726 lines
29 KiB
JavaScript
726 lines
29 KiB
JavaScript
var supernodeKBucket;
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var superNodeList;
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/*Kademlia DHT K-bucket implementation as a binary tree.*/
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if (typeof reactor == "undefined" || !reactor) {
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(function () {
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function Event(name) {
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this.name = name;
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this.callbacks = [];
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}
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Event.prototype.registerCallback = function (callback) {
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this.callbacks.push(callback);
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};
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function Reactor() {
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this.events = {};
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}
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Reactor.prototype.registerEvent = function (eventName) {
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var event = new Event(eventName);
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this.events[eventName] = event;
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};
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Reactor.prototype.dispatchEvent = function (eventName, eventArgs) {
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this.events[eventName].callbacks.forEach(function (callback) {
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callback(eventArgs);
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});
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};
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Reactor.prototype.addEventListener = function (eventName, callback) {
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this.events[eventName].registerCallback(callback);
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};
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window.reactor = new Reactor();
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})();
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}
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reactor.registerEvent('added');
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reactor.addEventListener('added', function (someObject) {
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console.log('Added fired with data ' + someObject);
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});
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reactor.registerEvent('removed');
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reactor.addEventListener('removed', function (someObject) {
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console.log('Removed fired with data ' + someObject);
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});
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reactor.registerEvent('updated');
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reactor.addEventListener('updated', function (someObject) {
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console.log('Updated fired with data ' + someObject);
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});
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reactor.registerEvent('bucket_full');
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reactor.addEventListener('bucket_full', function (someObject) {
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console.log('Bucket full ' + someObject);
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});
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/*
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//Sample Usage
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//Creating and defining the event
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reactor.registerEvent('big bang');
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reactor.addEventListener('big bang', function(someObject){
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console.log('This is big bang listener yo!'+ someObject.a);
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});
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//Firing the event
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reactor.dispatchEvent('big bang');
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reactor.dispatchEvent('big bang',{a:1});
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reactor.dispatchEvent('big bang',{a:55});
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*/
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//Checking if existing NodeID can be used
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//This first block of if will initialize the configuration of KBucket
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//Add Events, Messaging between different K-Buckets, and attach relevant distributed data
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/**
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* @param {Uint8Array} array1
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* @param {Uint8Array} array2
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* @return {Boolean}
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*/
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function arrayEquals(array1, array2) {
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if (array1 === array2) {
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return true
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}
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if (array1.length !== array2.length) {
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return false
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}
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for (let i = 0, length = array1.length; i < length; ++i) {
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if (array1[i] !== array2[i]) {
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return false
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}
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}
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return true
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}
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function createNode() {
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return {
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contacts: [],
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dontSplit: false,
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left: null,
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right: null
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}
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}
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function ensureInt8(name, val) {
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if (!(val instanceof Uint8Array)) {
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throw new TypeError(name + ' is not a Uint8Array')
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}
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}
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/**
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* Implementation of a Kademlia DHT k-bucket used for storing
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* contact (peer node) information.
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*
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* @extends EventEmitter
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*/
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function BuildKBucket(options = {}) {
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/**
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* `options`:
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* `distance`: Function
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* `function (firstId, secondId) { return distance }` An optional
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* `distance` function that gets two `id` Uint8Arrays
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* and return distance (as number) between them.
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* `arbiter`: Function (Default: vectorClock arbiter)
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* `function (incumbent, candidate) { return contact; }` An optional
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* `arbiter` function that givent two `contact` objects with the same `id`
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* returns the desired object to be used for updating the k-bucket. For
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* more details, see [arbiter function](#arbiter-function).
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* `localNodeId`: Uint8Array An optional Uint8Array representing the local node id.
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* If not provided, a local node id will be created via `randomBytes(20)`.
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* `metadata`: Object (Default: {}) Optional satellite data to include
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* with the k-bucket. `metadata` property is guaranteed not be altered by,
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* it is provided as an explicit container for users of k-bucket to store
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* implementation-specific data.
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* `numberOfNodesPerKBucket`: Integer (Default: 20) The number of nodes
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* that a k-bucket can contain before being full or split.
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* `numberOfNodesToPing`: Integer (Default: 3) The number of nodes to
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* ping when a bucket that should not be split becomes full. KBucket will
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* emit a `ping` event that contains `numberOfNodesToPing` nodes that have
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* not been contacted the longest.
