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blockchain.js
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blockchain.js
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const crypto = require('crypto');
const EC = require('elliptic').ec;
const ec = new EC('secp256k1');
class Transaction {
/**
* @param {string} fromAddress
* @param {string} toAddress
* @param {number} amount
*/
constructor(fromAddress, toAddress, amount) {
this.fromAddress = fromAddress;
this.toAddress = toAddress;
this.amount = amount;
this.timestamp = Date.now();
}
/**
* Creates a SHA256 hash of the transaction
*
* @returns {string}
*/
calculateHash() {
return crypto.createHash('sha256').update(this.fromAddress + this.toAddress + this.amount + this.timestamp).digest('hex');
}
/**
* Signs a transaction with the given signingKey (which is an Elliptic keypair
* object that contains a private key). The signature is then stored inside the
* transaction object and later stored on the blockchain.
*
* @param {string} signingKey
*/
signTransaction(signingKey) {
// You can only send a transaction from the wallet that is linked to your
// key. So here we check if the fromAddress matches your publicKey
if (signingKey.getPublic('hex') !== this.fromAddress) {
throw new Error('You cannot sign transactions for other wallets!');
}
// Calculate the hash of this transaction, sign it with the key
// and store it inside the transaction obect
const hashTx = this.calculateHash();
const sig = signingKey.sign(hashTx, 'base64');
this.signature = sig.toDER('hex');
}
/**
* Checks if the signature is valid (transaction has not been tampered with).
* It uses the fromAddress as the public key.
*
* @returns {boolean}
*/
isValid() {
// If the transaction doesn't have a from address we assume it's a
// mining reward and that it's valid. You could verify this in a
// different way (special field for instance)
if (this.fromAddress === null) return true;
if (!this.signature || this.signature.length === 0) {
throw new Error('No signature in this transaction');
}
const publicKey = ec.keyFromPublic(this.fromAddress, 'hex');
return publicKey.verify(this.calculateHash(), this.signature);
}
}
class Block {
/**
* @param {number} timestamp
* @param {Transaction[]} transactions
* @param {string} previousHash
*/
constructor(timestamp, transactions, previousHash = '') {
this.previousHash = previousHash;
this.timestamp = timestamp;
this.transactions = transactions;
this.nonce = 0;
this.hash = this.calculateHash();
}
/**
* Returns the SHA256 of this block (by processing all the data stored
* inside this block)
*
* @returns {string}
*/
calculateHash() {
return crypto.createHash('sha256').update(this.previousHash + this.timestamp + JSON.stringify(this.transactions) + this.nonce).digest('hex');
}
/**
* Starts the mining process on the block. It changes the 'nonce' until the hash
* of the block starts with enough zeros (= difficulty)
*
* @param {number} difficulty
*/
mineBlock(difficulty) {
while (this.hash.substring(0, difficulty) !== Array(difficulty + 1).join('0')) {
this.nonce++;
this.hash = this.calculateHash();
}
}
/**
* Validates all the transactions inside this block (signature + hash) and
* returns true if everything checks out. False if the block is invalid.
*
* @returns {boolean}
*/
hasValidTransactions() {
for (const tx of this.transactions) {
if (!tx.isValid()) {
return false;
}
}
return true;
}
}
class Blockchain {
constructor() {
this.chain = [this.createGenesisBlock()];
this.difficulty = 2;
this.pendingTransactions = [];
this.miningReward = 100;
}
/**
* @returns {Block}
*/
createGenesisBlock() {
return new Block(Date.parse('2017-01-01'), [], '0');
}
/**
* Returns the latest block on our chain. Useful when you want to create a
* new Block and you need the hash of the previous Block.
*
* @returns {Block[]}
*/
getLatestBlock() {
return this.chain[this.chain.length - 1];
}
/**
* Takes all the pending transactions, puts them in a Block and starts the
* mining process. It also adds a transaction to send the mining reward to
* the given address.
*
* @param {string} miningRewardAddress
*/
minePendingTransactions(miningRewardAddress) {
const rewardTx = new Transaction(null, miningRewardAddress, this.miningReward);
this.pendingTransactions.push(rewardTx);
const block = new Block(Date.now(), this.pendingTransactions, this.getLatestBlock().hash);
block.mineBlock(this.difficulty);
this.chain.push(block);
this.pendingTransactions = [];
}
/**
* Add a new transaction to the list of pending transactions (to be added
* next time the mining process starts). This verifies that the given
* transaction is properly signed.
*
* @param {Transaction} transaction
*/
addTransaction(transaction) {
if (!transaction.fromAddress || !transaction.toAddress) {
throw new Error('Transaction must include from and to address');
}
// Verify the transactiion
if (!transaction.isValid()) {
throw new Error('Cannot add invalid transaction to chain');
}
if (transaction.amount <= 0) {
throw new Error('Transaction amount should be higher than 0');
}
// Making sure that the amount sent is not greater than existing balance
if (this.getBalanceOfAddress(transaction.fromAddress) < transaction.amount) {
throw new Error('Not enough balance');
}
this.pendingTransactions.push(transaction);
}
/**
* Returns the balance of a given wallet address.
*
* @param {string} address
* @returns {number} The balance of the wallet
*/
getBalanceOfAddress(address) {
let balance = 0;
for (const block of this.chain) {
for (const trans of block.transactions) {
if (trans.fromAddress === address) {
balance -= trans.amount;
}
if (trans.toAddress === address) {
balance += trans.amount;
}
}
}
return balance;
}
/**
* Returns a list of all transactions that happened
* to and from the given wallet address.
*
* @param {string} address
* @return {Transaction[]}
*/
getAllTransactionsForWallet(address) {
const txs = [];
for (const block of this.chain) {
for (const tx of block.transactions) {
if (tx.fromAddress === address || tx.toAddress === address) {
txs.push(tx);
}
}
}
return txs;
}
/**
* Loops over all the blocks in the chain and verify if they are properly
* linked together and nobody has tampered with the hashes. By checking
* the blocks it also verifies the (signed) transactions inside of them.
*
* @returns {boolean}
*/
isChainValid() {
// Check if the Genesis block hasn't been tampered with by comparing
// the output of createGenesisBlock with the first block on our chain
const realGenesis = JSON.stringify(this.createGenesisBlock());
if (realGenesis !== JSON.stringify(this.chain[0])) {
return false;
}
// Check the remaining blocks on the chain to see if there hashes and
// signatures are correct
for (let i = 1; i < this.chain.length; i++) {
const currentBlock = this.chain[i];
if (!currentBlock.hasValidTransactions()) {
return false;
}
if (currentBlock.hash !== currentBlock.calculateHash()) {
return false;
}
}
return true;
}
}
module.exports.Blockchain = Blockchain;
module.exports.Block = Block;
module.exports.Transaction = Transaction;