import 'package:stackwallet/services/cashfusion/fusion.dart'; import 'package:pointycastle/ecc/api.dart'; import 'dart:math'; import 'dart:typed_data'; import 'dart:convert'; import 'package:crypto/crypto.dart' as crypto; import 'protocol.dart'; import 'fusion.pb.dart'; import 'dart:convert'; class Address { String addr = ""; Address({required this.addr}); // Constructor updated to accept addr as a named parameter Address._create({required this.addr}); static Address fromScriptPubKey(List scriptPubKey) { // This is just a placeholder code String addr = ""; // This should be computed from the scriptPubKey return Address(addr: addr); } // Public constructor for testing static Address fromString(String address) { return Address._create(addr: address); } List toScript() { return []; } } class Tuple { T1 item1; T2 item2; Tuple(this.item1, this.item2); set setItem1(T1 value) { this.item1 = value; } set setItem2(T2 value) { this.item2 = value; } } class Util { static Uint8List hexToBytes(String hex) { var result = new Uint8List(hex.length ~/ 2); for (var i = 0; i < hex.length; i += 2) { var byte = int.parse(hex.substring(i, i + 2), radix: 16); result[i ~/ 2] = byte; } return result; } static void checkInputElectrumX(InputComponent inputComponent) { // Implementation needed here // } static int randPosition(Uint8List seed, int numPositions, int counter) { // counter to bytes var counterBytes = Uint8List(4); var counterByteData = ByteData.sublistView(counterBytes); counterByteData.setInt32(0, counter, Endian.big); // hash the seed and counter var digest = crypto.sha256.convert([...seed, ...counterBytes]); // take the first 8 bytes var first8Bytes = digest.bytes.take(8).toList(); var int64 = ByteData.sublistView(Uint8List.fromList(first8Bytes)).getUint64(0, Endian.big); // perform the modulo operation return ((int64 * numPositions) >> 64).toInt(); } static List pubkeysFromPrivkey(String privkey) { // This is a placeholder implementation. return ['public_key1_dummy', 'public_key2_dummy']; } static int dustLimit(int length) { // This is a dummy implementation. return 500; } static Address getAddressFromOutputScript(Uint8List scriptpubkey) { // Dummy implementation... // Throw exception if this is not a standard P2PKH address! return Address.fromString('dummy_address'); } static bool schnorrVerify(ECPoint pubkey, List signature, Uint8List messageHash) { // Implementation needed: actual Schnorr signature verification return true; } static String formatSatoshis(sats, {int numZeros=8}) { // To implement return ""; } static void updateWalletLabel(String txid, String label) { // Call the wallet layer. } static Uint8List getRandomBytes(int length) { final rand = Random.secure(); final bytes = Uint8List(length); for (int i = 0; i < length; i++) { bytes[i] = rand.nextInt(256); } return bytes; } static List> zip(List list1, List list2) { int length = min(list1.length, list2.length); return List>.generate(length, (i) => [list1[i], list2[i]]); } static List calcInitialHash(int tier, Uint8List covertDomainB, int covertPort, bool covertSsl, double beginTime) { // Converting int to bytes in BigEndian order var tierBytes = ByteData(8)..setInt64(0, tier, Endian.big); var covertPortBytes = ByteData(4)..setInt32(0, covertPort, Endian.big); var beginTimeBytes = ByteData(8)..setInt64(0, beginTime.toInt(), Endian.big); // Define constants const version = Protocol.VERSION; const cashFusionSession = "Cash Fusion Session"; // Creating the list of bytes List elements = []; elements.addAll(utf8.encode(cashFusionSession)); elements.addAll(utf8.encode(version)); elements.addAll(tierBytes.buffer.asInt8List()); elements.addAll(covertDomainB); elements.addAll(covertPortBytes.buffer.asInt8List()); elements.add(covertSsl ? 1 : 0); elements.addAll(beginTimeBytes.buffer.asInt8List()); // Hashing the concatenated elements var digest = crypto.sha256.convert(elements); return digest.bytes; } static List calcRoundHash(List lastHash, List roundPubkey, int roundTime, List> allCommitments, List> allComponents) { return listHash([ utf8.encode('Cash Fusion Round'), lastHash, roundPubkey, bigIntToBytes(BigInt.from(roundTime)), listHash(allCommitments), listHash(allComponents), ]); } static List listHash(Iterable> iterable) { var bytes = []; for (var x in iterable) { var length = ByteData(4)..setUint32(0, x.length, Endian.big); bytes.addAll(length.buffer.asUint8List()); bytes.addAll(x); } return crypto.sha256.convert(bytes).bytes; } static Uint8List get_current_genesis_hash() { var GENESIS = "000000000019d6689c085ae165831e934ff763ae46a2a6c172b3f1b60a8ce26f"; var _lastGenesisHash = hexToBytes(GENESIS).reversed.toList(); return Uint8List.fromList(_lastGenesisHash); } static List
