x86_64/usr/lib/rustlib/src/rust/library/core/tests/result.rs - manifest_repos/toolchain - Git at Google

 use core::ops::DerefMut;
 use core::option::*;

 fn op1() -> Result<isize, &'static str> {
     Ok(666)
 }
 fn op2() -> Result<isize, &'static str> {
     Err("sadface")
 }

 #[test]
 fn test_and() {
     assert_eq!(op1().and(Ok(667)).unwrap(), 667);
     assert_eq!(op1().and(Err::<i32, &'static str>("bad")).unwrap_err(), "bad");

     assert_eq!(op2().and(Ok(667)).unwrap_err(), "sadface");
     assert_eq!(op2().and(Err::<i32, &'static str>("bad")).unwrap_err(), "sadface");
 }

 #[test]
 fn test_and_then() {
     assert_eq!(op1().and_then(|i| Ok::<isize, &'static str>(i + 1)).unwrap(), 667);
     assert_eq!(op1().and_then(|_| Err::<isize, &'static str>("bad")).unwrap_err(), "bad");

     assert_eq!(op2().and_then(|i| Ok::<isize, &'static str>(i + 1)).unwrap_err(), "sadface");
     assert_eq!(op2().and_then(|_| Err::<isize, &'static str>("bad")).unwrap_err(), "sadface");
 }

 #[test]
 fn test_or() {
     assert_eq!(op1().or(Ok::<_, &'static str>(667)).unwrap(), 666);
     assert_eq!(op1().or(Err("bad")).unwrap(), 666);

     assert_eq!(op2().or(Ok::<_, &'static str>(667)).unwrap(), 667);
     assert_eq!(op2().or(Err("bad")).unwrap_err(), "bad");
 }

 #[test]
 fn test_or_else() {
     assert_eq!(op1().or_else(|_| Ok::<isize, &'static str>(667)).unwrap(), 666);
     assert_eq!(op1().or_else(|e| Err::<isize, &'static str>(e)).unwrap(), 666);

     assert_eq!(op2().or_else(|_| Ok::<isize, &'static str>(667)).unwrap(), 667);
     assert_eq!(op2().or_else(|e| Err::<isize, &'static str>(e)).unwrap_err(), "sadface");
 }

 #[test]
 fn test_impl_map() {
     assert!(Ok::<isize, isize>(1).map(|x| x + 1) == Ok(2));
     assert!(Err::<isize, isize>(1).map(|x| x + 1) == Err(1));
 }

 #[test]
 fn test_impl_map_err() {
     assert!(Ok::<isize, isize>(1).map_err(|x| x + 1) == Ok(1));
     assert!(Err::<isize, isize>(1).map_err(|x| x + 1) == Err(2));
 }

 #[test]
 fn test_collect() {
     let v: Result<Vec<isize>, ()> = (0..0).map(|_| Ok::<isize, ()>(0)).collect();
     assert!(v == Ok(vec![]));

     let v: Result<Vec<isize>, ()> = (0..3).map(|x| Ok::<isize, ()>(x)).collect();
     assert!(v == Ok(vec![0, 1, 2]));

     let v: Result<Vec<isize>, isize> = (0..3).map(|x| if x > 1 { Err(x) } else { Ok(x) }).collect();
     assert!(v == Err(2));

     // test that it does not take more elements than it needs
     let mut functions: [Box<dyn Fn() -> Result<(), isize>>; 3] =
         [Box::new(|| Ok(())), Box::new(|| Err(1)), Box::new(|| panic!())];

     let v: Result<Vec<()>, isize> = functions.iter_mut().map(|f| (*f)()).collect();
     assert!(v == Err(1));
 }

 #[test]
 fn test_fmt_default() {
     let ok: Result<isize, &'static str> = Ok(100);
     let err: Result<isize, &'static str> = Err("Err");

     let s = format!("{ok:?}");
     assert_eq!(s, "Ok(100)");
     let s = format!("{err:?}");
     assert_eq!(s, "Err(\"Err\")");
 }

