rust/tests/ui-fulldeps/stable-mir/projections.rs
2023-11-22 07:32:37 -08:00

181 lines
6.8 KiB
Rust

// run-pass
// Tests the Stable MIR projections API
// 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)]
extern crate rustc_hir;
extern crate rustc_middle;
#[macro_use]
extern crate rustc_smir;
extern crate rustc_driver;
extern crate rustc_interface;
extern crate stable_mir;
use rustc_middle::ty::TyCtxt;
use rustc_smir::rustc_internal;
use stable_mir::crate_def::CrateDef;
use stable_mir::mir::{ProjectionElem, Rvalue, StatementKind};
use stable_mir::ty::{RigidTy, TyKind, UintTy};
use stable_mir::ItemKind;
use std::assert_matches::assert_matches;
use std::io::Write;
use std::ops::ControlFlow;
const CRATE_NAME: &str = "input";
/// Tests projections within Place objects
fn test_place_projections(_tcx: TyCtxt<'_>) -> ControlFlow<()> {
let items = stable_mir::all_local_items();
let body = get_item(&items, (ItemKind::Fn, "projections")).unwrap().body();
assert_eq!(body.blocks.len(), 4);
// The first statement assigns `&s.c` to a local. The projections include a deref for `s`, since
// `s` is passed as a reference argument, and a field access for field `c`.
match &body.blocks[0].statements[0].kind {
StatementKind::Assign(
place @ stable_mir::mir::Place { local: _, projection: local_proj },
Rvalue::Ref(_, _, stable_mir::mir::Place { local: _, projection: r_proj }),
) => {
// We can't match on vecs, only on slices. Comparing statements for equality wouldn't be
// any easier since we'd then have to add in the expected local and region values
// instead of matching on wildcards.
assert!(local_proj.is_empty());
match &r_proj[..] {
// Similarly we can't match against a type, only against its kind.
[ProjectionElem::Deref, ProjectionElem::Field(2, ty)] => {
assert_matches!(
ty.kind(),
TyKind::RigidTy(RigidTy::Uint(stable_mir::ty::UintTy::U8))
);
let ty = place.ty(body.locals()).unwrap();
assert_matches!(ty.kind().rigid(), Some(RigidTy::Ref(..)));
},
other => panic!(
"Unable to match against expected rvalue projection. Expected the projection \
for `s.c`, which is a Deref and u8 Field. Got: {:?}",
other
),
};
}
other => panic!(
"Unable to match against expected Assign statement with a Ref rvalue. Expected the \
statement to assign `&s.c` to a local. Got: {:?}",
other
),
};
// This statement assigns `slice[1]` to a local. The projections include a deref for `slice`,
// since `slice` is a reference, and an index.
match &body.blocks[2].statements[0].kind {
StatementKind::Assign(
place @ stable_mir::mir::Place { local: _, projection: local_proj },
Rvalue::Use(stable_mir::mir::Operand::Copy(stable_mir::mir::Place {
local: _,
projection: r_proj,
})),
) => {
// We can't match on vecs, only on slices. Comparing for equality wouldn't be any easier
// since we'd then have to add in the expected local values instead of matching on
// wildcards.
assert!(local_proj.is_empty());
assert_matches!(r_proj[..], [ProjectionElem::Deref, ProjectionElem::Index(_)]);
let ty = place.ty(body.locals()).unwrap();
assert_matches!(ty.kind().rigid(), Some(RigidTy::Uint(UintTy::U8)));
}
other => panic!(
"Unable to match against expected Assign statement with a Use rvalue. Expected the \
statement to assign `slice[1]` to a local. Got: {:?}",
other
),
};
// The first terminator gets a slice of an array via the Index operation. Specifically it
// performs `&vals[1..3]`. There are no projections in this case, the arguments are just locals.
match &body.blocks[0].terminator.kind {
stable_mir::mir::TerminatorKind::Call { args, .. } =>
// We can't match on vecs, only on slices. Comparing for equality wouldn't be any easier
// since we'd then have to add in the expected local values instead of matching on
// wildcards.
{
match &args[..] {
[
stable_mir::mir::Operand::Move(stable_mir::mir::Place {
local: _,
projection: arg1_proj,
}),
stable_mir::mir::Operand::Move(stable_mir::mir::Place {
local: _,
projection: arg2_proj,
}),
] => {
assert!(arg1_proj.is_empty());
assert!(arg2_proj.is_empty());
}
other => {
panic!(
"Unable to match against expected arguments to Index call. Expected two \
move operands. Got: {:?}",
other
)
}
}
}
other => panic!(
"Unable to match against expected Call terminator. Expected a terminator that calls \
the Index operation. Got: {:?}",
other
),
};
ControlFlow::Continue(())
}
// Use internal API to find a function in a crate.
fn get_item<'a>(
items: &'a stable_mir::CrateItems,
item: (ItemKind, &str),
) -> Option<&'a stable_mir::CrateItem> {
items.iter().find(|crate_item| {
crate_item.kind() == item.0 && crate_item.name() == item.1
})
}
/// 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 = "input.rs";
generate_input(&path).unwrap();
let args = vec![
"rustc".to_string(),
"--crate-type=lib".to_string(),
"--crate-name".to_string(),
CRATE_NAME.to_string(),
path.to_string(),
];
run!(args, tcx, test_place_projections(tcx)).unwrap();
}
fn generate_input(path: &str) -> std::io::Result<()> {
let mut file = std::fs::File::create(path)?;
write!(
file,
r#"
pub struct Struct1 {{ _a: u8, _b: u16, c: u8 }}
pub fn projections(s: &Struct1) -> u8 {{
let v = &s.c;
let vals = [1, 2, 3, 4];
let slice = &vals[1..3];
v + slice[1]
}}"#
)?;
Ok(())
}