser": "babel-eslint",
"parserOptions": {
"ecmaVersion": 2018
},
"parser": "@typescript-eslint/parser",
"plugins": [
"@typescript-eslint"
],
"extends": [
"eslint:recommended",
"plugin:@typescript-eslint/recommended",
"prettier"
],
"ignorePatterns": [
"test/*.spec.ts",
"lib"
],
"rules": {
"indent": ["error", 2],
"linebreak-style": ["error", "unix"],
"quotes": ["error", "single"],
"semi": ["error", "never"],
"object-curly-spacing": ["error", "always"],
"comma-dangle": ["error", "always-multiline"],
"@typescript-eslint/no-unused-vars": "error",
"@typescript-eslint/consistent-type-definitions": [
"error",
"type"
],
"indent": [
"error",
2
],
"linebreak-style": [
"error",
"unix"
],
"quotes": [
"error",
"single"
],
"semi": [
"error",
"never"
],
"object-curly-spacing": [
"error",
"always"
],
"comma-dangle": [
"error",
"always-multiline"
],
"require-await": "error"
},
"env": {
"browser": true,
"es2021": true,
"node": true,
"mocha": true
}
}

5
.gitignore vendored

@ -1 +1,6 @@
node_modules
build
yarn-error.log
.idea
.nyc_output
.run

1
.npmrc Normal file

@ -0,0 +1 @@
@tornado:registry=https://git.tornado.ws/api/packages/tornado-packages/npm/

1
.nvmrc Normal file

@ -0,0 +1 @@
14.23

@ -5,27 +5,68 @@ This is a fixed depth merkle tree implementation with sequential inserts
## Usage
```javascript
const MerkleTree = require('MerkleTree')
import { MerkleTree, PartialMerkleTree } from 'fixed-merkle-tree'
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
tree.insert(6)
tree.update(3, 42)
const path = tree.path(tree.indexOf(2))
const path = tree.proof(3)
console.log(path)
// output:
// output
{
pathIndex: [0, 1, 0, 0, 0, 0, 0, 0, 0, 0],
pathElements: [
'42',
'19814528709687996974327303300007262407299502847885145507292406548098437687919',
'11545490348087423460235196042660837039811055736960842865648632633825765931887',
'14506027710748750947258687001455876266559341618222612722926156490737302846427',
'4766583705360062980279572762279781527342845808161105063909171241304075622345',
'16640205414190175414380077665118269450294358858897019640557533278896634808665',
'13024477302430254842915163302704885770955784224100349847438808884122720088412',
'11345696205391376769769683860277269518617256738724086786512014734609753488820',
'17235543131546745471991808272245772046758360534180976603221801364506032471936',
'155962837046691114236524362966874066300454611955781275944230309195800494087'
]
42,
'4027992409016347597424110157229339967488',
'2008015086710634950773855228781840564224',
'938972308169430750202858820582946897920',
'3743880566844110745576746962917825445888',
'2074434463882483178614385966084599578624',
'2808856778596740691845240322870189490176',
'4986731814143931240516913804278285467648',
'1918547053077726613961101558405545328640',
'5444383861051812288142814494928935059456'
],
pathIndices: [
0, 1, 0, 0, 0,
0, 0, 0, 0, 0
],
pathPositions: [
3, 0, 1, 0, 0,
0, 0, 0, 0, 0
],
pathRoot: '3917789723822252567979048877718291611648'
}
const treeEdge = tree.getTreeEdge(2)
const partialTree = new PartialMerkleTree(10, treeEdge, tree.elements.slice(treeEdge.edgeIndex))
console.log(partialTree.elements)
// [<2 empty items >, 3, 42, 5, 6]
const proofPath = partialTree.proof(3)
console.log(proofPath)
// output
{
pathElements: [
42,
'4027992409016347597424110157229339967488',
'2008015086710634950773855228781840564224',
'938972308169430750202858820582946897920',
'3743880566844110745576746962917825445888',
'2074434463882483178614385966084599578624',
'2808856778596740691845240322870189490176',
'4986731814143931240516913804278285467648',
'1918547053077726613961101558405545328640',
'5444383861051812288142814494928935059456'
],
pathIndices: [
0, 1, 0, 0, 0,
0, 0, 0, 0, 0
],
pathPositions: [
3, 0, 1, 0, 0,
0, 0, 0, 0, 0
],
pathRoot: '3917789723822252567979048877718291611648'
}
```

43
lib/BaseTree.d.ts vendored Normal file

@ -0,0 +1,43 @@
import { Element, HashFunction, ProofPath } from './';
export declare class BaseTree {
levels: number;
protected _hashFn: HashFunction<Element>;
protected zeroElement: Element;
protected _zeros: Element[];
protected _layers: Array<Element[]>;
get capacity(): number;
get layers(): Array<Element[]>;
get zeros(): Element[];
get elements(): Element[];
get root(): Element;
/**
* Find an element in the tree
* @param elements elements of tree
* @param element An element to find
* @param comparator A function that checks leaf value equality
* @param fromIndex The index to start the search at. If the index is greater than or equal to the array's length, -1 is returned
* @returns {number} Index if element is found, otherwise -1
*/
static indexOf(elements: Element[], element: Element, fromIndex?: number, comparator?: <T>(arg0: T, arg1: T) => boolean): number;
/**
* Insert new element into the tree
* @param element Element to insert
*/
insert(element: Element): void;
bulkInsert(elements: Element[]): void;
/**
* Change an element in the tree
* @param {number} index Index of element to change
* @param element Updated element value
*/
update(index: number, element: Element): void;
/**
* Get merkle path to a leaf
* @param {number} index Leaf index to generate path for
* @returns {{pathElements: Object[], pathIndex: number[]}} An object containing adjacent elements and left-right index
*/
path(index: number): ProofPath;
protected _buildZeros(): void;
protected _processNodes(nodes: Element[], layerIndex: number): any[];
protected _processUpdate(index: number): void;
}

154
lib/BaseTree.js Normal file

@ -0,0 +1,154 @@
"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.BaseTree = void 0;
class BaseTree {
get capacity() {
return 2 ** this.levels;
}
get layers() {
return this._layers.slice();
}
get zeros() {
return this._zeros.slice();
}
get elements() {
return this._layers[0].slice();
}
get root() {
var _a;
return (_a = this._layers[this.levels][0]) !== null && _a !== void 0 ? _a : this._zeros[this.levels];
}
/**
* Find an element in the tree
* @param elements elements of tree
* @param element An element to find
* @param comparator A function that checks leaf value equality
* @param fromIndex The index to start the search at. If the index is greater than or equal to the array's length, -1 is returned
* @returns {number} Index if element is found, otherwise -1
*/
static indexOf(elements, element, fromIndex, comparator) {
if (comparator) {
return elements.findIndex((el) => comparator(element, el));
}
else {
return elements.indexOf(element, fromIndex);
}
}
/**
* Insert new element into the tree
* @param element Element to insert
*/
insert(element) {
if (this._layers[0].length >= this.capacity) {
throw new Error('Tree is full');
}
this.update(this._layers[0].length, element);
}
/*
* Insert multiple elements into the tree.
* @param {Array} elements Elements to insert
*/
bulkInsert(elements) {
if (!elements.length) {
return;
}
if (this._layers[0].length + elements.length > this.capacity) {
throw new Error('Tree is full');
}
// First we insert all elements except the last one
// updating only full subtree hashes (all layers where inserted element has odd index)
// the last element will update the full path to the root making the tree consistent again
for (let i = 0; i < elements.length - 1; i++) {
this._layers[0].push(elements[i]);
let level = 0;
let index = this._layers[0].length - 1;
while (index % 2 === 1) {
level++;
index >>= 1;
const left = this._layers[level - 1][index * 2];
const right = this._layers[level - 1][index * 2 + 1];
this._layers[level][index] = this._hashFn(left, right);
}
}
this.insert(elements[elements.length - 1]);
}
/**
* Change an element in the tree
* @param {number} index Index of element to change
* @param element Updated element value
*/
update(index, element) {
if (isNaN(Number(index)) || index < 0 || index > this._layers[0].length || index >= this.capacity) {
throw new Error('Insert index out of bounds: ' + index);
}
this._layers[0][index] = element;
this._processUpdate(index);
}
/**
* Get merkle path to a leaf
* @param {number} index Leaf index to generate path for
* @returns {{pathElements: Object[], pathIndex: number[]}} An object containing adjacent elements and left-right index
*/
path(index) {
if (isNaN(Number(index)) || index < 0 || index >= this._layers[0].length) {
throw new Error('Index out of bounds: ' + index);
}
let elIndex = +index;
const pathElements = [];
const pathIndices = [];
const pathPositions = [];
for (let level = 0; level < this.levels; level++) {
pathIndices[level] = elIndex % 2;
const leafIndex = elIndex ^ 1;
if (leafIndex < this._layers[level].length) {
pathElements[level] = this._layers[level][leafIndex];
pathPositions[level] = leafIndex;
}
else {
pathElements[level] = this._zeros[level];
pathPositions[level] = 0;
}
elIndex >>= 1;
}
return {
pathElements,
pathIndices,
pathPositions,
pathRoot: this.root,
};
}
_buildZeros() {
this._zeros = [this.zeroElement];
for (let i = 1; i <= this.levels; i++) {
this._zeros[i] = this._hashFn(this._zeros[i - 1], this._zeros[i - 1]);
}
}
_processNodes(nodes, layerIndex) {
const length = nodes.length;
let currentLength = Math.ceil(length / 2);
const currentLayer = new Array(currentLength);
currentLength--;
const starFrom = length - ((length % 2) ^ 1);
let j = 0;
for (let i = starFrom; i >= 0; i -= 2) {
if (nodes[i - 1] === undefined)
break;
const left = nodes[i - 1];
const right = (i === starFrom && length % 2 === 1) ? this._zeros[layerIndex - 1] : nodes[i];
currentLayer[currentLength - j] = this._hashFn(left, right);
j++;
}
return currentLayer;
}
_processUpdate(index) {
for (let level = 1; level <= this.levels; level++) {
index >>= 1;
const left = this._layers[level - 1][index * 2];
const right = index * 2 + 1 < this._layers[level - 1].length
? this._layers[level - 1][index * 2 + 1]
: this._zeros[level - 1];
this._layers[level][index] = this._hashFn(left, right);
}
}
}
exports.BaseTree = BaseTree;