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*
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* @param {Object=} options optional
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*/
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this.localNodeId = options.localNodeId || window.crypto.getRandomValues(new Uint8Array(20))
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this.numberOfNodesPerKBucket = options.numberOfNodesPerKBucket || 20
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this.numberOfNodesToPing = options.numberOfNodesToPing || 3
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this.distance = options.distance || this.distance
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// use an arbiter from options or vectorClock arbiter by default
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this.arbiter = options.arbiter || this.arbiter
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this.metadata = Object.assign({}, options.metadata)
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ensureInt8('option.localNodeId as parameter 1', this.localNodeId)
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this.root = createNode()
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/**
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* Default arbiter function for contacts with the same id. Uses
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* contact.vectorClock to select which contact to update the k-bucket with.
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* Contact with larger vectorClock field will be selected. If vectorClock is
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* the same, candidat will be selected.
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*
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* @param {Object} incumbent Contact currently stored in the k-bucket.
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* @param {Object} candidate Contact being added to the k-bucket.
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* @return {Object} Contact to updated the k-bucket with.
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*/
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this.arbiter = function (incumbent, candidate) {
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return incumbent.vectorClock > candidate.vectorClock ? incumbent : candidate
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}
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/**
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* Default distance function. Finds the XOR
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* distance between firstId and secondId.
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*
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* @param {Uint8Array} firstId Uint8Array containing first id.
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* @param {Uint8Array} secondId Uint8Array containing second id.
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* @return {Number} Integer The XOR distance between firstId
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* and secondId.
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*/
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this.distance = function (firstId, secondId) {
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let distance = 0
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let i = 0
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const min = Math.min(firstId.length, secondId.length)
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const max = Math.max(firstId.length, secondId.length)
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for (; i < min; ++i) {
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distance = distance * 256 + (firstId[i] ^ secondId[i])
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}
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for (; i < max; ++i) distance = distance * 256 + 255
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return distance
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}
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/**
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* Adds a contact to the k-bucket.
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*
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* @param {Object} contact the contact object to add
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*/
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this.add = function (contact) {
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ensureInt8('contact.id', (contact || {}).id)
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let bitIndex = 0
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let node = this.root
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while (node.contacts === null) {
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// this is not a leaf node but an inner node with 'low' and 'high'
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// branches; we will check the appropriate bit of the identifier and
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// delegate to the appropriate node for further processing
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node = this._determineNode(node, contact.id, bitIndex++)
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}
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// check if the contact already exists
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const index = this._indexOf(node, contact.id)
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if (index >= 0) {
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this._update(node, index, contact)
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return this
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}
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if (node.contacts.length < this.numberOfNodesPerKBucket) {
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node.contacts.push(contact)
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reactor.dispatchEvent('added', contact)
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return this
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}
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// the bucket is full
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if (node.dontSplit) {
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// we are not allowed to split the bucket
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// we need to ping the first this.numberOfNodesToPing
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// in order to determine if they are alive
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// only if one of the pinged nodes does not respond, can the new contact
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// be added (this prevents DoS flodding with new invalid contacts)
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reactor.dispatchEvent('bucket_full', {1: node.contacts.slice(0, this.numberOfNodesToPing),2: contact})
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return this
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}
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this._split(node, bitIndex)
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return this.add(contact)
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}
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/**
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* Get the n closest contacts to the provided node id. "Closest" here means:
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* closest according to the XOR metric of the contact node id.
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*
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* @param {Uint8Array} id Contact node id
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* @param {Number=} n Integer (Default: Infinity) The maximum number of
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* closest contacts to return
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* @return {Array} Array Maximum of n closest contacts to the node id
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*/
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this.closest = function (id, n = Infinity) {
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ensureInt8('id', id)
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if ((!Number.isInteger(n) && n !== Infinity) || n <= 0) {
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throw new TypeError('n is not positive number')
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}
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let contacts = []
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for (let nodes = [this.root], bitIndex = 0; nodes.length > 0 && contacts.length < n;) {
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const node = nodes.pop()
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if (node.contacts === null) {
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const detNode = this._determineNode(node, id, bitIndex++)
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nodes.push(node.left === detNode ? node.right : node.left)
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nodes.push(detNode)
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} else {
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contacts = contacts.concat(node.contacts)
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}
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}
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return contacts
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.map(a => [this.distance(a.id, id), a])
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.sort((a, b) => a[0] - b[0])
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.slice(0, n)
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.map(a => a[1])
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}
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/**
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* Counts the total number of contacts in the tree.