 #[test]
 fn test_unwrap_or() {
     let ok: Result<isize, &'static str> = Ok(100);
     let ok_err: Result<isize, &'static str> = Err("Err");

     assert_eq!(ok.unwrap_or(50), 100);
     assert_eq!(ok_err.unwrap_or(50), 50);
 }

 #[test]
 fn test_unwrap_or_else() {
     fn handler(msg: &'static str) -> isize {
         if msg == "I got this." { 50 } else { panic!("BadBad") }
     }

     let ok: Result<isize, &'static str> = Ok(100);
     let ok_err: Result<isize, &'static str> = Err("I got this.");

     assert_eq!(ok.unwrap_or_else(handler), 100);
     assert_eq!(ok_err.unwrap_or_else(handler), 50);
 }

 #[test]
 #[should_panic]
 pub fn test_unwrap_or_else_panic() {
     fn handler(msg: &'static str) -> isize {
         if msg == "I got this." { 50 } else { panic!("BadBad") }
     }

     let bad_err: Result<isize, &'static str> = Err("Unrecoverable mess.");
     let _: isize = bad_err.unwrap_or_else(handler);
 }

 #[test]
 fn test_unwrap_unchecked() {
     let ok: Result<isize, &'static str> = Ok(100);
     assert_eq!(unsafe { ok.unwrap_unchecked() }, 100);
 }

 #[test]
 fn test_unwrap_err_unchecked() {
     let ok_err: Result<isize, &'static str> = Err("Err");
     assert_eq!(unsafe { ok_err.unwrap_err_unchecked() }, "Err");
 }

 #[test]
 pub fn test_expect_ok() {
     let ok: Result<isize, &'static str> = Ok(100);
     assert_eq!(ok.expect("Unexpected error"), 100);
 }
 #[test]
 #[should_panic(expected = "Got expected error: \"All good\"")]
 pub fn test_expect_err() {
     let err: Result<isize, &'static str> = Err("All good");
     err.expect("Got expected error");
 }

 #[test]
 pub fn test_expect_err_err() {
     let ok: Result<&'static str, isize> = Err(100);
     assert_eq!(ok.expect_err("Unexpected ok"), 100);
 }
 #[test]
 #[should_panic(expected = "Got expected ok: \"All good\"")]
 pub fn test_expect_err_ok() {
     let err: Result<&'static str, isize> = Ok("All good");
     err.expect_err("Got expected ok");
 }

 #[test]
 pub fn test_iter() {
     let ok: Result<isize, &'static str> = Ok(100);
     let mut it = ok.iter();
     assert_eq!(it.size_hint(), (1, Some(1)));
     assert_eq!(it.next(), Some(&100));
     assert_eq!(it.size_hint(), (0, Some(0)));
     assert!(it.next().is_none());
     assert_eq!((&ok).into_iter().next(), Some(&100));

     let err: Result<isize, &'static str> = Err("error");
     assert_eq!(err.iter().next(), None);
 }

 #[test]
 pub fn test_iter_mut() {
     let mut ok: Result<isize, &'static str> = Ok(100);
     for loc in ok.iter_mut() {
         *loc = 200;
     }
     assert_eq!(ok, Ok(200));
     for loc in &mut ok {
         *loc = 300;
     }
     assert_eq!(ok, Ok(300));

     let mut err: Result<isize, &'static str> = Err("error");
     for loc in err.iter_mut() {
         *loc = 200;
     }
     assert_eq!(err, Err("error"));
 }

 #[test]
 pub fn test_unwrap_or_default() {
     assert_eq!(op1().unwrap_or_default(), 666);
     assert_eq!(op2().unwrap_or_default(), 0);
 }

