//! Non-public macros macro_rules! arr_newtype_fmt_impl { ($ty:ident, $bytes:expr $(, $gen:ident: $gent:ident)*) => { impl<$($gen: $gent),*> $crate::_export::_core::fmt::LowerHex for $ty<$($gen),*> { #[inline] fn fmt(&self, f: &mut $crate::_export::_core::fmt::Formatter) -> $crate::_export::_core::fmt::Result { #[allow(unused)] use crate::Hash as _; let case = internals::hex::Case::Lower; if <$ty<$($gen),*>>::DISPLAY_BACKWARD { internals::hex::display::fmt_hex_exact!(f, $bytes, self.0.iter().rev(), case) } else { internals::hex::display::fmt_hex_exact!(f, $bytes, self.0.iter(), case) } } } impl<$($gen: $gent),*> $crate::_export::_core::fmt::UpperHex for $ty<$($gen),*> { #[inline] fn fmt(&self, f: &mut $crate::_export::_core::fmt::Formatter) -> $crate::_export::_core::fmt::Result { #[allow(unused)] use crate::Hash as _; let case = internals::hex::Case::Upper; if <$ty<$($gen),*>>::DISPLAY_BACKWARD { internals::hex::display::fmt_hex_exact!(f, $bytes, self.0.iter().rev(), case) } else { internals::hex::display::fmt_hex_exact!(f, $bytes, self.0.iter(), case) } } } impl<$($gen: $gent),*> $crate::_export::_core::fmt::Display for $ty<$($gen),*> { #[inline] fn fmt(&self, f: &mut $crate::_export::_core::fmt::Formatter) -> $crate::_export::_core::fmt::Result { $crate::_export::_core::fmt::LowerHex::fmt(self, f) } } impl<$($gen: $gent),*> $crate::_export::_core::fmt::Debug for $ty<$($gen),*> { #[inline] fn fmt(&self, f: &mut $crate::_export::_core::fmt::Formatter) -> $crate::_export::_core::fmt::Result { write!(f, "{:#}", self) } } } } pub(crate) use arr_newtype_fmt_impl; /// Adds trait impls to the type called `Hash` in the current scope. /// /// Implpements various conversion traits as well as the [`crate::Hash`] trait. /// Arguments: /// /// * `$bits` - number of bits this hash type has /// * `$reverse` - `bool` - `true` if the hash type should be displayed backwards, `false` /// otherwise. /// * `$gen: $gent` - generic type(s) and trait bound(s) /// /// Restrictions on usage: /// /// * There must be a free-standing `fn from_engine(HashEngine) -> Hash` in the scope /// * `fn internal_new([u8; $bits / 8]) -> Self` must exist on `Hash` /// * `fn internal_engine() -> HashEngine` must exist on `Hash` /// /// `from_engine` obviously implements the finalization algorithm. /// `internal_new` is required so that types with more than one field are constructible. /// `internal_engine` is required to initialize the engine for given hash type. macro_rules! hash_trait_impls { ($bits:expr, $reverse:expr $(, $gen:ident: $gent:ident)*) => { impl<$($gen: $gent),*> Hash<$($gen),*> { /// Displays hex forwards, regardless of how this type would display it naturally. /// /// This is mainly intended as an internal method and you shouldn't need it unless /// you're doing something special. pub fn forward_hex(&self) -> impl '_ + core::fmt::LowerHex + core::fmt::UpperHex { internals::hex::display::DisplayHex::as_hex(&self.0) } /// Displays hex backwards, regardless of how this type would display it naturally. /// /// This is mainly intended as an internal method and you shouldn't need it unless /// you're doing something special. pub fn backward_hex(&self) -> impl '_ + core::fmt::LowerHex + core::fmt::UpperHex { internals::hex::display::DisplayArray::<_, [u8; $bits / 8 * 2]>::new(self.0.iter().rev()) } } impl<$($gen: $gent),*> str::FromStr for Hash<$($gen),*> { type Err = $crate::hex::Error; fn from_str(s: &str) -> Result { $crate::hex::FromHex::from_hex(s) } } $crate::internal_macros::arr_newtype_fmt_impl!(Hash, $bits / 8 $(, $gen: $gent)*); serde_impl!(Hash, $bits / 8 $(, $gen: $gent)*); borrow_slice_impl!(Hash $(, $gen: $gent)*); impl $(, $gen: $gent)*> Index for Hash<$($gen),*> { type Output = I::Output; #[inline] fn index(&self, index: I) -> &Self::Output { &self.0[index] } } impl<$($gen: $gent),*> crate::Hash for Hash<$($gen),*> { type Engine = HashEngine; type Inner = [u8; $bits / 8]; const LEN: usize = $bits / 8; const DISPLAY_BACKWARD: bool = $reverse; fn engine() -> Self::Engine { Self::internal_engine() } fn from_engine(e: HashEngine) -> Hash<$($gen),*> { from_engine(e) } fn from_slice(sl: &[u8]) -> Result, Error> { if sl.len() != $bits / 8 { Err(Error::InvalidLength(Self::LEN, sl.len())) } else { let mut ret = [0; $bits / 8]; ret.copy_from_slice(sl); Ok(Self::internal_new(ret)) } } fn into_inner(self) -> Self::Inner { self.0 } fn as_inner(&self) -> &Self::Inner { &self.0 } fn from_inner(inner: Self::Inner) -> Self { Self::internal_new(inner) } fn all_zeros() -> Self { Hash::internal_new([0x00; $bits / 8]) } } } } pub(crate) use hash_trait_impls; /// Creates a type called `Hash` and implements standard interface for it. /// /// The created type will have all standard derives, `Hash` impl and implementation of /// `internal_engine` returning default. The created type has a single field. /// /// Arguments: /// /// * `$bits` - the number of bits of the hash type /// * `$reverse` - `true` if the hash should be displayed backwards, `false` otherwise /// * `$doc` - doc string to put on the type /// * `$schemars` - a literal that goes into `schema_with`. /// /// The `from_engine` free-standing function is still required with this macro. See the doc of /// [`hash_trait_impls`]. macro_rules! hash_type { ($bits:expr, $reverse:expr, $doc:literal, $schemars:literal) => { #[doc = $doc] #[derive(Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)] #[cfg_attr(feature = "schemars", derive(crate::schemars::JsonSchema))] #[repr(transparent)] pub struct Hash( #[cfg_attr(feature = "schemars", schemars(schema_with = $schemars))] [u8; $bits / 8] ); impl Hash { fn internal_new(arr: [u8; $bits / 8]) -> Self { Hash(arr) } fn internal_engine() -> HashEngine { Default::default() } } crate::internal_macros::hash_trait_impls!($bits, $reverse); } } pub(crate) use hash_type;