use core::mem::size_of; use bytemuck::*; #[test] fn test_try_cast_slice() { // some align4 data let u32_slice: &[u32] = &[4, 5, 6]; // the same data as align1 let the_bytes: &[u8] = try_cast_slice(u32_slice).unwrap(); assert_eq!( u32_slice.as_ptr() as *const u32 as usize, the_bytes.as_ptr() as *const u8 as usize ); assert_eq!( u32_slice.len() * size_of::(), the_bytes.len() * size_of::() ); // by taking one byte off the front, we're definitely mis-aligned for u32. let mis_aligned_bytes = &the_bytes[1..]; assert_eq!( try_cast_slice::(mis_aligned_bytes), Err(PodCastError::TargetAlignmentGreaterAndInputNotAligned) ); // by taking one byte off the end, we're aligned but would have slop bytes for u32 let the_bytes_len_minus1 = the_bytes.len() - 1; let slop_bytes = &the_bytes[..the_bytes_len_minus1]; assert_eq!( try_cast_slice::(slop_bytes), Err(PodCastError::OutputSliceWouldHaveSlop) ); // if we don't mess with it we can up-alignment cast try_cast_slice::(the_bytes).unwrap(); } #[test] fn test_try_cast_slice_mut() { // some align4 data let u32_slice: &mut [u32] = &mut [4, 5, 6]; let u32_len = u32_slice.len(); let u32_ptr = u32_slice.as_ptr(); // the same data as align1 let the_bytes: &mut [u8] = try_cast_slice_mut(u32_slice).unwrap(); let the_bytes_len = the_bytes.len(); let the_bytes_ptr = the_bytes.as_ptr(); assert_eq!( u32_ptr as *const u32 as usize, the_bytes_ptr as *const u8 as usize ); assert_eq!(u32_len * size_of::(), the_bytes_len * size_of::()); // by taking one byte off the front, we're definitely mis-aligned for u32. let mis_aligned_bytes = &mut the_bytes[1..]; assert_eq!( try_cast_slice_mut::(mis_aligned_bytes), Err(PodCastError::TargetAlignmentGreaterAndInputNotAligned) ); // by taking one byte off the end, we're aligned but would have slop bytes for u32 let the_bytes_len_minus1 = the_bytes.len() - 1; let slop_bytes = &mut the_bytes[..the_bytes_len_minus1]; assert_eq!( try_cast_slice_mut::(slop_bytes), Err(PodCastError::OutputSliceWouldHaveSlop) ); // if we don't mess with it we can up-alignment cast try_cast_slice_mut::(the_bytes).unwrap(); } #[test] fn test_types() { let _: i32 = cast(1.0_f32); let _: &mut i32 = cast_mut(&mut 1.0_f32); let _: &i32 = cast_ref(&1.0_f32); let _: &[i32] = cast_slice(&[1.0_f32]); let _: &mut [i32] = cast_slice_mut(&mut [1.0_f32]); // let _: Result = try_cast(1.0_f32); let _: Result<&mut i32, PodCastError> = try_cast_mut(&mut 1.0_f32); let _: Result<&i32, PodCastError> = try_cast_ref(&1.0_f32); let _: Result<&[i32], PodCastError> = try_cast_slice(&[1.0_f32]); let _: Result<&mut [i32], PodCastError> = try_cast_slice_mut(&mut [1.0_f32]); } #[test] fn test_bytes_of() { assert_eq!(bytes_of(&0xaabbccdd_u32), &0xaabbccdd_u32.to_ne_bytes()); assert_eq!(bytes_of_mut(&mut 0xaabbccdd_u32), &mut 0xaabbccdd_u32.to_ne_bytes()); let mut a = 0xaabbccdd_u32; let a_addr = &a as *const _ as usize; // ensure addresses match. assert_eq!(bytes_of(&a).as_ptr() as usize, a_addr); assert_eq!(bytes_of_mut(&mut a).as_ptr() as usize, a_addr); } #[test] fn test_try_from_bytes() { let u32s = [0xaabbccdd, 0x11223344_u32]; let bytes = bytemuck::cast_slice::(&u32s); assert_eq!(try_from_bytes::(&bytes[..4]), Ok(&u32s[0])); assert_eq!(try_from_bytes::(&bytes[..5]), Err(PodCastError::SizeMismatch)); assert_eq!(try_from_bytes::(&bytes[..3]), Err(PodCastError::SizeMismatch)); assert_eq!(try_from_bytes::(&bytes[1..5]), Err(PodCastError::TargetAlignmentGreaterAndInputNotAligned)); } #[test] fn test_try_from_bytes_mut() { let mut abcd = 0xaabbccdd; let mut u32s = [abcd, 0x11223344_u32]; let bytes = bytemuck::cast_slice_mut::(&mut u32s); assert_eq!(try_from_bytes_mut::(&mut bytes[..4]), Ok(&mut abcd)); assert_eq!(try_from_bytes_mut::(&mut bytes[..4]), Ok(&mut abcd)); assert_eq!(try_from_bytes_mut::(&mut bytes[..5]), Err(PodCastError::SizeMismatch)); assert_eq!(try_from_bytes_mut::(&mut bytes[..3]), Err(PodCastError::SizeMismatch)); assert_eq!(try_from_bytes::(&mut bytes[1..5]), Err(PodCastError::TargetAlignmentGreaterAndInputNotAligned)); } #[test] fn test_from_bytes() { let abcd = 0xaabbccdd_u32; let aligned_bytes = bytemuck::bytes_of(&abcd); assert_eq!(from_bytes::(aligned_bytes), &abcd); assert!(core::ptr::eq(from_bytes(aligned_bytes), &abcd)); } #[test] fn test_from_bytes_mut() { let mut a = 0xaabbccdd_u32; let a_addr = &a as *const _ as usize; let aligned_bytes = bytemuck::bytes_of_mut(&mut a); assert_eq!(*from_bytes_mut::(aligned_bytes), 0xaabbccdd_u32); assert_eq!(from_bytes_mut::(aligned_bytes) as *const u32 as usize, a_addr); } // like #[should_panic], but can be a part of another test, instead of requiring // it to be it's own test. macro_rules! should_panic { ($ex:expr) => { assert!( std::panic::catch_unwind(|| { let _ = $ex; }).is_err(), concat!("should have panicked: `", stringify!($ex), "`") ); }; } #[test] fn test_panics() { should_panic!(cast_slice::(&[1u8, 2u8])); should_panic!(cast_slice_mut::(&mut [1u8, 2u8])); should_panic!(from_bytes::(&[1u8, 2])); should_panic!(from_bytes::(&[1u8, 2, 3, 4, 5])); should_panic!(from_bytes_mut::(&mut [1u8, 2])); should_panic!(from_bytes_mut::(&mut [1u8, 2, 3, 4, 5])); // use cast_slice on some u32s to get some align>=4 bytes, so we can know // we'll give from_bytes unaligned ones. let aligned_bytes = bytemuck::cast_slice::(&[0, 0]); should_panic!(from_bytes::(&aligned_bytes[1..5])); }