 #[test]
 pub fn test_into_ok() {
     fn infallible_op() -> Result<isize, !> {
         Ok(666)
     }

     assert_eq!(infallible_op().into_ok(), 666);

     enum MyNeverToken {}
     impl From<MyNeverToken> for ! {
         fn from(never: MyNeverToken) -> ! {
             match never {}
         }
     }

     fn infallible_op2() -> Result<isize, MyNeverToken> {
         Ok(667)
     }

     assert_eq!(infallible_op2().into_ok(), 667);
 }

 #[test]
 pub fn test_into_err() {
     fn until_error_op() -> Result<!, isize> {
         Err(666)
     }

     assert_eq!(until_error_op().into_err(), 666);

     enum MyNeverToken {}
     impl From<MyNeverToken> for ! {
         fn from(never: MyNeverToken) -> ! {
             match never {}
         }
     }

     fn until_error_op2() -> Result<MyNeverToken, isize> {
         Err(667)
     }

     assert_eq!(until_error_op2().into_err(), 667);
 }

 #[test]
 fn test_try() {
     fn try_result_ok() -> Result<u8, u32> {
         let result: Result<u8, u8> = Ok(1);
         let val = result?;
         Ok(val)
     }
     assert_eq!(try_result_ok(), Ok(1));

     fn try_result_err() -> Result<u8, u32> {
         let result: Result<u8, u8> = Err(1);
         let val = result?;
         Ok(val)
     }
     assert_eq!(try_result_err(), Err(1));
 }

 #[test]
 fn test_result_as_deref() {
     // &Result<T: Deref, E>::Ok(T).as_deref() ->
     //      Result<&T::Deref::Target, &E>::Ok(&*T)
     let ref_ok = &Result::Ok::<&i32, u8>(&42);
     let expected_result = Result::Ok::<&i32, &u8>(&42);
     assert_eq!(ref_ok.as_deref(), expected_result);

     let ref_ok = &Result::Ok::<String, u32>(String::from("a result"));
     let expected_result = Result::Ok::<&str, &u32>("a result");
     assert_eq!(ref_ok.as_deref(), expected_result);

     let ref_ok = &Result::Ok::<Vec<i32>, u32>(vec![1, 2, 3, 4, 5]);
     let expected_result = Result::Ok::<&[i32], &u32>([1, 2, 3, 4, 5].as_slice());
     assert_eq!(ref_ok.as_deref(), expected_result);

     // &Result<T: Deref, E>::Err(T).as_deref() ->
     //      Result<&T::Deref::Target, &E>::Err(&*E)
     let val = 41;
     let ref_err = &Result::Err::<&u8, i32>(val);
     let expected_result = Result::Err::<&u8, &i32>(&val);
     assert_eq!(ref_err.as_deref(), expected_result);

     let s = String::from("an error");
     let ref_err = &Result::Err::<&u32, String>(s.clone());
     let expected_result = Result::Err::<&u32, &String>(&s);
     assert_eq!(ref_err.as_deref(), expected_result);

     let v = vec![5, 4, 3, 2, 1];
     let ref_err = &Result::Err::<&u32, Vec<i32>>(v.clone());
     let expected_result = Result::Err::<&u32, &Vec<i32>>(&v);
     assert_eq!(ref_err.as_deref(), expected_result);
 }

 #[test]
 fn test_result_as_deref_mut() {
     // &mut Result<T: DerefMut, E>::Ok(T).as_deref_mut() ->
     //      Result<&mut T::DerefMut::Target, &mut E>::Ok(&mut *T)
     let mut val = 42;
     let mut expected_val = 42;
     let mut_ok = &mut Result::Ok::<&mut i32, u8>(&mut val);
     let expected_result = Result::Ok::<&mut i32, &mut u8>(&mut expected_val);
     assert_eq!(mut_ok.as_deref_mut(), expected_result);

     let mut expected_string = String::from("a result");
     let mut_ok = &mut Result::Ok::<String, u32>(expected_string.clone());
     let expected_result = Result::Ok::<&mut str, &mut u32>(expected_string.deref_mut());
     assert_eq!(mut_ok.as_deref_mut(), expected_result);

     let mut expected_vec = vec![1, 2, 3, 4, 5];
     let mut_ok = &mut Result::Ok::<Vec<i32>, u32>(expected_vec.clone());
     let expected_result = Result::Ok::<&mut [i32], &mut u32>(expected_vec.as_mut_slice());
     assert_eq!(mut_ok.as_deref_mut(), expected_result);

