// This test checks that we get proper type names for closure environments and // async-fn environments in debuginfo, especially making sure that generic arguments // of the enclosing functions don't get lost. // // Unfortunately, the order that debuginfo gets emitted into LLVM IR becomes a bit hard // to predict once async fns are involved, so DAG allows any order. // // Note that the test does not check async-fns when targeting MSVC because debuginfo for // those does not follow the enum-fallback encoding yet and thus is incomplete. // ignore-tidy-linelength // Use the v0 symbol mangling scheme to codegen order independent of rustc version. // Unnamed items like shims are generated in lexicographical order of their symbol name and in the // legacy mangling scheme rustc version and generic parameters are both hashed into a single part // of the name, thus randomizing item order with respect to rustc version. //@ compile-flags: -Cdebuginfo=2 --edition 2021 -Copt-level=0 -Csymbol-mangling-version=v0 // non_generic_closure() // NONMSVC: !DICompositeType(tag: DW_TAG_structure_type, name: "{closure_env#0}", scope: ![[non_generic_closure_NAMESPACE:[0-9]+]], // MSVC: !DICompositeType(tag: DW_TAG_structure_type, name: "closure_env$0", scope: ![[non_generic_closure_NAMESPACE:[0-9]+]], // CHECK: ![[non_generic_closure_NAMESPACE]] = !DINamespace(name: "non_generic_closure" // CHECK: ![[function_containing_closure_NAMESPACE:[0-9]+]] = !DINamespace(name: "function_containing_closure" // CHECK: ![[generic_async_function_NAMESPACE:[0-9]+]] = !DINamespace(name: "generic_async_function" // CHECK: ![[generic_async_block_NAMESPACE:[0-9]+]] = !DINamespace(name: "generic_async_block" // function_containing_closure() // NONMSVC-DAG: !DICompositeType(tag: DW_TAG_structure_type, name: "{closure_env#0}", scope: ![[function_containing_closure_NAMESPACE]] // MSVC-DAG: !DICompositeType(tag: DW_TAG_structure_type, name: "closure_env$0", scope: ![[function_containing_closure_NAMESPACE]] // generic_async_function() // NONMSVC-DAG: !DICompositeType(tag: DW_TAG_structure_type, name: "{async_fn_env#0}", scope: ![[generic_async_function_NAMESPACE]] // generic_async_function() // NONMSVC-DAG: !DICompositeType(tag: DW_TAG_structure_type, name: "{async_fn_env#0}", scope: ![[generic_async_function_NAMESPACE]] // generic_async_block() // NONMSVC-DAG: !DICompositeType(tag: DW_TAG_structure_type, name: "{async_block_env#0}", scope: ![[generic_async_block_NAMESPACE]] // generic_async_block() // NONMSVC-DAG: !DICompositeType(tag: DW_TAG_structure_type, name: "{async_block_env#0}", scope: ![[generic_async_block_NAMESPACE]] // function_containing_closure() // NONMSVC-DAG: !DICompositeType(tag: DW_TAG_structure_type, name: "{closure_env#0}", scope: ![[function_containing_closure_NAMESPACE]] // MSVC-DAG: !DICompositeType(tag: DW_TAG_structure_type, name: "closure_env$0", scope: ![[function_containing_closure_NAMESPACE]] #![crate_type = "lib"] use std::future::Future; pub struct Foo; pub fn non_generic_closure(x: Foo) -> Box Foo> { return Box::new(move || x); } fn function_containing_closure(x: T) -> impl FnOnce() -> T { // This static only exists to trigger generating the namespace debuginfo for // `function_containing_closure` at a predictable, early point, which makes // writing the FileCheck tests above simpler. static _X: u8 = 0; return move || x; } async fn generic_async_function(x: T) -> T { static _X: u8 = 0; // Same as above x } fn generic_async_block(x: T) -> impl Future { static _X: u8 = 0; // Same as above async move { x } } pub fn instantiate_generics() { let _closure_u32 = function_containing_closure(7u32); let _closure_foo = function_containing_closure(Foo); let _async_fn_u32 = generic_async_function(42u32); let _async_fn_foo = generic_async_function(Foo); let _async_block_u32 = generic_async_block(64u32); let _async_block_foo = generic_async_block(Foo); }