/* global describe, it */ var assert = require('assert') var base58 = require('bs58') var base58check = require('bs58check') var Bitcoin = require('../') var Address = Bitcoin.Address var Block = Bitcoin.Block var ECKey = Bitcoin.ECKey var ECSignature = Bitcoin.ECSignature var Transaction = Bitcoin.Transaction var Script = Bitcoin.Script var networks = Bitcoin.networks var base58_encode_decode = require('./fixtures/core/base58_encode_decode.json') var base58_keys_invalid = require('./fixtures/core/base58_keys_invalid.json') var base58_keys_valid = require('./fixtures/core/base58_keys_valid.json') var blocks_valid = require('./fixtures/core/blocks.json') var sig_canonical = require('./fixtures/core/sig_canonical.json') var sig_noncanonical = require('./fixtures/core/sig_noncanonical.json') var sighash = require('./fixtures/core/sighash.json') var tx_valid = require('./fixtures/core/tx_valid.json') describe('Bitcoin-core', function () { // base58_encode_decode describe('base58', function () { base58_encode_decode.forEach(function (f) { var fhex = f[0] var fb58 = f[1] it('can decode ' + fb58, function () { var buffer = base58.decode(fb58) var actual = new Buffer(buffer).toString('hex') assert.equal(actual, fhex) }) it('can encode ' + fhex, function () { var buffer = new Buffer(fhex, 'hex') var actual = base58.encode(buffer) assert.equal(actual, fb58) }) }) }) // base58_keys_valid describe('Address', function () { var typeMap = { 'pubkey': 'pubKeyHash', 'script': 'scriptHash' } base58_keys_valid.forEach(function (f) { var string = f[0] var hex = f[1] var params = f[2] var network = networks.bitcoin if (params.isPrivkey) return if (params.isTestnet) network = networks.testnet it('can import ' + string, function () { var address = Address.fromBase58Check(string) assert.equal(address.hash.toString('hex'), hex) assert.equal(address.version, network[typeMap[params.addrType]]) }) }) }) // base58_keys_invalid describe('Address', function () { var allowedNetworks = [ networks.bitcoin.pubkeyhash, networks.bitcoin.scripthash, networks.testnet.pubkeyhash, networks.testnet.scripthash ] base58_keys_invalid.forEach(function (f) { var string = f[0] it('throws on ' + string, function () { assert.throws(function () { var address = Address.fromBase58Check(string) assert.notEqual(allowedNetworks.indexOf(address.version), -1, 'Invalid network') }, /Invalid (checksum|hash length|network)/) }) }) }) // base58_keys_valid describe('ECKey', function () { base58_keys_valid.forEach(function (f) { var string = f[0] var hex = f[1] var params = f[2] var network = params.isTestnet ? networks.testnet : networks.bitcoin if (!params.isPrivkey) return var privKey = ECKey.fromWIF(string) it('imports ' + string + ' correctly', function () { assert.equal(privKey.d.toHex(), hex) assert.equal(privKey.pub.compressed, params.isCompressed) }) it('exports ' + hex + ' to ' + string, function () { assert.equal(privKey.toWIF(network), string) }) }) }) // base58_keys_invalid describe('ECKey', function () { var allowedNetworks = [ networks.bitcoin.wif, networks.testnet.wif ] base58_keys_invalid.forEach(function (f) { var string = f[0] it('throws on ' + string, function () { assert.throws(function () { ECKey.fromWIF(string) var version = base58check.decode(string).readUInt8(0) assert.notEqual(allowedNetworks.indexOf(version), -1, 'Invalid network') }, /Invalid (checksum|compression flag|network|WIF payload)/) }) }) }) describe('Block', function () { blocks_valid.forEach(function (f) { it('fromHex can parse ' + f.id, function () { var block = Block.fromHex(f.hex) assert.equal(block.getId(), f.id) assert.equal(block.transactions.length, f.transactions) }) }) }) // tx_valid describe('Transaction', function () { tx_valid.forEach(function (f) { // Objects that are only a single string are ignored if (f.length === 1) return var inputs = f[0] var fhex = f[1] // var verifyFlags = f[2] // TODO: do we need to test this? it('can decode ' + fhex, function () { var transaction = Transaction.fromHex(fhex) transaction.ins.forEach(function (txin, i) { var input = inputs[i] var prevOutHash = input[0] var prevOutIndex = input[1] // var prevOutScriptPubKey = input[2] // TODO: we don't have a ASM parser var actualHash = txin.hash // Test data is big-endian Array.prototype.reverse.call(actualHash) assert.equal(actualHash.toString('hex'), prevOutHash) // we read UInt32, not Int32 assert.equal(txin.index & 0xffffffff, prevOutIndex) }) }) }) }) // sighash describe('Transaction', function () { sighash.forEach(function (f) { // Objects that are only a single string are ignored if (f.length === 1) return var txHex = f[0] var scriptHex = f[1] var inIndex = f[2] var hashType = f[3] var expectedHash = f[4] it('should hash ' + txHex + ' correctly', function () { var transaction = Transaction.fromHex(txHex) assert.equal(transaction.toHex(), txHex) var script = Script.fromHex(scriptHex) assert.equal(script.toHex(), scriptHex) var actualHash try { actualHash = transaction.hashForSignature(inIndex, script, hashType) } catch (e) { // don't fail if we don't support it yet, TODO if (!e.message.match(/not yet supported/)) throw e } if (actualHash !== undefined) { // Test data is big-endian Array.prototype.reverse.call(actualHash) assert.equal(actualHash.toString('hex'), expectedHash) } }) }) }) describe('ECSignature', function () { sig_canonical.forEach(function (hex) { var buffer = new Buffer(hex, 'hex') it('can parse ' + hex, function () { var parsed = ECSignature.parseScriptSignature(buffer) var actual = parsed.signature.toScriptSignature(parsed.hashType) assert.equal(actual.toString('hex'), hex) }) }) sig_noncanonical.forEach(function (hex, i) { if (i === 0) return if (i % 2 !== 0) return var description = sig_noncanonical[i - 1].slice(0, -1) if (description === 'too long') return // we support non secp256k1 signatures var buffer = new Buffer(hex, 'hex') it('throws on ' + description, function () { assert.throws(function () { ECSignature.parseScriptSignature(buffer) }) }) }) }) })