32
lib/FixedMerkleTree.d.ts vendored Normal file

@ -0,0 +1,32 @@
import { Element, HashFunction, MerkleTreeOptions, ProofPath, SerializedTreeState, TreeEdge, TreeSlice } from './';
import { BaseTree } from './BaseTree';
export default class MerkleTree extends BaseTree {
constructor(levels: number, elements?: Element[], { hashFunction, zeroElement, }?: MerkleTreeOptions);
private _buildHashes;
/**
* Insert multiple elements into the tree.
* @param {Array} elements Elements to insert
*/
bulkInsert(elements: Element[]): void;
indexOf(element: Element, comparator?: <T>(arg0: T, arg1: T) => boolean): number;
proof(element: Element): ProofPath;
getTreeEdge(edgeIndex: number): TreeEdge;
/**
* 🪓
* @param count
*/
getTreeSlices(count?: number): TreeSlice[];
/**
* Serialize entire tree state including intermediate layers into a plain object
* Deserializing it back will not require to recompute any hashes
* Elements are not converted to a plain type, this is responsibility of the caller
*/
serialize(): SerializedTreeState;
/**
* Deserialize data into a MerkleTree instance
* Make sure to provide the same hashFunction as was used in the source tree,
* otherwise the tree state will be invalid
*/
static deserialize(data: SerializedTreeState, hashFunction?: HashFunction<Element>): MerkleTree;
toString(): string;
}

114
lib/FixedMerkleTree.js Normal file

@ -0,0 +1,114 @@
"use strict";
var __importDefault = (this && this.__importDefault) || function (mod) {
return (mod && mod.__esModule) ? mod : { "default": mod };
};
Object.defineProperty(exports, "__esModule", { value: true });
const simpleHash_1 = __importDefault(require("./simpleHash"));
const BaseTree_1 = require("./BaseTree");
class MerkleTree extends BaseTree_1.BaseTree {
constructor(levels, elements = [], { hashFunction = simpleHash_1.default, zeroElement = 0, } = {}) {
super();
this.levels = levels;
if (elements.length > this.capacity) {
throw new Error('Tree is full');
}
this._hashFn = hashFunction;
this.zeroElement = zeroElement;
this._layers = [];
const leaves = elements.slice();
this._layers = [leaves];
this._buildZeros();
this._buildHashes();
}
_buildHashes() {
for (let layerIndex = 1; layerIndex <= this.levels; layerIndex++) {
const nodes = this._layers[layerIndex - 1];
this._layers[layerIndex] = this._processNodes(nodes, layerIndex);
}
}
/**
* Insert multiple elements into the tree.
* @param {Array} elements Elements to insert
*/
bulkInsert(elements) {
if (!elements.length) {
return;
}
if (this._layers[0].length + elements.length > this.capacity) {
throw new Error('Tree is full');
}
// First we insert all elements except the last one
// updating only full subtree hashes (all layers where inserted element has odd index)
// the last element will update the full path to the root making the tree consistent again
for (let i = 0; i < elements.length - 1; i++) {
this._layers[0].push(elements[i]);
let level = 0;
let index = this._layers[0].length - 1;
while (index % 2 === 1) {
level++;
index >>= 1;
this._layers[level][index] = this._hashFn(this._layers[level - 1][index * 2], this._layers[level - 1][index * 2 + 1]);
}
}
this.insert(elements[elements.length - 1]);
}
indexOf(element, comparator) {
return BaseTree_1.BaseTree.indexOf(this._layers[0], element, 0, comparator);
}
proof(element) {
const index = this.indexOf(element);
return this.path(index);
}
getTreeEdge(edgeIndex) {
const edgeElement = this._layers[0][edgeIndex];
if (edgeElement === undefined) {
throw new Error('Element not found');
}
const edgePath = this.path(edgeIndex);
return { edgePath, edgeElement, edgeIndex, edgeElementsCount: this._layers[0].length };
}
/**
* 🪓
* @param count
*/
getTreeSlices(count = 4) {
const length = this._layers[0].length;
let size = Math.ceil(length / count);
if (size % 2)
size++;
const slices = [];
for (let i = 0; i < length; i += size) {
const edgeLeft = i;
const edgeRight = i + size;
slices.push({ edge: this.getTreeEdge(edgeLeft), elements: this.elements.slice(edgeLeft, edgeRight) });
}
return slices;
}
/**
* Serialize entire tree state including intermediate layers into a plain object
* Deserializing it back will not require to recompute any hashes
* Elements are not converted to a plain type, this is responsibility of the caller
*/
serialize() {
return {
levels: this.levels,
_zeros: this._zeros,
_layers: this._layers,
};
}
/**
* Deserialize data into a MerkleTree instance
* Make sure to provide the same hashFunction as was used in the source tree,
* otherwise the tree state will be invalid
*/
static deserialize(data, hashFunction) {
const instance = Object.assign(Object.create(this.prototype), data);
instance._hashFn = hashFunction || simpleHash_1.default;
instance.zeroElement = instance._zeros[0];
return instance;
}
toString() {
return JSON.stringify(this.serialize());
}
}
exports.default = MerkleTree;

35
lib/PartialMerkleTree.d.ts vendored Normal file

@ -0,0 +1,35 @@
import { Element, HashFunction, MerkleTreeOptions, ProofPath, SerializedPartialTreeState, TreeEdge } from './';
import { BaseTree } from './BaseTree';
export declare class PartialMerkleTree extends BaseTree {
private _leaves;
private _leavesAfterEdge;
private _edgeLeaf;
private _initialRoot;
private _edgeLeafProof;
private _proofMap;
constructor(levels: number, { edgePath, edgeElement, edgeIndex, edgeElementsCount, }: TreeEdge, leaves: Element[], { hashFunction, zeroElement }?: MerkleTreeOptions);
get edgeIndex(): number;
get edgeElement(): Element;
get edgeLeafProof(): ProofPath;
private _createProofMap;
private _buildTree;
private _buildHashes;
/**
* Change an element in the tree
* @param {number} index Index of element to change
* @param element Updated element value
*/
update(index: number, element: Element): void;
path(index: number): ProofPath;
indexOf(element: Element, comparator?: <T>(arg0: T, arg1: T) => boolean): number;
proof(element: Element): ProofPath;
/**
* Shifts edge of tree to left
* @param edge new TreeEdge below current edge
* @param elements leaves between old and new edge
*/
shiftEdge(edge: TreeEdge, elements: Element[]): void;
serialize(): SerializedPartialTreeState;
static deserialize(data: SerializedPartialTreeState, hashFunction?: HashFunction<Element>): PartialMerkleTree;
toString(): string;
}

159
lib/PartialMerkleTree.js Normal file

@ -0,0 +1,159 @@
"use strict";
var __importDefault = (this && this.__importDefault) || function (mod) {
return (mod && mod.__esModule) ? mod : { "default": mod };
};
Object.defineProperty(exports, "__esModule", { value: true });
exports.PartialMerkleTree = void 0;
const simpleHash_1 = __importDefault(require("./simpleHash"));
const BaseTree_1 = require("./BaseTree");
class PartialMerkleTree extends BaseTree_1.BaseTree {
constructor(levels, { edgePath, edgeElement, edgeIndex, edgeElementsCount, }, leaves, { hashFunction, zeroElement } = {}) {
super();
if (edgeIndex + leaves.length !== edgeElementsCount)
throw new Error('Invalid number of elements');
this._edgeLeafProof = edgePath;
this._initialRoot = edgePath.pathRoot;
this.zeroElement = zeroElement !== null && zeroElement !== void 0 ? zeroElement : 0;
this._edgeLeaf = { data: edgeElement, index: edgeIndex };
this._leavesAfterEdge = leaves;
this.levels = levels;
this._hashFn = hashFunction || simpleHash_1.default;
this._createProofMap();
this._buildTree();
}
get edgeIndex() {
return this._edgeLeaf.index;
}
get edgeElement() {
return this._edgeLeaf.data;
}
get edgeLeafProof() {
return this._edgeLeafProof;
}
_createProofMap() {
this._proofMap = this.edgeLeafProof.pathPositions.reduce((p, c, i) => {
p.set(i, [c, this.edgeLeafProof.pathElements[i]]);
return p;
}, new Map());
this._proofMap.set(this.levels, [0, this.edgeLeafProof.pathRoot]);
}
_buildTree() {
const edgeLeafIndex = this._edgeLeaf.index;
this._leaves = Array(edgeLeafIndex).concat(this._leavesAfterEdge);
if (this._proofMap.has(0)) {
const [proofPos, proofEl] = this._proofMap.get(0);
this._leaves[proofPos] = proofEl;
}
this._layers = [this._leaves];
this._buildZeros();
this._buildHashes();
}
_buildHashes() {
for (let layerIndex = 1; layerIndex <= this.levels; layerIndex++) {
const nodes = this._layers[layerIndex - 1];
const currentLayer = this._processNodes(nodes, layerIndex);
if (this._proofMap.has(layerIndex)) {
const [proofPos, proofEl] = this._proofMap.get(layerIndex);
if (!currentLayer[proofPos])
currentLayer[proofPos] = proofEl;
}
this._layers[layerIndex] = currentLayer;
}
}
/**
* Change an element in the tree
* @param {number} index Index of element to change
* @param element Updated element value
*/
update(index, element) {
if (isNaN(Number(index)) || index < 0 || index > this._layers[0].length || index >= this.capacity) {
throw new Error('Insert index out of bounds: ' + index);
}
if (index < this._edgeLeaf.index) {
throw new Error(`Index ${index} is below the edge: ${this._edgeLeaf.index}`);
}
this._layers[0][index] = element;
this._processUpdate(index);
}
path(index) {
var _a;
if (isNaN(Number(index)) || index < 0 || index >= this._layers[0].length) {
throw new Error('Index out of bounds: ' + index);
}
if (index < this._edgeLeaf.index) {
throw new Error(`Index ${index} is below the edge: ${this._edgeLeaf.index}`);
}
let elIndex = Number(index);
const pathElements = [];
const pathIndices = [];
const pathPositions = [];
for (let level = 0; level < this.levels; level++) {
pathIndices[level] = elIndex % 2;
const leafIndex = elIndex ^ 1;
if (leafIndex < this._layers[level].length) {
pathElements[level] = this._layers[level][leafIndex];
pathPositions[level] = leafIndex;
}
else {
pathElements[level] = this._zeros[level];
pathPositions[level] = 0;
}
const [proofPos, proofEl] = this._proofMap.get(level);
pathElements[level] = (_a = pathElements[level]) !== null && _a !== void 0 ? _a : (proofPos === leafIndex ? proofEl : this._zeros[level]);
elIndex >>= 1;
}
return {
pathElements,
pathIndices,
pathPositions,
pathRoot: this.root,
};
}
indexOf(element, comparator) {
return BaseTree_1.BaseTree.indexOf(this._layers[0], element, this.edgeIndex, comparator);
}
proof(element) {
const index = this.indexOf(element);
return this.path(index);
}
/**
* Shifts edge of tree to left
* @param edge new TreeEdge below current edge
* @param elements leaves between old and new edge
*/
shiftEdge(edge, elements) {
if (this._edgeLeaf.index <= edge.edgeIndex) {
throw new Error(`New edgeIndex should be smaller then ${this._edgeLeaf.index}`);
}
if (elements.length !== (this._edgeLeaf.index - edge.edgeIndex)) {
throw new Error(`Elements length should be ${this._edgeLeaf.index - edge.edgeIndex}`);
}
this._edgeLeafProof = edge.edgePath;
this._edgeLeaf = { index: edge.edgeIndex, data: edge.edgeElement };
this._leavesAfterEdge = [...elements, ...this._leavesAfterEdge];
this._createProofMap();
this._buildTree();
}
serialize() {
return {
_edgeLeafProof: this._edgeLeafProof,
_edgeLeaf: this._edgeLeaf,
_layers: this._layers,
_zeros: this._zeros,
levels: this.levels,
};
}
static deserialize(data, hashFunction) {
const instance = Object.assign(Object.create(this.prototype), data);
instance._hashFn = hashFunction || simpleHash_1.default;
instance._initialRoot = data._edgeLeafProof.pathRoot;
instance.zeroElement = instance._zeros[0];
instance._leavesAfterEdge = instance._layers[0].slice(data._edgeLeaf.index);
instance._createProofMap();
return instance;
}
toString() {
return JSON.stringify(this.serialize());
}
}
exports.PartialMerkleTree = PartialMerkleTree;

