aarch64/usr/lib/rustlib/src/rust/library/alloc/src/raw_vec/tests.rs - manifest_repos/toolchain - Git at Google

 use super::*;
 use std::cell::Cell;

 #[test]
 fn allocator_param() {
     use crate::alloc::AllocError;

     // Writing a test of integration between third-party
     // allocators and `RawVec` is a little tricky because the `RawVec`
     // API does not expose fallible allocation methods, so we
     // cannot check what happens when allocator is exhausted
     // (beyond detecting a panic).
     //
     // Instead, this just checks that the `RawVec` methods do at
     // least go through the Allocator API when it reserves
     // storage.

     // A dumb allocator that consumes a fixed amount of fuel
     // before allocation attempts start failing.
     struct BoundedAlloc {
         fuel: Cell<usize>,
     }
     unsafe impl Allocator for BoundedAlloc {
         fn allocate(&self, layout: Layout) -> Result<NonNull<[u8]>, AllocError> {
             let size = layout.size();
             if size > self.fuel.get() {
                 return Err(AllocError);
             }
             match Global.allocate(layout) {
                 ok @ Ok(_) => {
                     self.fuel.set(self.fuel.get() - size);
                     ok
                 }
                 err @ Err(_) => err,
             }
         }
         unsafe fn deallocate(&self, ptr: NonNull<u8>, layout: Layout) {
             unsafe { Global.deallocate(ptr, layout) }
         }
     }

     let a = BoundedAlloc { fuel: Cell::new(500) };
     let mut v: RawVec<u8, _> = RawVec::with_capacity_in(50, a);
     assert_eq!(v.alloc.fuel.get(), 450);
     v.reserve(50, 150); // (causes a realloc, thus using 50 + 150 = 200 units of fuel)
     assert_eq!(v.alloc.fuel.get(), 250);
 }

 #[test]
 fn reserve_does_not_overallocate() {
     {
         let mut v: RawVec<u32> = RawVec::new();
         // First, `reserve` allocates like `reserve_exact`.
         v.reserve(0, 9);
         assert_eq!(9, v.capacity());
     }

     {
         let mut v: RawVec<u32> = RawVec::new();
         v.reserve(0, 7);
         assert_eq!(7, v.capacity());
         // 97 is more than double of 7, so `reserve` should work
         // like `reserve_exact`.
         v.reserve(7, 90);
         assert_eq!(97, v.capacity());
     }

     {
         let mut v: RawVec<u32> = RawVec::new();
         v.reserve(0, 12);
         assert_eq!(12, v.capacity());
         v.reserve(12, 3);
         // 3 is less than half of 12, so `reserve` must grow
         // exponentially. At the time of writing this test grow
         // factor is 2, so new capacity is 24, however, grow factor
         // of 1.5 is OK too. Hence `>= 18` in assert.
         assert!(v.capacity() >= 12 + 12 / 2);
     }
 }

 struct ZST;

 // A `RawVec` holding zero-sized elements should always look like this.
 fn zst_sanity<T>(v: &RawVec<T>) {
     assert_eq!(v.capacity(), usize::MAX);
     assert_eq!(v.ptr(), core::ptr::Unique::<T>::dangling().as_ptr());
     assert_eq!(v.current_memory(), None);
 }

 #[test]
 fn zst() {
     let cap_err = Err(crate::collections::TryReserveErrorKind::CapacityOverflow.into());

     assert_eq!(std::mem::size_of::<ZST>(), 0);

     // All these different ways of creating the RawVec produce the same thing.

     let v: RawVec<ZST> = RawVec::new();
     zst_sanity(&v);

     let v: RawVec<ZST> = RawVec::with_capacity_in(100, Global);
     zst_sanity(&v);

     let v: RawVec<ZST> = RawVec::with_capacity_in(100, Global);
     zst_sanity(&v);

     let v: RawVec<ZST> = RawVec::allocate_in(0, AllocInit::Uninitialized, Global);
     zst_sanity(&v);

     let v: RawVec<ZST> = RawVec::allocate_in(100, AllocInit::Uninitialized, Global);
     zst_sanity(&v);

     let mut v: RawVec<ZST> = RawVec::allocate_in(usize::MAX, AllocInit::Uninitialized, Global);
     zst_sanity(&v);

