mirror of
https://github.com/embassy-rs/embassy.git
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478 lines
15 KiB
Rust
478 lines
15 KiB
Rust
#![macro_use]
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// Credit: taken from `rp-hal` (also licensed Apache+MIT)
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// https://github.com/rp-rs/rp-hal/blob/main/rp2040-hal/src/intrinsics.rs
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/// Generate a series of aliases for an intrinsic function.
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macro_rules! intrinsics_aliases {
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(
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extern $abi:tt fn $name:ident( $($argname:ident: $ty:ty),* ) -> $ret:ty,
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) => {};
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(
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unsafe extern $abi:tt fn $name:ident( $($argname:ident: $ty:ty),* ) -> $ret:ty,
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) => {};
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(
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extern $abi:tt fn $name:ident( $($argname:ident: $ty:ty),* ) -> $ret:ty,
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$alias:ident
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$($rest:ident)*
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) => {
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#[cfg(all(target_arch = "arm", feature = "intrinsics"))]
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intrinsics! {
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extern $abi fn $alias( $($argname: $ty),* ) -> $ret {
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$name($($argname),*)
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}
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}
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intrinsics_aliases! {
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extern $abi fn $name( $($argname: $ty),* ) -> $ret,
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$($rest)*
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}
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};
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(
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unsafe extern $abi:tt fn $name:ident( $($argname:ident: $ty:ty),* ) -> $ret:ty,
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$alias:ident
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$($rest:ident)*
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) => {
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#[cfg(all(target_arch = "arm", feature = "intrinsics"))]
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intrinsics! {
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unsafe extern $abi fn $alias( $($argname: $ty),* ) -> $ret {
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$name($($argname),*)
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}
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}
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intrinsics_aliases! {
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unsafe extern $abi fn $name( $($argname: $ty),* ) -> $ret,
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$($rest)*
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}
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};
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}
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/// The macro used to define overridden intrinsics.
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///
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/// This is heavily inspired by the macro used by compiler-builtins. The idea
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/// is to abstract anything special that needs to be done to override an
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/// intrinsic function. Intrinsic generation is disabled for non-ARM targets
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/// so things like CI and docs generation do not have problems. Additionally
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/// they can be disabled by disabling the crate feature `intrinsics` for
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/// testing or comparing performance.
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///
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/// Like the compiler-builtins macro, it accepts a series of functions that
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/// looks like normal Rust code:
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///
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/// ```rust,ignore
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/// intrinsics! {
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/// extern "C" fn foo(a: i32) -> u32 {
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/// // ...
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/// }
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/// #[nonstandard_attribute]
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/// extern "C" fn bar(a: i32) -> u32 {
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/// // ...
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/// }
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/// }
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/// ```
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///
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/// Each function can also be decorated with nonstandard attributes to control
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/// additional behaviour:
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///
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/// * `slower_than_default` - indicates that the override is slower than the
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/// default implementation. Currently this just disables the override
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/// entirely.
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/// * `bootrom_v2` - indicates that the override is only available
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/// on a V2 bootrom or higher. Only enabled when the feature
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/// `rom-v2-intrinsics` is set.
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/// * `alias` - accepts a list of names to alias the intrinsic to.
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/// * `aeabi` - accepts a list of ARM EABI names to alias to.