45
lib/index.d.ts vendored Normal file

@ -0,0 +1,45 @@
import { default as MerkleTree } from './FixedMerkleTree';
export { PartialMerkleTree } from './PartialMerkleTree';
export { simpleHash } from './simpleHash';
export { MerkleTree };
export default MerkleTree;
export type HashFunction<T> = {
(left: T, right: T): string;
};
export type MerkleTreeOptions = {
hashFunction?: HashFunction<Element>;
zeroElement?: Element;
};
export type Element = string | number;
export type SerializedTreeState = {
levels: number;
_zeros: Array<Element>;
_layers: Array<Element[]>;
};
export type SerializedPartialTreeState = {
levels: number;
_layers: Element[][];
_zeros: Array<Element>;
_edgeLeafProof: ProofPath;
_edgeLeaf: LeafWithIndex;
};
export type ProofPath = {
pathElements: Element[];
pathIndices: number[];
pathPositions: number[];
pathRoot: Element;
};
export type TreeEdge = {
edgeElement: Element;
edgePath: ProofPath;
edgeIndex: number;
edgeElementsCount: number;
};
export type TreeSlice = {
edge: TreeEdge;
elements: Element[];
};
export type LeafWithIndex = {
index: number;
data: Element;
};

13
lib/index.js Normal file

@ -0,0 +1,13 @@
"use strict";
var __importDefault = (this && this.__importDefault) || function (mod) {
return (mod && mod.__esModule) ? mod : { "default": mod };
};
Object.defineProperty(exports, "__esModule", { value: true });
exports.MerkleTree = exports.simpleHash = exports.PartialMerkleTree = void 0;
const FixedMerkleTree_1 = __importDefault(require("./FixedMerkleTree"));
Object.defineProperty(exports, "MerkleTree", { enumerable: true, get: function () { return FixedMerkleTree_1.default; } });
var PartialMerkleTree_1 = require("./PartialMerkleTree");
Object.defineProperty(exports, "PartialMerkleTree", { enumerable: true, get: function () { return PartialMerkleTree_1.PartialMerkleTree; } });
var simpleHash_1 = require("./simpleHash");
Object.defineProperty(exports, "simpleHash", { enumerable: true, get: function () { return simpleHash_1.simpleHash; } });
exports.default = FixedMerkleTree_1.default;

10
lib/simpleHash.d.ts vendored Normal file

@ -0,0 +1,10 @@
import { Element } from './';
/***
* This is insecure hash function, just for example only
* @param data
* @param seed
* @param hashLength
*/
export declare function simpleHash<T>(data: T[], seed?: number, hashLength?: number): string;
declare const _default: (left: Element, right: Element) => string;
export default _default;

21
lib/simpleHash.js Normal file

@ -0,0 +1,21 @@
"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.simpleHash = void 0;
/***
* This is insecure hash function, just for example only
* @param data
* @param seed
* @param hashLength
*/
function simpleHash(data, seed, hashLength = 40) {
const str = data.join('');
let i, l, hval = seed !== null && seed !== void 0 ? seed : 0x811c9dcc5;
for (i = 0, l = str.length; i < l; i++) {
hval ^= str.charCodeAt(i);
hval += (hval << 1) + (hval << 4) + (hval << 6) + (hval << 8) + (hval << 24);
}
const hash = (hval >>> 0).toString(16);
return BigInt('0x' + hash.padEnd(hashLength - (hash.length - 1), '0')).toString(10);
}
exports.simpleHash = simpleHash;
exports.default = (left, right) => simpleHash([left, right]);

7589
package-lock.json generated

File diff suppressed because it is too large Load Diff

@ -1,12 +1,17 @@
{
"name": "fixed-merkle-tree",
"version": "0.6.0",
"name": "@tornado/fixed-merkle-tree",
"version": "0.7.3",
"description": "Fixed depth merkle tree implementation with sequential inserts",
"repository": "https://github.com/tornadocash/fixed-merkle-tree.git",
"main": "src/merkleTree.js",
"repository": "https://git.tornado.ws/tornado-packages/fixed-merkle-tree.git",
"main": "lib/index.js",
"types": "lib/index.d.ts",
"scripts": {
"test": "mocha",
"lint": "eslint ."
"test": "ts-mocha 'test/*.spec.ts' -s 10",
"coverage": "nyc npm run test",
"build": "tsc",
"clean": "rm -rf lib/",
"prepare": "npm run clean && npm run build",
"lint": "eslint src"
},
"keywords": [
"merkle",
@ -16,16 +21,20 @@
"author": "Roman Semenov <semenov.roma@gmail.com>",
"license": "ISC",
"files": [
"src/*"
"src/*",
"lib/*"
],
"dependencies": {
"snarkjs": "git+https://github.com/tornadocash/snarkjs.git#869181cfaf7526fe8972073d31655493a04326d5",
"circomlib": "git+https://github.com/tornadocash/circomlib.git#5beb6aee94923052faeecea40135d45b6ce6172c"
},
"devDependencies": {
"babel-eslint": "^10.1.0",
"@types/expect": "^24.3.0",
"@types/mocha": "^9.1.0",
"@typescript-eslint/eslint-plugin": "^5.12.0",
"@typescript-eslint/parser": "^5.12.0",
"chai": "^4.2.0",
"eslint": "^7.5.0",
"mocha": "^8.1.0"
"eslint": "^8.9.0",
"eslint-config-prettier": "^8.3.0",
"mocha": "^9.2.2",
"nyc": "^15.1.0",
"ts-mocha": "^9.0.2",
"typescript": "^4.6.2"
}
}

169
src/BaseTree.ts Normal file

@ -0,0 +1,169 @@
import { Element, HashFunction, ProofPath } from './'
export class BaseTree {
levels: number
protected _hashFn: HashFunction<Element>
protected zeroElement: Element
protected _zeros: Element[]
protected _layers: Array<Element[]>
get capacity() {
return 2 ** this.levels
}
get layers(): Array<Element[]> {
return this._layers.slice()
}
get zeros(): Element[] {
return this._zeros.slice()
}
get elements(): Element[] {
return this._layers[0].slice()
}
get root(): Element {
return this._layers[this.levels][0] ?? this._zeros[this.levels]
}
/**
* Find an element in the tree
* @param elements elements of tree
* @param element An element to find
* @param comparator A function that checks leaf value equality
* @param fromIndex The index to start the search at. If the index is greater than or equal to the array's length, -1 is returned
* @returns {number} Index if element is found, otherwise -1
*/
static indexOf(elements: Element[], element: Element, fromIndex?: number, comparator?: <T> (arg0: T, arg1: T) => boolean): number {
if (comparator) {
return elements.findIndex((el) => comparator<Element>(element, el))
} else {
return elements.indexOf(element, fromIndex)
}
}
/**
* Insert new element into the tree
* @param element Element to insert
*/
insert(element: Element) {
if (this._layers[0].length >= this.capacity) {
throw new Error('Tree is full')
}
this.update(this._layers[0].length, element)
}
/*
* Insert multiple elements into the tree.
* @param {Array} elements Elements to insert
*/
bulkInsert(elements: Element[]): void {
if (!elements.length) {
return
}
if (this._layers[0].length + elements.length > this.capacity) {
throw new Error('Tree is full')
}
// First we insert all elements except the last one
// updating only full subtree hashes (all layers where inserted element has odd index)
// the last element will update the full path to the root making the tree consistent again
for (let i = 0; i < elements.length - 1; i++) {
this._layers[0].push(elements[i])
let level = 0
let index = this._layers[0].length - 1
while (index % 2 === 1) {
level++
index >>= 1
const left = this._layers[level - 1][index * 2]
const right = this._layers[level - 1][index * 2 + 1]
this._layers[level][index] = this._hashFn(left, right)
}
}
this.insert(elements[elements.length - 1])
}
/**
* Change an element in the tree
* @param {number} index Index of element to change
* @param element Updated element value
*/
update(index: number, element: Element) {
if (isNaN(Number(index)) || index < 0 || index > this._layers[0].length || index >= this.capacity) {
throw new Error('Insert index out of bounds: ' + index)
}
this._layers[0][index] = element
this._processUpdate(index)
}
/**
* Get merkle path to a leaf
* @param {number} index Leaf index to generate path for
* @returns {{pathElements: Object[], pathIndex: number[]}} An object containing adjacent elements and left-right index
*/
path(index: number): ProofPath {
if (isNaN(Number(index)) || index < 0 || index >= this._layers[0].length) {
throw new Error('Index out of bounds: ' + index)
}
let elIndex = +index
const pathElements: Element[] = []
const pathIndices: number[] = []
const pathPositions: number [] = []
for (let level = 0; level < this.levels; level++) {
pathIndices[level] = elIndex % 2
const leafIndex = elIndex ^ 1
if (leafIndex < this._layers[level].length) {
pathElements[level] = this._layers[level][leafIndex]
pathPositions[level] = leafIndex
} else {
pathElements[level] = this._zeros[level]
pathPositions[level] = 0
}
elIndex >>= 1
}
return {
pathElements,
pathIndices,
pathPositions,
pathRoot: this.root,
}
}
protected _buildZeros() {
this._zeros = [this.zeroElement]
for (let i = 1; i <= this.levels; i++) {
this._zeros[i] = this._hashFn(this._zeros[i - 1], this._zeros[i - 1])
}
}
protected _processNodes(nodes: Element[], layerIndex: number) {
const length = nodes.length
let currentLength = Math.ceil(length / 2)
const currentLayer = new Array(currentLength)
currentLength--
const starFrom = length - ((length % 2) ^ 1)
let j = 0
for (let i = starFrom; i >= 0; i -= 2) {
if (nodes[i - 1] === undefined) break
const left = nodes[i - 1]
const right = (i === starFrom && length % 2 === 1) ? this._zeros[layerIndex - 1] : nodes[i]
currentLayer[currentLength - j] = this._hashFn(left, right)
j++
}
return currentLayer
}
protected _processUpdate(index: number) {
for (let level = 1; level <= this.levels; level++) {
index >>= 1
const left = this._layers[level - 1][index * 2]
const right = index * 2 + 1 < this._layers[level - 1].length
? this._layers[level - 1][index * 2 + 1]
: this._zeros[level - 1]
this._layers[level][index] = this._hashFn(left, right)
}
}
}

