// SPDX-License-Identifier: CC0-1.0 //! Bitcoin scripts. //! //! *[See also the `Script` type](Script).* //! //! This module provides the structures and functions needed to support scripts. //! //!

//!

What is Bitcoin script

//! //! Scripts define Bitcoin's digital signature scheme: a signature is formed //! from a script (the second half of which is defined by a coin to be spent, //! and the first half provided by the spending transaction), and is valid iff //! the script leaves `TRUE` on the stack after being evaluated. Bitcoin's //! script is a stack-based assembly language similar in spirit to [Forth]. //! //! Script is represented as a sequence of bytes on the wire, each byte representing an operation, //! or data to be pushed on the stack. //! //! See [Bitcoin Wiki: Script][wiki-script] for more information. //! //! [Forth]: https://en.wikipedia.org/wiki/Forth_(programming_language) //! //! [wiki-script]: https://en.bitcoin.it/wiki/Script //!

//! //! In this library we chose to keep the byte representation in memory and decode opcodes only when //! processing the script. This is similar to Rust choosing to represent strings as UTF-8-encoded //! bytes rather than slice of `char`s. In both cases the individual items can have different sizes //! and forcing them to be larger would waste memory and, in case of Bitcoin script, even some //! performance (forcing allocations). //! //! ## `Script` vs `ScriptBuf` vs `Builder` //! //! These are the most important types in this module and they are quite similar, so it may seem //! confusing what the differences are. `Script` is an unsized type much like `str` or `Path` are //! and `ScriptBuf` is an owned counterpart to `Script` just like `String` is an owned counterpart //! to `str`. //! //! However it is common to construct an owned script and then pass it around. For this case a //! builder API is more convenient. To support this we provide `Builder` type which is very similar //! to `ScriptBuf` but its methods take `self` instead of `&mut self` and return `Self`. It also //! contains a cache that may make some modifications faster. This cache is usually not needed //! outside of creating the script. //! //! At the time of writing there's only one operation using the cache - `push_verify`, so the cache //! is minimal but we may extend it in the future if needed. mod borrowed; mod builder; mod instruction; mod owned; mod push_bytes; #[cfg(test)] mod tests; pub mod witness_program; pub mod witness_version; use core::convert::Infallible; use core::fmt; use io::{BufRead, Write}; use crate::consensus::{encode, Decodable, Encodable}; use crate::internal_macros::impl_asref_push_bytes; use crate::key::WPubkeyHash; use crate::opcodes::all::*; use crate::opcodes::Opcode; use crate::prelude::Vec; use crate::OutPoint; #[rustfmt::skip] // Keep public re-exports separate. #[doc(inline)] pub use self::{ borrowed::ScriptExt, builder::Builder, instruction::{Instruction, Instructions, InstructionIndices}, owned::ScriptBufExt, push_bytes::{PushBytes, PushBytesBuf, PushBytesError, PushBytesErrorReport}, }; #[doc(inline)] pub use primitives::script::{ RedeemScriptSizeError, Script, ScriptBuf, ScriptHash, WScriptHash, WitnessScriptSizeError, }; pub(crate) use self::borrowed::ScriptExtPriv; pub(crate) use self::owned::ScriptBufExtPriv; impl_asref_push_bytes!(ScriptHash, WScriptHash); /// Constructs a new [`ScriptBuf`] containing the script code used for spending a P2WPKH output. /// /// The `scriptCode` is described in [BIP143]. /// /// [BIP143]: pub fn p2wpkh_script_code(wpkh: WPubkeyHash) -> ScriptBuf { Builder::new() .push_opcode(OP_DUP) .push_opcode(OP_HASH160) .push_slice(wpkh) .push_opcode(OP_EQUALVERIFY) .push_opcode(OP_CHECKSIG) .into_script() } /// Encodes an integer in script(minimal CScriptNum) format. /// /// Writes bytes into the buffer and returns the number of bytes written. /// /// Note that `write_scriptint`/`read_scriptint` do not roundtrip if the value written