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///
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macro_rules! intrinsics {
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() => {};
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(
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#[slower_than_default]
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$(#[$($attr:tt)*])*
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extern $abi:tt fn $name:ident( $($argname:ident: $ty:ty),* ) -> $ret:ty {
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$($body:tt)*
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}
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$($rest:tt)*
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) => {
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// Not exported, but defined so the actual implementation is
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// considered used
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#[allow(dead_code)]
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fn $name( $($argname: $ty),* ) -> $ret {
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$($body)*
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}
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intrinsics!($($rest)*);
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};
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(
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#[bootrom_v2]
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$(#[$($attr:tt)*])*
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extern $abi:tt fn $name:ident( $($argname:ident: $ty:ty),* ) -> $ret:ty {
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$($body:tt)*
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}
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$($rest:tt)*
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) => {
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// Not exported, but defined so the actual implementation is
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// considered used
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#[cfg(not(feature = "rom-v2-intrinsics"))]
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#[allow(dead_code)]
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fn $name( $($argname: $ty),* ) -> $ret {
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$($body)*
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}
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#[cfg(feature = "rom-v2-intrinsics")]
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intrinsics! {
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$(#[$($attr)*])*
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extern $abi fn $name( $($argname: $ty),* ) -> $ret {
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$($body)*
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}
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}
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intrinsics!($($rest)*);
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};
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(
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#[alias = $($alias:ident),*]
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$(#[$($attr:tt)*])*
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extern $abi:tt fn $name:ident( $($argname:ident: $ty:ty),* ) -> $ret:ty {
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$($body:tt)*
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}
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$($rest:tt)*
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) => {
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intrinsics! {
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$(#[$($attr)*])*
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extern $abi fn $name( $($argname: $ty),* ) -> $ret {
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$($body)*
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}
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}
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intrinsics_aliases! {
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extern $abi fn $name( $($argname: $ty),* ) -> $ret,
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$($alias) *
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}
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intrinsics!($($rest)*);
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};
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(
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#[alias = $($alias:ident),*]
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$(#[$($attr:tt)*])*
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unsafe extern $abi:tt fn $name:ident( $($argname:ident: $ty:ty),* ) -> $ret:ty {
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$($body:tt)*
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}
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$($rest:tt)*
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) => {
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intrinsics! {
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$(#[$($attr)*])*
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unsafe extern $abi fn $name( $($argname: $ty),* ) -> $ret {
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$($body)*
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}
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}
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intrinsics_aliases! {
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unsafe extern $abi fn $name( $($argname: $ty),* ) -> $ret,
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$($alias) *
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}
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intrinsics!($($rest)*);
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};
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(
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#[aeabi = $($alias:ident),*]
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$(#[$($attr:tt)*])*
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extern $abi:tt fn $name:ident( $($argname:ident: $ty:ty),* ) -> $ret:ty {
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$($body:tt)*
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}
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$($rest:tt)*
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) => {
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intrinsics! {
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$(#[$($attr)*])*
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extern $abi fn $name( $($argname: $ty),* ) -> $ret {
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$($body)*
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}
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}
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intrinsics_aliases! {
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extern "aapcs" fn $name( $($argname: $ty),* ) -> $ret,
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$($alias) *
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}
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intrinsics!($($rest)*);
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};
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(
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$(#[$($attr:tt)*])*
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extern $abi:tt fn $name:ident( $($argname:ident: $ty:ty),* ) -> $ret:ty {
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$($body:tt)*
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}
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$($rest:tt)*
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) => {
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#[cfg(all(target_arch = "arm", feature = "intrinsics"))]
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$(#[$($attr)*])*
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extern $abi fn $name( $($argname: $ty),* ) -> $ret {
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$($body)*
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}
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#[cfg(all(target_arch = "arm", feature = "intrinsics"))]
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mod $name {
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#[no_mangle]
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$(#[$($attr)*])*
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pub extern $abi fn $name( $($argname: $ty),* ) -> $ret {
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super::$name($($argname),*)
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}
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}
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// Not exported, but defined so the actual implementation is
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// considered used
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#[cfg(not(all(target_arch = "arm", feature = "intrinsics")))]
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#[allow(dead_code)]
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fn $name( $($argname: $ty),* ) -> $ret {
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$($body)*
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}
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intrinsics!($($rest)*);
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};
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(
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$(#[$($attr:tt)*])*
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unsafe extern $abi:tt fn $name:ident( $($argname:ident: $ty:ty),* ) -> $ret:ty {
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$($body:tt)*
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}
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$($rest:tt)*
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) => {
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#[cfg(all(target_arch = "arm", feature = "intrinsics"))]
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$(#[$($attr)*])*
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unsafe extern $abi fn $name( $($argname: $ty),* ) -> $ret {
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$($body)*
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}
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#[cfg(all(target_arch = "arm", feature = "intrinsics"))]
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mod $name {
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#[no_mangle]
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$(#[$($attr)*])*
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pub unsafe extern $abi fn $name( $($argname: $ty),* ) -> $ret {
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super::$name($($argname),*)
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}
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}
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// Not exported, but defined so the actual implementation is
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// considered used
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#[cfg(not(all(target_arch = "arm", feature = "intrinsics")))]
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#[allow(dead_code)]
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unsafe fn $name( $($argname: $ty),* ) -> $ret {
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$($body)*
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}
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intrinsics!($($rest)*);
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};
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}
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// Credit: taken from `rp-hal` (also licensed Apache+MIT)
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// https://github.com/rp-rs/rp-hal/blob/main/rp2040-hal/src/sio.rs
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// This takes advantage of how AAPCS defines a 64-bit return on 32-bit registers
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// by packing it into r0[0:31] and r1[32:63]. So all we need to do is put
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// the remainder in the high order 32 bits of a 64 bit result. We can also
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// alias the division operators to these for a similar reason r0 is the
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// result either way and r1 a scratch register, so the caller can't assume it
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// retains the argument value.
