move ABI sanity check from LLVM codegen backend to ABI computation logic

compiler/rustc_codegen_llvm/src/abi.rs

@@ -348,50 +348,18 @@ impl<'ll, 'tcx> FnAbiLlvmExt<'ll, 'tcx> for FnAbi<'tcx, Ty<'tcx>> {
                 PassMode::Direct(_) => {
                     // ABI-compatible Rust types have the same `layout.abi` (up to validity ranges),
                     // and for Scalar ABIs the LLVM type is fully determined by `layout.abi`,
-                    // guarnateeing that we generate ABI-compatible LLVM IR. Things get tricky for
-                    // aggregates...
-                    if matches!(arg.layout.abi, abi::Abi::Aggregate { .. }) {
-                        assert!(
-                            arg.layout.is_sized(),
-                            "`PassMode::Direct` for unsized type: {}",
-                            arg.layout.ty
-                        );
-                        // This really shouldn't happen, since `immediate_llvm_type` will use
-                        // `layout.fields` to turn this Rust type into an LLVM type. This means all
-                        // sorts of Rust type details leak into the ABI. However wasm sadly *does*
-                        // currently use this mode so we have to allow it -- but we absolutely
-                        // shouldn't let any more targets do that.
-                        // (Also see <https://github.com/rust-lang/rust/issues/115666>.)
-                        //
-                        // The unstable abi `PtxKernel` also uses Direct for now.
-                        // It needs to switch to something else before stabilization can happen.
-                        // (See issue: https://github.com/rust-lang/rust/issues/117271)
-                        assert!(
-                            matches!(&*cx.tcx.sess.target.arch, "wasm32" | "wasm64")
-                                || self.conv == Conv::PtxKernel,
-                            "`PassMode::Direct` for aggregates only allowed on wasm and `extern \"ptx-kernel\"` fns\nProblematic type: {:#?}",
-                            arg.layout,
-                        );
-                    }
+                    // guaranteeing that we generate ABI-compatible LLVM IR.
                     arg.layout.immediate_llvm_type(cx)
                 }
                 PassMode::Pair(..) => {
                     // ABI-compatible Rust types have the same `layout.abi` (up to validity ranges),
                     // so for ScalarPair we can easily be sure that we are generating ABI-compatible
                     // LLVM IR.
-                    assert!(
-                        matches!(arg.layout.abi, abi::Abi::ScalarPair(..)),
-                        "PassMode::Pair for type {}",
-                        arg.layout.ty
-                    );
                     llargument_tys.push(arg.layout.scalar_pair_element_llvm_type(cx, 0, true));
                     llargument_tys.push(arg.layout.scalar_pair_element_llvm_type(cx, 1, true));
                     continue;
                 }
-                PassMode::Indirect { attrs: _, meta_attrs: Some(_), on_stack } => {
-                    // `Indirect` with metadata is only for unsized types, and doesn't work with
-                    // on-stack passing.
-                    assert!(arg.layout.is_unsized() && !on_stack);
+                PassMode::Indirect { attrs: _, meta_attrs: Some(_), on_stack: _ } => {
                     // Construct the type of a (wide) pointer to `ty`, and pass its two fields.
                     // Any two ABI-compatible unsized types have the same metadata type and
                     // moreover the same metadata value leads to the same dynamic size and
@@ -402,13 +370,8 @@ impl<'ll, 'tcx> FnAbiLlvmExt<'ll, 'tcx> for FnAbi<'tcx, Ty<'tcx>> {
                     llargument_tys.push(ptr_layout.scalar_pair_element_llvm_type(cx, 1, true));
                     continue;
                 }
-                PassMode::Indirect { attrs: _, meta_attrs: None, on_stack: _ } => {
-                    assert!(arg.layout.is_sized());
-                    cx.type_ptr()
-                }
+                PassMode::Indirect { attrs: _, meta_attrs: None, on_stack: _ } => cx.type_ptr(),
                 PassMode::Cast { cast, pad_i32 } => {
-                    // `Cast` means "transmute to `CastType`"; that only makes sense for sized types.
-                    assert!(arg.layout.is_sized());
                     // add padding
                     if *pad_i32 {
                         llargument_tys.push(Reg::i32().llvm_type(cx));