requires /// more than 4 bytes, this is in line with Bitcoin Core (see [`CScriptNum::serialize`]). /// /// [`CScriptNum::serialize`]: pub fn write_scriptint(out: &mut [u8; 8], n: i64) -> usize { let mut len = 0; if n == 0 { return len; } let neg = n < 0; let mut abs = n.unsigned_abs(); while abs > 0xFF { out[len] = (abs & 0xFF) as u8; len += 1; abs >>= 8; } // If the number's value causes the sign bit to be set, we need an extra // byte to get the correct value and correct sign bit if abs & 0x80 != 0 { out[len] = abs as u8; len += 1; out[len] = if neg { 0x80u8 } else { 0u8 }; len += 1; } // Otherwise we just set the sign bit ourselves else { abs |= if neg { 0x80 } else { 0 }; out[len] = abs as u8; len += 1; } len } /// Decodes an integer in script format without non-minimal error. /// /// The overflow error for slices over 4 bytes long is still there. /// /// See [`push_bytes::PushBytes::read_scriptint`] for a description of some subtleties of /// this function. pub fn read_scriptint_non_minimal(v: &[u8]) -> Result { if v.is_empty() { return Ok(0); } if v.len() > 4 { return Err(Error::NumericOverflow); } Ok(scriptint_parse(v)) } // Caller to guarantee that `v` is not empty. fn scriptint_parse(v: &[u8]) -> i64 { let (mut ret, sh) = v.iter().fold((0, 0), |(acc, sh), n| (acc + ((*n as i64) << sh), sh + 8)); if v[v.len() - 1] & 0x80 != 0 { ret &= (1 << (sh - 1)) - 1; ret = -ret; } ret } /// Decodes a boolean. /// /// This is like "`read_scriptint` then map 0 to false and everything /// else as true", except that the overflow rules don't apply. #[inline] pub fn read_scriptbool(v: &[u8]) -> bool { match v.split_last() { Some((last, rest)) => !((last & !0x80 == 0x00) && rest.iter().all(|&b| b == 0)), None => false, } } fn opcode_to_verify(opcode: Option) -> Option { opcode.and_then(|opcode| match opcode { OP_EQUAL => Some(OP_EQUALVERIFY), OP_NUMEQUAL => Some(OP_NUMEQUALVERIFY), OP_CHECKSIG => Some(OP_CHECKSIGVERIFY), OP_CHECKMULTISIG => Some(OP_CHECKMULTISIGVERIFY), _ => None, }) } impl Encodable for Script { #[inline] fn consensus_encode(&self, w: &mut W) -> Result { crate::consensus::encode::consensus_encode_with_size(self.as_bytes(), w) } } impl Encodable for ScriptBuf { #[inline] fn consensus_encode(&self, w: &mut W) -> Result { self.as_script().consensus_encode(w) } } impl Decodable for ScriptBuf { #[inline] fn consensus_decode_from_finite_reader( r: &mut R, ) -> Result { let v: Vec = Decodable::consensus_decode_from_finite_reader(r)?; Ok(ScriptBuf::from_bytes(v)) } } /// Ways that a script might fail. Not everything is split up as /// much as it could be; patches welcome if more detailed errors /// would help you. #[derive(Debug, Clone, PartialEq, Eq)] #[non_exhaustive] pub enum Error { /// Something did a non-minimal push; for more information see /// NonMinimalPush, /// Some opcode expected a parameter but it was missing or truncated. EarlyEndOfScript, /// Tried to read an array off the stack as a number when it was more than 4 bytes. NumericOverflow, /// Can not find the spent output. UnknownSpentOutput(OutPoint), /// Can not serialize the spending transaction. Serialization, } impl From for Error { fn from(never: Infallible) -> Self { match never {} } } impl fmt::Display for Error { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { use Error::*; match *self { NonMinimalPush => f.write_str("non-minimal datapush"), EarlyEndOfScript => f.write_str("unexpected end of script"), NumericOverflow => f.write_str("numeric overflow (number on stack larger than 4 bytes)"), UnknownSpentOutput(ref point) => write!(f, "unknown spent output: {}", point), Serialization => f.write_str("can not serialize the spending transaction in Transaction::verify()"), } } } #[cfg(feature = "std")] impl std::error::Error for Error { fn source(&self) -> Option<&(dyn std::error::Error + 'static)> { use Error::*; match *self { NonMinimalPush | EarlyEndOfScript | NumericOverflow | UnknownSpentOutput(_) | Serialization => None, } } }