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#[cfg(target_arch = "arm")]
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core::arch::global_asm!(
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".macro hwdivider_head",
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"ldr r2, =(0xd0000000)", // SIO_BASE
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// Check the DIRTY state of the divider by shifting it into the C
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// status bit.
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"ldr r3, [r2, #0x078]", // DIV_CSR
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"lsrs r3, #2", // DIRTY = 1, so shift 2 down
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// We only need to save the state when DIRTY, otherwise we can just do the
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// division directly.
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"bcs 2f",
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"1:",
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// Do the actual division now, we're either not DIRTY, or we've saved the
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// state and branched back here so it's safe now.
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".endm",
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".macro hwdivider_tail",
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// 8 cycle delay to wait for the result. Each branch takes two cycles
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// and fits into a 2-byte Thumb instruction, so this is smaller than
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// 8 NOPs.
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"b 3f",
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"3: b 3f",
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"3: b 3f",
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"3: b 3f",
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"3:",
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// Read the quotient last, since that's what clears the dirty flag.
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"ldr r1, [r2, #0x074]", // DIV_REMAINDER
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"ldr r0, [r2, #0x070]", // DIV_QUOTIENT
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// Either return to the caller or back to the state restore.
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"bx lr",
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"2:",
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// Since we can't save the signed-ness of the calculation, we have to make
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// sure that there's at least an 8 cycle delay before we read the result.
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// The push takes 5 cycles, and we've already spent at least 7 checking
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// the DIRTY state to get here.
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"push {{r4-r6, lr}}",
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// Read the quotient last, since that's what clears the dirty flag.
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"ldr r3, [r2, #0x060]", // DIV_UDIVIDEND
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"ldr r4, [r2, #0x064]", // DIV_UDIVISOR
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"ldr r5, [r2, #0x074]", // DIV_REMAINDER
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"ldr r6, [r2, #0x070]", // DIV_QUOTIENT
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// If we get interrupted here (before a write sets the DIRTY flag) it's
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// fine, since we have the full state, so the interruptor doesn't have to
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// restore it. Once the write happens and the DIRTY flag is set, the
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// interruptor becomes responsible for restoring our state.
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"bl 1b",
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// If we are interrupted here, then the interruptor will start an incorrect
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// calculation using a wrong divisor, but we'll restore the divisor and
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// result ourselves correctly. This sets DIRTY, so any interruptor will
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// save the state.
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"str r3, [r2, #0x060]", // DIV_UDIVIDEND
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// If we are interrupted here, the the interruptor may start the
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// calculation using incorrectly signed inputs, but we'll restore the
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// result ourselves. This sets DIRTY, so any interruptor will save the
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// state.
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"str r4, [r2, #0x064]", // DIV_UDIVISOR
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// If we are interrupted here, the interruptor will have restored
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// everything but the quotient may be wrongly signed. If the calculation
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// started by the above writes is still ongoing it is stopped, so it won't
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// replace the result we're restoring. DIRTY and READY set, but only
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// DIRTY matters to make the interruptor save the state.
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"str r5, [r2, #0x074]", // DIV_REMAINDER
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// State fully restored after the quotient write. This sets both DIRTY
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// and READY, so whatever we may have interrupted can read the result.
