//! Implements methods to read a vector type from a slice. macro_rules! impl_slice_from_slice { ([$elem_ty:ident; $elem_count:expr]: $id:ident | $test_tt:tt) => { impl $id { /// Instantiates a new vector with the values of the `slice`. /// /// # Panics /// /// If `slice.len() < Self::lanes()` or `&slice[0]` is not aligned /// to an `align_of::()` boundary. #[inline] pub fn from_slice_aligned(slice: &[$elem_ty]) -> Self { unsafe { assert!(slice.len() >= $elem_count); let target_ptr = slice.get_unchecked(0) as *const $elem_ty; assert_eq!( target_ptr .align_offset(crate::mem::align_of::()), 0 ); Self::from_slice_aligned_unchecked(slice) } } /// Instantiates a new vector with the values of the `slice`. /// /// # Panics /// /// If `slice.len() < Self::lanes()`. #[inline] pub fn from_slice_unaligned(slice: &[$elem_ty]) -> Self { unsafe { assert!(slice.len() >= $elem_count); Self::from_slice_unaligned_unchecked(slice) } } /// Instantiates a new vector with the values of the `slice`. /// /// # Safety /// /// If `slice.len() < Self::lanes()` or `&slice[0]` is not aligned /// to an `align_of::()` boundary, the behavior is undefined. #[inline] pub unsafe fn from_slice_aligned_unchecked( slice: &[$elem_ty], ) -> Self { debug_assert!(slice.len() >= $elem_count); let target_ptr = slice.get_unchecked(0) as *const $elem_ty; debug_assert_eq!( target_ptr.align_offset(crate::mem::align_of::()), 0 ); #[allow(clippy::cast_ptr_alignment)] *(target_ptr as *const Self) } /// Instantiates a new vector with the values of the `slice`. /// /// # Safety /// /// If `slice.len() < Self::lanes()` the behavior is undefined. #[inline] pub unsafe fn from_slice_unaligned_unchecked( slice: &[$elem_ty], ) -> Self { use crate::mem::size_of; debug_assert!(slice.len() >= $elem_count); let target_ptr = slice.get_unchecked(0) as *const $elem_ty as *const u8; let mut x = Self::splat(0 as $elem_ty); let self_ptr = &mut x as *mut Self as *mut u8; crate::ptr::copy_nonoverlapping( target_ptr, self_ptr, size_of::(), ); x } } test_if! { $test_tt: paste::item! { // Comparisons use integer casts within mantissa^1 range. #[allow(clippy::float_cmp)] pub mod [<$id _slice_from_slice>] { use super::*; use crate::iter::Iterator; #[cfg_attr(not(target_arch = "wasm32"), test)] #[cfg_attr(target_arch = "wasm32", wasm_bindgen_test)] fn from_slice_unaligned() { let mut unaligned = [42 as $elem_ty; $id::lanes() + 1]; unaligned[0] = 0 as $elem_ty; let vec = $id::from_slice_unaligned(&unaligned[1..]); for (index, &b) in unaligned.iter().enumerate() { if index == 0 { assert_eq!(b, 0 as $elem_ty); } else { assert_eq!(b, 42 as $elem_ty); assert_eq!(b, vec.extract(index - 1)); } } } // FIXME: wasm-bindgen-test does not support #[should_panic] // #[cfg_attr(not(target_arch = "wasm32"), test)] // #[cfg_attr(target_arch = "wasm32", wasm_bindgen_test)] #[cfg(not(target_arch = "wasm32"))] #[test] #[should_panic] fn from_slice_unaligned_fail() { let mut unaligned = [42 as $elem_ty; $id::lanes() + 1]; unaligned[0] = 0 as $elem_ty; // the slice is not large enough => panic let _vec = $id::from_slice_unaligned(&unaligned[2..]); } union A { data: [$elem_ty; 2 * $id::lanes()], _vec: $id, } #[cfg_attr(not(target_arch = "wasm32"), test)] #[cfg_attr(target_arch = "wasm32", wasm_bindgen_test)] fn from_slice_aligned() { let mut aligned = A { data: [0 as $elem_ty; 2 * $id::lanes()], }; for i in $id::lanes()..(2 * $id::lanes()) { unsafe { aligned.data[i] = 42 as $elem_ty; } } let vec = unsafe { $id::from_slice_aligned( &aligned.data[$id::lanes()..] ) }; for (index, &b) in unsafe { aligned.data.iter().enumerate() } { if index < $id::lanes() { assert_eq!(b, 0 as $elem_ty); } else { assert_eq!(b, 42 as $elem_ty); assert_eq!( b, vec.extract(index - $id::lanes()) ); } } } // FIXME: wasm-bindgen-test does not support #[should_panic] // #[cfg_attr(not(target_arch = "wasm32"), test)] // #[cfg_attr(target_arch = "wasm32", wasm_bindgen_test)] #[cfg(not(target_arch = "wasm32"))] #[test] #[should_panic] fn from_slice_aligned_fail_lanes() { let aligned = A { data: [0 as $elem_ty; 2 * $id::lanes()], }; let _vec = unsafe { $id::from_slice_aligned( &aligned.data[2 * $id::lanes()..] ) }; } // FIXME: wasm-bindgen-test does not support #[should_panic] // #[cfg_attr(not(target_arch = "wasm32"), test)] // #[cfg_attr(target_arch = "wasm32", wasm_bindgen_test)] #[cfg(not(target_arch = "wasm32"))] #[test] #[should_panic] fn from_slice_aligned_fail_align() { unsafe { let aligned = A { data: [0 as $elem_ty; 2 * $id::lanes()], }; // get a pointer to the front of data let ptr: *const $elem_ty = aligned.data.as_ptr() as *const $elem_ty; // offset pointer by one element let ptr = ptr.wrapping_add(1); if ptr.align_offset( crate::mem::align_of::<$id>() ) == 0 { // the pointer is properly aligned, so // from_slice_aligned won't fail here (e.g. this // can happen for i128x1). So we panic to make // the "should_fail" test pass: panic!("ok"); } // create a slice - this is safe, because the // elements of the slice exist, are properly // initialized, and properly aligned: let s: &[$elem_ty] = slice::from_raw_parts( ptr, $id::lanes() ); // this should always panic because the slice // alignment does not match the alignment // requirements for the vector type: let _vec = $id::from_slice_aligned(s); } } } } } }; }