tests/cast_slice_tests.rs - platform/external/rust/crates/bytemuck - Git at Google

 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::<u32>(),
     the_bytes.len() * size_of::<u8>()
   );

   // 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::<u8, u32>(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::<u8, u32>(slop_bytes),
     Err(PodCastError::OutputSliceWouldHaveSlop)
   );

   // if we don't mess with it we can up-alignment cast
   try_cast_slice::<u8, u32>(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::<u32>(), the_bytes_len * size_of::<u8>());

   // 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::<u8, u32>(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::<u8, u32>(slop_bytes),
     Err(PodCastError::OutputSliceWouldHaveSlop)
   );

   // if we don't mess with it we can up-alignment cast
   try_cast_slice_mut::<u8, u32>(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<i32, PodCastError> = 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::<u32, u8>(&u32s);
   assert_eq!(try_from_bytes::<u32>(&bytes[..4]), Ok(&u32s[0]));
   assert_eq!(
     try_from_bytes::<u32>(&bytes[..5]),
     Err(PodCastError::SizeMismatch)
   );
   assert_eq!(
     try_from_bytes::<u32>(&bytes[..3]),
     Err(PodCastError::SizeMismatch)
   );
   assert_eq!(
     try_from_bytes::<u32>(&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::<u32, u8>(&mut u32s);
   assert_eq!(try_from_bytes_mut::<u32>(&mut bytes[..4]), Ok(&mut abcd));
   assert_eq!(try_from_bytes_mut::<u32>(&mut bytes[..4]), Ok(&mut abcd));
   assert_eq!(
     try_from_bytes_mut::<u32>(&mut bytes[..5]),
     Err(PodCastError::SizeMismatch)
   );
   assert_eq!(
     try_from_bytes_mut::<u32>(&mut bytes[..3]),
     Err(PodCastError::SizeMismatch)
   );
   assert_eq!(
     try_from_bytes::<u32>(&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::<u32>(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::<u32>(aligned_bytes), 0xaabbccdd_u32);
   assert_eq!(
     from_bytes_mut::<u32>(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::<u8, u32>(&[1u8, 2u8]));
   should_panic!(cast_slice_mut::<u8, u32>(&mut [1u8, 2u8]));
   should_panic!(from_bytes::<u32>(&[1u8, 2]));
   should_panic!(from_bytes::<u32>(&[1u8, 2, 3, 4, 5]));
   should_panic!(from_bytes_mut::<u32>(&mut [1u8, 2]));
   should_panic!(from_bytes_mut::<u32>(&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::<u32, u8>(&[0, 0]);
   should_panic!(from_bytes::<u32>(&aligned_bytes[1..5]));
 }
	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::<u32>(),
	the_bytes.len() * size_of::<u8>()
	);

	// 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::<u8, u32>(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::<u8, u32>(slop_bytes),
	Err(PodCastError::OutputSliceWouldHaveSlop)
	);

	// if we don't mess with it we can up-alignment cast
	try_cast_slice::<u8, u32>(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::<u32>(), the_bytes_len * size_of::<u8>());

	// 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::<u8, u32>(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::<u8, u32>(slop_bytes),
	Err(PodCastError::OutputSliceWouldHaveSlop)
	);

	// if we don't mess with it we can up-alignment cast
	try_cast_slice_mut::<u8, u32>(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<i32, PodCastError> = 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::<u32, u8>(&u32s);
	assert_eq!(try_from_bytes::<u32>(&bytes[..4]), Ok(&u32s[0]));
	assert_eq!(
	try_from_bytes::<u32>(&bytes[..5]),
	Err(PodCastError::SizeMismatch)
	);
	assert_eq!(
	try_from_bytes::<u32>(&bytes[..3]),
	Err(PodCastError::SizeMismatch)
	);
	assert_eq!(
	try_from_bytes::<u32>(&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::<u32, u8>(&mut u32s);
	assert_eq!(try_from_bytes_mut::<u32>(&mut bytes[..4]), Ok(&mut abcd));
	assert_eq!(try_from_bytes_mut::<u32>(&mut bytes[..4]), Ok(&mut abcd));
	assert_eq!(
	try_from_bytes_mut::<u32>(&mut bytes[..5]),
	Err(PodCastError::SizeMismatch)
	);
	assert_eq!(
	try_from_bytes_mut::<u32>(&mut bytes[..3]),
	Err(PodCastError::SizeMismatch)
	);
	assert_eq!(
	try_from_bytes::<u32>(&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::<u32>(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::<u32>(aligned_bytes), 0xaabbccdd_u32);
	assert_eq!(
	from_bytes_mut::<u32>(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::<u8, u32>(&[1u8, 2u8]));
	should_panic!(cast_slice_mut::<u8, u32>(&mut [1u8, 2u8]));
	should_panic!(from_bytes::<u32>(&[1u8, 2]));
	should_panic!(from_bytes::<u32>(&[1u8, 2, 3, 4, 5]));
	should_panic!(from_bytes_mut::<u32>(&mut [1u8, 2]));
	should_panic!(from_bytes_mut::<u32>(&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::<u32, u8>(&[0, 0]);
	should_panic!(from_bytes::<u32>(&aligned_bytes[1..5]));
	}