vendor/arbitrary-1.3.2/tests/derive.rs - toolchain/rustc - Git at Google

 #![cfg(feature = "derive")]
 // Various structs/fields that we are deriving `Arbitrary` for aren't actually
 // used except to exercise the derive.
 #![allow(dead_code)]

 use arbitrary::*;

 fn arbitrary_from<'a, T: Arbitrary<'a>>(input: &'a [u8]) -> T {
     let mut buf = Unstructured::new(input);
     T::arbitrary(&mut buf).expect("can create arbitrary instance OK")
 }

 #[derive(Copy, Clone, Debug, Eq, PartialEq, Arbitrary)]
 pub struct Rgb {
     pub r: u8,
     pub g: u8,
     pub b: u8,
 }

 #[test]
 fn struct_with_named_fields() {
     let rgb: Rgb = arbitrary_from(&[4, 5, 6]);
     assert_eq!(rgb.r, 4);
     assert_eq!(rgb.g, 5);
     assert_eq!(rgb.b, 6);

     assert_eq!((3, Some(3)), <Rgb as Arbitrary>::size_hint(0));
 }

 #[derive(Copy, Clone, Debug, Arbitrary)]
 struct MyTupleStruct(u8, bool);

 #[test]
 fn tuple_struct() {
     let s: MyTupleStruct = arbitrary_from(&[43, 42]);
     assert_eq!(s.0, 43);
     assert_eq!(s.1, false);

     let s: MyTupleStruct = arbitrary_from(&[42, 43]);
     assert_eq!(s.0, 42);
     assert_eq!(s.1, true);

     assert_eq!((2, Some(2)), <MyTupleStruct as Arbitrary>::size_hint(0));
 }

 #[derive(Clone, Debug, Arbitrary)]
 struct EndingInVec(u8, bool, u32, Vec<u16>);
 #[derive(Clone, Debug, Arbitrary)]
 struct EndingInString(u8, bool, u32, String);

 #[test]
 fn test_take_rest() {
     let bytes = [1, 1, 1, 2, 3, 4, 5, 6, 7, 8];
     let s1 = EndingInVec::arbitrary_take_rest(Unstructured::new(&bytes)).unwrap();
     let s2 = EndingInString::arbitrary_take_rest(Unstructured::new(&bytes)).unwrap();
     assert_eq!(s1.0, 1);
     assert_eq!(s2.0, 1);
     assert_eq!(s1.1, true);
     assert_eq!(s2.1, true);
     assert_eq!(s1.2, 0x4030201);
     assert_eq!(s2.2, 0x4030201);
     assert_eq!(s1.3, vec![0x0706]);
     assert_eq!(s2.3, "\x05\x06\x07\x08");
 }

 #[derive(Copy, Clone, Debug, Arbitrary)]
 enum MyEnum {
     Unit,
     Tuple(u8, u16),
     Struct { a: u32, b: (bool, u64) },
 }

 #[test]
 fn derive_enum() {
     let mut raw = vec![
         // The choice of which enum variant takes 4 bytes.
         1, 2, 3, 4,
         // And then we need up to 13 bytes for creating `MyEnum::Struct`, the
         // largest variant.
         1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13,
     ];

     let mut saw_unit = false;
     let mut saw_tuple = false;
     let mut saw_struct = false;

     for i in 0..=255 {
         // Choose different variants each iteration.
         for el in &mut raw[..4] {
             *el = i;
         }

         let e: MyEnum = arbitrary_from(&raw);

         match e {
             MyEnum::Unit => {
                 saw_unit = true;
             }
             MyEnum::Tuple(a, b) => {
                 saw_tuple = true;
                 assert_eq!(a, arbitrary_from(&raw[4..5]));
                 assert_eq!(b, arbitrary_from(&raw[5..]));
             }
             MyEnum::Struct { a, b } => {
                 saw_struct = true;
                 assert_eq!(a, arbitrary_from(&raw[4..8]));
                 assert_eq!(b, arbitrary_from(&raw[8..]));
             }
         }
     }

     assert!(saw_unit);
     assert!(saw_tuple);
     assert!(saw_struct);

     assert_eq!((4, Some(17)), <MyEnum as Arbitrary>::size_hint(0));
 }

 #[derive(Arbitrary, Debug)]
 enum RecursiveTree {
     Leaf,
     Node {
         left: Box<RecursiveTree>,
         right: Box<RecursiveTree>,
     },
 }