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*
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* @return {Number} The number of contacts held in the tree
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*/
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this.count = function () {
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// return this.toArray().length
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let count = 0
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for (const nodes = [this.root]; nodes.length > 0;) {
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const node = nodes.pop()
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if (node.contacts === null) nodes.push(node.right, node.left)
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else count += node.contacts.length
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}
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return count
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}
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/**
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* Determines whether the id at the bitIndex is 0 or 1.
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* Return left leaf if `id` at `bitIndex` is 0, right leaf otherwise
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*
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* @param {Object} node internal object that has 2 leafs: left and right
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* @param {Uint8Array} id Id to compare localNodeId with.
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* @param {Number} bitIndex Integer (Default: 0) The bit index to which bit
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* to check in the id Uint8Array.
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* @return {Object} left leaf if id at bitIndex is 0, right leaf otherwise.
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*/
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this._determineNode = function (node, id, bitIndex) {
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// *NOTE* remember that id is a Uint8Array and has granularity of
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// bytes (8 bits), whereas the bitIndex is the bit index (not byte)
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// id's that are too short are put in low bucket (1 byte = 8 bits)
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// (bitIndex >> 3) finds how many bytes the bitIndex describes
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// bitIndex % 8 checks if we have extra bits beyond byte multiples
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// if number of bytes is <= no. of bytes described by bitIndex and there
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// are extra bits to consider, this means id has less bits than what
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// bitIndex describes, id therefore is too short, and will be put in low
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// bucket
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const bytesDescribedByBitIndex = bitIndex >> 3
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const bitIndexWithinByte = bitIndex % 8
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if ((id.length <= bytesDescribedByBitIndex) && (bitIndexWithinByte !== 0)) {
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return node.left
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}
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const byteUnderConsideration = id[bytesDescribedByBitIndex]
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// byteUnderConsideration is an integer from 0 to 255 represented by 8 bits
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// where 255 is 11111111 and 0 is 00000000
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// in order to find out whether the bit at bitIndexWithinByte is set
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// we construct (1 << (7 - bitIndexWithinByte)) which will consist
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// of all bits being 0, with only one bit set to 1
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// for example, if bitIndexWithinByte is 3, we will construct 00010000 by
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// (1 << (7 - 3)) -> (1 << 4) -> 16
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if (byteUnderConsideration & (1 << (7 - bitIndexWithinByte))) {
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return node.right
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}
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return node.left
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}
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/**
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* Get a contact by its exact ID.
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* If this is a leaf, loop through the bucket contents and return the correct
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* contact if we have it or null if not. If this is an inner node, determine
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* which branch of the tree to traverse and repeat.
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*
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* @param {Uint8Array} id The ID of the contact to fetch.
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* @return {Object|Null} The contact if available, otherwise null
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*/
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this.get = function (id) {
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ensureInt8('id', id)
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let bitIndex = 0
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let node = this.root
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while (node.contacts === null) {
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node = this._determineNode(node, id, bitIndex++)
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}
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// index of uses contact id for matching
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const index = this._indexOf(node, id)
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return index >= 0 ? node.contacts[index] : null
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}
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/**
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* Returns the index of the contact with provided
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* id if it exists, returns -1 otherwise.
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*
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* @param {Object} node internal object that has 2 leafs: left and right
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* @param {Uint8Array} id Contact node id.
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* @return {Number} Integer Index of contact with provided id if it
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* exists, -1 otherwise.
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*/
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this._indexOf = function (node, id) {
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for (let i = 0; i < node.contacts.length; ++i) {
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if (arrayEquals(node.contacts[i].id, id)) return i
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}
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return -1
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}
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/**
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* Removes contact with the provided id.
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*
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* @param {Uint8Array} id The ID of the contact to remove.
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* @return {Object} The k-bucket itself.
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*/
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this.remove = function (id) {
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ensureInt8('the id as parameter 1', id)
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let bitIndex = 0
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let node = this.root
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while (node.contacts === null) {
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node = this._determineNode(node, id, bitIndex++)
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}
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const index = this._indexOf(node, id)
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if (index >= 0) {
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const contact = node.contacts.splice(index, 1)[0]
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reactor.dispatchEvent('removed', contact)
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}
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return this
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}
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/**
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* Splits the node, redistributes contacts to the new nodes, and marks the
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* node that was split as an inner node of the binary tree of nodes by
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* setting this.root.contacts = null
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*
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* @param {Object} node node for splitting
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* @param {Number} bitIndex the bitIndex to which byte to check in the
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* Uint8Array for navigating the binary tree
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*/
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this._split = function (node, bitIndex) {
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node.left = createNode()
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node.right = createNode()
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// redistribute existing contacts amongst the two newly created nodes
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for (const contact of node.contacts) {
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this._determineNode(node, contact.id, bitIndex).contacts.push(contact)
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}
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node.contacts = null // mark as inner tree node
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// don't split the "far away" node
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// we check where the local node would end up and mark the other one as
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// "dontSplit" (i.e. "far away")
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const detNode = this._determineNode(node, this.localNodeId, bitIndex)
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const otherNode = node.left === detNode ? node.right : node.left
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otherNode.dontSplit = true
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}
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/**
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* Returns all the contacts contained in the tree as an array.