     // &mut Result<T: DerefMut, E>::Err(T).as_deref_mut() ->
     //      Result<&mut T, &mut E>::Err(&mut *E)
     let mut val = 41;
     let mut_err = &mut Result::Err::<&mut u8, i32>(val);
     let expected_result = Result::Err::<&mut u8, &mut i32>(&mut val);
     assert_eq!(mut_err.as_deref_mut(), expected_result);

     let mut expected_string = String::from("an error");
     let mut_err = &mut Result::Err::<&mut u32, String>(expected_string.clone());
     let expected_result = Result::Err::<&mut u32, &mut String>(&mut expected_string);
     assert_eq!(mut_err.as_deref_mut(), expected_result);

     let mut expected_vec = vec![5, 4, 3, 2, 1];
     let mut_err = &mut Result::Err::<&mut u32, Vec<i32>>(expected_vec.clone());
     let expected_result = Result::Err::<&mut u32, &mut Vec<i32>>(&mut expected_vec);
     assert_eq!(mut_err.as_deref_mut(), expected_result);
 }

 #[test]
 fn result_const() {
     // test that the methods of `Result` are usable in a const context

     const RESULT: Result<usize, bool> = Ok(32);

     const REF: Result<&usize, &bool> = RESULT.as_ref();
     assert_eq!(REF, Ok(&32));

     const IS_OK: bool = RESULT.is_ok();
     assert!(IS_OK);

     const IS_ERR: bool = RESULT.is_err();
     assert!(!IS_ERR)
 }

 #[test]
 const fn result_const_mut() {
     let mut result: Result<usize, bool> = Ok(32);

     {
         let as_mut = result.as_mut();
         match as_mut {
             Ok(v) => *v = 42,
             Err(_) => unreachable!(),
         }
     }

     let mut result_err: Result<usize, bool> = Err(false);

     {
         let as_mut = result_err.as_mut();
         match as_mut {
             Ok(_) => unreachable!(),
             Err(v) => *v = true,
         }
     }
 }

 #[test]
 fn result_opt_conversions() {
     #[derive(Copy, Clone, Debug, PartialEq)]
     struct BadNumErr;

     fn try_num(x: i32) -> Result<i32, BadNumErr> {
         if x <= 5 { Ok(x + 1) } else { Err(BadNumErr) }
     }

     type ResOpt = Result<Option<i32>, BadNumErr>;
     type OptRes = Option<Result<i32, BadNumErr>>;

     let mut x: ResOpt = Ok(Some(5));
     let mut y: OptRes = Some(Ok(5));
     assert_eq!(x, y.transpose());
     assert_eq!(x.transpose(), y);

     x = Ok(None);
     y = None;
     assert_eq!(x, y.transpose());
     assert_eq!(x.transpose(), y);

     x = Err(BadNumErr);
     y = Some(Err(BadNumErr));
     assert_eq!(x, y.transpose());
     assert_eq!(x.transpose(), y);

     let res: Result<Vec<i32>, BadNumErr> = (0..10)
         .map(|x| {
             let y = try_num(x)?;
             Ok(if y % 2 == 0 { Some(y - 1) } else { None })
         })
         .filter_map(Result::transpose)
         .collect();

     assert_eq!(res, Err(BadNumErr))
 }

 #[test]
 fn result_try_trait_v2_branch() {
     use core::num::NonZeroU32;
     use core::ops::{ControlFlow::*, Try};
     assert_eq!(Ok::<i32, i32>(4).branch(), Continue(4));
     assert_eq!(Err::<i32, i32>(4).branch(), Break(Err(4)));
     let one = NonZeroU32::new(1).unwrap();
     assert_eq!(Ok::<(), NonZeroU32>(()).branch(), Continue(()));
     assert_eq!(Err::<(), NonZeroU32>(one).branch(), Break(Err(one)));
     assert_eq!(Ok::<NonZeroU32, ()>(one).branch(), Continue(one));
     assert_eq!(Err::<NonZeroU32, ()>(()).branch(), Break(Err(())));
 }
	use core::ops::DerefMut;
	use core::option::*;

	fn op1() -> Result<isize, &'static str> {
	Ok(666)
	}
	fn op2() -> Result<isize, &'static str> {
	Err("sadface")
	}