 #[test]
 fn recursive() {
     let raw = vec![1, 2, 3, 4, 5, 6, 7, 8, 9];
     let _rec: RecursiveTree = arbitrary_from(&raw);

     let (lower, upper) = <RecursiveTree as Arbitrary>::size_hint(0);
     assert_eq!(lower, 4, "need a u32 for the discriminant at minimum");
     assert!(
         upper.is_none(),
         "potentially infinitely recursive, so no upper bound"
     );
 }

 #[derive(Arbitrary, Debug)]
 struct Generic<T> {
     inner: T,
 }

 #[test]
 fn generics() {
     let raw = vec![1, 2, 3, 4, 5, 6, 7, 8, 9];
     let gen: Generic<bool> = arbitrary_from(&raw);
     assert!(gen.inner);

     let (lower, upper) = <Generic<u32> as Arbitrary>::size_hint(0);
     assert_eq!(lower, 4);
     assert_eq!(upper, Some(4));
 }

 #[derive(Arbitrary, Debug)]
 struct OneLifetime<'a> {
     alpha: &'a str,
 }

 #[test]
 fn one_lifetime() {
     // Last byte is used for length
     let raw: Vec<u8> = vec![97, 98, 99, 100, 3];
     let lifetime: OneLifetime = arbitrary_from(&raw);
     assert_eq!("abc", lifetime.alpha);

     let (lower, upper) = <OneLifetime as Arbitrary>::size_hint(0);
     assert_eq!(lower, 0);
     assert_eq!(upper, None);
 }

 #[derive(Arbitrary, Debug)]
 struct TwoLifetimes<'a, 'b> {
     alpha: &'a str,
     beta: &'b str,
 }

 #[test]
 fn two_lifetimes() {
     // Last byte is used for length
     let raw: Vec<u8> = vec![97, 98, 99, 100, 101, 102, 103, 3];
     let lifetime: TwoLifetimes = arbitrary_from(&raw);
     assert_eq!("abc", lifetime.alpha);
     assert_eq!("def", lifetime.beta);

     let (lower, upper) = <TwoLifetimes as Arbitrary>::size_hint(0);
     assert_eq!(lower, 0);
     assert_eq!(upper, None);
 }

 #[test]
 fn recursive_and_empty_input() {
     // None of the following derives should result in a stack overflow. See
     // https://github.com/rust-fuzz/arbitrary/issues/107 for details.

     #[derive(Debug, Arbitrary)]
     enum Nat {
         Succ(Box<Nat>),
         Zero,
     }

     let _ = Nat::arbitrary(&mut Unstructured::new(&[]));

     #[derive(Debug, Arbitrary)]
     enum Nat2 {
         Zero,
         Succ(Box<Nat2>),
     }

     let _ = Nat2::arbitrary(&mut Unstructured::new(&[]));

     #[derive(Debug, Arbitrary)]
     struct Nat3 {
         f: Option<Box<Nat3>>,
     }

     let _ = Nat3::arbitrary(&mut Unstructured::new(&[]));

     #[derive(Debug, Arbitrary)]
     struct Nat4(Option<Box<Nat4>>);

     let _ = Nat4::arbitrary(&mut Unstructured::new(&[]));

     #[derive(Debug, Arbitrary)]
     enum Nat5 {
         Zero,
         Succ { f: Box<Nat5> },
     }

     let _ = Nat5::arbitrary(&mut Unstructured::new(&[]));
 }

 #[test]
 fn test_field_attributes() {
     // A type that DOES NOT implement Arbitrary
     #[derive(Debug)]
     struct Weight(u8);

     #[derive(Debug, Arbitrary)]
     struct Parcel {
         #[arbitrary(with = arbitrary_weight)]
         weight: Weight,

         #[arbitrary(default)]
         width: u8,

         #[arbitrary(value = 2 + 2)]
         length: u8,

         height: u8,

         #[arbitrary(with = |u: &mut Unstructured| u.int_in_range(0..=100))]
         price: u8,
     }

     fn arbitrary_weight(u: &mut Unstructured) -> arbitrary::Result<Weight> {
         u.int_in_range(45..=56).map(Weight)
     }

     let parcel: Parcel = arbitrary_from(&[6, 199, 17]);

     // 45 + 6 = 51
     assert_eq!(parcel.weight.0, 51);

     // u8::default()
     assert_eq!(parcel.width, 0);

     // 2 + 2 = 4
     assert_eq!(parcel.length, 4);

     // 199 is the 2nd byte used by arbitrary
     assert_eq!(parcel.height, 199);