     // Check all these operations work as expected with zero-sized elements.

     assert!(!v.needs_to_grow(100, usize::MAX - 100));
     assert!(v.needs_to_grow(101, usize::MAX - 100));
     zst_sanity(&v);

     v.reserve(100, usize::MAX - 100);
     //v.reserve(101, usize::MAX - 100); // panics, in `zst_reserve_panic` below
     zst_sanity(&v);

     v.reserve_exact(100, usize::MAX - 100);
     //v.reserve_exact(101, usize::MAX - 100); // panics, in `zst_reserve_exact_panic` below
     zst_sanity(&v);

     assert_eq!(v.try_reserve(100, usize::MAX - 100), Ok(()));
     assert_eq!(v.try_reserve(101, usize::MAX - 100), cap_err);
     zst_sanity(&v);

     assert_eq!(v.try_reserve_exact(100, usize::MAX - 100), Ok(()));
     assert_eq!(v.try_reserve_exact(101, usize::MAX - 100), cap_err);
     zst_sanity(&v);

     assert_eq!(v.grow_amortized(100, usize::MAX - 100), cap_err);
     assert_eq!(v.grow_amortized(101, usize::MAX - 100), cap_err);
     zst_sanity(&v);

     assert_eq!(v.grow_exact(100, usize::MAX - 100), cap_err);
     assert_eq!(v.grow_exact(101, usize::MAX - 100), cap_err);
     zst_sanity(&v);
 }

 #[test]
 #[should_panic(expected = "capacity overflow")]
 fn zst_reserve_panic() {
     let mut v: RawVec<ZST> = RawVec::new();
     zst_sanity(&v);

     v.reserve(101, usize::MAX - 100);
 }

 #[test]
 #[should_panic(expected = "capacity overflow")]
 fn zst_reserve_exact_panic() {
     let mut v: RawVec<ZST> = RawVec::new();
     zst_sanity(&v);

     v.reserve_exact(101, usize::MAX - 100);
 }
	use super::*;
	use std::cell::Cell;

	#[test]
	fn allocator_param() {
	use crate::alloc::AllocError;

	// Writing a test of integration between third-party
	// allocators and `RawVec` is a little tricky because the `RawVec`
	// API does not expose fallible allocation methods, so we
	// cannot check what happens when allocator is exhausted
	// (beyond detecting a panic).
	//
	// Instead, this just checks that the `RawVec` methods do at
	// least go through the Allocator API when it reserves
	// storage.

	// A dumb allocator that consumes a fixed amount of fuel
	// before allocation attempts start failing.
	struct BoundedAlloc {
	fuel: Cell<usize>,
	}
	unsafe impl Allocator for BoundedAlloc {
	fn allocate(&self, layout: Layout) -> Result<NonNull<[u8]>, AllocError> {
	let size = layout.size();
	if size > self.fuel.get() {
	return Err(AllocError);
	}
	match Global.allocate(layout) {
	ok @ Ok(_) => {
	self.fuel.set(self.fuel.get() - size);
	ok
	}
	err @ Err(_) => err,
	}
	}
	unsafe fn deallocate(&self, ptr: NonNull<u8>, layout: Layout) {
	unsafe { Global.deallocate(ptr, layout) }
	}
	}

	let a = BoundedAlloc { fuel: Cell::new(500) };
	let mut v: RawVec<u8, _> = RawVec::with_capacity_in(50, a);
	assert_eq!(v.alloc.fuel.get(), 450);
	v.reserve(50, 150); // (causes a realloc, thus using 50 + 150 = 200 units of fuel)
	assert_eq!(v.alloc.fuel.get(), 250);
	}

	#[test]
	fn reserve_does_not_overallocate() {
	{
	let mut v: RawVec<u32> = RawVec::new();
	// First, `reserve` allocates like `reserve_exact`.
	v.reserve(0, 9);
	assert_eq!(9, v.capacity());
	}

