use util::*; use basic_types::*; use error::*; use evm::Schedule; #[derive(Debug, Clone)] /// TODO [Gav Wood] Please document me pub enum Action { /// TODO [Gav Wood] Please document me Create, /// TODO [debris] Please document me Call(Address), } impl Default for Action { fn default() -> Action { Action::Create } } /// A set of information describing an externally-originating message call /// or contract creation operation. #[derive(Default, Debug, Clone)] pub struct Transaction { /// TODO [debris] Please document me pub nonce: U256, /// TODO [debris] Please document me pub gas_price: U256, /// TODO [debris] Please document me pub gas: U256, /// TODO [debris] Please document me pub action: Action, /// TODO [debris] Please document me pub value: U256, /// TODO [Gav Wood] Please document me pub data: Bytes, // signature /// TODO [Gav Wood] Please document me pub v: u8, /// TODO [Gav Wood] Please document me pub r: U256, /// TODO [debris] Please document me pub s: U256, hash: RefCell>, sender: RefCell>, } impl Transaction { /// TODO [Gav Wood] Please document me pub fn new() -> Self { Transaction { nonce: x!(0), gas_price: x!(0), gas: x!(0), action: Action::Create, value: x!(0), data: vec![], v: 0, r: x!(0), s: x!(0), hash: RefCell::new(None), sender: RefCell::new(None), } } /// Create a new message-call transaction. pub fn new_call(to: Address, value: U256, data: Bytes, gas: U256, gas_price: U256, nonce: U256) -> Transaction { Transaction { nonce: nonce, gas_price: gas_price, gas: gas, action: Action::Call(to), value: value, data: data, v: 0, r: x!(0), s: x!(0), hash: RefCell::new(None), sender: RefCell::new(None), } } /// Create a new contract-creation transaction. pub fn new_create(value: U256, data: Bytes, gas: U256, gas_price: U256, nonce: U256) -> Transaction { Transaction { nonce: nonce, gas_price: gas_price, gas: gas, action: Action::Create, value: value, data: data, v: 0, r: x!(0), s: x!(0), hash: RefCell::new(None), sender: RefCell::new(None), } } /// Get the nonce of the transaction. pub fn nonce(&self) -> &U256 { &self.nonce } /// Get the gas price of the transaction. pub fn gas_price(&self) -> &U256 { &self.gas_price } /// Get the gas of the transaction. pub fn gas(&self) -> &U256 { &self.gas } /// Get the action of the transaction (Create or Call). pub fn action(&self) -> &Action { &self.action } /// Get the value of the transaction. pub fn value(&self) -> &U256 { &self.value } /// Get the data of the transaction. pub fn data(&self) -> &Bytes { &self.data } /// Append object into RLP stream, optionally with or without the signature. pub fn rlp_append_opt(&self, s: &mut RlpStream, with_seal: Seal) { s.append_list(6 + match with_seal { Seal::With => 3, _ => 0 }); s.append(&self.nonce); s.append(&self.gas_price); s.append(&self.gas); match self.action { Action::Create => s.append_empty_data(), Action::Call(ref to) => s.append(to), }; s.append(&self.value); s.append(&self.data); if let Seal::With = with_seal { s.append(&(self.v as u16)).append(&self.r).append(&self.s); } } /// Get the RLP serialisation of the object, optionally with or without the signature. pub fn rlp_bytes_opt(&self, with_seal: Seal) -> Bytes { let mut s = RlpStream::new(); self.rlp_append_opt(&mut s, with_seal); s.out() } } impl FromJson for Transaction { fn from_json(json: &Json) -> Transaction { let mut r = Transaction { nonce: xjson!(&json["nonce"]), gas_price: xjson!(&json["gasPrice"]), gas: xjson!(&json["gasLimit"]), action: match Bytes::from_json(&json["to"]) { ref x if x.is_empty() => Action::Create, ref x => Action::Call(Address::from_slice(x)), }, value: xjson!(&json["value"]), data: xjson!(&json["data"]), v: match json.find("v") { Some(ref j) => u16::from_json(j) as u8, None => 0 }, r: match json.find("r") { Some(j) => xjson!(j), None => x!(0) }, s: match json.find("s") { Some(j) => xjson!(j), None => x!