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

 #![cfg(feature = "alloc")]
 #![allow(bad_style)]
 #![allow(clippy::redundant_clone)]

 #[cfg(feature = "serde")]
 use serde_test::{assert_tokens, Token};
 use std::iter::FromIterator;
 use tinyvec::*;

 #[test]
 fn TinyVec_swap_remove() {
   let mut tv: TinyVec<[i32; 10]> = Default::default();
   tv.push(1);
   tv.push(2);
   tv.push(3);
   tv.push(4);
   assert_eq!(tv.swap_remove(3), 4);
   assert_eq!(&tv[..], &[1, 2, 3][..]);
   assert_eq!(tv.swap_remove(0), 1);
   assert_eq!(&tv[..], &[3, 2][..]);
   assert_eq!(tv.swap_remove(0), 3);
   assert_eq!(&tv[..], &[2][..]);
   assert_eq!(tv.swap_remove(0), 2);
   assert_eq!(&tv[..], &[][..]);
 }

 #[test]
 fn TinyVec_capacity() {
   let mut tv: TinyVec<[i32; 1]> = Default::default();
   assert_eq!(tv.capacity(), 1);
   tv.move_to_the_heap();
   tv.extend_from_slice(&[1, 2, 3, 4]);
   assert_eq!(tv.capacity(), 4);
 }

 #[test]
 fn TinyVec_drain() {
   let mut tv: TinyVec<[i32; 10]> = Default::default();
   tv.push(1);
   tv.push(2);
   tv.push(3);

   assert_eq!(Vec::from_iter(tv.clone().drain(..)), vec![1, 2, 3]);

   assert_eq!(Vec::from_iter(tv.clone().drain(..2)), vec![1, 2]);
   assert_eq!(Vec::from_iter(tv.clone().drain(..3)), vec![1, 2, 3]);

   assert_eq!(Vec::from_iter(tv.clone().drain(..=1)), vec![1, 2]);
   assert_eq!(Vec::from_iter(tv.clone().drain(..=2)), vec![1, 2, 3]);

   assert_eq!(Vec::from_iter(tv.clone().drain(0..)), vec![1, 2, 3]);
   assert_eq!(Vec::from_iter(tv.clone().drain(1..)), vec![2, 3]);

   assert_eq!(Vec::from_iter(tv.clone().drain(0..2)), vec![1, 2]);
   assert_eq!(Vec::from_iter(tv.clone().drain(0..3)), vec![1, 2, 3]);
   assert_eq!(Vec::from_iter(tv.clone().drain(1..2)), vec![2]);
   assert_eq!(Vec::from_iter(tv.clone().drain(1..3)), vec![2, 3]);

   assert_eq!(Vec::from_iter(tv.clone().drain(0..=1)), vec![1, 2]);
   assert_eq!(Vec::from_iter(tv.clone().drain(0..=2)), vec![1, 2, 3]);
   assert_eq!(Vec::from_iter(tv.clone().drain(1..=1)), vec![2]);
   assert_eq!(Vec::from_iter(tv.clone().drain(1..=2)), vec![2, 3]);
 }

 #[test]
 fn TinyVec_splice() {
   let mut tv: TinyVec<[i32; 10]> = Default::default();
   tv.push(1);
   tv.push(2);
   tv.push(3);

   // splice returns the same things as drain
   assert_eq!(Vec::from_iter(tv.clone().splice(.., None)), vec![1, 2, 3]);

   assert_eq!(Vec::from_iter(tv.clone().splice(..2, None)), vec![1, 2]);
   assert_eq!(Vec::from_iter(tv.clone().splice(..3, None)), vec![1, 2, 3]);

   assert_eq!(Vec::from_iter(tv.clone().splice(..=1, None)), vec![1, 2]);
   assert_eq!(Vec::from_iter(tv.clone().splice(..=2, None)), vec![1, 2, 3]);

   assert_eq!(Vec::from_iter(tv.clone().splice(0.., None)), vec![1, 2, 3]);
   assert_eq!(Vec::from_iter(tv.clone().splice(1.., None)), vec![2, 3]);

