arm/usr/lib/rustlib/src/rust/library/alloc/tests/boxed.rs - manifest_repos/toolchain - Git at Google

 use core::alloc::{AllocError, Allocator, Layout};
 use core::cell::Cell;
 use core::mem::MaybeUninit;
 use core::ptr::NonNull;

 #[test]
 fn uninitialized_zero_size_box() {
     assert_eq!(
         &*Box::<()>::new_uninit() as *const _,
         NonNull::<MaybeUninit<()>>::dangling().as_ptr(),
     );
     assert_eq!(
         Box::<[()]>::new_uninit_slice(4).as_ptr(),
         NonNull::<MaybeUninit<()>>::dangling().as_ptr(),
     );
     assert_eq!(
         Box::<[String]>::new_uninit_slice(0).as_ptr(),
         NonNull::<MaybeUninit<String>>::dangling().as_ptr(),
     );
 }

 #[derive(Clone, PartialEq, Eq, Debug)]
 struct Dummy {
     _data: u8,
 }

 #[test]
 fn box_clone_and_clone_from_equivalence() {
     for size in (0..8).map(|i| 2usize.pow(i)) {
         let control = vec![Dummy { _data: 42 }; size].into_boxed_slice();
         let clone = control.clone();
         let mut copy = vec![Dummy { _data: 84 }; size].into_boxed_slice();
         copy.clone_from(&control);
         assert_eq!(control, clone);
         assert_eq!(control, copy);
     }
 }

 /// This test might give a false positive in case the box reallocates,
 /// but the allocator keeps the original pointer.
 ///
 /// On the other hand, it won't give a false negative: If it fails, then the
 /// memory was definitely not reused.
 #[test]
 fn box_clone_from_ptr_stability() {
     for size in (0..8).map(|i| 2usize.pow(i)) {
         let control = vec![Dummy { _data: 42 }; size].into_boxed_slice();
         let mut copy = vec![Dummy { _data: 84 }; size].into_boxed_slice();
         let copy_raw = copy.as_ptr() as usize;
         copy.clone_from(&control);
         assert_eq!(copy.as_ptr() as usize, copy_raw);
     }
 }

 #[test]
 fn box_deref_lval() {
     let x = Box::new(Cell::new(5));
     x.set(1000);
     assert_eq!(x.get(), 1000);
 }

 pub struct ConstAllocator;

 unsafe impl const Allocator for ConstAllocator {
     fn allocate(&self, layout: Layout) -> Result<NonNull<[u8]>, AllocError> {
         match layout.size() {
             0 => Ok(NonNull::slice_from_raw_parts(layout.dangling(), 0)),
             _ => unsafe {
                 let ptr = core::intrinsics::const_allocate(layout.size(), layout.align());
                 Ok(NonNull::new_unchecked(ptr as *mut [u8; 0] as *mut [u8]))
             },
         }
     }

     unsafe fn deallocate(&self, _ptr: NonNull<u8>, layout: Layout) {
         match layout.size() {
             0 => { /* do nothing */ }
             _ => { /* do nothing too */ }
         }
     }

     fn allocate_zeroed(&self, layout: Layout) -> Result<NonNull<[u8]>, AllocError> {
         let ptr = self.allocate(layout)?;
         if layout.size() > 0 {
             unsafe {
                 ptr.as_mut_ptr().write_bytes(0, layout.size());
             }
         }
         Ok(ptr)
     }

     unsafe fn grow(
         &self,
         ptr: NonNull<u8>,
         old_layout: Layout,
         new_layout: Layout,
     ) -> Result<NonNull<[u8]>, AllocError> {
         debug_assert!(
             new_layout.size() >= old_layout.size(),
             "`new_layout.size()` must be greater than or equal to `old_layout.size()`"
         );

         let new_ptr = self.allocate(new_layout)?;
         if new_layout.size() > 0 {
             // Safety: `new_ptr` is valid for writes and `ptr` for reads of
             // `old_layout.size()`, because `new_layout.size() >=
             // old_layout.size()` (which is an invariant that must be upheld by
             // callers).
             unsafe {
                 new_ptr.as_mut_ptr().copy_from_nonoverlapping(ptr.as_ptr(), old_layout.size());
             }
             // Safety: `ptr` is never used again is also an invariant which must
             // be upheld by callers.
             unsafe {
                 self.deallocate(ptr, old_layout);
             }
         }
         Ok(new_ptr)
     }