(0) }, hash: RefCell::new(None), sender: match json.find("sender") { Some(&Json::String(ref sender)) => RefCell::new(Some(address_from_hex(clean(sender)))), _ => RefCell::new(None), }, }; if let Some(&Json::String(ref secret_key)) = json.find("secretKey") { r.sign(&h256_from_hex(clean(secret_key))); } r } } impl RlpStandard for Transaction { fn rlp_append(&self, s: &mut RlpStream) { self.rlp_append_opt(s, Seal::With) } } impl Transaction { /// Get the hash of this header (sha3 of the RLP). pub fn hash(&self) -> H256 { let mut hash = self.hash.borrow_mut(); match &mut *hash { &mut Some(ref h) => h.clone(), hash @ &mut None => { *hash = Some(self.rlp_sha3()); hash.as_ref().unwrap().clone() } } } /// Note that some fields have changed. Resets the memoised hash. pub fn note_dirty(&self) { *self.hash.borrow_mut() = None; } /// 0 is `v` is 27, 1 if 28, and 4 otherwise. pub fn standard_v(&self) -> u8 { match self.v { 27 => 0, 28 => 1, _ => 4 } } /// Construct a signature object from the sig. pub fn signature(&self) -> Signature { Signature::from_rsv(&From::from(&self.r), &From::from(&self.s), self.standard_v()) } /// The message hash of the transaction. pub fn message_hash(&self) -> H256 { self.rlp_bytes_opt(Seal::Without).sha3() } /// Returns transaction sender. pub fn sender(&self) -> Result { let mut sender = self.sender.borrow_mut(); match &mut *sender { &mut Some(ref h) => Ok(h.clone()), sender @ &mut None => { *sender = Some(From::from(try!(ec::recover(&self.signature(), &self.message_hash())).sha3())); Ok(sender.as_ref().unwrap().clone()) } } } /// Signs the transaction as coming from `sender`. pub fn sign(&mut self, secret: &Secret) { // TODO: make always low. let sig = ec::sign(secret, &self.message_hash()); let (r, s, v) = sig.unwrap().to_rsv(); self.r = r; self.s = s; self.v = v + 27; } /// Signs the transaction as coming from `sender`. pub fn signed(self, secret: &Secret) -> Transaction { let mut r = self; r.sign(secret); r } /// Get the transaction cost in gas for the given params. pub fn gas_required_for(is_create: bool, data: &[u8], schedule: &Schedule) -> u64 { data.iter().fold( (if is_create {schedule.tx_create_gas} else {schedule.tx_gas}) as u64, |g, b| g + (match *b { 0 => schedule.tx_data_zero_gas, _ => schedule.tx_data_non_zero_gas }) as u64 ) } /// Get the transaction cost in gas for this transaction. pub fn gas_required(&self, schedule: &Schedule) -> u64 { Self::gas_required_for(match self.action{Action::Create=>true, Action::Call(_)=>false}, &self.data, schedule) } /// Checks whether the signature has a low 's' value. pub fn check_low_s(&self) -> Result<(), Error> { if !ec::is_low_s(&self.s) { Err(Error::Util(UtilError::Crypto(CryptoError::InvalidSignature))) } else { Ok(()) } } /// Do basic validation, checking for valid signature and minimum gas, pub fn validate(self, schedule: &Schedule, require_low: bool) -> Result { if require_low && !ec::is_low_s(&self.s) { return Err(Error::Util(UtilError::Crypto(CryptoError::InvalidSignature))); } try!(self.sender()); if self.gas < U256::from(self.gas_required(&schedule)) { Err(From::from(TransactionError::InvalidGasLimit(OutOfBounds{min: Some(U256::from(self.gas_required(&schedule))), max: None, found: self.gas}))) } else { Ok(self) } } } impl Decodable for Action { fn decode(decoder: &D) -> Result where D: Decoder { let rlp = decoder.as_rlp(); if rlp.is_empty() { Ok(Action::Create) } else { Ok(Action::Call(try!(rlp.as_val()))) } } } impl Decodable for Transaction { fn decode(decoder: &D) -> Result where D: Decoder { let d = try!(decoder.as_list()); if d.len() != 9 { return Err(DecoderError::RlpIncorrectListLen); } Ok(Transaction { nonce: try!(Decodable::decode(&d[0])), gas_price: try!(Decodable::decode(&d[1])), gas: try!(Decodable::decode(&d[2])), action: try!(Decodable::decode(&d[3])), value: try!(Decodable::decode(&d[4])), data: try!(Decodable::decode(&d[5])), v: try!(u16::decode(&d[6])) as u8, r: try!(Decodable::decode(&d[7])), s: try!(Decodable::decode(&d[8])), hash: RefCell::new(None), sender: RefCell::new(None), }) } } #[test] fn sender_test() { let t: Transaction = decode(&FromHex::from_hex("f85f800182520894095e7baea6a6c7c4c2dfeb977efac326af552d870a801ba048b55bfa915ac795c431978d8a6a992b628d557da5ff759b307d495a36649353a0efffd310ac743f371de3b9f7f9cb56c0b28ad43601b4ab949f53faa07bd2c804").unwrap()); assert_eq!(t.data, b""); assert_eq!(t.gas, U256::from(0x5208u64)); assert_eq!(t.gas_price, U256::from(0x01u64)); assert_eq!(t.nonce, U256::from(0x00u64)); if let Action::Call(ref to) = t.action { assert_eq!(*to, address_from_hex("095e7baea6a6c7c4c2dfeb977efac326af552d87")); } else { panic!(); } assert_eq!(t.value, U256::from(0x0au64)); assert_eq!(t.sender().unwrap(), address_from_hex("0f65fe9276bc9a24ae7083ae28e2660ef72df99e")); } #[test] fn signing() { let key = KeyPair::create().unwrap(); let t = Transaction::new_create(U256::from(42u64), b"Hello!".to_vec(), U256::from(3000u64), U256::from(50_000u64), U256::from(1u64)).signed(&key.secret()); assert_eq!(Address::from(key.public().sha3()), t.sender().unwrap()); }