   assert_eq!(Vec::from_iter(tv.clone().splice(0..2, None)), vec![1, 2]);
   assert_eq!(Vec::from_iter(tv.clone().splice(0..3, None)), vec![1, 2, 3]);
   assert_eq!(Vec::from_iter(tv.clone().splice(1..2, None)), vec![2]);
   assert_eq!(Vec::from_iter(tv.clone().splice(1..3, None)), vec![2, 3]);

   assert_eq!(Vec::from_iter(tv.clone().splice(0..=1, None)), vec![1, 2]);
   assert_eq!(Vec::from_iter(tv.clone().splice(0..=2, None)), vec![1, 2, 3]);
   assert_eq!(Vec::from_iter(tv.clone().splice(1..=1, None)), vec![2]);
   assert_eq!(Vec::from_iter(tv.clone().splice(1..=2, None)), vec![2, 3]);

   // splice removes the same things as drain
   let mut tv2 = tv.clone();
   tv2.splice(.., None);
   assert_eq!(tv2, tiny_vec![]);

   let mut tv2 = tv.clone();
   tv2.splice(..2, None);
   assert_eq!(tv2, tiny_vec![3]);

   let mut tv2 = tv.clone();
   tv2.splice(..3, None);
   assert_eq!(tv2, tiny_vec![]);

   let mut tv2 = tv.clone();
   tv2.splice(..=1, None);
   assert_eq!(tv2, tiny_vec![3]);
   let mut tv2 = tv.clone();
   tv2.splice(..=2, None);
   assert_eq!(tv2, tiny_vec![]);

   let mut tv2 = tv.clone();
   tv2.splice(0.., None);
   assert_eq!(tv2, tiny_vec![]);
   let mut tv2 = tv.clone();
   tv2.splice(1.., None);
   assert_eq!(tv2, tiny_vec![1]);

   let mut tv2 = tv.clone();
   tv2.splice(0..2, None);
   assert_eq!(tv2, tiny_vec![3]);

   let mut tv2 = tv.clone();
   tv2.splice(0..3, None);
   assert_eq!(tv2, tiny_vec![]);
   let mut tv2 = tv.clone();
   tv2.splice(1..2, None);
   assert_eq!(tv2, tiny_vec![1, 3]);

   let mut tv2 = tv.clone();
   tv2.splice(1..3, None);
   assert_eq!(tv2, tiny_vec![1]);

   let mut tv2 = tv.clone();
   tv2.splice(0..=1, None);
   assert_eq!(tv2, tiny_vec![3]);

   let mut tv2 = tv.clone();
   tv2.splice(0..=2, None);
   assert_eq!(tv2, tiny_vec![]);

   let mut tv2 = tv.clone();
   tv2.splice(1..=1, None);
   assert_eq!(tv2, tiny_vec![1, 3]);

   let mut tv2 = tv.clone();
   tv2.splice(1..=2, None);
   assert_eq!(tv2, tiny_vec![1]);

   // splice adds the elements correctly
   let mut tv2 = tv.clone();
   tv2.splice(.., 4..=6);
   assert_eq!(tv2, tiny_vec![4, 5, 6]);

   let mut tv2 = tv.clone();
   tv2.splice(..2, 4..=6);
   assert_eq!(tv2, tiny_vec![4, 5, 6, 3]);

   let mut tv2 = tv.clone();
   tv2.splice(..3, 4..=6);
   assert_eq!(tv2, tiny_vec![4, 5, 6]);

   let mut tv2 = tv.clone();
   tv2.splice(..=1, 4..=6);
   assert_eq!(tv2, tiny_vec![4, 5, 6, 3]);

   let mut tv2 = tv.clone();
   tv2.splice(..=2, 4..=6);
   assert_eq!(tv2, tiny_vec![4, 5, 6]);

   let mut tv2 = tv.clone();
   tv2.splice(0.., 4..=6);
   assert_eq!(tv2, tiny_vec![4, 5, 6]);

   let mut tv2 = tv.clone();
   tv2.splice(1.., 4..=6);
   assert_eq!(tv2, tiny_vec![1, 4, 5, 6]);

   let mut tv2 = tv.clone();
   tv2.splice(0..2, 4..=6);
   assert_eq!(tv2, tiny_vec![4, 5, 6, 3]);