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* If this is a leaf, return a copy of the bucket. `slice` is used so that we
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* don't accidentally leak an internal reference out that might be
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* accidentally misused. If this is not a leaf, return the union of the low
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* and high branches (themselves also as arrays).
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*
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* @return {Array} All of the contacts in the tree, as an array
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*/
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this.toArray = function () {
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let result = []
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for (const nodes = [this.root]; nodes.length > 0;) {
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const node = nodes.pop()
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if (node.contacts === null) nodes.push(node.right, node.left)
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else result = result.concat(node.contacts)
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}
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return result
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}
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/**
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* Updates the contact selected by the arbiter.
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* If the selection is our old contact and the candidate is some new contact
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* then the new contact is abandoned (not added).
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* If the selection is our old contact and the candidate is our old contact
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* then we are refreshing the contact and it is marked as most recently
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* contacted (by being moved to the right/end of the bucket array).
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* If the selection is our new contact, the old contact is removed and the new
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* contact is marked as most recently contacted.
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*
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* @param {Object} node internal object that has 2 leafs: left and right
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* @param {Number} index the index in the bucket where contact exists
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* (index has already been computed in a previous
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* calculation)
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* @param {Object} contact The contact object to update.
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*/
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this._update = function (node, index, contact) {
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// sanity check
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if (!arrayEquals(node.contacts[index].id, contact.id)) {
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throw new Error('wrong index for _update')
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}
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const incumbent = node.contacts[index]
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/***************Change made by Abhishek*************/
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const selection = this.arbiter(incumbent, contact)
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//const selection = localbitcoinplusplus.kademlia.arbiter(incumbent, contact);
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// if the selection is our old contact and the candidate is some new
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// contact, then there is nothing to do
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if (selection === incumbent && incumbent !== contact) return
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node.contacts.splice(index, 1) // remove old contact
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node.contacts.push(selection) // add more recent contact version
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/***************Change made by Abhishek*************/
