// Bitcoin Hashes Library // Written in 2018 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 . // //! Rust hashes library. //! //! This is a simple, no-dependency library which implements the hash functions //! needed by Bitcoin. These are SHA256, SHA256d, and RIPEMD160. As an ancillary //! thing, it exposes hexadecimal serialization and deserialization, since these //! are needed to display hashes anway. //! //! ## Commonly used operations //! //! Hashing a single byte slice or a string: //! //! ```rust //! use bitcoin_hashes::sha256; //! use bitcoin_hashes::Hash; //! //! let bytes = [0u8; 5]; //! let hash_of_bytes = sha256::Hash::hash(&bytes); //! let hash_of_string = sha256::Hash::hash("some string".as_bytes()); //! ``` //! //! //! Hashing content from a reader: //! //! ```rust //! use bitcoin_hashes::sha256; //! use bitcoin_hashes::Hash; //! //! #[cfg(std)] //! # fn main() -> std::io::Result<()> { //! let mut reader: &[u8] = b"hello"; // in real code, this could be a `File` or `TcpStream` //! let mut engine = sha256::HashEngine::default(); //! std::io::copy(&mut reader, &mut engine)?; //! let hash = sha256::Hash::from_engine(engine); //! # Ok(()) //! # } //! //! #[cfg(not(std))] //! # fn main() {} //! ``` //! //! //! Hashing content by [`std::io::Write`] on HashEngine: //! //! ```rust //! use bitcoin_hashes::sha256; //! use bitcoin_hashes::Hash; //! use std::io::Write; //! //! #[cfg(std)] //! # fn main() -> std::io::Result<()> { //! let mut part1: &[u8] = b"hello"; //! let mut part2: &[u8] = b" "; //! let mut part3: &[u8] = b"world"; //! let mut engine = sha256::HashEngine::default(); //! engine.write_all(part1)?; //! engine.write_all(part2)?; //! engine.write_all(part3)?; //! let hash = sha256::Hash::from_engine(engine); //! # Ok(()) //! # } //! //! #[cfg(not(std))] //! # fn main() {} //! ``` // Coding conventions #![deny(non_upper_case_globals)] #![deny(non_camel_case_types)] #![deny(non_snake_case)] #![deny(unused_mut)] #![deny(missing_docs)] // Experimental features we need. #![cfg_attr(docsrs, feature(doc_cfg))] #![cfg_attr(bench, feature(test))] // In general, rust is absolutely horrid at supporting users doing things like, // for example, compiling Rust code for real environments. Disable useless lints // that don't do anything but annoy us and cant actually ever be resolved. #![allow(bare_trait_objects)] #![allow(ellipsis_inclusive_range_patterns)] #![cfg_attr(all(not(test), not(feature = "std")), no_std)] #[cfg(bench)] extern crate test; #[cfg(any(test, feature = "std"))] extern crate core; #[cfg(feature = "core2")] extern crate core2; #[cfg(feature = "alloc")] extern crate alloc; #[cfg(all(not(feature = "alloc"), feature = "std"))] use std as alloc; #[cfg(feature = "serde")] pub extern crate serde; #[cfg(all(test,feature = "serde"))] extern crate serde_test; #[doc(hidden)] pub mod _export { /// A re-export of core::* pub mod _core { pub use core::*; } } #[cfg(feature = "schemars")] extern crate actual_schemars as schemars; mod internal_macros; #[macro_use] mod util; #[macro_use] pub mod serde_macros; #[cfg(any(feature = "std", feature = "core2"))] mod impls; pub mod error; pub mod hex; pub mod hash160; pub mod hmac; pub mod ripemd160; pub mod sha1; pub mod sha256; pub mod sha256d; pub mod sha256t; pub mod siphash24; pub mod sha512; pub mod sha512_256; pub mod cmp; use core::{borrow, fmt, hash, ops}; pub use hmac::{Hmac, HmacEngine}; pub use error::Error; /// A hashing engine which bytes can be serialized into. pub trait HashEngine: Clone + Default { /// Byte array representing the internal state of the hash engine. type MidState; /// Outputs the midstate of the hash engine. This function should not be /// used directly unless you really know what you're doing. fn midstate(&self) -> Self::MidState; /// Length of the hash's internal block size, in bytes. const BLOCK_SIZE: usize; /// Add data to the hash engine. fn input(&mut self, data: &[u8]); /// Return the number of bytes already n_bytes_hashed(inputted). fn n_bytes_hashed(&self) -> usize; } /// Trait which applies to hashes of all types. pub trait Hash: Copy + Clone + PartialEq + Eq + PartialOrd + Ord + hash::Hash + fmt::Debug + fmt::Display + fmt::LowerHex + ops::Index + ops::Index, Output = [u8]> + ops::Index, Output = [u8]> + ops::Index, Output = [u8]> + ops::Index + borrow::Borrow<[u8]> { /// A hashing engine which bytes can be serialized into. It is expected /// to implement the `io::Write` trait, and to never return errors under /// any conditions. type Engine: HashEngine; /// The byte array that represents the hash internally. type Inner: hex::FromHex; /// Constructs a new engine. fn engine() -> Self::Engine { Self::Engine::default() } /// Produces a hash from the current state of a given engine. fn from_engine(e: Self::Engine) -> Self; /// Length of the hash, in bytes. const LEN: usize; /// Copies a byte slice into a hash object. fn from_slice(sl: &[u8]) -> Result; /// Hashes some bytes. fn hash(data: &[u8]) -> Self { let mut engine = Self::engine(); engine.input(data); Self::from_engine(engine) } /// Flag indicating whether user-visible serializations of this hash /// should be backward. For some reason Satoshi decided this should be /// true for `Sha256dHash`, so here we are. const DISPLAY_BACKWARD: bool = false; /// Unwraps the hash and returns the underlying byte array. fn into_inner(self) -> Self::Inner; /// Unwraps the hash and returns a reference to the underlying byte array. fn as_inner(&self) -> &Self::Inner; /// Constructs a hash from the underlying byte array. fn from_inner(inner: Self::Inner) -> Self; /// Returns an all zero hash. /// /// An all zeros hash is a made up construct because there is not a known input that can create /// it, however it is used in various places in Bitcoin e.g., the Bitcoin genesis block's /// previous blockhash and the coinbase transaction's outpoint txid. fn all_zeros() -> Self; } #[cfg(test)] mod tests { use crate::{Hash, sha256d}; hash_newtype!(TestNewtype, sha256d::Hash, 32, doc="A test newtype"); hash_newtype!(TestNewtype2, sha256d::Hash, 32, doc="A test newtype"); #[test] fn convert_newtypes() { let h1 = TestNewtype::hash(&[]); let h2: TestNewtype2 = h1.as_hash().into(); assert_eq!(&h1[..], &h2[..]); let h = sha256d::Hash::hash(&[]); let h2: TestNewtype = h.to_string().parse().unwrap(); assert_eq!(h2.as_hash(), h); } }