   let mut tv2 = tv.clone();
   tv2.splice(0..3, 4..=6);
   assert_eq!(tv2, tiny_vec![4, 5, 6]);

   let mut tv2 = tv.clone();
   tv2.splice(1..2, 4..=6);
   assert_eq!(tv2, tiny_vec![1, 4, 5, 6, 3]);

   let mut tv2 = tv.clone();
   tv2.splice(1..3, 4..=6);
   assert_eq!(tv2, tiny_vec![1, 4, 5, 6]);

   let mut tv2 = tv.clone();
   tv2.splice(0..=1, 4..=6);
   assert_eq!(tv2, tiny_vec![4, 5, 6, 3]);

   let mut tv2 = tv.clone();
   tv2.splice(0..=2, 4..=6);
   assert_eq!(tv2, tiny_vec![4, 5, 6]);

   let mut tv2 = tv.clone();
   tv2.splice(1..=1, 4..=6);
   assert_eq!(tv2, tiny_vec![1, 4, 5, 6, 3]);

   let mut tv2 = tv.clone();
   tv2.splice(1..=2, 4..=6);
   assert_eq!(tv2, tiny_vec![1, 4, 5, 6]);

   // splice adds the elements correctly when the replacement is smaller
   let mut tv2 = tv.clone();
   tv2.splice(.., Some(4));
   assert_eq!(tv2, tiny_vec![4]);

   let mut tv2 = tv.clone();
   tv2.splice(..2, Some(4));
   assert_eq!(tv2, tiny_vec![4, 3]);

   let mut tv2 = tv.clone();
   tv2.splice(1.., Some(4));
   assert_eq!(tv2, tiny_vec![1, 4]);

   let mut tv2 = tv.clone();
   tv2.splice(1..=1, Some(4));
   assert_eq!(tv2, tiny_vec![1, 4, 3]);
 }

 #[test]
 fn TinyVec_resize() {
   let mut tv: TinyVec<[i32; 10]> = Default::default();
   tv.resize(20, 5);
   assert_eq!(&tv[..], &[5; 20]);
 }

 #[test]
 fn TinyVec_from_slice_impl() {
   let bigger_slice: [u8; 11] = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10];
   let tinyvec: TinyVec<[u8; 10]> = TinyVec::Heap((&bigger_slice[..]).into());
   assert_eq!(TinyVec::from(&bigger_slice[..]), tinyvec);

   let smaller_slice: [u8; 5] = [0, 1, 2, 3, 4];
   let tinyvec: TinyVec<[u8; 10]> = TinyVec::Inline(ArrayVec::from_array_len(
     [0, 1, 2, 3, 4, 0, 0, 0, 0, 0],
     5,
   ));
   assert_eq!(TinyVec::from(&smaller_slice[..]), tinyvec);

   let same_size: [u8; 4] = [0, 1, 2, 3];
   let tinyvec: TinyVec<[u8; 4]> =
     TinyVec::Inline(ArrayVec::from_array_len(same_size, 4));
   assert_eq!(TinyVec::from(&same_size[..]), tinyvec);
 }

 #[test]
 fn TinyVec_from_array() {
   let array = [9, 8, 7, 6, 5, 4, 3, 2, 1];
   let tv = TinyVec::from(array);
   assert_eq!(&array, &tv[..]);
 }

 #[test]
 fn TinyVec_macro() {
   let mut expected: TinyVec<[i32; 4]> = Default::default();
   expected.push(1);
   expected.push(2);
   expected.push(3);

   let actual = tiny_vec!(1, 2, 3);

   assert_eq!(expected, actual);

   assert_eq!(tiny_vec![0u8; 4], tiny_vec!(0u8, 0u8, 0u8, 0u8));
   assert_eq!(tiny_vec![0u8; 4], tiny_vec!([u8; 4] => 0, 0, 0, 0));
   assert_eq!(tiny_vec![0; 4], tiny_vec!(0, 0, 0, 0));
   assert_eq!(tiny_vec![0; 4], tiny_vec!([u8; 4] => 0, 0, 0, 0));

   let expected2 = tiny_vec![1.1; 3];
   let actual2 = tiny_vec!([f32; 3] => 1.1, 1.1, 1.1);
   assert_eq!(expected2, actual2);
 }