	#[test]
	fn test_and() {
	assert_eq!(op1().and(Ok(667)).unwrap(), 667);
	assert_eq!(op1().and(Err::<i32, &'static str>("bad")).unwrap_err(), "bad");

	assert_eq!(op2().and(Ok(667)).unwrap_err(), "sadface");
	assert_eq!(op2().and(Err::<i32, &'static str>("bad")).unwrap_err(), "sadface");
	}

	#[test]
	fn test_and_then() {
	assert_eq!(op1().and_then(\|i\| Ok::<isize, &'static str>(i + 1)).unwrap(), 667);
	assert_eq!(op1().and_then(\|_\| Err::<isize, &'static str>("bad")).unwrap_err(), "bad");

	assert_eq!(op2().and_then(\|i\| Ok::<isize, &'static str>(i + 1)).unwrap_err(), "sadface");
	assert_eq!(op2().and_then(\|_\| Err::<isize, &'static str>("bad")).unwrap_err(), "sadface");
	}

	#[test]
	fn test_or() {
	assert_eq!(op1().or(Ok::<_, &'static str>(667)).unwrap(), 666);
	assert_eq!(op1().or(Err("bad")).unwrap(), 666);

	assert_eq!(op2().or(Ok::<_, &'static str>(667)).unwrap(), 667);
	assert_eq!(op2().or(Err("bad")).unwrap_err(), "bad");
	}

	#[test]
	fn test_or_else() {
	assert_eq!(op1().or_else(\|_\| Ok::<isize, &'static str>(667)).unwrap(), 666);
	assert_eq!(op1().or_else(\|e\| Err::<isize, &'static str>(e)).unwrap(), 666);

	assert_eq!(op2().or_else(\|_\| Ok::<isize, &'static str>(667)).unwrap(), 667);
	assert_eq!(op2().or_else(\|e\| Err::<isize, &'static str>(e)).unwrap_err(), "sadface");
	}

	#[test]
	fn test_impl_map() {
	assert!(Ok::<isize, isize>(1).map(\|x\| x + 1) == Ok(2));
	assert!(Err::<isize, isize>(1).map(\|x\| x + 1) == Err(1));
	}

	#[test]
	fn test_impl_map_err() {
	assert!(Ok::<isize, isize>(1).map_err(\|x\| x + 1) == Ok(1));
	assert!(Err::<isize, isize>(1).map_err(\|x\| x + 1) == Err(2));
	}

	#[test]
	fn test_collect() {
	let v: Result<Vec<isize>, ()> = (0..0).map(\|_\| Ok::<isize, ()>(0)).collect();
	assert!(v == Ok(vec![]));

	let v: Result<Vec<isize>, ()> = (0..3).map(\|x\| Ok::<isize, ()>(x)).collect();
	assert!(v == Ok(vec![0, 1, 2]));

	let v: Result<Vec<isize>, isize> = (0..3).map(\|x\| if x > 1 { Err(x) } else { Ok(x) }).collect();
	assert!(v == Err(2));

	// test that it does not take more elements than it needs
	let mut functions: [Box<dyn Fn() -> Result<(), isize>>; 3] =
	[Box::new(\|\| Ok(())), Box::new(\|\| Err(1)), Box::new(\|\| panic!())];

	let v: Result<Vec<()>, isize> = functions.iter_mut().map(\|f\| (*f)()).collect();
	assert!(v == Err(1));
	}

	#[test]
	fn test_fmt_default() {
	let ok: Result<isize, &'static str> = Ok(100);
	let err: Result<isize, &'static str> = Err("Err");

	let s = format!("{ok:?}");
	assert_eq!(s, "Ok(100)");
	let s = format!("{err:?}");
	assert_eq!(s, "Err(\"Err\")");
	}