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reactor.dispatchEvent('updated', {
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...incumbent,
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...selection
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})
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//reactor.dispatchEvent('updated', incumbent.concat(selection))
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}
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}
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kBucketObj = {
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decodeBase58Address: function (blockchain, address) {
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let k = bitjs.Base58.decode(address)
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k.shift()
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k.splice(-4, 4)
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return Crypto.util.bytesToHex(k)
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},
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launchKBucket: function() {
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return new Promise((resolve, reject)=>{
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try {
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//const master_flo_pubKey = localbitcoinplusplus.master_configurations.masterFLOPubKey;
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const master_flo_addr = adminID;
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const SuKBucketId = this.floIdToKbucketId(crypto, master_flo_addr);
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const SukbOptions = { localNodeId: SuKBucketId }
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supernodeKBucket = new BuildKBucket(SukbOptions);
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for(var i=0; i<superNodeList.length ; i++){
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this.addNewUserNodeInKbucket(crypto,superNodeList[i],supernodeKBucket)
|
|
}
|
|
resolve('SuperNode KBucket formed');
|
|
} catch (error) {
|
|
reject(error);
|
|
}
|
|
});
|
|
},
|
|
launchSupernodesKBucket: function() {
|
|
|
|
localbitcoinplusplus.master_configurations.supernodesPubKeys.map(pubKey=>{
|
|
return new Promise((resolve, reject)=>{
|
|
try {
|
|
let flo_id = bitjs.pubkey2address(pubKey);
|
|
let kname = `SKBucket_${pubKey}`;
|
|
const KBucketId = this.floIdToKbucketId(crypto, flo_id)
|
|
const kbOptions = { localNodeId: KBucketId }
|
|
window[kname] = new BuildKBucket(kbOptions);
|
|
resolve(true);
|
|
} catch (error) {
|
|
reject(error);
|
|
}
|
|
})
|
|
})
|
|
},
|
|
addContact: function (id, floID, KB=supernodeKBucket) {
|
|
const contact = {
|
|
id: id,
|
|
floID: floID
|
|
};
|
|
KB.add(contact)
|
|
},
|
|
addNewUserNodeInKbucket: function(blockchain, address, KB=supernodeKBucket) {
|
|
let decodedId = address;
|
|
try {
|
|
decodedId = this.floIdToKbucketId(blockchain, address);
|
|
} catch(e) {
|
|
decodedId = address;
|
|
}
|
|
const addNewUserNode = this.addContact(decodedId, address, KB);
|
|
return {decodedId:decodedId, address:address};
|
|
},
|
|
floIdToKbucketId: function (blockchain, address) {
|
|
const decodedId = this.decodeBase58Address(blockchain, address);
|
|
const nodeIdBigInt = new BigInteger(decodedId, 16);
|
|
const nodeIdBytes = nodeIdBigInt.toByteArrayUnsigned();
|
|
const nodeIdNewInt8Array = new Uint8Array(nodeIdBytes);
|
|
return nodeIdNewInt8Array;
|
|
},
|
|
arbiter: function (incumbent, candidate) {
|
|
// we create a new object so that our selection is guaranteed to replace
|
|
// the incumbent
|
|
const merged = {
|
|
id: incumbent.id, // incumbent.id === candidate.id within an arbiter
|
|
data: incumbent.data
|
|
}
|
|
|
|
Object.keys(candidate.data).forEach(workerNodeId => {
|
|
merged.data[workerNodeId] = candidate.data[workerNodeId];
|
|
})
|
|
|
|
return merged;
|
|
},
|
|
newBase64DiscoverId: function (pubKey) {
|
|
let pubKeyBytes = Crypto.util.hexToBytes(pubKey);
|
|
return Crypto.util.bytesToBase64(pubKeyBytes);
|
|
},
|
|
restoreKbucket: function(flo_addr, blockchain="FLO_TEST", KB=KBucket) {
|
|
return new Promise((resolve, reject)=>{
|
|
readAllDB('kBucketStore')
|
|
.then(dbObject => {
|
|
if (typeof dbObject=="object") {
|
|
let su_flo_addr_array = localbitcoinplusplus.master_configurations.supernodesPubKeys
|
|
.map(pubk=>bitjs.pubkey2address(pubk));
|
|
// Prevent supernode to re-added in kbucket
|
|
dbObject
|
|
.filter(f=>!su_flo_addr_array.includes(f.data.id))
|
|
.map(dbObj=>{
|
|
this.addNewUserNodeInKbucket(blockchain, flo_addr, dbObj.data, KB);