 #[test]
 fn TinyVec_macro_non_copy() {
   // must use a variable here to avoid macro shenanigans
   let s = String::new();
   let _: TinyVec<[String; 10]> = tiny_vec!([String; 10] => s);
 }

 #[test]
 fn TinyVec_reserve() {
   let mut tv: TinyVec<[i32; 4]> = Default::default();
   assert_eq!(tv.capacity(), 4);
   tv.extend_from_slice(&[1, 2]);
   assert_eq!(tv.capacity(), 4);
   tv.reserve(2);
   assert_eq!(tv.capacity(), 4);
   tv.reserve(4);
   assert!(tv.capacity() >= 6);
   tv.extend_from_slice(&[3, 4, 5, 6]);
   tv.reserve(4);
   assert!(tv.capacity() >= 10);
 }

 #[test]
 fn TinyVec_reserve_exact() {
   let mut tv: TinyVec<[i32; 4]> = Default::default();
   assert_eq!(tv.capacity(), 4);

   tv.extend_from_slice(&[1, 2]);
   assert_eq!(tv.capacity(), 4);
   tv.reserve_exact(2);
   assert_eq!(tv.capacity(), 4);
   tv.reserve_exact(4);
   assert!(tv.capacity() >= 6);
   tv.extend_from_slice(&[3, 4, 5, 6]);
   tv.reserve_exact(4);
   assert!(tv.capacity() >= 10);
 }

 #[test]
 fn TinyVec_move_to_heap_and_shrink() {
   let mut tv: TinyVec<[i32; 4]> = Default::default();
   assert!(tv.is_inline());
   tv.move_to_the_heap();
   assert!(tv.is_heap());
   assert_eq!(tv.capacity(), 0);

   tv.push(1);
   tv.shrink_to_fit();
   assert!(tv.is_inline());
   assert_eq!(tv.capacity(), 4);

   tv.move_to_the_heap_and_reserve(3);
   assert!(tv.is_heap());
   assert_eq!(tv.capacity(), 4);
   tv.extend(2..=4);
   assert_eq!(tv.capacity(), 4);
   assert_eq!(tv.as_slice(), [1, 2, 3, 4]);
 }

 #[cfg(feature = "serde")]
 #[test]
 fn TinyVec_ser_de_empty() {
   let tv: TinyVec<[i32; 0]> = tiny_vec![];

   assert_tokens(&tv, &[Token::Seq { len: Some(0) }, Token::SeqEnd]);
 }

 #[cfg(feature = "serde")]
 #[test]
 fn TinyVec_ser_de() {
   let tv: TinyVec<[i32; 4]> = tiny_vec![1, 2, 3, 4];

   assert_tokens(
     &tv,
     &[
       Token::Seq { len: Some(4) },
       Token::I32(1),
       Token::I32(2),
       Token::I32(3),
       Token::I32(4),
       Token::SeqEnd,
     ],
   );
 }

 #[cfg(feature = "serde")]
 #[test]
 fn TinyVec_ser_de_heap() {
   let mut tv: TinyVec<[i32; 4]> = tiny_vec![1, 2, 3, 4];
   tv.move_to_the_heap();

   assert_tokens(
     &tv,
     &[
       Token::Seq { len: Some(4) },
       Token::I32(1),
       Token::I32(2),
       Token::I32(3),
       Token::I32(4),
       Token::SeqEnd,
     ],
   );
 }

 #[test]
 fn TinyVec_pretty_debug() {
   let tv: TinyVec<[i32; 6]> = tiny_vec![1, 2, 3];
   let s = format!("{:#?}", tv);
   let expected = format!("{:#?}", tv.as_slice());

   assert_eq!(s, expected);
 }

 #[cfg(feature = "std")]
 #[test]
 fn TinyVec_std_io_write() {
   use std::io::Write;
   let mut tv: TinyVec<[u8; 3]> = TinyVec::new();

   tv.write_all(b"foo").ok();
   assert!(tv.is_inline());
   assert_eq!(tv, tiny_vec![b'f', b'o', b'o']);

   tv.write_all(b"bar").ok();
   assert!(tv.is_heap());
   assert_eq!(tv, tiny_vec![b'f', b'o', b'o', b'b', b'a', b'r']);
 }
	#![cfg(feature = "alloc")]
	#![allow(bad_style)]
	#![allow(clippy::redundant_clone)]