     // 17 is the 3rd byte used by arbitrary
     assert_eq!(parcel.price, 17);
 }
	#![cfg(feature = "derive")]
	// Various structs/fields that we are deriving `Arbitrary` for aren't actually
	// used except to exercise the derive.
	#![allow(dead_code)]

	use arbitrary::*;

	fn arbitrary_from<'a, T: Arbitrary<'a>>(input: &'a [u8]) -> T {
	let mut buf = Unstructured::new(input);
	T::arbitrary(&mut buf).expect("can create arbitrary instance OK")
	}

	#[derive(Copy, Clone, Debug, Eq, PartialEq, Arbitrary)]
	pub struct Rgb {
	pub r: u8,
	pub g: u8,
	pub b: u8,
	}

	#[test]
	fn struct_with_named_fields() {
	let rgb: Rgb = arbitrary_from(&[4, 5, 6]);
	assert_eq!(rgb.r, 4);
	assert_eq!(rgb.g, 5);
	assert_eq!(rgb.b, 6);

	assert_eq!((3, Some(3)), <Rgb as Arbitrary>::size_hint(0));
	}

	#[derive(Copy, Clone, Debug, Arbitrary)]
	struct MyTupleStruct(u8, bool);

	#[test]
	fn tuple_struct() {
	let s: MyTupleStruct = arbitrary_from(&[43, 42]);
	assert_eq!(s.0, 43);
	assert_eq!(s.1, false);

	let s: MyTupleStruct = arbitrary_from(&[42, 43]);
	assert_eq!(s.0, 42);
	assert_eq!(s.1, true);

	assert_eq!((2, Some(2)), <MyTupleStruct as Arbitrary>::size_hint(0));
	}

	#[derive(Clone, Debug, Arbitrary)]
	struct EndingInVec(u8, bool, u32, Vec<u16>);
	#[derive(Clone, Debug, Arbitrary)]
	struct EndingInString(u8, bool, u32, String);

	#[test]
	fn test_take_rest() {
	let bytes = [1, 1, 1, 2, 3, 4, 5, 6, 7, 8];
	let s1 = EndingInVec::arbitrary_take_rest(Unstructured::new(&bytes)).unwrap();
	let s2 = EndingInString::arbitrary_take_rest(Unstructured::new(&bytes)).unwrap();
	assert_eq!(s1.0, 1);
	assert_eq!(s2.0, 1);
	assert_eq!(s1.1, true);
	assert_eq!(s2.1, true);
	assert_eq!(s1.2, 0x4030201);
	assert_eq!(s2.2, 0x4030201);
	assert_eq!(s1.3, vec![0x0706]);
	assert_eq!(s2.3, "\x05\x06\x07\x08");
	}

	#[derive(Copy, Clone, Debug, Arbitrary)]
	enum MyEnum {
	Unit,
	Tuple(u8, u16),
	Struct { a: u32, b: (bool, u64) },
	}

	#[test]
	fn derive_enum() {
	let mut raw = vec![
	// The choice of which enum variant takes 4 bytes.
	1, 2, 3, 4,
	// And then we need up to 13 bytes for creating `MyEnum::Struct`, the
	// largest variant.
	1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13,
	];

	let mut saw_unit = false;
	let mut saw_tuple = false;
	let mut saw_struct = false;

	for i in 0..=255 {
	// Choose different variants each iteration.
	for el in &mut raw[..4] {
	*el = i;
	}

	let e: MyEnum = arbitrary_from(&raw);

	match e {
	MyEnum::Unit => {
	saw_unit = true;
	}
	MyEnum::Tuple(a, b) => {
	saw_tuple = true;
	assert_eq!(a, arbitrary_from(&raw[4..5]));
	assert_eq!(b, arbitrary_from(&raw[5..]));
	}
	MyEnum::Struct { a, b } => {
	saw_struct = true;
	assert_eq!(a, arbitrary_from(&raw[4..8]));
	assert_eq!(b, arbitrary_from(&raw[8..]));
	}
	}
	}

	assert!(saw_unit);
	assert!(saw_tuple);
	assert!(saw_struct);

	assert_eq!((4, Some(17)), <MyEnum as Arbitrary>::size_hint(0));
	}

	#[derive(Arbitrary, Debug)]
	enum RecursiveTree {
	Leaf,
	Node {
	left: Box<RecursiveTree>,
	right: Box<RecursiveTree>,
	},
	}