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"str r6, [r2, #0x070]", // DIV_QUOTIENT
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"pop {{r4-r6, pc}}",
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".endm",
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);
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macro_rules! division_function {
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(
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$name:ident $($intrinsic:ident)* ( $argty:ty ) {
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$($begin:literal),+
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}
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) => {
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#[cfg(all(target_arch = "arm", feature = "intrinsics"))]
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core::arch::global_asm!(
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// Mangle the name slightly, since this is a global symbol.
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concat!(".section .text._erphal_", stringify!($name)),
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concat!(".global _erphal_", stringify!($name)),
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concat!(".type _erphal_", stringify!($name), ", %function"),
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".align 2",
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concat!("_erphal_", stringify!($name), ":"),
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$(
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concat!(".global ", stringify!($intrinsic)),
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concat!(".type ", stringify!($intrinsic), ", %function"),
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concat!(stringify!($intrinsic), ":"),
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)*
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"hwdivider_head",
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$($begin),+ ,
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"hwdivider_tail",
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);
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#[cfg(all(target_arch = "arm", not(feature = "intrinsics")))]
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core::arch::global_asm!(
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// Mangle the name slightly, since this is a global symbol.
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concat!(".section .text._erphal_", stringify!($name)),
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concat!(".global _erphal_", stringify!($name)),
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concat!(".type _erphal_", stringify!($name), ", %function"),
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".align 2",
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concat!("_erphal_", stringify!($name), ":"),
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"hwdivider_head",
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$($begin),+ ,
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"hwdivider_tail",
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);
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#[cfg(target_arch = "arm")]
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extern "aapcs" {
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// Connect a local name to global symbol above through FFI.
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#[link_name = concat!("_erphal_", stringify!($name)) ]
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fn $name(n: $argty, d: $argty) -> u64;
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}
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#[cfg(not(target_arch = "arm"))]
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#[allow(unused_variables)]
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unsafe fn $name(n: $argty, d: $argty) -> u64 { 0 }
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};
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}
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division_function! {
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unsigned_divmod __aeabi_uidivmod __aeabi_uidiv ( u32 ) {
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"str r0, [r2, #0x060]", // DIV_UDIVIDEND
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"str r1, [r2, #0x064]" // DIV_UDIVISOR
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}
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}
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division_function! {
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signed_divmod __aeabi_idivmod __aeabi_idiv ( i32 ) {
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"str r0, [r2, #0x068]", // DIV_SDIVIDEND
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"str r1, [r2, #0x06c]" // DIV_SDIVISOR
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}
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}
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fn divider_unsigned(n: u32, d: u32) -> DivResult<u32> {
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let packed = unsafe { unsigned_divmod(n, d) };
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DivResult {
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quotient: packed as u32,
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remainder: (packed >> 32) as u32,
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}
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}
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fn divider_signed(n: i32, d: i32) -> DivResult<i32> {
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let packed = unsafe { signed_divmod(n, d) };
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// Double casts to avoid sign extension
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DivResult {
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quotient: packed as u32 as i32,
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remainder: (packed >> 32) as u32 as i32,
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}
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}
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/// Result of divide/modulo operation
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struct DivResult<T> {
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/// The quotient of divide/modulo operation
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pub quotient: T,
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/// The remainder of divide/modulo operation
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pub remainder: T,
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}
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intrinsics! {
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extern "C" fn __udivsi3(n: u32, d: u32) -> u32 {
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divider_unsigned(n, d).quotient
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}
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extern "C" fn __umodsi3(n: u32, d: u32) -> u32 {
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divider_unsigned(n, d).remainder
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}
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extern "C" fn __udivmodsi4(n: u32, d: u32, rem: Option<&mut u32>) -> u32 {
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let quo_rem = divider_unsigned(n, d);
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if let Some(rem) = rem {
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*rem = quo_rem.remainder;
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}
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quo_rem.quotient
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}
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extern "C" fn __divsi3(n: i32, d: i32) -> i32 {
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divider_signed(n, d).quotient
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}
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extern "C" fn __modsi3(n: i32, d: i32) -> i32 {
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divider_signed(n, d).remainder
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}
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extern "C" fn __divmodsi4(n: i32, d: i32, rem: &mut i32) -> i32 {
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let quo_rem = divider_signed(n, d);
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*rem = quo_rem.remainder;
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quo_rem.quotient
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}
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}
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