128
src/FixedMerkleTree.ts Normal file

@ -0,0 +1,128 @@
import { Element, HashFunction, MerkleTreeOptions, ProofPath, SerializedTreeState, TreeEdge, TreeSlice } from './'
import defaultHash from './simpleHash'
import { BaseTree } from './BaseTree'
export default class MerkleTree extends BaseTree {
constructor(levels: number, elements: Element[] = [], {
hashFunction = defaultHash,
zeroElement = 0,
}: MerkleTreeOptions = {}) {
super()
this.levels = levels
if (elements.length > this.capacity) {
throw new Error('Tree is full')
}
this._hashFn = hashFunction
this.zeroElement = zeroElement
this._layers = []
const leaves = elements.slice()
this._layers = [leaves]
this._buildZeros()
this._buildHashes()
}
private _buildHashes() {
for (let layerIndex = 1; layerIndex <= this.levels; layerIndex++) {
const nodes = this._layers[layerIndex - 1]
this._layers[layerIndex] = this._processNodes(nodes, layerIndex)
}
}
/**
* Insert multiple elements into the tree.
* @param {Array} elements Elements to insert
*/
bulkInsert(elements: Element[]): void {
if (!elements.length) {
return
}
if (this._layers[0].length + elements.length > this.capacity) {
throw new Error('Tree is full')
}
// First we insert all elements except the last one
// updating only full subtree hashes (all layers where inserted element has odd index)
// the last element will update the full path to the root making the tree consistent again
for (let i = 0; i < elements.length - 1; i++) {
this._layers[0].push(elements[i])
let level = 0
let index = this._layers[0].length - 1
while (index % 2 === 1) {
level++
index >>= 1
this._layers[level][index] = this._hashFn(
this._layers[level - 1][index * 2],
this._layers[level - 1][index * 2 + 1],
)
}
}
this.insert(elements[elements.length - 1])
}
indexOf(element: Element, comparator?: <T> (arg0: T, arg1: T) => boolean): number {
return BaseTree.indexOf(this._layers[0], element, 0, comparator)
}
proof(element: Element): ProofPath {
const index = this.indexOf(element)
return this.path(index)
}
getTreeEdge(edgeIndex: number): TreeEdge {
const edgeElement = this._layers[0][edgeIndex]
if (edgeElement === undefined) {
throw new Error('Element not found')
}
const edgePath = this.path(edgeIndex)
return { edgePath, edgeElement, edgeIndex, edgeElementsCount: this._layers[0].length }
}
/**
* 🪓
* @param count
*/
getTreeSlices(count = 4): TreeSlice[] {
const length = this._layers[0].length
let size = Math.ceil(length / count)
if (size % 2) size++
const slices: TreeSlice[] = []
for (let i = 0; i < length; i += size) {
const edgeLeft = i
const edgeRight = i + size
slices.push({ edge: this.getTreeEdge(edgeLeft), elements: this.elements.slice(edgeLeft, edgeRight) })
}
return slices
}
/**
* Serialize entire tree state including intermediate layers into a plain object
* Deserializing it back will not require to recompute any hashes
* Elements are not converted to a plain type, this is responsibility of the caller
*/
serialize(): SerializedTreeState {
return {
levels: this.levels,
_zeros: this._zeros,
_layers: this._layers,
}
}
/**
* Deserialize data into a MerkleTree instance
* Make sure to provide the same hashFunction as was used in the source tree,
* otherwise the tree state will be invalid
*/
static deserialize(data: SerializedTreeState, hashFunction?: HashFunction<Element>): MerkleTree {
const instance: MerkleTree = Object.assign(Object.create(this.prototype), data)
instance._hashFn = hashFunction || defaultHash
instance.zeroElement = instance._zeros[0]
return instance
}
toString() {
return JSON.stringify(this.serialize())
}
}

186
src/PartialMerkleTree.ts Normal file

@ -0,0 +1,186 @@
import {
Element,
HashFunction,
LeafWithIndex,
MerkleTreeOptions,
ProofPath,
SerializedPartialTreeState,
TreeEdge,
} from './'
import defaultHash from './simpleHash'
import { BaseTree } from './BaseTree'
export class PartialMerkleTree extends BaseTree {
private _leaves: Element[]
private _leavesAfterEdge: Element[]
private _edgeLeaf: LeafWithIndex
private _initialRoot: Element
private _edgeLeafProof: ProofPath
private _proofMap: Map<number, [i: number, el: Element]>
constructor(levels: number, {
edgePath,
edgeElement,
edgeIndex,
edgeElementsCount,
}: TreeEdge, leaves: Element[], { hashFunction, zeroElement }: MerkleTreeOptions = {}) {
super()
if (edgeIndex + leaves.length !== edgeElementsCount) throw new Error('Invalid number of elements')
this._edgeLeafProof = edgePath
this._initialRoot = edgePath.pathRoot
this.zeroElement = zeroElement ?? 0
this._edgeLeaf = { data: edgeElement, index: edgeIndex }
this._leavesAfterEdge = leaves
this.levels = levels
this._hashFn = hashFunction || defaultHash
this._createProofMap()
this._buildTree()
}
get edgeIndex(): number {
return this._edgeLeaf.index
}
get edgeElement(): Element {
return this._edgeLeaf.data
}
get edgeLeafProof(): ProofPath {
return this._edgeLeafProof
}
private _createProofMap() {
this._proofMap = this.edgeLeafProof.pathPositions.reduce((p, c, i) => {
p.set(i, [c, this.edgeLeafProof.pathElements[i]])
return p
}, new Map())
this._proofMap.set(this.levels, [0, this.edgeLeafProof.pathRoot])
}
private _buildTree(): void {
const edgeLeafIndex = this._edgeLeaf.index
this._leaves = Array(edgeLeafIndex).concat(this._leavesAfterEdge)
if (this._proofMap.has(0)) {
const [proofPos, proofEl] = this._proofMap.get(0)
this._leaves[proofPos] = proofEl
}
this._layers = [this._leaves]
this._buildZeros()
this._buildHashes()
}
private _buildHashes() {
for (let layerIndex = 1; layerIndex <= this.levels; layerIndex++) {
const nodes = this._layers[layerIndex - 1]
const currentLayer = this._processNodes(nodes, layerIndex)
if (this._proofMap.has(layerIndex)) {
const [proofPos, proofEl] = this._proofMap.get(layerIndex)
if (!currentLayer[proofPos]) currentLayer[proofPos] = proofEl
}
this._layers[layerIndex] = currentLayer
}
}
/**
* Change an element in the tree
* @param {number} index Index of element to change
* @param element Updated element value
*/
update(index: number, element: Element) {
if (isNaN(Number(index)) || index < 0 || index > this._layers[0].length || index >= this.capacity) {
throw new Error('Insert index out of bounds: ' + index)
}
if (index < this._edgeLeaf.index) {
throw new Error(`Index ${index} is below the edge: ${this._edgeLeaf.index}`)
}
this._layers[0][index] = element
this._processUpdate(index)
}
path(index: number): ProofPath {
if (isNaN(Number(index)) || index < 0 || index >= this._layers[0].length) {
throw new Error('Index out of bounds: ' + index)
}
if (index < this._edgeLeaf.index) {
throw new Error(`Index ${index} is below the edge: ${this._edgeLeaf.index}`)
}
let elIndex = Number(index)
const pathElements: Element[] = []
const pathIndices: number[] = []
const pathPositions: number [] = []
for (let level = 0; level < this.levels; level++) {
pathIndices[level] = elIndex % 2
const leafIndex = elIndex ^ 1
if (leafIndex < this._layers[level].length) {
pathElements[level] = this._layers[level][leafIndex]
pathPositions[level] = leafIndex
} else {
pathElements[level] = this._zeros[level]
pathPositions[level] = 0
}
const [proofPos, proofEl] = this._proofMap.get(level)
pathElements[level] = pathElements[level] ?? (proofPos === leafIndex ? proofEl : this._zeros[level])
elIndex >>= 1
}
return {
pathElements,
pathIndices,
pathPositions,
pathRoot: this.root,
}
}
indexOf(element: Element, comparator?: <T> (arg0: T, arg1: T) => boolean): number {
return BaseTree.indexOf(this._layers[0], element, this.edgeIndex, comparator)
}
proof(element: Element): ProofPath {
const index = this.indexOf(element)
return this.path(index)
}
/**
* Shifts edge of tree to left
* @param edge new TreeEdge below current edge
* @param elements leaves between old and new edge
*/
shiftEdge(edge: TreeEdge, elements: Element[]) {
if (this._edgeLeaf.index <= edge.edgeIndex) {
throw new Error(`New edgeIndex should be smaller then ${this._edgeLeaf.index}`)
}
if (elements.length !== (this._edgeLeaf.index - edge.edgeIndex)) {
throw new Error(`Elements length should be ${this._edgeLeaf.index - edge.edgeIndex}`)
}
this._edgeLeafProof = edge.edgePath
this._edgeLeaf = { index: edge.edgeIndex, data: edge.edgeElement }
this._leavesAfterEdge = [...elements, ...this._leavesAfterEdge]
this._createProofMap()
this._buildTree()
}
serialize(): SerializedPartialTreeState {
return {
_edgeLeafProof: this._edgeLeafProof,
_edgeLeaf: this._edgeLeaf,
_layers: this._layers,
_zeros: this._zeros,
levels: this.levels,
}
}
static deserialize(data: SerializedPartialTreeState, hashFunction?: HashFunction<Element>): PartialMerkleTree {
const instance: PartialMerkleTree = Object.assign(Object.create(this.prototype), data)
instance._hashFn = hashFunction || defaultHash
instance._initialRoot = data._edgeLeafProof.pathRoot
instance.zeroElement = instance._zeros[0]
instance._leavesAfterEdge = instance._layers[0].slice(data._edgeLeaf.index)
instance._createProofMap()
return instance
}
toString() {
return JSON.stringify(this.serialize())
}
}

