tests/ui/dropck/dropck-eyepatch.rs - toolchain/rustc - Git at Google

 #![feature(dropck_eyepatch)]

 // The point of this test is to illustrate that the `#[may_dangle]`
 // attribute specifically allows, in the context of a type
 // implementing `Drop`, a generic parameter to be instantiated with a
 // lifetime that does not strictly outlive the owning type itself.
 //
 // Here we test that only the expected errors are issued.
 //
 // The illustration is made concrete by comparison with two variations
 // on the type with `#[may_dangle]`:
 //
 //   1. an analogous type that does not implement `Drop` (and thus
 //      should exhibit maximal flexibility with respect to dropck), and
 //
 //   2. an analogous type that does not use `#[may_dangle]` (and thus
 //      should exhibit the standard limitations imposed by dropck.
 //
 // The types in this file follow a pattern, {D,P,S}{t,r}, where:
 //
 // - D means "I implement Drop"
 //
 // - P means "I implement Drop but guarantee my (first) parameter is
 //     pure, i.e., not accessed from the destructor"; no other parameters
 //     are pure.
 //
 // - S means "I do not implement Drop"
 //
 // - t suffix is used when the first generic is a type
 //
 // - r suffix is used when the first generic is a lifetime.

 use std::fmt;

 struct Dt<A: fmt::Debug>(&'static str, A);
 struct Dr<'a, B:'a+fmt::Debug>(&'static str, &'a B);
 struct Pt<A,B: fmt::Debug>(&'static str, A, B);
 struct Pr<'a, 'b, B:'a+'b+fmt::Debug>(&'static str, &'a B, &'b B);
 struct St<A: fmt::Debug>(&'static str, A);
 struct Sr<'a, B:'a+fmt::Debug>(&'static str, &'a B);

 impl<A: fmt::Debug> Drop for Dt<A> {
     fn drop(&mut self) { println!("drop {} {:?}", self.0, self.1); }
 }
 impl<'a, B: fmt::Debug> Drop for Dr<'a, B> {
     fn drop(&mut self) { println!("drop {} {:?}", self.0, self.1); }
 }
 unsafe impl<#[may_dangle] A, B: fmt::Debug> Drop for Pt<A, B> {
     // (unsafe to access self.1  due to #[may_dangle] on A)
     fn drop(&mut self) { println!("drop {} {:?}", self.0, self.2); }
 }
 unsafe impl<#[may_dangle] 'a, 'b, B: fmt::Debug> Drop for Pr<'a, 'b, B> {
     // (unsafe to access self.1 due to #[may_dangle] on 'a)
     fn drop(&mut self) { println!("drop {} {:?}", self.0, self.2); }
 }


 fn main() {
     use std::cell::Cell;

     // We use separate blocks with separate variable to prevent the error
     // messages from being deduplicated.

     {
         let c_long;
         let (mut dt, mut dr): (Dt<_>, Dr<_>);
         c_long = Cell::new(1);

         // No error: sufficiently long-lived state can be referenced in dtors
         dt = Dt("dt", &c_long);
         dr = Dr("dr", &c_long);
     }

     {
         let (c, mut dt, mut dr): (Cell<_>, Dt<_>, Dr<_>);
         c = Cell::new(1);

         // No Error: destructor order precisely modelled
         dt = Dt("dt", &c);
         dr = Dr("dr", &c);
     }

     {
         let (mut dt, mut dr, c_shortest): (Dt<_>, Dr<_>, Cell<_>);
         c_shortest = Cell::new(1);

         // Error: `c_shortest` dies too soon for the references in dtors to be valid.
         dt = Dt("dt", &c_shortest);
         //~^ ERROR `c_shortest` does not live long enough
         dr = Dr("dr", &c_shortest);
     }

     {
         let c_long;
         let (mut pt, mut pr, c_shortest): (Pt<_, _>, Pr<_>, Cell<_>);
         c_long = Cell::new(1);
         c_shortest = Cell::new(1);

         // No error: Drop impl asserts .1 (A and &'a _) are not accessed
         pt = Pt("pt", &c_shortest, &c_long);
         pr = Pr("pr", &c_shortest, &c_long);
     }

     {
         let c_long;
         let (mut pt, mut pr, c_shortest): (Pt<_, _>, Pr<_>, Cell<_>);
         c_long = Cell::new(1);
         c_shortest = Cell::new(1);
         // Error: Drop impl's assertion does not apply to `B` nor `&'b _`
         pt = Pt("pt", &c_long, &c_shortest);
         //~^ ERROR `c_shortest` does not live long enough
         pr = Pr("pr", &c_long, &c_shortest);
     }

     {
         let (st, sr, c_shortest): (St<_>, Sr<_>, Cell<_>);
         c_shortest = Cell::new(1);
         // No error: St and Sr have no destructor.
         st = St("st", &c_shortest);
         sr = Sr("sr", &c_shortest);
     }
 }
 fn use_imm<T>(_: &T) { }
	#![feature(dropck_eyepatch)]