	#[test]
	fn test_unwrap_or() {
	let ok: Result<isize, &'static str> = Ok(100);
	let ok_err: Result<isize, &'static str> = Err("Err");

	assert_eq!(ok.unwrap_or(50), 100);
	assert_eq!(ok_err.unwrap_or(50), 50);
	}

	#[test]
	fn test_unwrap_or_else() {
	fn handler(msg: &'static str) -> isize {
	if msg == "I got this." { 50 } else { panic!("BadBad") }
	}

	let ok: Result<isize, &'static str> = Ok(100);
	let ok_err: Result<isize, &'static str> = Err("I got this.");

	assert_eq!(ok.unwrap_or_else(handler), 100);
	assert_eq!(ok_err.unwrap_or_else(handler), 50);
	}

	#[test]
	#[should_panic]
	pub fn test_unwrap_or_else_panic() {
	fn handler(msg: &'static str) -> isize {
	if msg == "I got this." { 50 } else { panic!("BadBad") }
	}

	let bad_err: Result<isize, &'static str> = Err("Unrecoverable mess.");
	let _: isize = bad_err.unwrap_or_else(handler);
	}

	#[test]
	fn test_unwrap_unchecked() {
	let ok: Result<isize, &'static str> = Ok(100);
	assert_eq!(unsafe { ok.unwrap_unchecked() }, 100);
	}

	#[test]
	fn test_unwrap_err_unchecked() {
	let ok_err: Result<isize, &'static str> = Err("Err");
	assert_eq!(unsafe { ok_err.unwrap_err_unchecked() }, "Err");
	}

	#[test]
	pub fn test_expect_ok() {
	let ok: Result<isize, &'static str> = Ok(100);
	assert_eq!(ok.expect("Unexpected error"), 100);
	}
	#[test]
	#[should_panic(expected = "Got expected error: \"All good\"")]
	pub fn test_expect_err() {
	let err: Result<isize, &'static str> = Err("All good");
	err.expect("Got expected error");
	}

	#[test]
	pub fn test_expect_err_err() {
	let ok: Result<&'static str, isize> = Err(100);
	assert_eq!(ok.expect_err("Unexpected ok"), 100);
	}
	#[test]
	#[should_panic(expected = "Got expected ok: \"All good\"")]
	pub fn test_expect_err_ok() {
	let err: Result<&'static str, isize> = Ok("All good");
	err.expect_err("Got expected ok");
	}

	#[test]
	pub fn test_iter() {
	let ok: Result<isize, &'static str> = Ok(100);
	let mut it = ok.iter();
	assert_eq!(it.size_hint(), (1, Some(1)));
	assert_eq!(it.next(), Some(&100));
	assert_eq!(it.size_hint(), (0, Some(0)));
	assert!(it.next().is_none());
	assert_eq!((&ok).into_iter().next(), Some(&100));

	let err: Result<isize, &'static str> = Err("error");
	assert_eq!(err.iter().next(), None);
	}

	#[test]
	pub fn test_iter_mut() {
	let mut ok: Result<isize, &'static str> = Ok(100);
	for loc in ok.iter_mut() {
	*loc = 200;
	}
	assert_eq!(ok, Ok(200));
	for loc in &mut ok {
	*loc = 300;
	}
	assert_eq!(ok, Ok(300));

	let mut err: Result<isize, &'static str> = Err("error");
	for loc in err.iter_mut() {
	*loc = 200;
	}
	assert_eq!(err, Err("error"));
	}

	#[test]
	pub fn test_unwrap_or_default() {
	assert_eq!(op1().unwrap_or_default(), 666);
	assert_eq!(op2().unwrap_or_default(), 0);
	}