46
src/index.ts Normal file

@ -0,0 +1,46 @@
import { default as MerkleTree } from './FixedMerkleTree'
export { PartialMerkleTree } from './PartialMerkleTree'
export { simpleHash } from './simpleHash'
export { MerkleTree }
export default MerkleTree
export type HashFunction<T> = {
(left: T, right: T): string
}
export type MerkleTreeOptions = {
hashFunction?: HashFunction<Element>
zeroElement?: Element
}
export type Element = string | number
export type SerializedTreeState = {
levels: number,
_zeros: Array<Element>,
_layers: Array<Element[]>
}
export type SerializedPartialTreeState = {
levels: number
_layers: Element[][]
_zeros: Array<Element>
_edgeLeafProof: ProofPath
_edgeLeaf: LeafWithIndex
}
export type ProofPath = {
pathElements: Element[],
pathIndices: number[],
pathPositions: number[],
pathRoot: Element
}
export type TreeEdge = {
edgeElement: Element;
edgePath: ProofPath;
edgeIndex: number;
edgeElementsCount: number;
}
export type TreeSlice = { edge: TreeEdge, elements: Element[] }
export type LeafWithIndex = { index: number, data: Element }

@ -1,208 +0,0 @@
// keccak256("tornado") % BN254_FIELD_SIZE
const DEFAULT_ZERO = '21663839004416932945382355908790599225266501822907911457504978515578255421292'
const defaultHash = require('./mimc')
// todo ensure consistent types in tree and inserted elements?
// todo make sha3 default hasher (and update tests) to get rid of mimc/snarkjs/circomlib dependency
/**
* @callback hashFunction
* @param left Left leaf
* @param right Right leaf
*/
/**
* Merkle tree
*/
class MerkleTree {
/**
* Constructor
* @param {number} levels Number of levels in the tree
* @param {Array} [elements] Initial elements
* @param {Object} options
* @param {hashFunction} [options.hashFunction] Function used to hash 2 leaves
* @param [options.zeroElement] Value for non-existent leaves
*/
constructor(levels, elements = [], { hashFunction, zeroElement = DEFAULT_ZERO } = {}) {
this.levels = levels
this.capacity = 2 ** levels
if (elements.length > this.capacity) {
throw new Error('Tree is full')
}
this._hash = hashFunction || defaultHash
this.zeroElement = zeroElement
this._zeros = []
this._zeros[0] = zeroElement
for (let i = 1; i <= levels; i++) {
this._zeros[i] = this._hash(this._zeros[i - 1], this._zeros[i - 1])
}
this._layers = []
this._layers[0] = elements.slice()
this._rebuild()
}
_rebuild() {
for (let level = 1; level <= this.levels; level++) {
this._layers[level] = []
for (let i = 0; i < Math.ceil(this._layers[level - 1].length / 2); i++) {
this._layers[level][i] = this._hash(
this._layers[level - 1][i * 2],
i * 2 + 1 < this._layers[level - 1].length
? this._layers[level - 1][i * 2 + 1]
: this._zeros[level - 1],
)
}
}
}
/**
* Get tree root
* @returns {*}
*/
root() {
return this._layers[this.levels].length > 0 ? this._layers[this.levels][0] : this._zeros[this.levels]
}
/**
* Insert new element into the tree
* @param element Element to insert
*/
insert(element) {
if (this._layers[0].length >= this.capacity) {
throw new Error('Tree is full')
}
this.update(this._layers[0].length, element)
}
/**
* Insert multiple elements into the tree.
* @param {Array} elements Elements to insert
*/
bulkInsert(elements) {
if (this._layers[0].length + elements.length > this.capacity) {
throw new Error('Tree is full')
}
// First we insert all elements except the last one
// updating only full subtree hashes (all layers where inserted element has odd index)
// the last element will update the full path to the root making the tree consistent again
for (let i = 0; i < elements.length - 1; i++) {
this._layers[0].push(elements[i])
let level = 0
let index = this._layers[0].length - 1
while (index % 2 === 1) {
level++
index >>= 1
this._layers[level][index] = this._hash(
this._layers[level - 1][index * 2],
this._layers[level - 1][index * 2 + 1],
)
}
}
this.insert(elements[elements.length - 1])
}
/**
* Change an element in the tree
* @param {number} index Index of element to change
* @param element Updated element value
*/
update(index, element) {
if (isNaN(Number(index)) || index < 0 || index > this._layers[0].length || index >= this.capacity) {
throw new Error('Insert index out of bounds: ' + index)
}
this._layers[0][index] = element
for (let level = 1; level <= this.levels; level++) {
index >>= 1
this._layers[level][index] = this._hash(
this._layers[level - 1][index * 2],
index * 2 + 1 < this._layers[level - 1].length
? this._layers[level - 1][index * 2 + 1]
: this._zeros[level - 1],
)
}
}
/**
* Get merkle path to a leaf
* @param {number} index Leaf index to generate path for
* @returns {{pathElements: Object[], pathIndex: number[]}} An object containing adjacent elements and left-right index
*/
path(index) {
if (isNaN(Number(index)) || index < 0 || index >= this._layers[0].length) {
throw new Error('Index out of bounds: ' + index)
}
const pathElements = []
const pathIndices = []
for (let level = 0; level < this.levels; level++) {
pathIndices[level] = index % 2
pathElements[level] =
(index ^ 1) < this._layers[level].length ? this._layers[level][index ^ 1] : this._zeros[level]
index >>= 1
}
return {
pathElements,
pathIndices,
}
}
/**
* Find an element in the tree
* @param element An element to find
* @param comparator A function that checks leaf value equality
* @returns {number} Index if element is found, otherwise -1
*/
indexOf(element, comparator) {
if (comparator) {
return this._layers[0].findIndex((el) => comparator(element, el))
} else {
return this._layers[0].indexOf(element)
}
}
/**
* Returns a copy of non-zero tree elements
* @returns {Object[]}
*/
elements() {
return this._layers[0].slice()
}
/**
* Returns a copy of n-th zero elements array
* @returns {Object[]}
*/
zeros() {
return this._zeros.slice()
}
/**
* Serialize entire tree state including intermediate layers into a plain object
* Deserializing it back will not require to recompute any hashes
* Elements are not converted to a plain type, this is responsibility of the caller
*/
serialize() {
return {
levels: this.levels,
_zeros: this._zeros,
_layers: this._layers,
}
}
/**
* Deserialize data into a MerkleTree instance
* Make sure to provide the same hashFunction as was used in the source tree,
* otherwise the tree state will be invalid
*
* @param data
* @param hashFunction
* @returns {MerkleTree}
*/
static deserialize(data, hashFunction) {
const instance = Object.assign(Object.create(this.prototype), data)
instance._hash = hashFunction || defaultHash
instance.capacity = 2 ** instance.levels
instance.zeroElement = instance._zeros[0]
return instance
}
}
module.exports = MerkleTree

@ -1,3 +0,0 @@
const { mimcsponge } = require('circomlib')
const { bigInt } = require('snarkjs')
module.exports = (left, right) => mimcsponge.multiHash([bigInt(left), bigInt(right)]).toString()

22
src/simpleHash.ts Normal file

@ -0,0 +1,22 @@
import { Element } from './'
/***
* This is insecure hash function, just for example only
* @param data
* @param seed
* @param hashLength
*/
export function simpleHash<T>(data: T[], seed?: number, hashLength = 40): string {
const str = data.join('')
let i, l,
hval = seed ?? 0x811c9dcc5
for (i = 0, l = str.length; i < l; i++) {
hval ^= str.charCodeAt(i)
hval += (hval << 1) + (hval << 4) + (hval << 6) + (hval << 8) + (hval << 24)
}
const hash = (hval >>> 0).toString(16)
return BigInt('0x' + hash.padEnd(hashLength - (hash.length - 1), '0')).toString(10)
}
export default (left: Element, right: Element): string => simpleHash([left, right])

