//! Handles codegen of callees as well as other call-related //! things. Callees are a superset of normal rust values and sometimes //! have different representations. In particular, top-level fn items //! and methods are represented as just a fn ptr and not a full //! closure. use crate::abi::FnAbiLlvmExt; use crate::attributes; use crate::common; use crate::context::CodegenCx; use crate::llvm; use crate::value::Value; use rustc_codegen_ssa::traits::*; use rustc_middle::ty::layout::{FnAbiOf, HasTyCtxt}; use rustc_middle::ty::{self, Instance, TypeVisitable}; /// Codegens a reference to a fn/method item, monomorphizing and /// inlining as it goes. /// /// # Parameters /// /// - `cx`: the crate context /// - `instance`: the instance to be instantiated pub fn get_fn<'ll, 'tcx>(cx: &CodegenCx<'ll, 'tcx>, instance: Instance<'tcx>) -> &'ll Value { let tcx = cx.tcx(); debug!("get_fn(instance={:?})", instance); assert!(!instance.substs.needs_infer()); assert!(!instance.substs.has_escaping_bound_vars()); if let Some(&llfn) = cx.instances.borrow().get(&instance) { return llfn; } let sym = tcx.symbol_name(instance).name; debug!( "get_fn({:?}: {:?}) => {}", instance, instance.ty(cx.tcx(), ty::ParamEnv::reveal_all()), sym ); let fn_abi = cx.fn_abi_of_instance(instance, ty::List::empty()); let llfn = if let Some(llfn) = cx.get_declared_value(sym) { // Create a fn pointer with the new signature. let llptrty = fn_abi.ptr_to_llvm_type(cx); // This is subtle and surprising, but sometimes we have to bitcast // the resulting fn pointer. The reason has to do with external // functions. If you have two crates that both bind the same C // library, they may not use precisely the same types: for // example, they will probably each declare their own structs, // which are distinct types from LLVM's point of view (nominal // types). // // Now, if those two crates are linked into an application, and // they contain inlined code, you can wind up with a situation // where both of those functions wind up being loaded into this // application simultaneously. In that case, the same function // (from LLVM's point of view) requires two types. But of course // LLVM won't allow one function to have two types. // // What we currently do, therefore, is declare the function with // one of the two types (whichever happens to come first) and then // bitcast as needed when the function is referenced to make sure // it has the type we expect. // // This can occur on either a crate-local or crate-external // reference. It also occurs when testing libcore and in some // other weird situations. Annoying. if cx.val_ty(llfn) != llptrty { debug!("get_fn: casting {:?} to {:?}", llfn, llptrty); cx.const_ptrcast(llfn, llptrty) } else { debug!("get_fn: not casting pointer!"); llfn } } else { let instance_def_id = instance.def_id(); let llfn = if tcx.sess.target.arch == "x86" && let Some(dllimport) = common::get_dllimport(tcx, instance_def_id, sym) { // Fix for https://github.com/rust-lang/rust/issues/104453 // On x86 Windows, LLVM uses 'L' as the prefix for any private // global symbols, so when we create an undecorated function symbol // that begins with an 'L' LLVM misinterprets that as a private // global symbol that it created and so fails the compilation at a // later stage since such a symbol must have a definition. // // To avoid this, we set the Storage Class to "DllImport" so that // LLVM will prefix the name with `__imp_`. Ideally, we'd like the // existing logic below to set the Storage Class, but it has an // exemption for MinGW for backwards compatability. let llfn = cx.declare_fn(&common::i686_decorated_name(&dllimport, common::is_mingw_gnu_toolchain(&tcx.sess.target), true), fn_abi); unsafe { llvm::LLVMSetDLLStorageClass(llfn, llvm::DLLStorageClass::DllImport); } llfn } else { cx.declare_fn(sym, fn_abi) }; debug!("get_fn: not casting pointer!"); attributes::from_fn_attrs(cx, llfn, instance); // Apply an appropriate linkage/visibility value to our item that we // just declared. // // This is sort of subtle. Inside our codegen unit we started off // compilation by predefining all our own `MonoItem` instances. That // is, everything we're codegenning ourselves is already defined. That // means that anything we're actually codegenning in this codegen unit // will have hit the above branch in `get_declared_value`. As a result, // we're guaranteed here that we're declaring a symbol that won't get // defined, or in other words we're referencing a value from another // codegen unit or even another crate. // // So because this is a foreign value we blanket apply an external // linkage directive because it's coming from a different object file. // The visibility here is where it gets tricky. This symbol could be // referencing some foreign crate or foreign library (an `extern` // block) in which case we want to leave the default visibility. We may // also, though, have multiple codegen units. It could be a // monomorphization, in which case its expected visibility depends on // whether we are sharing generics or not. The important thing here is // that the visibility we apply to the declaration is the same one that // has been applied to the definition (wherever that definition may be). unsafe { llvm::LLVMRustSetLinkage(llfn, llvm::Linkage::ExternalLinkage); let is_generic = instance.substs.non_erasable_generics().next().is_some(); if is_generic { // This is a monomorphization. Its expected visibility depends // on whether we are in share-generics mode. if cx.tcx.sess.opts.share_generics() { // We are in share_generics mode. if let Some(instance_def_id) = instance_def_id.as_local() { // This is a definition from the current crate. If the // definition is unreachable for downstream crates or // the current crate does not re-export generics, the // definition of the instance will have been declared // as `hidden`. if cx.tcx.is_unreachable_local_definition(instance_def_id) || !cx.tcx.local_crate_exports_generics() { llvm::LLVMRustSetVisibility(llfn, llvm::Visibility::Hidden); } } else { // This is a monomorphization of a generic function // defined in an upstream crate. if instance.upstream_monomorphization(tcx).is_some() { // This is instantiated in another crate. It cannot // be `hidden`. } else { // This is a local instantiation of an upstream definition. // If the current crate does not re-export it // (because it is a C library or an executable), it // will have been declared `hidden`. if !cx.tcx.local_crate_exports_generics() { llvm::LLVMRustSetVisibility(llfn, llvm::Visibility::Hidden); } } } } else { // When not sharing generics, all instances are in the same // crate and have hidden visibility llvm::LLVMRustSetVisibility(llfn, llvm::Visibility::Hidden); } } else { // This is a non-generic function if cx.tcx.is_codegened_item(instance_def_id) { // This is a function that is instantiated in the local crate if instance_def_id.is_local() { // This is function that is defined in the local crate. // If it is not reachable, it is hidden. if !cx.tcx.is_reachable_non_generic(instance_def_id) { llvm::LLVMRustSetVisibility(llfn, llvm::Visibility::Hidden); } } else { // This is a function from an upstream crate that has // been instantiated here. These are always hidden. llvm::LLVMRustSetVisibility(llfn, llvm::Visibility::Hidden); } } } // MinGW: For backward compatibility we rely on the linker to decide whether it // should use dllimport for functions. if cx.use_dll_storage_attrs && let Some(library) = tcx.native_library(instance_def_id) && library.kind.is_dllimport() && !matches!(tcx.sess.target.env.as_ref(), "gnu" | "uclibc") { llvm::LLVMSetDLLStorageClass(llfn, llvm::DLLStorageClass::DllImport); } if cx.should_assume_dso_local(llfn, true) { llvm::LLVMRustSetDSOLocal(llfn, true); } } llfn }; cx.instances.borrow_mut().insert(instance, llfn); llfn }