	#[cfg(feature = "serde")]
	use serde_test::{assert_tokens, Token};
	use std::iter::FromIterator;
	use tinyvec::*;

	#[test]
	fn TinyVec_swap_remove() {
	let mut tv: TinyVec<[i32; 10]> = Default::default();
	tv.push(1);
	tv.push(2);
	tv.push(3);
	tv.push(4);
	assert_eq!(tv.swap_remove(3), 4);
	assert_eq!(&tv[..], &[1, 2, 3][..]);
	assert_eq!(tv.swap_remove(0), 1);
	assert_eq!(&tv[..], &[3, 2][..]);
	assert_eq!(tv.swap_remove(0), 3);
	assert_eq!(&tv[..], &[2][..]);
	assert_eq!(tv.swap_remove(0), 2);
	assert_eq!(&tv[..], &[][..]);
	}

	#[test]
	fn TinyVec_capacity() {
	let mut tv: TinyVec<[i32; 1]> = Default::default();
	assert_eq!(tv.capacity(), 1);
	tv.move_to_the_heap();
	tv.extend_from_slice(&[1, 2, 3, 4]);
	assert_eq!(tv.capacity(), 4);
	}

	#[test]
	fn TinyVec_drain() {
	let mut tv: TinyVec<[i32; 10]> = Default::default();
	tv.push(1);
	tv.push(2);
	tv.push(3);

	assert_eq!(Vec::from_iter(tv.clone().drain(..)), vec![1, 2, 3]);

	assert_eq!(Vec::from_iter(tv.clone().drain(..2)), vec![1, 2]);
	assert_eq!(Vec::from_iter(tv.clone().drain(..3)), vec![1, 2, 3]);

	assert_eq!(Vec::from_iter(tv.clone().drain(..=1)), vec![1, 2]);
	assert_eq!(Vec::from_iter(tv.clone().drain(..=2)), vec![1, 2, 3]);

	assert_eq!(Vec::from_iter(tv.clone().drain(0..)), vec![1, 2, 3]);
	assert_eq!(Vec::from_iter(tv.clone().drain(1..)), vec![2, 3]);

	assert_eq!(Vec::from_iter(tv.clone().drain(0..2)), vec![1, 2]);
	assert_eq!(Vec::from_iter(tv.clone().drain(0..3)), vec![1, 2, 3]);
	assert_eq!(Vec::from_iter(tv.clone().drain(1..2)), vec![2]);
	assert_eq!(Vec::from_iter(tv.clone().drain(1..3)), vec![2, 3]);

	assert_eq!(Vec::from_iter(tv.clone().drain(0..=1)), vec![1, 2]);
	assert_eq!(Vec::from_iter(tv.clone().drain(0..=2)), vec![1, 2, 3]);
	assert_eq!(Vec::from_iter(tv.clone().drain(1..=1)), vec![2]);
	assert_eq!(Vec::from_iter(tv.clone().drain(1..=2)), vec![2, 3]);
	}

	#[test]
	fn TinyVec_splice() {
	let mut tv: TinyVec<[i32; 10]> = Default::default();
	tv.push(1);
	tv.push(2);
	tv.push(3);

	// splice returns the same things as drain
	assert_eq!(Vec::from_iter(tv.clone().splice(.., None)), vec![1, 2, 3]);

	assert_eq!(Vec::from_iter(tv.clone().splice(..2, None)), vec![1, 2]);
	assert_eq!(Vec::from_iter(tv.clone().splice(..3, None)), vec![1, 2, 3]);

	assert_eq!(Vec::from_iter(tv.clone().splice(..=1, None)), vec![1, 2]);
	assert_eq!(Vec::from_iter(tv.clone().splice(..=2, None)), vec![1, 2, 3]);

	assert_eq!(Vec::from_iter(tv.clone().splice(0.., None)), vec![1, 2, 3]);
	assert_eq!(Vec::from_iter(tv.clone().splice(1.., None)), vec![2, 3]);