compiler/rustc_ty_utils/src/abi.rs

@@ -327,6 +327,76 @@ fn adjust_for_rust_scalar<'tcx>(
     }
 }
 
+/// Ensure that the ABI makes basic sense.
+fn fn_abi_sanity_check<'tcx>(cx: &LayoutCx<'tcx, TyCtxt<'tcx>>, fn_abi: &FnAbi<'tcx, Ty<'tcx>>) {
+    fn fn_arg_sanity_check<'tcx>(
+        cx: &LayoutCx<'tcx, TyCtxt<'tcx>>,
+        fn_abi: &FnAbi<'tcx, Ty<'tcx>>,
+        arg: &ArgAbi<'tcx, Ty<'tcx>>,
+    ) {
+        match &arg.mode {
+            PassMode::Ignore => {}
+            PassMode::Direct(_) => {
+                // Here the Rust type is used to determine the actual ABI, so we have to be very
+                // careful. Scalar/ScalarPair is fine, since backends will generally use
+                // `layout.abi` and ignore everything else. We should just reject `Aggregate`
+                // entirely here, but some targets need to be fixed first.
+                if matches!(arg.layout.abi, Abi::Aggregate { .. }) {
+                    // For an unsized type we'd only pass the sized prefix, so there is no universe
+                    // in which we ever want to allow this.
+                    assert!(
+                        arg.layout.is_sized(),
+                        "`PassMode::Direct` for unsized type in ABI: {:#?}",
+                        fn_abi
+                    );
+                    // This really shouldn't happen even for sized aggregates, since
+                    // `immediate_llvm_type` will use `layout.fields` to turn this Rust type into an
+                    // LLVM type. This means all sorts of Rust type details leak into the ABI.
+                    // However wasm sadly *does* currently use this mode so we have to allow it --
+                    // but we absolutely shouldn't let any more targets do that.
+                    // (Also see <https://github.com/rust-lang/rust/issues/115666>.)
+                    //
+                    // The unstable abi `PtxKernel` also uses Direct for now.
+                    // It needs to switch to something else before stabilization can happen.
+                    // (See issue: https://github.com/rust-lang/rust/issues/117271)
+                    assert!(
+                        matches!(&*cx.tcx.sess.target.arch, "wasm32" | "wasm64")
+                            || fn_abi.conv == Conv::PtxKernel,
+                        "`PassMode::Direct` for aggregates only allowed on wasm and `extern \"ptx-kernel\"` fns\nProblematic type: {:#?}",
+                        arg.layout,
+                    );
+                }
+            }
+            PassMode::Pair(_, _) => {
+                // Similar to `Direct`, we need to make sure that backends use `layout.abi` and
+                // ignore the rest of the layout.
+                assert!(
+                    matches!(arg.layout.abi, Abi::ScalarPair(..)),
+                    "PassMode::Pair for type {}",
+                    arg.layout.ty
+                );
+            }
+            PassMode::Cast { .. } => {
+                // `Cast` means "transmute to `CastType`"; that only makes sense for sized types.
+                assert!(arg.layout.is_sized());
+            }
+            PassMode::Indirect { meta_attrs: None, .. } => {
+                // No metadata, must be sized.
+                assert!(arg.layout.is_sized());
+            }
+            PassMode::Indirect { meta_attrs: Some(_), on_stack, .. } => {
+                // With metadata. Must be unsized and not on the stack.
+                assert!(arg.layout.is_unsized() && !on_stack);
+            }
+        }
+    }
+
+    for arg in fn_abi.args.iter() {
+        fn_arg_sanity_check(cx, fn_abi, arg);
+    }
+    fn_arg_sanity_check(cx, fn_abi, &fn_abi.ret);
+}
+
 // FIXME(eddyb) perhaps group the signature/type-containing (or all of them?)
 // arguments of this method, into a separate `struct`.
 #[tracing::instrument(level = "debug", skip(cx, caller_location, fn_def_id, force_thin_self_ptr))]
@@ -453,6 +523,7 @@ fn fn_abi_new_uncached<'tcx>(
     };
     fn_abi_adjust_for_abi(cx, &mut fn_abi, sig.abi, fn_def_id)?;
     debug!("fn_abi_new_uncached = {:?}", fn_abi);
+    fn_abi_sanity_check(cx, &fn_abi);
     Ok(cx.tcx.arena.alloc(fn_abi))
 }
 

tests/ui/abi/compatibility.rs

@@ -37,9 +37,11 @@
 // revisions: wasi
 //[wasi] compile-flags: --target wasm32-wasi
 //[wasi] needs-llvm-components: webassembly
-// revisions: nvptx64
-//[nvptx64] compile-flags: --target nvptx64-nvidia-cuda
-//[nvptx64] needs-llvm-components: nvptx
+// FIXME: disabled on nvptx64 since the target ABI fails the sanity check
+/* revisions: nvptx64
+  [nvptx64] compile-flags: --target nvptx64-nvidia-cuda
+  [nvptx64] needs-llvm-components: nvptx
+*/
 #![feature(rustc_attrs, unsized_fn_params, transparent_unions)]
 #![cfg_attr(not(host), feature(no_core, lang_items), no_std, no_core)]
 #![allow(unused, improper_ctypes_definitions, internal_features)]