//! Hashing with the [SHA-256] hash function, and a general [`Hash`] type. //! //! [SHA-256]: https://en.wikipedia.org/wiki/SHA-2 //! [`Hash`]: struct@Hash use { crate::{sanitize::Sanitize, wasm_bindgen}, borsh::{BorshDeserialize, BorshSchema, BorshSerialize}, sha2::{Digest, Sha256}, std::{convert::TryFrom, fmt, mem, str::FromStr}, thiserror::Error, }; /// Size of a hash in bytes. pub const HASH_BYTES: usize = 32; /// Maximum string length of a base58 encoded hash. const MAX_BASE58_LEN: usize = 44; /// A hash; the 32-byte output of a hashing algorithm. /// /// This struct is used most often in `solana-sdk` and related crates to contain /// a [SHA-256] hash, but may instead contain a [blake3] hash, as created by the /// [`blake3`] module (and used in [`Message::hash`]). /// /// [SHA-256]: https://en.wikipedia.org/wiki/SHA-2 /// [blake3]: https://github.com/BLAKE3-team/BLAKE3 /// [`blake3`]: crate::blake3 /// [`Message::hash`]: crate::message::Message::hash #[wasm_bindgen] #[derive( Serialize, Deserialize, BorshSerialize, BorshDeserialize, BorshSchema, Clone, Copy, Default, Eq, PartialEq, Ord, PartialOrd, Hash, AbiExample, )] #[repr(transparent)] pub struct Hash(pub(crate) [u8; HASH_BYTES]); #[derive(Clone, Default)] pub struct Hasher { hasher: Sha256, } impl Hasher { pub fn hash(&mut self, val: &[u8]) { self.hasher.update(val); } pub fn hashv(&mut self, vals: &[&[u8]]) { for val in vals { self.hash(val); } } pub fn result(self) -> Hash { // At the time of this writing, the sha2 library is stuck on an old version // of generic_array (0.9.0). Decouple ourselves with a clone to our version. Hash(<[u8; HASH_BYTES]>::try_from(self.hasher.finalize().as_slice()).unwrap()) } } impl Sanitize for Hash {} impl From<[u8; HASH_BYTES]> for Hash { fn from(from: [u8; 32]) -> Self { Self(from) } } impl AsRef<[u8]> for Hash { fn as_ref(&self) -> &[u8] { &self.0[..] } } impl fmt::Debug for Hash { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { write!(f, "{}", bs58::encode(self.0).into_string()) } } impl fmt::Display for Hash { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { write!(f, "{}", bs58::encode(self.0).into_string()) } } #[derive(Debug, Clone, PartialEq, Eq, Error)] pub enum ParseHashError { #[error("string decoded to wrong size for hash")] WrongSize, #[error("failed to decoded string to hash")] Invalid, } impl FromStr for Hash { type Err = ParseHashError; fn from_str(s: &str) -> Result { if s.len() > MAX_BASE58_LEN { return Err(ParseHashError::WrongSize); } let bytes = bs58::decode(s) .into_vec() .map_err(|_| ParseHashError::Invalid)?; if bytes.len() != mem::size_of::() { Err(ParseHashError::WrongSize) } else { Ok(Hash::new(&bytes)) } } } impl Hash { pub fn new(hash_slice: &[u8]) -> Self { Hash(<[u8; HASH_BYTES]>::try_from(hash_slice).unwrap()) } pub const fn new_from_array(hash_array: [u8; HASH_BYTES]) -> Self { Self(hash_array) } /// unique Hash for tests and benchmarks. pub fn new_unique() -> Self { use crate::atomic_u64::AtomicU64; static I: AtomicU64 = AtomicU64::new(1); let mut b = [0u8; HASH_BYTES]; let i = I.fetch_add(1); b[0..8].copy_from_slice(&i.to_le_bytes()); Self::new(&b) } pub fn to_bytes(self) -> [u8; HASH_BYTES] { self.0 } } /// Return a Sha256 hash for the given data. pub fn hashv(vals: &[&[u8]]) -> Hash { // Perform the calculation inline, calling this from within a program is // not supported #[cfg(not(target_os = "solana"))] { let mut hasher = Hasher::default(); hasher.hashv(vals); hasher.result() } // Call via a system call to perform the calculation #[cfg(target_os = "solana")] { extern "C" { fn sol_sha256(vals: *const u8, val_len: u64, hash_result: *mut u8) -> u64; } let mut hash_result = [0; HASH_BYTES]; unsafe { sol_sha256( vals as *const _ as *const u8, vals.len() as u64, &mut hash_result as *mut _ as *mut u8, ); } Hash::new_from_array(hash_result) } } /// Return a Sha256 hash for the given data. pub fn hash(val: &[u8]) -> Hash { hashv(&[val]) } /// Return the hash of the given hash extended with the given value. pub fn extend_and_hash(id: &Hash, val: &[u8]) -> Hash { let mut hash_data = id.as_ref().to_vec(); hash_data.extend_from_slice(val); hash(&hash_data) } #[cfg(test)] mod tests { use super::*; #[test] fn test_new_unique() { assert!(Hash::new_unique() != Hash::new_unique()); } #[test] fn test_hash_fromstr() { let hash = hash(&[1u8]); let mut hash_base58_str = bs58::encode(hash).into_string(); assert_eq!(hash_base58_str.parse::(), Ok(hash)); hash_base58_str.push_str(&bs58::encode(hash.0).into_string()); assert_eq!( hash_base58_str.parse::(), Err(ParseHashError::WrongSize) ); hash_base58_str.truncate(hash_base58_str.len() / 2); assert_eq!(hash_base58_str.parse::(), Ok(hash)); hash_base58_str.truncate(hash_base58_str.len() / 2); assert_eq!( hash_base58_str.parse::(), Err(ParseHashError::WrongSize) ); let input_too_big = bs58::encode(&[0xffu8; HASH_BYTES + 1]).into_string(); assert!(input_too_big.len() > MAX_BASE58_LEN); assert_eq!( input_too_big.parse::(), Err(ParseHashError::WrongSize) ); let mut hash_base58_str = bs58::encode(hash.0).into_string(); assert_eq!(hash_base58_str.parse::(), Ok(hash)); // throw some non-base58 stuff in there hash_base58_str.replace_range(..1, "I"); assert_eq!( hash_base58_str.parse::(), Err(ParseHashError::Invalid) ); } }