	assert_eq!(Vec::from_iter(tv.clone().splice(0..2, None)), vec![1, 2]);
	assert_eq!(Vec::from_iter(tv.clone().splice(0..3, None)), vec![1, 2, 3]);
	assert_eq!(Vec::from_iter(tv.clone().splice(1..2, None)), vec![2]);
	assert_eq!(Vec::from_iter(tv.clone().splice(1..3, None)), vec![2, 3]);

	assert_eq!(Vec::from_iter(tv.clone().splice(0..=1, None)), vec![1, 2]);
	assert_eq!(Vec::from_iter(tv.clone().splice(0..=2, None)), vec![1, 2, 3]);
	assert_eq!(Vec::from_iter(tv.clone().splice(1..=1, None)), vec![2]);
	assert_eq!(Vec::from_iter(tv.clone().splice(1..=2, None)), vec![2, 3]);

	// splice removes the same things as drain
	let mut tv2 = tv.clone();
	tv2.splice(.., None);
	assert_eq!(tv2, tiny_vec![]);

	let mut tv2 = tv.clone();
	tv2.splice(..2, None);
	assert_eq!(tv2, tiny_vec![3]);

	let mut tv2 = tv.clone();
	tv2.splice(..3, None);
	assert_eq!(tv2, tiny_vec![]);

	let mut tv2 = tv.clone();
	tv2.splice(..=1, None);
	assert_eq!(tv2, tiny_vec![3]);
	let mut tv2 = tv.clone();
	tv2.splice(..=2, None);
	assert_eq!(tv2, tiny_vec![]);

	let mut tv2 = tv.clone();
	tv2.splice(0.., None);
	assert_eq!(tv2, tiny_vec![]);
	let mut tv2 = tv.clone();
	tv2.splice(1.., None);
	assert_eq!(tv2, tiny_vec![1]);

	let mut tv2 = tv.clone();
	tv2.splice(0..2, None);
	assert_eq!(tv2, tiny_vec![3]);

	let mut tv2 = tv.clone();
	tv2.splice(0..3, None);
	assert_eq!(tv2, tiny_vec![]);
	let mut tv2 = tv.clone();
	tv2.splice(1..2, None);
	assert_eq!(tv2, tiny_vec![1, 3]);

	let mut tv2 = tv.clone();
	tv2.splice(1..3, None);
	assert_eq!(tv2, tiny_vec![1]);

	let mut tv2 = tv.clone();
	tv2.splice(0..=1, None);
	assert_eq!(tv2, tiny_vec![3]);

	let mut tv2 = tv.clone();
	tv2.splice(0..=2, None);
	assert_eq!(tv2, tiny_vec![]);

	let mut tv2 = tv.clone();
	tv2.splice(1..=1, None);
	assert_eq!(tv2, tiny_vec![1, 3]);

	let mut tv2 = tv.clone();
	tv2.splice(1..=2, None);
	assert_eq!(tv2, tiny_vec![1]);

	// splice adds the elements correctly
	let mut tv2 = tv.clone();
	tv2.splice(.., 4..=6);
	assert_eq!(tv2, tiny_vec![4, 5, 6]);

	let mut tv2 = tv.clone();
	tv2.splice(..2, 4..=6);
	assert_eq!(tv2, tiny_vec![4, 5, 6, 3]);

	let mut tv2 = tv.clone();
	tv2.splice(..3, 4..=6);
	assert_eq!(tv2, tiny_vec![4, 5, 6]);

	let mut tv2 = tv.clone();
	tv2.splice(..=1, 4..=6);
	assert_eq!(tv2, tiny_vec![4, 5, 6, 3]);

	let mut tv2 = tv.clone();
	tv2.splice(..=2, 4..=6);
	assert_eq!(tv2, tiny_vec![4, 5, 6]);

	let mut tv2 = tv.clone();
	tv2.splice(0.., 4..=6);
	assert_eq!(tv2, tiny_vec![4, 5, 6]);

	let mut tv2 = tv.clone();
	tv2.splice(1.., 4..=6);
	assert_eq!(tv2, tiny_vec![1, 4, 5, 6]);

	let mut tv2 = tv.clone();
	tv2.splice(0..2, 4..=6);
	assert_eq!(tv2, tiny_vec![4, 5, 6, 3]);