@ -0,0 +1,428 @@
import { MerkleTree, PartialMerkleTree, TreeEdge } from '../src'
import { assert, should } from 'chai'
import { createHash } from 'crypto'
import { it } from 'mocha'
const sha256Hash = (left, right) => createHash('sha256').update(`${left}${right}`).digest('hex')
const ZERO_ELEMENT = '21663839004416932945382355908790599225266501822907911457504978515578255421292'
describe('MerkleTree', () => {
describe('#constructor', () => {
it('should have correct zero root', () => {
const tree = new MerkleTree(10, [])
return should().equal(tree.root, '3060353338620102847451617558650138132480')
})
it('should have correct 1 element root', () => {
const tree = new MerkleTree(10, [1])
should().equal(tree.root, '4059654748770657324723044385589999697920')
})
it('should have correct even elements root', () => {
const tree = new MerkleTree(10, [1, 2])
should().equal(tree.root, '3715471817149864798706576217905179918336')
})
it('should have correct odd elements root', () => {
const tree = new MerkleTree(10, [1, 2, 3])
should().equal(tree.root, '5199180210167621115778229238102210117632')
})
it('should be able to create a full tree', () => {
new MerkleTree(2, [1, 2, 3, 4])
})
it('should fail to create tree with too many elements', () => {
const call = () => new MerkleTree(2, [1, 2, 3, 4, 5])
should().throw(call, 'Tree is full')
})
it('should work with optional hash function and zero element', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5, 6], { hashFunction: sha256Hash, zeroElement: 'zero' })
should().equal(tree.root, 'a377b9fa0ed41add83e56f7e1d0e2ebdb46550b9d8b26b77dece60cb67283f19')
})
})
describe('#insert', () => {
it('should insert into empty tree', () => {
const tree = new MerkleTree(10)
tree.insert(42)
should().equal(tree.root, '750572848877730275626358141391262973952')
})
it('should insert into odd tree', () => {
const tree = new MerkleTree(10, [1])
tree.insert(42)
should().equal(tree.root, '5008383558940708447763798816817296703488')
})
it('should insert into even tree', () => {
const tree = new MerkleTree(10, [1, 2])
tree.insert(42)
should().equal(tree.root, '5005864318873356880627322373636156817408')
})
it('should insert last element', () => {
const tree = new MerkleTree(2, [1, 2, 3])
tree.insert(4)
})
it('should fail to insert when tree is full', () => {
const tree = new MerkleTree(2, [1, 2, 3, 4])
const call = () => tree.insert(5)
should().throw(call, 'Tree is full')
})
})
describe('#bulkInsert', () => {
it('should work', () => {
const tree = new MerkleTree(10, [1, 2, 3])
tree.bulkInsert([4, 5, 6])
should().equal(tree.root, '4066635800770511602067209448381558554624')
})
it('should give the same result as sequential inserts', () => {
const initialArray = [
[1],
[1, 2],
[1, 2, 3],
[1, 2, 3, 4],
]
const insertedArray = [
[11],
[11, 12],
[11, 12, 13],
[11, 12, 13, 14],
]
for (const initial of initialArray) {
for (const inserted of insertedArray) {
const tree1 = new MerkleTree(10, initial)
const tree2 = new MerkleTree(10, initial)
tree1.bulkInsert(inserted)
for (const item of inserted) {
tree2.insert(item)
}
should().equal(tree1.root, tree2.root)
}
}
}).timeout(10000)
it('should work with max elements', () => {
const tree = new MerkleTree(2, [1, 2])
tree.bulkInsert([3, 4])
})
it('should fail to insert too many elements', () => {
const tree = new MerkleTree(2, [1, 2])
const call = () => tree.bulkInsert([3, 4, 5])
should().throw(call, 'Tree is full')
})
it('should bypass empty elements', () => {
const elements = [1, 2, 3, 4]
const tree = new MerkleTree(2, elements)
tree.bulkInsert([])
assert.deepEqual(tree.elements, elements, 'No elements inserted')
})
})
describe('#update', () => {
it('should update first element', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
tree.update(0, 42)
should().equal(tree.root, '3884161948856565981263417078389340635136')
})
it('should update last element', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
tree.update(4, 42)
should().equal(tree.root, '3564959811529894228734180300843252711424')
})
it('should update odd element', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
tree.update(1, 42)
should().equal(tree.root, '4576704573778433422699674477203122290688')
})
it('should update even element', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
tree.update(2, 42)
should().equal(tree.root, '1807994110952186123819489133812038762496')
})
it('should update extra element', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4])
tree.update(4, 5)
should().equal(tree.root, '1099080610107164849381389194938128793600')
})
it('should fail to update incorrect index', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
should().throw((() => tree.update(-1, 42)), 'Insert index out of bounds: -1')
should().throw((() => tree.update(6, 42)), 'Insert index out of bounds: 6')
// @ts-ignore
should().throw((() => tree.update('qwe', 42)), 'Insert index out of bounds: qwe')
})
it('should fail to update over capacity', () => {
const tree = new MerkleTree(2, [1, 2, 3, 4])
const call = () => tree.update(4, 42)
should().throw(call, 'Insert index out of bounds: 4')
})
})
describe('#indexOf', () => {
it('should find index', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
should().equal(tree.indexOf(3), 2)
})
it('should work with comparator', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
should().equal(tree.indexOf(4, (arg0, arg1) => arg0 === arg1), 3)
})
it('should return -1 for non existent element', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
should().equal(tree.indexOf(42), -1)
})
})
describe('#path', () => {
it('should work for even index', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
const path = tree.path(2)
assert.deepEqual(path.pathIndices, [0, 1, 0, 0, 0, 0, 0, 0, 0, 0])
assert.deepEqual(path.pathElements, [
4,
'4027992409016347597424110157229339967488',
'3591172241203040147397382471352592629760',
'938972308169430750202858820582946897920',
'3743880566844110745576746962917825445888',
'2074434463882483178614385966084599578624',
'2808856778596740691845240322870189490176',
'4986731814143931240516913804278285467648',
'1918547053077726613961101558405545328640',
'5444383861051812288142814494928935059456',
])
})
it('should work for odd index', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
const path = tree.path(3)
assert.deepEqual(path.pathIndices, [1, 1, 0, 0, 0, 0, 0, 0, 0, 0])
assert.deepEqual(path.pathElements, [
3,
'4027992409016347597424110157229339967488',
'3591172241203040147397382471352592629760',
'938972308169430750202858820582946897920',
'3743880566844110745576746962917825445888',
'2074434463882483178614385966084599578624',
'2808856778596740691845240322870189490176',
'4986731814143931240516913804278285467648',
'1918547053077726613961101558405545328640',
'5444383861051812288142814494928935059456',
])
})
it('should fail on incorrect index', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4])
should().throw((() => tree.path(-1)), 'Index out of bounds: -1')
should().throw((() => tree.path(5)), 'Index out of bounds: 5')
// @ts-ignore
should().throw((() => tree.path('qwe')), 'Index out of bounds: qwe')
})
it('should work for correct string index', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
// @ts-ignore
const path = tree.path('2')
assert.deepEqual(path.pathIndices, [0, 1, 0, 0, 0, 0, 0, 0, 0, 0])
assert.deepEqual(path.pathElements, [
4,
'4027992409016347597424110157229339967488',
'3591172241203040147397382471352592629760',
'938972308169430750202858820582946897920',
'3743880566844110745576746962917825445888',
'2074434463882483178614385966084599578624',
'2808856778596740691845240322870189490176',
'4986731814143931240516913804278285467648',
'1918547053077726613961101558405545328640',
'5444383861051812288142814494928935059456',
])
})
})
describe('#proof', () => {
it('should return proof for leaf', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
assert.deepEqual(tree.proof(4), tree.path(3))
})
})
describe('#getTreeEdge', () => {
it('should return correct treeEdge', () => {
const expectedEdge: TreeEdge = {
edgePath: {
pathElements: [
5,
'1390935134112885103361924701261056180224',
'1952916572242076545231119328171167580160',
'938972308169430750202858820582946897920',
],
pathIndices: [0, 0, 1, 0],
pathPositions: [5, 0, 0, 0],
pathRoot: '3283298202329284319899364273680487022592',
},
edgeElement: 4,
edgeIndex: 4,
edgeElementsCount: 6,
}
const tree = new MerkleTree(4, [0, 1, 2, 3, 4, 5])
assert.deepEqual(tree.getTreeEdge(4), expectedEdge)
})
it('should fail if element not found', () => {
const tree = new MerkleTree(4, [0, 1, 2, 3, 4, 5])
const call = () => tree.getTreeEdge(6)
should().throw(call, 'Element not found')
})
})
describe('#getTreeSlices', () => {
let fullTree: MerkleTree
before(async () => {
const elements = Array.from({ length: 2 ** 10 }, (_, i) => i)
fullTree = new MerkleTree(10, elements)
return Promise.resolve()
})
it('should return correct slices count', () => {
const count = 4
const slicesCount = fullTree.getTreeSlices(4).length
should().equal(count, slicesCount)
}).timeout(10000)
it('should be able to create partial tree from last slice', () => {
const [, , , lastSlice] = fullTree.getTreeSlices()
const partialTree = new PartialMerkleTree(10, lastSlice.edge, lastSlice.elements)
assert.deepEqual(fullTree.root, partialTree.root)
}).timeout(10000)
it('should be able to build full tree from slices', () => {
const slices = fullTree.getTreeSlices()
const lastSlice = slices.pop()
const partialTree = new PartialMerkleTree(10, lastSlice.edge, lastSlice.elements)
slices.reverse().forEach(({ edge, elements }) => {
partialTree.shiftEdge(edge, elements)
})
assert.deepEqual(fullTree.layers, partialTree.layers)
}).timeout(10000)
it('should return same path', () => {
const slices = fullTree.getTreeSlices()
const lastSlice = slices.pop()
const partialTree = new PartialMerkleTree(10, lastSlice.edge, lastSlice.elements)
slices.reverse().forEach(({ edge, elements }) => {
partialTree.shiftEdge(edge, elements)
})
assert.deepEqual(fullTree.path(100), partialTree.path(100))
}).timeout(10000)
it('should throw if invalid number of elements', () => {
const [firstSlice] = fullTree.getTreeSlices()
const call = () => new PartialMerkleTree(10, firstSlice.edge, firstSlice.elements)
should().throw(call, 'Invalid number of elements')
}).timeout(10000)
})
describe('#getters', () => {
const elements = [1, 2, 3, 4, 5]
const layers = [
[1, 2, 3, 4, 5],
[
'4027992409016347597424110157229339967488',
'923221781152860005594997320673730232320',
'752191049236692618445397735417537626112',
],
[
'81822854828781486047086122479545722339328',
'3591172241203040147397382471352592629760',
],
['2729943778107054496417267081388406865920'],
['4562739390655416913642128116127918718976'],
]
it('should return same elements in array', () => {
const tree = new MerkleTree(10, elements)
assert.deepEqual(tree.elements, elements)
})
it('should return copy of elements array', () => {
const tree = new MerkleTree(10, elements)
const elements1 = tree.elements
tree.insert(6)
const elements2 = tree.elements
should().not.equal(elements1, elements2)
})
it('should return same layers in array', () => {
const tree = new MerkleTree(4, elements)
assert.deepEqual(tree.layers, layers)
})
it('should return copy of elements array', () => {
const tree = new MerkleTree(4, elements)
const layers1 = tree.layers
tree.insert(6)
const layers2 = tree.layers
should().not.equal(layers1, layers2)
})
it('should return correct zeros array', () => {
const zeros = [
0,
'1390935134112885103361924701261056180224',
'3223901263414086620636498663535535980544',
'938972308169430750202858820582946897920',
'3743880566844110745576746962917825445888',
]
const tree = new MerkleTree(4, [])
assert.deepEqual(tree.zeros, zeros, 'Not equal')
})
it('should return copy of zeros array', () => {
const tree = new MerkleTree(4, [])
const zeros1 = tree.zeros
tree.insert(6)
const zeros2 = tree.zeros
should().not.equal(zeros1, zeros2)
})
})
describe('#serialize', () => {
it('should work', () => {
const src = new MerkleTree(10, [1, 2, 3, 4, 5, 6, 7, 8, 9])
const data = src.serialize()
const dst = MerkleTree.deserialize(data)
should().equal(src.root, dst.root)
src.insert(10)
dst.insert(10)
should().equal(src.root, dst.root)
})
})
describe('#toString', () => {
it('should return correct stringified representation', () => {
const src = new MerkleTree(10, [1, 2, 3, 4, 5, 6, 7, 8, 9])
const str = src.toString()
const dst = MerkleTree.deserialize(JSON.parse(str))
should().equal(src.root, dst.root)
src.insert(10)
dst.insert(10)
should().equal(src.root, dst.root)
})
})
})

