vendor/rust-analyzer-salsa/tests/parallel/parallel_cycle_mid_recover.rs - toolchain/rustc - Git at Google

 //! Test for cycle recover spread across two threads.
 //! See `../cycles.rs` for a complete listing of cycle tests,
 //! both intra and cross thread.

 use crate::setup::{Knobs, ParDatabaseImpl};
 use salsa::ParallelDatabase;
 use test_log::test;

 // Recover cycle test:
 //
 // The pattern is as follows.
 //
 // Thread A                   Thread B
 // --------                   --------
 // a1                         b1
 // |                          wait for stage 1 (blocks)
 // signal stage 1             |
 // wait for stage 2 (blocks)  (unblocked)
 // |                          |
 // |                          b2
 // |                          b3
 // |                          a1 (blocks -> stage 2)
 // (unblocked)                |
 // a2 (cycle detected)        |
 //                            b3 recovers
 //                            b2 resumes
 //                            b1 panics because bug

 #[test]
 fn parallel_cycle_mid_recovers() {
     let db = ParDatabaseImpl::default();
     db.knobs().signal_on_will_block.set(2);

     let thread_a = std::thread::spawn({
         let db = db.snapshot();
         move || db.a1(1)
     });

     let thread_b = std::thread::spawn({
         let db = db.snapshot();
         move || db.b1(1)
     });

     // We expect that the recovery function yields
     // `1 * 20 + 2`, which is returned (and forwarded)
     // to b1, and from there to a2 and a1.
     assert_eq!(thread_a.join().unwrap(), 22);
     assert_eq!(thread_b.join().unwrap(), 22);
 }

 #[salsa::query_group(ParallelCycleMidRecovers)]
 pub(crate) trait TestDatabase: Knobs {
     fn a1(&self, key: i32) -> i32;

     fn a2(&self, key: i32) -> i32;

     #[salsa::cycle(recover_b1)]
     fn b1(&self, key: i32) -> i32;

     fn b2(&self, key: i32) -> i32;

     #[salsa::cycle(recover_b3)]
     fn b3(&self, key: i32) -> i32;
 }

 fn recover_b1(_db: &dyn TestDatabase, _cycle: &salsa::Cycle, key: &i32) -> i32 {
     log::debug!("recover_b1");
     key * 20 + 2
 }

 fn recover_b3(_db: &dyn TestDatabase, _cycle: &salsa::Cycle, key: &i32) -> i32 {
     log::debug!("recover_b1");
     key * 200 + 2
 }

 fn a1(db: &dyn TestDatabase, key: i32) -> i32 {
     // tell thread b we have started
     db.signal(1);

     // wait for thread b to block on a1
     db.wait_for(2);

     db.a2(key)
 }

 fn a2(db: &dyn TestDatabase, key: i32) -> i32 {
     // create the cycle
     db.b1(key)
 }

 fn b1(db: &dyn TestDatabase, key: i32) -> i32 {
     // wait for thread a to have started
     db.wait_for(1);

     db.b2(key);

     0
 }

 fn b2(db: &dyn TestDatabase, key: i32) -> i32 {
     // will encounter a cycle but recover
     db.b3(key);
     db.b1(key); // hasn't recovered yet
     0
 }

 fn b3(db: &dyn TestDatabase, key: i32) -> i32 {
     // will block on thread a, signaling stage 2
     db.a1(key)
 }
	//! Test for cycle recover spread across two threads.
	//! See `../cycles.rs` for a complete listing of cycle tests,
	//! both intra and cross thread.

	use crate::setup::{Knobs, ParDatabaseImpl};
	use salsa::ParallelDatabase;
	use test_log::test;

	// Recover cycle test:
	//
	// The pattern is as follows.
	//
	// Thread A Thread B
	// -------- --------
	// a1 b1
	// \| wait for stage 1 (blocks)
	// signal stage 1 \|
	// wait for stage 2 (blocks) (unblocked)
	// \| \|
	// \| b2
	// \| b3
	// \| a1 (blocks -> stage 2)
	// (unblocked) \|
	// a2 (cycle detected) \|
	// b3 recovers
	// b2 resumes
	// b1 panics because bug

	#[test]
	fn parallel_cycle_mid_recovers() {
	let db = ParDatabaseImpl::default();
	db.knobs().signal_on_will_block.set(2);

	let thread_a = std::thread::spawn({
	let db = db.snapshot();
	move \|\| db.a1(1)
	});

	let thread_b = std::thread::spawn({
	let db = db.snapshot();
	move \|\| db.b1(1)
	});

	// We expect that the recovery function yields
	// `1 * 20 + 2`, which is returned (and forwarded)
	// to b1, and from there to a2 and a1.
	assert_eq!(thread_a.join().unwrap(), 22);
	assert_eq!(thread_b.join().unwrap(), 22);
	}

	#[salsa::query_group(ParallelCycleMidRecovers)]
	pub(crate) trait TestDatabase: Knobs {
	fn a1(&self, key: i32) -> i32;

	fn a2(&self, key: i32) -> i32;

	#[salsa::cycle(recover_b1)]
	fn b1(&self, key: i32) -> i32;

	fn b2(&self, key: i32) -> i32;

	#[salsa::cycle(recover_b3)]
	fn b3(&self, key: i32) -> i32;
	}

	fn recover_b1(_db: &dyn TestDatabase, _cycle: &salsa::Cycle, key: &i32) -> i32 {
	log::debug!("recover_b1");
	key * 20 + 2
	}

	fn recover_b3(_db: &dyn TestDatabase, _cycle: &salsa::Cycle, key: &i32) -> i32 {
	log::debug!("recover_b1");
	key * 200 + 2
	}

	fn a1(db: &dyn TestDatabase, key: i32) -> i32 {
	// tell thread b we have started
	db.signal(1);

	// wait for thread b to block on a1
	db.wait_for(2);

	db.a2(key)
	}

	fn a2(db: &dyn TestDatabase, key: i32) -> i32 {
	// create the cycle
	db.b1(key)
	}

	fn b1(db: &dyn TestDatabase, key: i32) -> i32 {
	// wait for thread a to have started
	db.wait_for(1);

	db.b2(key);

	0
	}

	fn b2(db: &dyn TestDatabase, key: i32) -> i32 {
	// will encounter a cycle but recover
	db.b3(key);
	db.b1(key); // hasn't recovered yet
	0
	}

	fn b3(db: &dyn TestDatabase, key: i32) -> i32 {
	// will block on thread a, signaling stage 2
	db.a1(key)
	}