	#[test]
	pub fn test_into_ok() {
	fn infallible_op() -> Result<isize, !> {
	Ok(666)
	}

	assert_eq!(infallible_op().into_ok(), 666);

	enum MyNeverToken {}
	impl From<MyNeverToken> for ! {
	fn from(never: MyNeverToken) -> ! {
	match never {}
	}
	}

	fn infallible_op2() -> Result<isize, MyNeverToken> {
	Ok(667)
	}

	assert_eq!(infallible_op2().into_ok(), 667);
	}

	#[test]
	pub fn test_into_err() {
	fn until_error_op() -> Result<!, isize> {
	Err(666)
	}

	assert_eq!(until_error_op().into_err(), 666);

	enum MyNeverToken {}
	impl From<MyNeverToken> for ! {
	fn from(never: MyNeverToken) -> ! {
	match never {}
	}
	}

	fn until_error_op2() -> Result<MyNeverToken, isize> {
	Err(667)
	}

	assert_eq!(until_error_op2().into_err(), 667);
	}

	#[test]
	fn test_try() {
	fn try_result_ok() -> Result<u8, u32> {
	let result: Result<u8, u8> = Ok(1);
	let val = result?;
	Ok(val)
	}
	assert_eq!(try_result_ok(), Ok(1));

	fn try_result_err() -> Result<u8, u32> {
	let result: Result<u8, u8> = Err(1);
	let val = result?;
	Ok(val)
	}
	assert_eq!(try_result_err(), Err(1));
	}

	#[test]
	fn test_result_as_deref() {
	// &Result<T: Deref, E>::Ok(T).as_deref() ->
	// Result<&T::Deref::Target, &E>::Ok(&*T)
	let ref_ok = &Result::Ok::<&i32, u8>(&42);
	let expected_result = Result::Ok::<&i32, &u8>(&42);
	assert_eq!(ref_ok.as_deref(), expected_result);

	let ref_ok = &Result::Ok::<String, u32>(String::from("a result"));
	let expected_result = Result::Ok::<&str, &u32>("a result");
	assert_eq!(ref_ok.as_deref(), expected_result);

	let ref_ok = &Result::Ok::<Vec<i32>, u32>(vec![1, 2, 3, 4, 5]);
	let expected_result = Result::Ok::<&[i32], &u32>([1, 2, 3, 4, 5].as_slice());
	assert_eq!(ref_ok.as_deref(), expected_result);

	// &Result<T: Deref, E>::Err(T).as_deref() ->
	// Result<&T::Deref::Target, &E>::Err(&*E)
	let val = 41;
	let ref_err = &Result::Err::<&u8, i32>(val);
	let expected_result = Result::Err::<&u8, &i32>(&val);
	assert_eq!(ref_err.as_deref(), expected_result);

	let s = String::from("an error");
	let ref_err = &Result::Err::<&u32, String>(s.clone());
	let expected_result = Result::Err::<&u32, &String>(&s);
	assert_eq!(ref_err.as_deref(), expected_result);

	let v = vec![5, 4, 3, 2, 1];
	let ref_err = &Result::Err::<&u32, Vec<i32>>(v.clone());
	let expected_result = Result::Err::<&u32, &Vec<i32>>(&v);
	assert_eq!(ref_err.as_deref(), expected_result);
	}

	#[test]
	fn test_result_as_deref_mut() {
	// &mut Result<T: DerefMut, E>::Ok(T).as_deref_mut() ->
	// Result<&mut T::DerefMut::Target, &mut E>::Ok(&mut *T)
	let mut val = 42;
	let mut expected_val = 42;
	let mut_ok = &mut Result::Ok::<&mut i32, u8>(&mut val);
	let expected_result = Result::Ok::<&mut i32, &mut u8>(&mut expected_val);
	assert_eq!(mut_ok.as_deref_mut(), expected_result);

	let mut expected_string = String::from("a result");
	let mut_ok = &mut Result::Ok::<String, u32>(expected_string.clone());
	let expected_result = Result::Ok::<&mut str, &mut u32>(expected_string.deref_mut());
	assert_eq!(mut_ok.as_deref_mut(), expected_result);

	let mut expected_vec = vec![1, 2, 3, 4, 5];
	let mut_ok = &mut Result::Ok::<Vec<i32>, u32>(expected_vec.clone());
	let expected_result = Result::Ok::<&mut [i32], &mut u32>(expected_vec.as_mut_slice());
	assert_eq!(mut_ok.as_deref_mut(), expected_result);