	{
	let mut v: RawVec<u32> = RawVec::new();
	v.reserve(0, 7);
	assert_eq!(7, v.capacity());
	// 97 is more than double of 7, so `reserve` should work
	// like `reserve_exact`.
	v.reserve(7, 90);
	assert_eq!(97, v.capacity());
	}

	{
	let mut v: RawVec<u32> = RawVec::new();
	v.reserve(0, 12);
	assert_eq!(12, v.capacity());
	v.reserve(12, 3);
	// 3 is less than half of 12, so `reserve` must grow
	// exponentially. At the time of writing this test grow
	// factor is 2, so new capacity is 24, however, grow factor
	// of 1.5 is OK too. Hence `>= 18` in assert.
	assert!(v.capacity() >= 12 + 12 / 2);
	}
	}

	struct ZST;

	// A `RawVec` holding zero-sized elements should always look like this.
	fn zst_sanity<T>(v: &RawVec<T>) {
	assert_eq!(v.capacity(), usize::MAX);
	assert_eq!(v.ptr(), core::ptr::Unique::<T>::dangling().as_ptr());
	assert_eq!(v.current_memory(), None);
	}

	#[test]
	fn zst() {
	let cap_err = Err(crate::collections::TryReserveErrorKind::CapacityOverflow.into());

	assert_eq!(std::mem::size_of::<ZST>(), 0);

	// All these different ways of creating the RawVec produce the same thing.

	let v: RawVec<ZST> = RawVec::new();
	zst_sanity(&v);

	let v: RawVec<ZST> = RawVec::with_capacity_in(100, Global);
	zst_sanity(&v);

	let v: RawVec<ZST> = RawVec::with_capacity_in(100, Global);
	zst_sanity(&v);

	let v: RawVec<ZST> = RawVec::allocate_in(0, AllocInit::Uninitialized, Global);
	zst_sanity(&v);

	let v: RawVec<ZST> = RawVec::allocate_in(100, AllocInit::Uninitialized, Global);
	zst_sanity(&v);

	let mut v: RawVec<ZST> = RawVec::allocate_in(usize::MAX, AllocInit::Uninitialized, Global);
	zst_sanity(&v);

	// Check all these operations work as expected with zero-sized elements.

	assert!(!v.needs_to_grow(100, usize::MAX - 100));
	assert!(v.needs_to_grow(101, usize::MAX - 100));
	zst_sanity(&v);

	v.reserve(100, usize::MAX - 100);
	//v.reserve(101, usize::MAX - 100); // panics, in `zst_reserve_panic` below
	zst_sanity(&v);

	v.reserve_exact(100, usize::MAX - 100);
	//v.reserve_exact(101, usize::MAX - 100); // panics, in `zst_reserve_exact_panic` below
	zst_sanity(&v);

	assert_eq!(v.try_reserve(100, usize::MAX - 100), Ok(()));
	assert_eq!(v.try_reserve(101, usize::MAX - 100), cap_err);
	zst_sanity(&v);

	assert_eq!(v.try_reserve_exact(100, usize::MAX - 100), Ok(()));
	assert_eq!(v.try_reserve_exact(101, usize::MAX - 100), cap_err);
	zst_sanity(&v);

	assert_eq!(v.grow_amortized(100, usize::MAX - 100), cap_err);
	assert_eq!(v.grow_amortized(101, usize::MAX - 100), cap_err);
	zst_sanity(&v);

	assert_eq!(v.grow_exact(100, usize::MAX - 100), cap_err);
	assert_eq!(v.grow_exact(101, usize::MAX - 100), cap_err);
	zst_sanity(&v);
	}

	#[test]
	#[should_panic(expected = "capacity overflow")]
	fn zst_reserve_panic() {
	let mut v: RawVec<ZST> = RawVec::new();
	zst_sanity(&v);

	v.reserve(101, usize::MAX - 100);
	}

	#[test]
	#[should_panic(expected = "capacity overflow")]
	fn zst_reserve_exact_panic() {
	let mut v: RawVec<ZST> = RawVec::new();
	zst_sanity(&v);

	v.reserve_exact(101, usize::MAX - 100);
	}