src/test/ui/regions/regions-relate-bound-regions-on-closures-to-inference-variables.rs - third_party/rust - Git at Google

 // run-pass
 #![allow(dead_code)]
 // Test that this fairly specialized, but also reasonable, pattern
 // typechecks. The pattern involves regions bound in closures that
 // wind up related to inference variables.
 //
 // NB. Changes to the region implementations have broken this pattern
 // a few times, but it happens to be used in the compiler so those
 // changes were caught. However, those uses in the compiler could
 // easily get changed or refactored away in the future.

 #![feature(box_syntax)]

 struct Ctxt<'tcx> {
     x: &'tcx Vec<isize>
 }

 struct Foo<'a,'tcx:'a> {
     cx: &'a Ctxt<'tcx>,
 }

 impl<'a,'tcx> Foo<'a,'tcx> {
     fn bother(&mut self) -> isize {
         self.elaborate_bounds(Box::new(|this| {
             // (*) Here: type of `this` is `&'f0 Foo<&'f1, '_2>`,
             // where `'f0` and `'f1` are fresh, free regions that
             // result from the bound regions on the closure, and `'2`
             // is a region inference variable created by the call. Due
             // to the constraints on the type, we find that `'_2 : 'f1
             // + 'f2` must hold (and can be assumed by the callee).
             // Region inference has to do some clever stuff to avoid
             // inferring `'_2` to be `'static` in this case, because
             // it is created outside the closure but then related to
             // regions bound by the closure itself. See the
             // `region_constraints.rs` file (and the `givens` field, in
             // particular) for more details.
             this.foo()
         }))
     }

     fn foo(&mut self) -> isize {
         22
     }

     fn elaborate_bounds(
         &mut self,
         mut mk_cand: Box<dyn for<'b> FnMut(&mut Foo<'b, 'tcx>) -> isize>)
         -> isize
     {
         mk_cand(self)
     }
 }

 fn main() {
     let v = vec![];
     let cx = Ctxt { x: &v };
     let mut foo = Foo { cx: &cx };
     assert_eq!(foo.bother(), 22); // just so the code is not dead, basically
 }
	// run-pass
	#![allow(dead_code)]
	// Test that this fairly specialized, but also reasonable, pattern
	// typechecks. The pattern involves regions bound in closures that
	// wind up related to inference variables.
	//
	// NB. Changes to the region implementations have broken this pattern
	// a few times, but it happens to be used in the compiler so those
	// changes were caught. However, those uses in the compiler could
	// easily get changed or refactored away in the future.

	#![feature(box_syntax)]

	struct Ctxt<'tcx> {
	x: &'tcx Vec<isize>
	}

	struct Foo<'a,'tcx:'a> {
	cx: &'a Ctxt<'tcx>,
	}

	impl<'a,'tcx> Foo<'a,'tcx> {
	fn bother(&mut self) -> isize {
	self.elaborate_bounds(Box::new(\|this\| {
	// (*) Here: type of `this` is `&'f0 Foo<&'f1, '_2>`,
	// where `'f0` and `'f1` are fresh, free regions that
	// result from the bound regions on the closure, and `'2`
	// is a region inference variable created by the call. Due
	// to the constraints on the type, we find that `'_2 : 'f1
	// + 'f2` must hold (and can be assumed by the callee).
	// Region inference has to do some clever stuff to avoid
	// inferring `'_2` to be `'static` in this case, because
	// it is created outside the closure but then related to
	// regions bound by the closure itself. See the
	// `region_constraints.rs` file (and the `givens` field, in
	// particular) for more details.
	this.foo()
	}))
	}

	fn foo(&mut self) -> isize {
	22
	}

	fn elaborate_bounds(
	&mut self,
	mut mk_cand: Box<dyn for<'b> FnMut(&mut Foo<'b, 'tcx>) -> isize>)
	-> isize
	{
	mk_cand(self)
	}
	}

	fn main() {
	let v = vec![];
	let cx = Ctxt { x: &v };
	let mut foo = Foo { cx: &cx };
	assert_eq!(foo.bother(), 22); // just so the code is not dead, basically
	}