|
|
});
|
|
} else {
|
|
reject(`Failed to restore kBucket.`);
|
|
}
|
|
resolve(dbObject);
|
|
});
|
|
})
|
|
},
|
|
restoreSupernodeKBucket: function() {
|
|
return new Promise((resolve, reject)=>{
|
|
const supernodeSeeds = localbitcoinplusplus.master_configurations.supernodeSeeds;
|
|
if (typeof supernodeSeeds !== "object") reject("Failed to get supernode seeds.");
|
|
let supernodeSeedsObj = JSON.parse(supernodeSeeds);
|
|
|
|
Object.entries(supernodeSeedsObj).map(seedObj=>{
|
|
let kbuck = this.addNewUserNodeInKbucket(crypto, seedObj[1].kbucketId,
|
|
{ id: seedObj[1].kbucketId }, supernodeKBucket);
|
|
});
|
|
|
|
resolve(true);
|
|
})
|
|
},
|
|
updateClosestSupernodeSeeds: function(flo_addr) {
|
|
return new Promise(async (resolve, reject) => {
|
|
await removeAllinDB('myClosestSupernodes');
|
|
let nearestSupernodeAddresslist = await this.addClosestSupernodeInDB(flo_addr);
|
|
nearestSupernodeAddresslist.map((nearestSupernodeAddress, index)=>{
|
|
updateinDB('myClosestSupernodes', {
|
|
id: index+1,
|
|
ip: nearestSupernodeAddress.ip,
|
|
port: nearestSupernodeAddress.port,
|
|
trader_flo_address: nearestSupernodeAddress.kbucketId,
|
|
is_live: null
|
|
}).then(updatedClosestSupernodes=>{
|
|
readAllDB('myClosestSupernodes').then(nearestSupernodeAddresslist=>{
|
|
showMessage(`INFO: Updated closest supernodes list successfully.`);
|
|
resolve(nearestSupernodeAddresslist);
|
|
});
|
|
});
|
|
});
|
|
});
|
|
},
|
|
getSupernodeSeed: function (flo_addr) {
|
|
return new Promise(async (resolve, reject) => {
|
|
let nearestSupernodeAddresslist = await readAllDB('myClosestSupernodes');
|
|
if (nearestSupernodeAddresslist.length<1) {
|
|
nearestSupernodeAddresslist = await this.updateClosestSupernodeSeeds(flo_addr);
|
|
}
|
|
resolve(nearestSupernodeAddresslist);
|
|
});
|
|
},
|
|
isNodePresentInMyKbucket: function(flo_id, KB=KBucket) {
|
|
return new Promise((resolve, reject)=>{
|
|
let kArray = KB.toArray();
|
|
let kArrayFloIds = kArray.map(k=>k.data.id);
|
|
if (kArrayFloIds.includes(flo_id)) {
|
|
resolve(true);
|
|
} else {
|
|
reject(false);
|
|
}
|
|
});
|
|
},
|
|
determineClosestSupernode: function(flo_addr="", n=1, KB=supernodeKBucket, su="") {
|
|
return new Promise((resolve, reject)=>{
|
|
let msg = ``;
|
|
if (typeof supernodeKBucket !== "object") {
|
|
msg = `ERROR: Supernode KBucket not found.`;
|
|
showMessage(msg);
|
|
reject(msg);
|
|
return false;
|
|
}
|
|
|
|
if (su.length>0) {
|
|
try {
|
|
let closestSupernodeMasterList = supernodeKBucket.closest(supernodeKBucket.localNodeId);
|
|
const index = closestSupernodeMasterList.findIndex(f=>f.data.id==su);
|
|
let tail = closestSupernodeMasterList.splice(0, index);
|
|
const newClosestSupernodeMasterList = closestSupernodeMasterList.concat(tail);
|
|
resolve(newClosestSupernodeMasterList);
|
|
return true;
|
|
} catch (error) {
|
|
reject(error);
|
|
}
|
|
return false;
|
|
}
|
|
|
|
try {
|
|
if(flo_addr.length < 0) {
|
|
showMessage(`WARNING: No Flo Id provided to determine closest Supenode.`);
|
|
return;
|
|
}
|
|
let isFloIdUint8 = flo_addr instanceof Uint8Array;
|
|
if (!isFloIdUint8) {
|
|
flo_addr = this.floIdToKbucketId(crypto, flo_addr);
|
|
}
|
|
const closestSupernode = supernodeKBucket.closest(flo_addr, n);
|
|
resolve(closestSupernode);
|
|
return true;
|
|
} catch (error) {
|
|
showMessage(error);
|
|
reject(error);
|
|
return false;
|
|
}
|
|
})
|
|
},
|
|
|
|
addClosestSupernodeInDB: function(flo_addr, KB=KBucket) {
|
|
return new Promise(async (resolve, reject)=>{
|
|
const supernodeSeeds = localbitcoinplusplus.master_configurations.supernodeSeeds;
|
|
if (typeof supernodeSeeds !== "object") reject("Failed to get supernode seeds.");
|
|
let supernodeSeedsObj = JSON.parse(supernodeSeeds);
|
|
|
|
Object.entries(supernodeSeedsObj).map(seedObj=>{
|
|
console.log(seedObj);
|
|
this.addNewUserNodeInKbucketAndDB(
|
|
crypto, seedObj[1].kbucketId,
|
|
{ id: seedObj[1].kbucketId });
|
|
});
|
|
|
|
let primarySu = await this.determineClosestSupernode(flo_addr);
|
|
let nearestSupernode = await this.determineClosestSupernode(flo_addr="", n=1, supernodeKBucket, primarySu[0].data.id);
|
|
let nearestSupernodeIds = nearestSupernode.map(f=>f.data.id);
|
|
let supernodeSeedsArray = Object.values(supernodeSeedsObj)
|
|
.filter(seed=>nearestSupernodeIds.includes(seed.kbucketId))
|
|
.sort(function(a, b){
|
|
return nearestSupernodeIds.indexOf(a.kbucketId) - nearestSupernodeIds.indexOf(b.kbucketId);
|
|
});
|
|
|
|
if (supernodeSeedsArray.length>0) {
|
|
resolve(supernodeSeedsArray);
|
|
} else {
|
|
reject(false);
|
|
}
|
|
})
|
|
}
|
|
}
|