// Rust Bitcoin Library // Written in 2014 by // Andrew Poelstra // // To the extent possible under law, the author(s) have dedicated all // copyright and related and neighboring rights to this software to // the public domain worldwide. This software is distributed without // any warranty. // // You should have received a copy of the CC0 Public Domain Dedication // along with this software. // If not, see . // //! # Bitcoin Transaction //! //! A transaction describes a transfer of money. It consumes previously-unspent //! transaction outputs and produces new ones, satisfying the condition to spend //! the old outputs (typically a digital signature with a specific key must be //! provided) and defining the condition to spend the new ones. The use of digital //! signatures ensures that coins cannot be spent by unauthorized parties. //! //! This module provides the structures and functions needed to support transactions. //! use std::io::IoResult; use util::hash::Sha256dHash; use network::serialize::{Serializable, SerializeIter}; use blockdata::script::Script; #[cfg(test)] use util::misc::hex_bytes; /// A transaction input, which defines old coins to be consumed #[deriving(Clone, PartialEq, Show)] pub struct TxIn { /// The hash of the transaction whose output is being used an an input pub prev_hash: Sha256dHash, /// The index of the output in the previous transaction, which may have several pub prev_index: u32, /// The script which pushes values on the stack which will cause /// the referenced output's script to accept pub script_sig: Script, /// The sequence number, which suggests to miners which of two /// conflicting transactions should be preferred, or 0xFFFFFFFF /// to ignore this feature. This is generally never used since /// the miner behaviour cannot be enforced. pub sequence: u32, } /// A transaction output, which defines new coins to be created from old ones. #[deriving(Clone, PartialEq, Show)] pub struct TxOut { /// The value of the output, in satoshis pub value: u64, /// The script which must satisfy for the output to be spent pub script_pubkey: Script } /// A Bitcoin transaction, which describes an authenticated movement of coins #[deriving(Clone, PartialEq, Show)] pub struct Transaction { /// The protocol version, should always be 1. pub version: u32, /// Block number before which this transaction is valid, or 0 for /// valid immediately. pub lock_time: u32, /// List of inputs pub input: Vec, /// List of outputs pub output: Vec } impl_serializable!(TxIn, prev_hash, prev_index, script_sig, sequence) impl_json!(TxIn, prev_hash, prev_index, script_sig, sequence) impl_serializable!(TxOut, value, script_pubkey) impl_json!(TxOut, value, script_pubkey) impl_serializable!(Transaction, version, input, output, lock_time) impl_json!(Transaction, version, input, output, lock_time) #[test] fn test_txin() { let txin: IoResult = Serializable::deserialize(hex_bytes("a15d57094aa7a21a28cb20b59aab8fc7d1149a3bdbcddba9c622e4f5f6a99ece010000006c493046022100f93bb0e7d8db7bd46e40132d1f8242026e045f03a0efe71bbb8e3f475e970d790221009337cd7f1f929f00cc6ff01f03729b069a7c21b59b1736ddfee5db5946c5da8c0121033b9b137ee87d5a812d6f506efdd37f0affa7ffc310711c06c7f3e097c9447c52ffffffff").unwrap().iter().map(|n| *n)); assert!(txin.is_ok()); } #[test] fn test_transaction() { let hex_tx = hex_bytes("0100000001a15d57094aa7a21a28cb20b59aab8fc7d1149a3bdbcddba9c622e4f5f6a99ece010000006c493046022100f93bb0e7d8db7bd46e40132d1f8242026e045f03a0efe71bbb8e3f475e970d790221009337cd7f1f929f00cc6ff01f03729b069a7c21b59b1736ddfee5db5946c5da8c0121033b9b137ee87d5a812d6f506efdd37f0affa7ffc310711c06c7f3e097c9447c52ffffffff0100e1f505000000001976a9140389035a9225b3839e2bbf32d826a1e222031fd888ac00000000").unwrap(); let tx: IoResult = Serializable::deserialize(hex_tx.iter().map(|n| *n)); assert!(tx.is_ok()); let realtx = tx.unwrap(); // All these tests aren't really needed because if they fail, the hash check at the end // will also fail. But these will show you where the failure is so I'll leave them in. assert_eq!(realtx.version, 1); assert_eq!(realtx.input.len(), 1); // In particular this one is easy to get backward -- in bitcoin hashes are encoded // as little-endian 256-bit numbers rather than as data strings. assert_eq!(realtx.input[0].prev_hash.le_hex_string(), "ce9ea9f6f5e422c6a9dbcddb3b9a14d1c78fab9ab520cb281aa2a74a09575da1".to_string()); assert_eq!(realtx.input[0].prev_index, 1); assert_eq!(realtx.output.len(), 1); assert_eq!(realtx.lock_time, 0); assert_eq!(realtx.bitcoin_hash().le_hex_string(), "a6eab3c14ab5272a58a5ba91505ba1a4b6d7a3a9fcbd187b6cd99a7b6d548cb7".to_string()); }