@ -1,246 +0,0 @@
const MerkleTree = require('../src/merkleTree')
require('chai').should()
describe('MerkleTree', () => {
describe('#constructor', () => {
it('should have correct zero root', () => {
const tree = new MerkleTree(10)
return tree.root().should.equal('14030416097908897320437553787826300082392928432242046897689557706485311282736')
})
it('should have correct 1 element root', () => {
const tree = new MerkleTree(10, [1])
tree.root().should.equal('8423266420989796135179818298985240707844287090553672312129988553683991994663')
})
it('should have correct even elements root', () => {
const tree = new MerkleTree(10, [1, 2])
tree.root().should.equal('6632020347849276860492323008882350357301732786233864934344775324188835172576')
})
it('should have correct odd elements root', () => {
const tree = new MerkleTree(10, [1, 2, 3])
tree.root().should.equal('13605252518346649016266481317890801910232739395710162921320863289825142055129')
})
it('should be able to create a full tree', () => {
new MerkleTree(2, [1, 2, 3, 4])
})
it('should fail to create tree with too many elements', () => {
const call = () => new MerkleTree(2, [1, 2, 3, 4, 5])
call.should.throw('Tree is full')
})
})
describe('#insert', () => {
it('should insert into empty tree', () => {
const tree = new MerkleTree(10)
tree.insert(42)
tree.root().should.equal('5305397050004975530787056746976521882221645950652996479084366175595194436378')
})
it('should insert into odd tree', () => {
const tree = new MerkleTree(10, [1])
tree.insert(42)
tree.root().should.equal('4732716818150428188641303198013632061441036732749853605989871103991103096471')
})
it('should insert into even tree', () => {
const tree = new MerkleTree(10, [1, 2])
tree.insert(42)
tree.root().should.equal('6204016789747878948181936326719724987136198810274146408545977300318734508764')
})
it('should insert last element', () => {
const tree = new MerkleTree(2, [1, 2, 3])
tree.insert(4)
})
it('should fail to insert when tree is full', () => {
const tree = new MerkleTree(2, [1, 2, 3, 4])
const call = () => tree.insert(5)
call.should.throw('Tree is full')
})
})
describe('#bulkInsert', () => {
it('should work', () => {
const tree = new MerkleTree(10, [1, 2, 3])
tree.bulkInsert([4, 5, 6])
tree.root().should.equal('10132905325673518287563057607527946096399700874345297651940963130460267058606')
})
it('should give the same result as sequental inserts', () => {
const initialArray = [
[1],
[1, 2],
[1, 2, 3],
[1, 2, 3, 4],
]
const insertedArray = [
[11],
[11, 12],
[11, 12, 13],
[11, 12, 13, 14],
]
for (const initial of initialArray) {
for (const inserted of insertedArray) {
const tree1 = new MerkleTree(10, initial)
const tree2 = new MerkleTree(10, initial)
tree1.bulkInsert(inserted)
for (const item of inserted) {
tree2.insert(item)
}
tree1.root().should.equal(tree2.root())
}
}
}).timeout(10000)
it('should work with max elements', () => {
const tree = new MerkleTree(2, [1, 2])
tree.bulkInsert([3, 4])
})
it('should fail to insert too many elements', () => {
const tree = new MerkleTree(2, [1, 2])
const call = () => tree.bulkInsert([3, 4, 5])
call.should.throw('Tree is full')
})
})
describe('#update', () => {
it('should update first element', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
tree.update(0, 42)
tree.root().should.equal('153077538697962715163231177553585573790587443799974092612333826693999310199')
})
it('should update last element', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
tree.update(4, 42)
tree.root().should.equal('1955192134603843666100093417117434845771298375724087600313714421260719033775')
})
it('should update odd element', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
tree.update(1, 42)
tree.root().should.equal('6642888742811380760154112624880866754768235565211186414088321870395007150538')
})
it('should update even element', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
tree.update(2, 42)
tree.root().should.equal('11739358667442647096377238675718917508981868161724701476635082606510350785683')
})
it('should update extra element', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4])
tree.update(4, 5)
tree.root().should.equal('6341751103515285836339987888606244815365572869367801108789753151704260302930')
})
it('should fail to update incorrect index', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5]);
(() => tree.update(-1, 42)).should.throw('Insert index out of bounds: -1');
(() => tree.update(6, 42)).should.throw('Insert index out of bounds: 6');
(() => tree.update('qwe', 42)).should.throw('Insert index out of bounds: qwe')
})
it('should fail to update over capacity', () => {
const tree = new MerkleTree(2, [1, 2, 3, 4])
const call = () => tree.update(4, 42)
call.should.throw('Insert index out of bounds: 4')
})
})
describe('#indexOf', () => {
it('should find index', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
tree.indexOf(3).should.equal(2)
})
it('should return -1 for non existent element', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
tree.indexOf(42).should.equal(-1)
})
})
describe('#path', () => {
it('should work for even index', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
const path = tree.path(2)
path.pathIndices.should.be.deep.equal([0, 1, 0, 0, 0, 0, 0, 0, 0, 0])
path.pathElements.should.be.deep.equal([
4,
'19814528709687996974327303300007262407299502847885145507292406548098437687919',
'21305827034995891902714687670641862055126514524916463201449278400604999416145',
'14506027710748750947258687001455876266559341618222612722926156490737302846427',
'4766583705360062980279572762279781527342845808161105063909171241304075622345',
'16640205414190175414380077665118269450294358858897019640557533278896634808665',
'13024477302430254842915163302704885770955784224100349847438808884122720088412',
'11345696205391376769769683860277269518617256738724086786512014734609753488820',
'17235543131546745471991808272245772046758360534180976603221801364506032471936',
'155962837046691114236524362966874066300454611955781275944230309195800494087',
])
})
it('should work for odd index', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
const path = tree.path(3)
path.pathIndices.should.be.deep.equal([1, 1, 0, 0, 0, 0, 0, 0, 0, 0])
path.pathElements.should.be.deep.equal([
3,
'19814528709687996974327303300007262407299502847885145507292406548098437687919',
'21305827034995891902714687670641862055126514524916463201449278400604999416145',
'14506027710748750947258687001455876266559341618222612722926156490737302846427',
'4766583705360062980279572762279781527342845808161105063909171241304075622345',
'16640205414190175414380077665118269450294358858897019640557533278896634808665',
'13024477302430254842915163302704885770955784224100349847438808884122720088412',
'11345696205391376769769683860277269518617256738724086786512014734609753488820',
'17235543131546745471991808272245772046758360534180976603221801364506032471936',
'155962837046691114236524362966874066300454611955781275944230309195800494087',
])
})
it('should fail on incorrect index', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4]);
(() => tree.path(-1)).should.throw('Index out of bounds: -1');
(() => tree.path(5)).should.throw('Index out of bounds: 5');
(() => tree.path('qwe')).should.throw('Index out of bounds: qwe')
})
it('should work for correct string index', () => {
const tree = new MerkleTree(10, [1, 2, 3, 4, 5])
const path = tree.path('2')
path.pathIndices.should.be.deep.equal([0, 1, 0, 0, 0, 0, 0, 0, 0, 0])
path.pathElements.should.be.deep.equal([
4,
'19814528709687996974327303300007262407299502847885145507292406548098437687919',
'21305827034995891902714687670641862055126514524916463201449278400604999416145',
'14506027710748750947258687001455876266559341618222612722926156490737302846427',
'4766583705360062980279572762279781527342845808161105063909171241304075622345',
'16640205414190175414380077665118269450294358858897019640557533278896634808665',
'13024477302430254842915163302704885770955784224100349847438808884122720088412',
'11345696205391376769769683860277269518617256738724086786512014734609753488820',
'17235543131546745471991808272245772046758360534180976603221801364506032471936',
'155962837046691114236524362966874066300454611955781275944230309195800494087',
])
})
})
describe('#serialize', () => {
it('should work', () => {
const src = new MerkleTree(10, [1, 2, 3])
const data = src.serialize()
const dst = MerkleTree.deserialize(data)
src.root().should.equal(dst.root())
src.insert(10)
dst.insert(10)
src.root().should.equal(dst.root())
})
})
})