	let mut tv2 = tv.clone();
	tv2.splice(0..3, 4..=6);
	assert_eq!(tv2, tiny_vec![4, 5, 6]);

	let mut tv2 = tv.clone();
	tv2.splice(1..2, 4..=6);
	assert_eq!(tv2, tiny_vec![1, 4, 5, 6, 3]);

	let mut tv2 = tv.clone();
	tv2.splice(1..3, 4..=6);
	assert_eq!(tv2, tiny_vec![1, 4, 5, 6]);

	let mut tv2 = tv.clone();
	tv2.splice(0..=1, 4..=6);
	assert_eq!(tv2, tiny_vec![4, 5, 6, 3]);

	let mut tv2 = tv.clone();
	tv2.splice(0..=2, 4..=6);
	assert_eq!(tv2, tiny_vec![4, 5, 6]);

	let mut tv2 = tv.clone();
	tv2.splice(1..=1, 4..=6);
	assert_eq!(tv2, tiny_vec![1, 4, 5, 6, 3]);

	let mut tv2 = tv.clone();
	tv2.splice(1..=2, 4..=6);
	assert_eq!(tv2, tiny_vec![1, 4, 5, 6]);

	// splice adds the elements correctly when the replacement is smaller
	let mut tv2 = tv.clone();
	tv2.splice(.., Some(4));
	assert_eq!(tv2, tiny_vec![4]);

	let mut tv2 = tv.clone();
	tv2.splice(..2, Some(4));
	assert_eq!(tv2, tiny_vec![4, 3]);

	let mut tv2 = tv.clone();
	tv2.splice(1.., Some(4));
	assert_eq!(tv2, tiny_vec![1, 4]);

	let mut tv2 = tv.clone();
	tv2.splice(1..=1, Some(4));
	assert_eq!(tv2, tiny_vec![1, 4, 3]);
	}

	#[test]
	fn TinyVec_resize() {
	let mut tv: TinyVec<[i32; 10]> = Default::default();
	tv.resize(20, 5);
	assert_eq!(&tv[..], &[5; 20]);
	}

	#[test]
	fn TinyVec_from_slice_impl() {
	let bigger_slice: [u8; 11] = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10];
	let tinyvec: TinyVec<[u8; 10]> = TinyVec::Heap((&bigger_slice[..]).into());
	assert_eq!(TinyVec::from(&bigger_slice[..]), tinyvec);

	let smaller_slice: [u8; 5] = [0, 1, 2, 3, 4];
	let tinyvec: TinyVec<[u8; 10]> = TinyVec::Inline(ArrayVec::from_array_len(
	[0, 1, 2, 3, 4, 0, 0, 0, 0, 0],
	5,
	));
	assert_eq!(TinyVec::from(&smaller_slice[..]), tinyvec);

	let same_size: [u8; 4] = [0, 1, 2, 3];
	let tinyvec: TinyVec<[u8; 4]> =
	TinyVec::Inline(ArrayVec::from_array_len(same_size, 4));
	assert_eq!(TinyVec::from(&same_size[..]), tinyvec);
	}

	#[test]
	fn TinyVec_from_array() {
	let array = [9, 8, 7, 6, 5, 4, 3, 2, 1];
	let tv = TinyVec::from(array);
	assert_eq!(&array, &tv[..]);
	}

	#[test]
	fn TinyVec_macro() {
	let mut expected: TinyVec<[i32; 4]> = Default::default();
	expected.push(1);
	expected.push(2);
	expected.push(3);

	let actual = tiny_vec!(1, 2, 3);

	assert_eq!(expected, actual);

	assert_eq!(tiny_vec![0u8; 4], tiny_vec!(0u8, 0u8, 0u8, 0u8));
	assert_eq!(tiny_vec![0u8; 4], tiny_vec!([u8; 4] => 0, 0, 0, 0));
	assert_eq!(tiny_vec![0; 4], tiny_vec!(0, 0, 0, 0));
	assert_eq!(tiny_vec![0; 4], tiny_vec!([u8; 4] => 0, 0, 0, 0));

	let expected2 = tiny_vec![1.1; 3];
	let actual2 = tiny_vec!([f32; 3] => 1.1, 1.1, 1.1);
	assert_eq!(expected2, actual2);
	}