     unsafe fn grow_zeroed(
         &self,
         ptr: NonNull<u8>,
         old_layout: Layout,
         new_layout: Layout,
     ) -> Result<NonNull<[u8]>, AllocError> {
         // Safety: Invariants of `grow_zeroed` and `grow` are the same, and must
         // be enforced by callers.
         let new_ptr = unsafe { self.grow(ptr, old_layout, new_layout)? };
         if new_layout.size() > 0 {
             let old_size = old_layout.size();
             let new_size = new_layout.size();
             let raw_ptr = new_ptr.as_mut_ptr();
             // Safety:
             // - `grow` returned Ok, so the returned pointer must be valid for
             //   `new_size` bytes
             // - `new_size` must be larger than `old_size`, which is an
             //   invariant which must be upheld by callers.
             unsafe {
                 raw_ptr.add(old_size).write_bytes(0, new_size - old_size);
             }
         }
         Ok(new_ptr)
     }

     unsafe fn shrink(
         &self,
         ptr: NonNull<u8>,
         old_layout: Layout,
         new_layout: Layout,
     ) -> Result<NonNull<[u8]>, AllocError> {
         debug_assert!(
             new_layout.size() <= old_layout.size(),
             "`new_layout.size()` must be smaller than or equal to `old_layout.size()`"
         );

         let new_ptr = self.allocate(new_layout)?;
         if new_layout.size() > 0 {
             // Safety: `new_ptr` and `ptr` are valid for reads/writes of
             // `new_layout.size()` because of the invariants of shrink, which
             // include `new_layout.size()` being smaller than (or equal to)
             // `old_layout.size()`.
             unsafe {
                 new_ptr.as_mut_ptr().copy_from_nonoverlapping(ptr.as_ptr(), new_layout.size());
             }
             // Safety: `ptr` is never used again is also an invariant which must
             // be upheld by callers.
             unsafe {
                 self.deallocate(ptr, old_layout);
             }
         }
         Ok(new_ptr)
     }

     fn by_ref(&self) -> &Self
     where
         Self: Sized,
     {
         self
     }
 }

 #[test]
 fn const_box() {
     const VALUE: u32 = {
         let mut boxed = Box::new_in(1u32, ConstAllocator);
         assert!(*boxed == 1);

         *boxed = 42;
         assert!(*boxed == 42);

         *Box::leak(boxed)
     };

     assert!(VALUE == 42);
 }
	use core::alloc::{AllocError, Allocator, Layout};
	use core::cell::Cell;
	use core::mem::MaybeUninit;
	use core::ptr::NonNull;

	#[test]
	fn uninitialized_zero_size_box() {
	assert_eq!(
	&Box::<()>::new_uninit() as const _,
	NonNull::<MaybeUninit<()>>::dangling().as_ptr(),
	);
	assert_eq!(
	Box::<[()]>::new_uninit_slice(4).as_ptr(),
	NonNull::<MaybeUninit<()>>::dangling().as_ptr(),
	);
	assert_eq!(
	Box::<[String]>::new_uninit_slice(0).as_ptr(),
	NonNull::<MaybeUninit<String>>::dangling().as_ptr(),
	);
	}

	#[derive(Clone, PartialEq, Eq, Debug)]
	struct Dummy {
	_data: u8,
	}

	#[test]
	fn box_clone_and_clone_from_equivalence() {
	for size in (0..8).map(\|i\| 2usize.pow(i)) {
	let control = vec![Dummy { _data: 42 }; size].into_boxed_slice();
	let clone = control.clone();
	let mut copy = vec![Dummy { _data: 84 }; size].into_boxed_slice();
	copy.clone_from(&control);
	assert_eq!(control, clone);
	assert_eq!(control, copy);
	}
	}

	/// This test might give a false positive in case the box reallocates,
	/// but the allocator keeps the original pointer.
	///
	/// On the other hand, it won't give a false negative: If it fails, then the
	/// memory was definitely not reused.
	#[test]
	fn box_clone_from_ptr_stability() {
	for size in (0..8).map(\|i\| 2usize.pow(i)) {
	let control = vec![Dummy { _data: 42 }; size].into_boxed_slice();
	let mut copy = vec![Dummy { _data: 84 }; size].into_boxed_slice();
	let copy_raw = copy.as_ptr() as usize;
	copy.clone_from(&control);
	assert_eq!(copy.as_ptr() as usize, copy_raw);
	}
	}

