rust-bitcoin-unsafe-fast/src/blockdata/transaction.rs

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// Rust Bitcoin Library
// Written in 2014 by
// Andrew Poelstra <apoelstra@wpsoftware.net>
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//
// 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 <http://creativecommons.org/publicdomain/zero/1.0/>.
//
//! # 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::default::Default;
use std::fmt;
use serde;
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use util::hash::Sha256dHash;
use blockdata::script::{self, Script, ScriptTrace};
use network::encodable::ConsensusEncodable;
use network::serialize::BitcoinHash;
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/// A reference to a transaction output
#[derive(Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Debug, Hash)]
pub struct TxOutRef {
/// The referenced transaction's txid
pub txid: Sha256dHash,
/// The index of the referenced output in its transaction's vout
pub index: usize
}
impl fmt::Display for TxOutRef {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "{}:{}", self.txid, self.index)
}
}
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/// A transaction input, which defines old coins to be consumed
#[derive(Clone, PartialEq, Eq, Debug, Hash)]
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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,
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}
/// A transaction output, which defines new coins to be created from old ones.
#[derive(Clone, PartialEq, Eq, Debug, Hash)]
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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
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}
// This is used as a "null txout" in consensus signing code
impl Default for TxOut {
fn default() -> TxOut {
TxOut { value: 0xffffffffffffffff, script_pubkey: Script::new() }
}
}
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/// A Bitcoin transaction, which describes an authenticated movement of coins
#[derive(Clone, PartialEq, Eq, Debug, Hash)]
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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<TxIn>,
/// List of outputs
pub output: Vec<TxOut>
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}
/// A transaction error
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#[derive(PartialEq, Eq, Clone, Debug)]
pub enum Error {
/// Concatenated script failed in the input half (script error)
InputScriptFailure(script::Error),
/// Concatenated script failed in the output half (script error)
OutputScriptFailure(script::Error),
/// P2SH serialized script failed (script error)
P2shScriptFailure(script::Error),
/// P2SH serialized script ended with false at the top of the stack
P2shScriptReturnedFalse,
/// P2SH serialized script ended with nothing in the stack
P2shScriptReturnedEmptyStack,
/// Script ended with false at the top of the stack
ScriptReturnedFalse,
/// Script ended with nothing in the stack
ScriptReturnedEmptyStack,
/// Script ended with nothing in the stack (input txid, input vout)
InputNotFound(Sha256dHash, u32),
}
display_from_debug!(Error);
impl serde::Serialize for Error {
fn serialize<S>(&self, serializer: &mut S) -> Result<(), S::Error>
where S: serde::Serializer,
{
serializer.visit_str(&self.to_string())
}
}
/// A trace of a transaction input's script execution
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#[derive(PartialEq, Eq, Clone, Debug)]
pub struct InputTrace {
input_txid: Sha256dHash,
input_vout: usize,
sig_trace: ScriptTrace,
pubkey_trace: Option<ScriptTrace>,
p2sh_trace: Option<ScriptTrace>,
error: Option<Error>
}
/// A trace of a transaction's execution
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#[derive(PartialEq, Eq, Clone, Debug)]
pub struct TransactionTrace {
txid: Sha256dHash,
inputs: Vec<InputTrace>
}
impl BitcoinHash for Transaction {
fn bitcoin_hash(&self) -> Sha256dHash {
use network::serialize::serialize;
Sha256dHash::from_data(&serialize(self).unwrap())
}
}
impl_consensus_encoding!(TxIn, prev_hash, prev_index, script_sig, sequence);
impl_consensus_encoding!(TxOut, value, script_pubkey);
impl_consensus_encoding!(Transaction, version, input, output, lock_time);
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#[cfg(test)]
mod tests {
use super::{Transaction, TxIn};
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use network::serialize::BitcoinHash;
use network::serialize::deserialize;
use util::misc::hex_bytes;
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#[test]
fn test_txin() {
let txin: Result<TxIn, _> = deserialize(&hex_bytes("a15d57094aa7a21a28cb20b59aab8fc7d1149a3bdbcddba9c622e4f5f6a99ece010000006c493046022100f93bb0e7d8db7bd46e40132d1f8242026e045f03a0efe71bbb8e3f475e970d790221009337cd7f1f929f00cc6ff01f03729b069a7c21b59b1736ddfee5db5946c5da8c0121033b9b137ee87d5a812d6f506efdd37f0affa7ffc310711c06c7f3e097c9447c52ffffffff").unwrap());
assert!(txin.is_ok());
}
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#[test]
fn test_transaction() {
let hex_tx = hex_bytes("0100000001a15d57094aa7a21a28cb20b59aab8fc7d1149a3bdbcddba9c622e4f5f6a99ece010000006c493046022100f93bb0e7d8db7bd46e40132d1f8242026e045f03a0efe71bbb8e3f475e970d790221009337cd7f1f929f00cc6ff01f03729b069a7c21b59b1736ddfee5db5946c5da8c0121033b9b137ee87d5a812d6f506efdd37f0affa7ffc310711c06c7f3e097c9447c52ffffffff0100e1f505000000001976a9140389035a9225b3839e2bbf32d826a1e222031fd888ac00000000").unwrap();
let tx: Result<Transaction, _> = deserialize(&hex_tx);
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.be_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().be_hex_string(),
"a6eab3c14ab5272a58a5ba91505ba1a4b6d7a3a9fcbd187b6cd99a7b6d548cb7".to_string());
}
}
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