	// The point of this test is to illustrate that the `#[may_dangle]`
	// attribute specifically allows, in the context of a type
	// implementing `Drop`, a generic parameter to be instantiated with a
	// lifetime that does not strictly outlive the owning type itself.
	//
	// Here we test that only the expected errors are issued.
	//
	// The illustration is made concrete by comparison with two variations
	// on the type with `#[may_dangle]`:
	//
	// 1. an analogous type that does not implement `Drop` (and thus
	// should exhibit maximal flexibility with respect to dropck), and
	//
	// 2. an analogous type that does not use `#[may_dangle]` (and thus
	// should exhibit the standard limitations imposed by dropck.
	//
	// The types in this file follow a pattern, {D,P,S}{t,r}, where:
	//
	// - D means "I implement Drop"
	//
	// - P means "I implement Drop but guarantee my (first) parameter is
	// pure, i.e., not accessed from the destructor"; no other parameters
	// are pure.
	//
	// - S means "I do not implement Drop"
	//
	// - t suffix is used when the first generic is a type
	//
	// - r suffix is used when the first generic is a lifetime.

	use std::fmt;

	struct Dt<A: fmt::Debug>(&'static str, A);
	struct Dr<'a, B:'a+fmt::Debug>(&'static str, &'a B);
	struct Pt<A,B: fmt::Debug>(&'static str, A, B);
	struct Pr<'a, 'b, B:'a+'b+fmt::Debug>(&'static str, &'a B, &'b B);
	struct St<A: fmt::Debug>(&'static str, A);
	struct Sr<'a, B:'a+fmt::Debug>(&'static str, &'a B);

	impl<A: fmt::Debug> Drop for Dt<A> {
	fn drop(&mut self) { println!("drop {} {:?}", self.0, self.1); }
	}
	impl<'a, B: fmt::Debug> Drop for Dr<'a, B> {
	fn drop(&mut self) { println!("drop {} {:?}", self.0, self.1); }
	}
	unsafe impl<#[may_dangle] A, B: fmt::Debug> Drop for Pt<A, B> {
	// (unsafe to access self.1 due to #[may_dangle] on A)
	fn drop(&mut self) { println!("drop {} {:?}", self.0, self.2); }
	}
	unsafe impl<#[may_dangle] 'a, 'b, B: fmt::Debug> Drop for Pr<'a, 'b, B> {
	// (unsafe to access self.1 due to #[may_dangle] on 'a)
	fn drop(&mut self) { println!("drop {} {:?}", self.0, self.2); }
	}


	fn main() {
	use std::cell::Cell;

	// We use separate blocks with separate variable to prevent the error
	// messages from being deduplicated.

	{
	let c_long;
	let (mut dt, mut dr): (Dt<_>, Dr<_>);
	c_long = Cell::new(1);

	// No error: sufficiently long-lived state can be referenced in dtors
	dt = Dt("dt", &c_long);
	dr = Dr("dr", &c_long);
	}

	{
	let (c, mut dt, mut dr): (Cell<_>, Dt<_>, Dr<_>);
	c = Cell::new(1);

	// No Error: destructor order precisely modelled
	dt = Dt("dt", &c);
	dr = Dr("dr", &c);
	}

	{
	let (mut dt, mut dr, c_shortest): (Dt<_>, Dr<_>, Cell<_>);
	c_shortest = Cell::new(1);

	// Error: `c_shortest` dies too soon for the references in dtors to be valid.
	dt = Dt("dt", &c_shortest);
	//~^ ERROR `c_shortest` does not live long enough
	dr = Dr("dr", &c_shortest);
	}

	{
	let c_long;
	let (mut pt, mut pr, c_shortest): (Pt<_, _>, Pr<_>, Cell<_>);
	c_long = Cell::new(1);
	c_shortest = Cell::new(1);

	// No error: Drop impl asserts .1 (A and &'a _) are not accessed
	pt = Pt("pt", &c_shortest, &c_long);
	pr = Pr("pr", &c_shortest, &c_long);
	}

	{
	let c_long;
	let (mut pt, mut pr, c_shortest): (Pt<_, _>, Pr<_>, Cell<_>);
	c_long = Cell::new(1);
	c_shortest = Cell::new(1);
	// Error: Drop impl's assertion does not apply to `B` nor `&'b _`
	pt = Pt("pt", &c_long, &c_shortest);
	//~^ ERROR `c_shortest` does not live long enough
	pr = Pr("pr", &c_long, &c_shortest);
	}

	{
	let (st, sr, c_shortest): (St<_>, Sr<_>, Cell<_>);
	c_shortest = Cell::new(1);
	// No error: St and Sr have no destructor.
	st = St("st", &c_shortest);
	sr = Sr("sr", &c_shortest);
	}
	}
	fn use_imm<T>(_: &T) { }