@ -0,0 +1,297 @@
import { Element, MerkleTree, MerkleTreeOptions, PartialMerkleTree } from '../src'
import { it } from 'mocha'
import { should } from 'chai'
import * as assert from 'assert'
import { createHash } from 'crypto'
const sha256Hash = (left, right) => createHash('sha256').update(`${left}${right}`).digest('hex')
describe('PartialMerkleTree', () => {
const getTestTrees = (levels: number, elements: Element[], edgeIndex: number, treeOptions: MerkleTreeOptions = {}) => {
const fullTree = new MerkleTree(levels, elements, treeOptions)
const edge = fullTree.getTreeEdge(edgeIndex)
const leavesAfterEdge = elements.slice(edge.edgeIndex)
const partialTree = new PartialMerkleTree(levels, edge, leavesAfterEdge, treeOptions)
return { fullTree, partialTree }
}
describe('#constructor', () => {
const { fullTree, partialTree } = getTestTrees(20, ['0', '1', '2', '3', '4', '5'], 2)
it('should initialize merkle tree with same root', () => {
should().equal(fullTree.root, partialTree.root)
})
it('should initialize merkle tree with same leaves count', () => {
should().equal(fullTree.elements.length, partialTree.elements.length)
})
it('should work with optional hash function and zero element', () => {
const { partialTree, fullTree } = getTestTrees(10, [1, 2, 3, 4, 5, 6], 3, {
hashFunction: sha256Hash,
zeroElement: 'zero',
})
should().equal(partialTree.root, fullTree.root)
})
})
describe('#insert', () => {
it('should have equal root to full tree after insertion ', () => {
const { fullTree, partialTree } = getTestTrees(10, ['0', '1', '2', '3', '4', '5', '6', '7'], 5)
fullTree.insert('9')
partialTree.insert('9')
should().equal(fullTree.root, partialTree.root)
})
it('should fail to insert when tree is full', () => {
const { partialTree } = getTestTrees(3, ['0', '1', '2', '3', '4', '5', '6', '7'], 5)
const call = () => partialTree.insert('8')
should().throw(call, 'Tree is full')
})
})
describe('#bulkInsert', () => {
it('should work like full tree', () => {
const { fullTree, partialTree } = getTestTrees(20, [1, 2, 3, 4, 5], 2)
partialTree.bulkInsert([6, 7, 8])
fullTree.bulkInsert([6, 7, 8])
should().equal(fullTree.root, partialTree.root)
})
it('should give the same result as sequential inserts', () => {
const initialArray = [
[1],
[1, 2],
[1, 2, 3],
[1, 2, 3, 4],
]
const insertedArray = [
[11],
[11, 12],
[11, 12, 13],
[11, 12, 13, 14],
]
for (const initial of initialArray) {
for (const inserted of insertedArray) {
const { partialTree: tree1 } = getTestTrees(10, initial, initial.length - 1)
const { partialTree: tree2 } = getTestTrees(10, initial, initial.length - 1)
tree1.bulkInsert(inserted)
for (const item of inserted) {
tree2.insert(item)
}
should().equal(tree1.root, tree2.root)
}
}
}).timeout(10000)
it('should fail to insert too many elements', () => {
const { partialTree } = getTestTrees(2, [1, 2, 3, 4], 2)
const call = () => partialTree.bulkInsert([5, 6, 7])
should().throw(call, 'Tree is full')
})
it('should bypass empty elements', () => {
const elements = [1, 2, 3, 4]
const { partialTree } = getTestTrees(2, elements, 2)
partialTree.bulkInsert([])
should().equal(partialTree.elements.length, elements.length, 'No elements inserted')
})
})
describe('#update', () => {
it('should update last element', () => {
const { fullTree, partialTree } = getTestTrees(10, [1, 2, 3, 4, 5], 2)
partialTree.update(4, 42)
fullTree.update(4, 42)
should().equal(partialTree.root, fullTree.root)
})
it('should update odd element', () => {
const { fullTree, partialTree } = getTestTrees(10, [1, 2, 3, 4, 5, 6, 7, 8], 2)
partialTree.update(4, 42)
fullTree.update(4, 42)
should().equal(partialTree.root, fullTree.root)
})
it('should update even element', () => {
const { fullTree, partialTree } = getTestTrees(10, [1, 2, 3, 4, 5, 6, 7, 8], 2)
partialTree.update(3, 42)
fullTree.update(3, 42)
should().equal(partialTree.root, fullTree.root)
})
it('should update extra element', () => {
const { fullTree, partialTree } = getTestTrees(10, [1, 2, 3, 4, 5], 2)
partialTree.update(5, 6)
fullTree.update(5, 6)
should().equal(fullTree.root, partialTree.root)
})
it('should fail to update incorrect index', () => {
const { partialTree } = getTestTrees(10, [1, 2, 3, 4, 5], 3)
should().throw((() => partialTree.update(-1, 42)), 'Insert index out of bounds: -1')
should().throw((() => partialTree.update(6, 42)), 'Insert index out of bounds: 6')
should().throw((() => partialTree.update(2, 42)), 'Index 2 is below the edge: 3')
// @ts-ignore
should().throw((() => partialTree.update('qwe', 42)), 'Insert index out of bounds: qwe')
})
it('should fail to update over capacity', () => {
const { partialTree } = getTestTrees(2, [1, 2, 3, 4], 1)
const call = () => partialTree.update(4, 42)
should().throw(call, 'Insert index out of bounds: 4')
})
})
describe('#indexOf', () => {
it('should return same result as full tree', () => {
const { fullTree, partialTree } = getTestTrees(10, [1, 2, 3, 4, 5, 6, 7, 8], 3)
should().equal(partialTree.indexOf(5), fullTree.indexOf(5))
})
it('should find index', () => {
const { partialTree } = getTestTrees(10, [1, 2, 3, 4, 5], 2)
should().equal(partialTree.indexOf(3), 2)
})
it('should work with comparator', () => {
const { partialTree } = getTestTrees(10, [1, 2, 3, 4, 5], 2)
should().equal(partialTree.indexOf(4, (arg0, arg1) => arg0 === arg1), 3)
})
it('should return -1 for non existent element', () => {
const { partialTree } = getTestTrees(10, [1, 2, 3, 4, 5], 2)
should().equal(partialTree.indexOf(42), -1)
})
})
describe('#proof', () => {
it('should return proof for known leaf', () => {
const { partialTree } = getTestTrees(10, [1, 2, 3, 4, 5], 2)
assert.deepEqual(partialTree.proof(4), partialTree.path(3))
})
})
describe('#getters', () => {
it('should return capacity', () => {
const levels = 10
const capacity = 2 ** levels
const { fullTree, partialTree } = getTestTrees(levels, [1, 2, 3, 4, 5], 2)
should().equal(fullTree.capacity, capacity)
should().equal(partialTree.capacity, capacity)
})
it('should return same elements count as full tree', () => {
const levels = 10
const capacity = 2 ** levels
const elements = Array.from({ length: capacity }, (_, i) => i)
const { fullTree, partialTree } = getTestTrees(levels, elements, 200)
should().equal(partialTree.elements.length, fullTree.elements.length)
})
it('should return copy of layers', () => {
const { partialTree } = getTestTrees(10, [1, 2, 3, 4, 5], 2)
const layers = partialTree.layers
should().not.equal(layers, partialTree.layers)
})
it('should return copy of zeros', () => {
const { partialTree } = getTestTrees(10, [1, 2, 3, 4, 5], 2)
const zeros = partialTree.zeros
should().not.equal(zeros, partialTree.zeros)
})
it('should return edge leaf', () => {
const { partialTree } = getTestTrees(10, [1, 2, 3, 4, 5], 2)
should().equal(partialTree.edgeElement, 3)
})
})
describe('#path', () => {
it('should return path for known nodes', () => {
const levels = 10
const capacity = 2 ** levels
const elements = Array.from({ length: capacity / 2 }, (_, i) => i)
const { fullTree, partialTree } = getTestTrees(levels, elements, 250)
assert.deepEqual(fullTree.path(251), partialTree.path(251))
}).timeout(1000)
it('should fail on incorrect index', () => {
const { partialTree } = getTestTrees(10, [1, 2, 3, 4, 5, 6, 7, 8, 9], 4)
should().throw((() => partialTree.path(-1)), 'Index out of bounds: -1')
should().throw((() => partialTree.path(10)), 'Index out of bounds: 10')
// @ts-ignore
should().throw((() => partialTree.path('qwe')), 'Index out of bounds: qwe')
})
it('should fail if index is below edge', () => {
const { partialTree } = getTestTrees(10, [1, 2, 3, 4, 5, 6, 7, 8, 9], 4)
const call = () => partialTree.path(2)
should().throw(call, 'Index 2 is below the edge: 4')
})
})
describe('#shiftEdge', () => {
const levels = 20
const elements: Element[] = Array.from({ length: 2 ** 18 }, (_, i) => i)
const tree = new MerkleTree(levels, elements)
it('should work', () => {
const edge1 = tree.getTreeEdge(200)
const edge2 = tree.getTreeEdge(100)
const partialTree = new PartialMerkleTree(levels, edge1, elements.slice(edge1.edgeIndex))
partialTree.shiftEdge(edge2, elements.slice(edge2.edgeIndex, partialTree.edgeIndex))
tree.insert('1111')
partialTree.insert('1111')
assert.deepEqual(partialTree.path(150), tree.path(150))
})
it('should be able to build full tree from slices', () => {
const slices = tree.getTreeSlices(6)
const lastSlice = slices.pop()
const partialTree = new PartialMerkleTree(levels, lastSlice.edge, lastSlice.elements)
for (let i = slices.length - 1; i >= 0; i--) {
partialTree.shiftEdge(slices[i].edge, slices[i].elements)
}
partialTree.insert('1')
tree.insert('1')
assert.deepStrictEqual(partialTree.path(432), tree.path(432))
}).timeout(10000)
it('should fail if new edge index is over current edge', () => {
const { fullTree, partialTree } = getTestTrees(10, [0, 1, 2, 3, 4, 5, 6, 7, 8, 9], 4)
const newEdge = fullTree.getTreeEdge(4)
const call = () => partialTree.shiftEdge(newEdge, [1, 2])
should().throw(call, 'New edgeIndex should be smaller then 4')
})
it('should fail if elements length are incorrect', () => {
const { fullTree, partialTree } = getTestTrees(10, [1, 2, 3, 4, 5, 6, 7, 8, 9], 4)
const newEdge = fullTree.getTreeEdge(3)
const call = () => partialTree.shiftEdge(newEdge, [1, 2])
should().throw(call, 'Elements length should be 1')
})
})
describe('#serialize', () => {
it('should work', () => {
const { partialTree } = getTestTrees(5, [1, 2, 3, 4, 5, 6, 7, 8, 9], 5)
const data = partialTree.serialize()
const dst = PartialMerkleTree.deserialize(data)
should().equal(partialTree.root, dst.root)
partialTree.insert(10)
dst.insert(10)
assert.deepStrictEqual(partialTree.path(6), dst.path(6))
should().equal(partialTree.root, dst.root)
})
})
describe('#toString', () => {
it('should return correct stringified representation', () => {
const { partialTree } = getTestTrees(5, [1, 2, 3, 4, 5, 6, 7, 8, 9], 5)
const str = partialTree.toString()
const dst = PartialMerkleTree.deserialize(JSON.parse(str))
assert.deepStrictEqual(partialTree.path(6), dst.path(6))
partialTree.insert(10)
dst.insert(10)
assert.deepStrictEqual(partialTree.path(6), dst.path(6))
assert.deepStrictEqual(partialTree.root, dst.root)
})
})
})

18
test/simpleHash.spec.ts Normal file

@ -0,0 +1,18 @@
import { it } from 'mocha'
import { should } from 'chai'
import { simpleHash } from '../src'
describe('SimpleHash', () => {
it('should return correct hash string with default params', () => {
const hash = simpleHash([1, 2, 3])
return should().equal(hash, '3530513397947785053296897142557895557120')
})
it('should return correct hash string with length param', () => {
const hash = simpleHash([1, 2, 3], null, 77)
return should().equal(hash, '1259729275322113643079999203492506359813191573070980317691663537897682854338069790720')
})
it('should return correct hash string with seed param', () => {
const hash = simpleHash(['1', '2', '3'], 123)
return should().equal(hash, '1371592418687375416654554138100746944512')
})
})

25
tsconfig.json Normal file

@ -0,0 +1,25 @@
{
"compilerOptions": {
"lib": [
"es2020"
],
"target": "es2017",
"module": "CommonJS",
"moduleResolution": "Node",
"outDir": "./lib",
"rootDir": "./src",
"esModuleInterop": true,
"sourceMap": false,
"allowSyntheticDefaultImports": true,
"forceConsistentCasingInFileNames": true,
"declaration": true
},
"include": [
"src"
],
"exclude": [
"node_modules",
"types",
"**/*.spec.ts"
]
}