	#[test]
	fn TinyVec_macro_non_copy() {
	// must use a variable here to avoid macro shenanigans
	let s = String::new();
	let _: TinyVec<[String; 10]> = tiny_vec!([String; 10] => s);
	}

	#[test]
	fn TinyVec_reserve() {
	let mut tv: TinyVec<[i32; 4]> = Default::default();
	assert_eq!(tv.capacity(), 4);
	tv.extend_from_slice(&[1, 2]);
	assert_eq!(tv.capacity(), 4);
	tv.reserve(2);
	assert_eq!(tv.capacity(), 4);
	tv.reserve(4);
	assert!(tv.capacity() >= 6);
	tv.extend_from_slice(&[3, 4, 5, 6]);
	tv.reserve(4);
	assert!(tv.capacity() >= 10);
	}

	#[test]
	fn TinyVec_reserve_exact() {
	let mut tv: TinyVec<[i32; 4]> = Default::default();
	assert_eq!(tv.capacity(), 4);

	tv.extend_from_slice(&[1, 2]);
	assert_eq!(tv.capacity(), 4);
	tv.reserve_exact(2);
	assert_eq!(tv.capacity(), 4);
	tv.reserve_exact(4);
	assert!(tv.capacity() >= 6);
	tv.extend_from_slice(&[3, 4, 5, 6]);
	tv.reserve_exact(4);
	assert!(tv.capacity() >= 10);
	}

	#[test]
	fn TinyVec_move_to_heap_and_shrink() {
	let mut tv: TinyVec<[i32; 4]> = Default::default();
	assert!(tv.is_inline());
	tv.move_to_the_heap();
	assert!(tv.is_heap());
	assert_eq!(tv.capacity(), 0);

	tv.push(1);
	tv.shrink_to_fit();
	assert!(tv.is_inline());
	assert_eq!(tv.capacity(), 4);

	tv.move_to_the_heap_and_reserve(3);
	assert!(tv.is_heap());
	assert_eq!(tv.capacity(), 4);
	tv.extend(2..=4);
	assert_eq!(tv.capacity(), 4);
	assert_eq!(tv.as_slice(), [1, 2, 3, 4]);
	}

	#[cfg(feature = "serde")]
	#[test]
	fn TinyVec_ser_de_empty() {
	let tv: TinyVec<[i32; 0]> = tiny_vec![];

	assert_tokens(&tv, &[Token::Seq { len: Some(0) }, Token::SeqEnd]);
	}

	#[cfg(feature = "serde")]
	#[test]
	fn TinyVec_ser_de() {
	let tv: TinyVec<[i32; 4]> = tiny_vec![1, 2, 3, 4];

	assert_tokens(
	&tv,
	&[
	Token::Seq { len: Some(4) },
	Token::I32(1),
	Token::I32(2),
	Token::I32(3),
	Token::I32(4),
	Token::SeqEnd,
	],
	);
	}

	#[cfg(feature = "serde")]
	#[test]
	fn TinyVec_ser_de_heap() {
	let mut tv: TinyVec<[i32; 4]> = tiny_vec![1, 2, 3, 4];
	tv.move_to_the_heap();

	assert_tokens(
	&tv,
	&[
	Token::Seq { len: Some(4) },
	Token::I32(1),
	Token::I32(2),
	Token::I32(3),
	Token::I32(4),
	Token::SeqEnd,
	],
	);
	}

	#[test]
	fn TinyVec_pretty_debug() {
	let tv: TinyVec<[i32; 6]> = tiny_vec![1, 2, 3];
	let s = format!("{:#?}", tv);
	let expected = format!("{:#?}", tv.as_slice());

	assert_eq!(s, expected);
	}

	#[cfg(feature = "std")]
	#[test]
	fn TinyVec_std_io_write() {
	use std::io::Write;
	let mut tv: TinyVec<[u8; 3]> = TinyVec::new();

	tv.write_all(b"foo").ok();
	assert!(tv.is_inline());
	assert_eq!(tv, tiny_vec![b'f', b'o', b'o']);

	tv.write_all(b"bar").ok();
	assert!(tv.is_heap());
	assert_eq!(tv, tiny_vec![b'f', b'o', b'o', b'b', b'a', b'r']);
	}