//@ run-pass //! Test that item kind works as expected. //@ ignore-stage1 //@ ignore-cross-compile //@ ignore-remote //@ ignore-windows-gnu mingw has troubles with linking https://github.com/rust-lang/rust/pull/116837 //@ edition: 2021 #![feature(rustc_private)] #![feature(assert_matches)] #![feature(control_flow_enum)] #[macro_use] extern crate rustc_smir; extern crate rustc_driver; extern crate rustc_interface; extern crate stable_mir; use rustc_smir::rustc_internal; use stable_mir::*; use std::io::Write; use std::ops::ControlFlow; const CRATE_NAME: &str = "input"; /// This function uses the Stable MIR APIs to get information about the test crate. fn test_item_kind() -> ControlFlow<()> { let items = stable_mir::all_local_items(); assert_eq!(items.len(), 4); // Constructor item. for item in items { let expected_kind = match item.name().as_str() { "Dummy" => ItemKind::Ctor(CtorKind::Fn), "dummy" => ItemKind::Fn, "unit" => ItemKind::Fn, "DUMMY_CONST" => ItemKind::Const, name => unreachable!("Unexpected item {name}"), }; assert_eq!(item.kind(), expected_kind, "Mismatched type for {}", item.name()); } ControlFlow::Continue(()) } /// This test will generate and analyze a dummy crate using the stable mir. /// For that, it will first write the dummy crate into a file. /// Then it will create a `StableMir` using custom arguments and then /// it will run the compiler. fn main() { let path = "item_kind_input.rs"; generate_input(&path).unwrap(); let args = vec![ "rustc".to_string(), "-Cpanic=abort".to_string(), "--crate-type=lib".to_string(), "--crate-name".to_string(), CRATE_NAME.to_string(), path.to_string(), ]; run!(args, test_item_kind).unwrap(); } fn generate_input(path: &str) -> std::io::Result<()> { let mut file = std::fs::File::create(path)?; write!( file, r#" pub struct Dummy(u32); pub const DUMMY_CONST: Dummy = Dummy(0); pub struct DummyUnit; pub fn dummy() -> Dummy {{ Dummy(5) }} pub fn unit() -> DummyUnit {{ DummyUnit }} "# )?; Ok(()) }