	#[test]
	fn recursive() {
	let raw = vec![1, 2, 3, 4, 5, 6, 7, 8, 9];
	let _rec: RecursiveTree = arbitrary_from(&raw);

	let (lower, upper) = <RecursiveTree as Arbitrary>::size_hint(0);
	assert_eq!(lower, 4, "need a u32 for the discriminant at minimum");
	assert!(
	upper.is_none(),
	"potentially infinitely recursive, so no upper bound"
	);
	}

	#[derive(Arbitrary, Debug)]
	struct Generic<T> {
	inner: T,
	}

	#[test]
	fn generics() {
	let raw = vec![1, 2, 3, 4, 5, 6, 7, 8, 9];
	let gen: Generic<bool> = arbitrary_from(&raw);
	assert!(gen.inner);

	let (lower, upper) = <Generic<u32> as Arbitrary>::size_hint(0);
	assert_eq!(lower, 4);
	assert_eq!(upper, Some(4));
	}

	#[derive(Arbitrary, Debug)]
	struct OneLifetime<'a> {
	alpha: &'a str,
	}

	#[test]
	fn one_lifetime() {
	// Last byte is used for length
	let raw: Vec<u8> = vec![97, 98, 99, 100, 3];
	let lifetime: OneLifetime = arbitrary_from(&raw);
	assert_eq!("abc", lifetime.alpha);

	let (lower, upper) = <OneLifetime as Arbitrary>::size_hint(0);
	assert_eq!(lower, 0);
	assert_eq!(upper, None);
	}

	#[derive(Arbitrary, Debug)]
	struct TwoLifetimes<'a, 'b> {
	alpha: &'a str,
	beta: &'b str,
	}

	#[test]
	fn two_lifetimes() {
	// Last byte is used for length
	let raw: Vec<u8> = vec![97, 98, 99, 100, 101, 102, 103, 3];
	let lifetime: TwoLifetimes = arbitrary_from(&raw);
	assert_eq!("abc", lifetime.alpha);
	assert_eq!("def", lifetime.beta);

	let (lower, upper) = <TwoLifetimes as Arbitrary>::size_hint(0);
	assert_eq!(lower, 0);
	assert_eq!(upper, None);
	}

	#[test]
	fn recursive_and_empty_input() {
	// None of the following derives should result in a stack overflow. See
	// https://github.com/rust-fuzz/arbitrary/issues/107 for details.

	#[derive(Debug, Arbitrary)]
	enum Nat {
	Succ(Box<Nat>),
	Zero,
	}

	let _ = Nat::arbitrary(&mut Unstructured::new(&[]));

	#[derive(Debug, Arbitrary)]
	enum Nat2 {
	Zero,
	Succ(Box<Nat2>),
	}

	let _ = Nat2::arbitrary(&mut Unstructured::new(&[]));

	#[derive(Debug, Arbitrary)]
	struct Nat3 {
	f: Option<Box<Nat3>>,
	}

	let _ = Nat3::arbitrary(&mut Unstructured::new(&[]));

	#[derive(Debug, Arbitrary)]
	struct Nat4(Option<Box<Nat4>>);

	let _ = Nat4::arbitrary(&mut Unstructured::new(&[]));

	#[derive(Debug, Arbitrary)]
	enum Nat5 {
	Zero,
	Succ { f: Box<Nat5> },
	}

	let _ = Nat5::arbitrary(&mut Unstructured::new(&[]));
	}

	#[test]
	fn test_field_attributes() {
	// A type that DOES NOT implement Arbitrary
	#[derive(Debug)]
	struct Weight(u8);

	#[derive(Debug, Arbitrary)]
	struct Parcel {
	#[arbitrary(with = arbitrary_weight)]
	weight: Weight,

	#[arbitrary(default)]
	width: u8,

	#[arbitrary(value = 2 + 2)]
	length: u8,

	height: u8,

	#[arbitrary(with = \|u: &mut Unstructured\| u.int_in_range(0..=100))]
	price: u8,
	}

	fn arbitrary_weight(u: &mut Unstructured) -> arbitrary::Result<Weight> {
	u.int_in_range(45..=56).map(Weight)
	}

	let parcel: Parcel = arbitrary_from(&[6, 199, 17]);

	// 45 + 6 = 51
	assert_eq!(parcel.weight.0, 51);

	// u8::default()
	assert_eq!(parcel.width, 0);

	// 2 + 2 = 4
	assert_eq!(parcel.length, 4);

	// 199 is the 2nd byte used by arbitrary
	assert_eq!(parcel.height, 199);

	// 17 is the 3rd byte used by arbitrary
	assert_eq!(parcel.price, 17);
	}