	#[test]
	fn box_deref_lval() {
	let x = Box::new(Cell::new(5));
	x.set(1000);
	assert_eq!(x.get(), 1000);
	}

	pub struct ConstAllocator;

	unsafe impl const Allocator for ConstAllocator {
	fn allocate(&self, layout: Layout) -> Result<NonNull<[u8]>, AllocError> {
	match layout.size() {
	0 => Ok(NonNull::slice_from_raw_parts(layout.dangling(), 0)),
	_ => unsafe {
	let ptr = core::intrinsics::const_allocate(layout.size(), layout.align());
	Ok(NonNull::new_unchecked(ptr as mut [u8; 0] as mut [u8]))
	},
	}
	}

	unsafe fn deallocate(&self, _ptr: NonNull<u8>, layout: Layout) {
	match layout.size() {
	0 => { /* do nothing */ }
	_ => { /* do nothing too */ }
	}
	}

	fn allocate_zeroed(&self, layout: Layout) -> Result<NonNull<[u8]>, AllocError> {
	let ptr = self.allocate(layout)?;
	if layout.size() > 0 {
	unsafe {
	ptr.as_mut_ptr().write_bytes(0, layout.size());
	}
	}
	Ok(ptr)
	}

	unsafe fn grow(
	&self,
	ptr: NonNull<u8>,
	old_layout: Layout,
	new_layout: Layout,
	) -> Result<NonNull<[u8]>, AllocError> {
	debug_assert!(
	new_layout.size() >= old_layout.size(),
	"`new_layout.size()` must be greater than or equal to `old_layout.size()`"
	);

	let new_ptr = self.allocate(new_layout)?;
	if new_layout.size() > 0 {
	// Safety: `new_ptr` is valid for writes and `ptr` for reads of
	// `old_layout.size()`, because `new_layout.size() >=
	// old_layout.size()` (which is an invariant that must be upheld by
	// callers).
	unsafe {
	new_ptr.as_mut_ptr().copy_from_nonoverlapping(ptr.as_ptr(), old_layout.size());
	}
	// Safety: `ptr` is never used again is also an invariant which must
	// be upheld by callers.
	unsafe {
	self.deallocate(ptr, old_layout);
	}
	}
	Ok(new_ptr)
	}

	unsafe fn grow_zeroed(
	&self,
	ptr: NonNull<u8>,
	old_layout: Layout,
	new_layout: Layout,
	) -> Result<NonNull<[u8]>, AllocError> {
	// Safety: Invariants of `grow_zeroed` and `grow` are the same, and must
	// be enforced by callers.
	let new_ptr = unsafe { self.grow(ptr, old_layout, new_layout)? };
	if new_layout.size() > 0 {
	let old_size = old_layout.size();
	let new_size = new_layout.size();
	let raw_ptr = new_ptr.as_mut_ptr();
	// Safety:
	// - `grow` returned Ok, so the returned pointer must be valid for
	// `new_size` bytes
	// - `new_size` must be larger than `old_size`, which is an
	// invariant which must be upheld by callers.
	unsafe {
	raw_ptr.add(old_size).write_bytes(0, new_size - old_size);
	}
	}
	Ok(new_ptr)
	}

	unsafe fn shrink(
	&self,
	ptr: NonNull<u8>,
	old_layout: Layout,
	new_layout: Layout,
	) -> Result<NonNull<[u8]>, AllocError> {
	debug_assert!(
	new_layout.size() <= old_layout.size(),
	"`new_layout.size()` must be smaller than or equal to `old_layout.size()`"
	);

	let new_ptr = self.allocate(new_layout)?;
	if new_layout.size() > 0 {
	// Safety: `new_ptr` and `ptr` are valid for reads/writes of
	// `new_layout.size()` because of the invariants of shrink, which
	// include `new_layout.size()` being smaller than (or equal to)
	// `old_layout.size()`.
	unsafe {
	new_ptr.as_mut_ptr().copy_from_nonoverlapping(ptr.as_ptr(), new_layout.size());
	}
	// Safety: `ptr` is never used again is also an invariant which must
	// be upheld by callers.
	unsafe {
	self.deallocate(ptr, old_layout);
	}
	}
	Ok(new_ptr)
	}

	fn by_ref(&self) -> &Self
	where
	Self: Sized,
	{
	self
	}
	}

	#[test]
	fn const_box() {
	const VALUE: u32 = {
	let mut boxed = Box::new_in(1u32, ConstAllocator);
	assert!(*boxed == 1);

	*boxed = 42;
	assert!(*boxed == 42);

	*Box::leak(boxed)
	};

	assert!(VALUE == 42);
	}