	// &mut Result<T: DerefMut, E>::Err(T).as_deref_mut() ->
	// Result<&mut T, &mut E>::Err(&mut *E)
	let mut val = 41;
	let mut_err = &mut Result::Err::<&mut u8, i32>(val);
	let expected_result = Result::Err::<&mut u8, &mut i32>(&mut val);
	assert_eq!(mut_err.as_deref_mut(), expected_result);

	let mut expected_string = String::from("an error");
	let mut_err = &mut Result::Err::<&mut u32, String>(expected_string.clone());
	let expected_result = Result::Err::<&mut u32, &mut String>(&mut expected_string);
	assert_eq!(mut_err.as_deref_mut(), expected_result);

	let mut expected_vec = vec![5, 4, 3, 2, 1];
	let mut_err = &mut Result::Err::<&mut u32, Vec<i32>>(expected_vec.clone());
	let expected_result = Result::Err::<&mut u32, &mut Vec<i32>>(&mut expected_vec);
	assert_eq!(mut_err.as_deref_mut(), expected_result);
	}

	#[test]
	fn result_const() {
	// test that the methods of `Result` are usable in a const context

	const RESULT: Result<usize, bool> = Ok(32);

	const REF: Result<&usize, &bool> = RESULT.as_ref();
	assert_eq!(REF, Ok(&32));

	const IS_OK: bool = RESULT.is_ok();
	assert!(IS_OK);

	const IS_ERR: bool = RESULT.is_err();
	assert!(!IS_ERR)
	}

	#[test]
	const fn result_const_mut() {
	let mut result: Result<usize, bool> = Ok(32);

	{
	let as_mut = result.as_mut();
	match as_mut {
	Ok(v) => *v = 42,
	Err(_) => unreachable!(),
	}
	}

	let mut result_err: Result<usize, bool> = Err(false);

	{
	let as_mut = result_err.as_mut();
	match as_mut {
	Ok(_) => unreachable!(),
	Err(v) => *v = true,
	}
	}
	}

	#[test]
	fn result_opt_conversions() {
	#[derive(Copy, Clone, Debug, PartialEq)]
	struct BadNumErr;

	fn try_num(x: i32) -> Result<i32, BadNumErr> {
	if x <= 5 { Ok(x + 1) } else { Err(BadNumErr) }
	}

	type ResOpt = Result<Option<i32>, BadNumErr>;
	type OptRes = Option<Result<i32, BadNumErr>>;

	let mut x: ResOpt = Ok(Some(5));
	let mut y: OptRes = Some(Ok(5));
	assert_eq!(x, y.transpose());
	assert_eq!(x.transpose(), y);

	x = Ok(None);
	y = None;
	assert_eq!(x, y.transpose());
	assert_eq!(x.transpose(), y);

	x = Err(BadNumErr);
	y = Some(Err(BadNumErr));
	assert_eq!(x, y.transpose());
	assert_eq!(x.transpose(), y);

	let res: Result<Vec<i32>, BadNumErr> = (0..10)
	.map(\|x\| {
	let y = try_num(x)?;
	Ok(if y % 2 == 0 { Some(y - 1) } else { None })
	})
	.filter_map(Result::transpose)
	.collect();

	assert_eq!(res, Err(BadNumErr))
	}

	#[test]
	fn result_try_trait_v2_branch() {
	use core::num::NonZeroU32;
	use core::ops::{ControlFlow::*, Try};
	assert_eq!(Ok::<i32, i32>(4).branch(), Continue(4));
	assert_eq!(Err::<i32, i32>(4).branch(), Break(Err(4)));
	let one = NonZeroU32::new(1).unwrap();
	assert_eq!(Ok::<(), NonZeroU32>(()).branch(), Continue(()));
	assert_eq!(Err::<(), NonZeroU32>(one).branch(), Break(Err(one)));
	assert_eq!(Ok::<NonZeroU32, ()>(one).branch(), Continue(one));
	assert_eq!(Err::<NonZeroU32, ()>(()).branch(), Break(Err(())));
	}