unreserve_change_address(Address addr) { //implement later based on wallet. return []; } static List
reserve_change_addresses(int number_addresses) { //implement later based on wallet. return []; } static bool walletHasTransaction(String txid) { // implement later based on wallet. return true; } static Uint8List bigIntToBytes(BigInt bigInt) { return Uint8List.fromList(bigInt.toRadixString(16).padLeft(32, '0').codeUnits); } static Tuple genKeypair() { var params = ECDomainParameters('secp256k1'); var privKeyBigInt = _generatePrivateKey(params.n.bitLength); var pubKeyPoint = params.G * privKeyBigInt; if (pubKeyPoint == null) { throw Exception("Error generating public key."); } Uint8List privKey = bigIntToBytes(privKeyBigInt); Uint8List pubKey = pubKeyPoint.getEncoded(true); return Tuple(privKey, pubKey); } // Generates a cryptographically secure private key static BigInt _generatePrivateKey(int bitLength) { final random = Random.secure(); var bytes = bitLength ~/ 8; // floor division var remBit = bitLength % 8; // Generate random BigInt List rnd = List.generate(bytes, (_) => random.nextInt(256)); var rndBit = random.nextInt(1 << remBit); rnd.add(rndBit); var privateKey = BigInt.parse(rnd.map((x) => x.toRadixString(16).padLeft(2, '0')).join(), radix: 16); return privateKey; } // Additional helper function to convert bytes to hex static String bytesToHex(Uint8List bytes) { return bytes.map((byte) => byte.toRadixString(16).padLeft(2, '0')).join(); } static BigInt bytesToBigInt(Uint8List bytes) { String hexString = bytesToHex(bytes); return BigInt.parse(hexString, radix: 16); } static Uint8List sha256(Uint8List bytes) { crypto.Digest digest = crypto.sha256.convert(bytes); return Uint8List.fromList(digest.bytes); } static Uint8List tokenBytes([int nbytes = 32]) { final Random _random = Random.secure(); return Uint8List.fromList(List.generate(nbytes, (i) => _random.nextInt(256))); } static int componentFee(int size, int feerate) { // feerate in sat/kB // size and feerate should both be integer // fee is always rounded up return ((size * feerate) + 999) ~/ 1000; } static ECPoint ser_to_point(Uint8List serializedPoint, ECDomainParameters params) { var point = params.curve.decodePoint(serializedPoint); if (point == null) { throw FormatException('Point decoding failed'); } return point; } static Uint8List point_to_ser(ECPoint point, bool compress) { return point.getEncoded(compress); } static BigInt secureRandomBigInt(int bitLength) { final random = Random.secure(); final bytes = (bitLength + 7) ~/ 8; // ceil division final Uint8List randomBytes = Uint8List(bytes); for (int i = 0; i < bytes; i++) { randomBytes[i] = random.nextInt(256); } BigInt randomNumber = BigInt.parse(randomBytes.map((e) => e.toRadixString(16).padLeft(2, '0')).join(), radix: 16); return randomNumber; } static ECPoint combinePubKeys(List pubKeys) { if (pubKeys.isEmpty) throw ArgumentError('pubKeys cannot be empty'); ECPoint combined = pubKeys.first.curve.infinity!; for (var pubKey in pubKeys) { combined = (combined + pubKey)!; } if (combined.isInfinity) { throw Exception('Combined point is at infinity'); } return combined; } static bool isPointOnCurve(ECPoint point, ECCurve curve) { var x = point.x!.toBigInteger()!; var y = point.y!.toBigInteger()!; var a = curve.a!.toBigInteger()!; var b = curve.b!.toBigInteger()!; // Calculate the left and right sides of the equation var left = y * y; var right = (x * x * x) + (a * x) + b; // Check if the point is on the curve return left == right; } } // END OF CLASS