// sync_failure.rs // // Various tests to ensure that failing components fail in a consistent way. use super::*; #[test] fn test_local_sync_failure() { // If the component exits cleanly, then the runtime exits cleanly, and the // test will finish const CODE: &'static str = " primitive immediate_failure_inside_sync() { u32[] only_allows_index_0 = { 1 }; while (true) sync { // note the infinite loop auto value = only_allows_index_0[1]; } } primitive immediate_failure_outside_sync() { u32[] only_allows_index_0 = { 1 }; auto never_gonna_get = only_allows_index_0[1]; while (true) sync {} } "; // let thing = TestTimer::new("local_sync_failure"); run_test_in_runtime(CODE, |api| { api.create_connector("", "immediate_failure_outside_sync", ValueGroup::new_stack(Vec::new())) .expect("create component"); api.create_connector("", "immediate_failure_inside_sync", ValueGroup::new_stack(Vec::new())) .expect("create component"); }) } #[test] fn test_shared_sync_failure() { // Same as above. One of the components should fail, the other should follow // suit because it cannot complete a sync round. const CODE: &'static str = " enum Location { BeforeSync, AfterPut, AfterGet, AfterSync, Never } primitive failing_at_location(in input, out output, Location loc) { u32[] failure_array = {}; while (true) { if (loc == Location::BeforeSync) failure_array[0]; sync { put(output, true); if (loc == Location::AfterPut) failure_array[0]; auto received = get(input); assert(received); if (loc == Location::AfterGet) failure_array[0]; } if (loc == Location::AfterSync) failure_array[0]; } } composite constructor(Location loc) { channel output_a -> input_a; channel output_b -> input_b; new failing_at_location(input_a, output_b, Location::Never); new failing_at_location(input_b, output_a, loc); } "; run_test_in_runtime(CODE, |api| { for variant in 0..1 { // Create the channels api.create_connector("", "constructor", ValueGroup::new_stack(vec![ Value::Enum(variant) ])).expect("create connector"); } }) }