// Copyright 2012-2015 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. // See doc.rs for documentation. mod doc; use self::VariableAccess::*; use self::VariableKind::*; use self::utils::{DIB, span_start, create_DIArray, is_node_local_to_unit}; use self::namespace::mangled_name_of_instance; use self::type_names::compute_debuginfo_type_name; use self::metadata::{type_metadata, file_metadata, TypeMap}; use self::source_loc::InternalDebugLocation::{self, UnknownLocation}; use llvm; use llvm::{ModuleRef, ContextRef, ValueRef}; use llvm::debuginfo::{DIFile, DIType, DIScope, DIBuilderRef, DISubprogram, DIArray, DIFlags}; use rustc::hir::def_id::{DefId, CrateNum}; use rustc::ty::subst::Substs; use abi::Abi; use common::CodegenCx; use builder::Builder; use monomorphize::Instance; use rustc::ty::{self, Ty}; use rustc::mir; use rustc::session::config::{self, FullDebugInfo, LimitedDebugInfo, NoDebugInfo}; use rustc::util::nodemap::{DefIdMap, FxHashMap, FxHashSet}; use libc::c_uint; use std::cell::{Cell, RefCell}; use std::ffi::CString; use std::ptr; use syntax_pos::{self, Span, Pos}; use syntax::ast; use syntax::symbol::Symbol; use rustc::ty::layout::{self, LayoutOf}; pub mod gdb; mod utils; mod namespace; mod type_names; pub mod metadata; mod create_scope_map; mod source_loc; pub use self::create_scope_map::{create_mir_scopes, MirDebugScope}; pub use self::source_loc::start_emitting_source_locations; pub use self::metadata::create_global_var_metadata; pub use self::metadata::create_vtable_metadata; pub use self::metadata::extend_scope_to_file; pub use self::source_loc::set_source_location; #[allow(non_upper_case_globals)] const DW_TAG_auto_variable: c_uint = 0x100; #[allow(non_upper_case_globals)] const DW_TAG_arg_variable: c_uint = 0x101; /// A context object for maintaining all state needed by the debuginfo module. pub struct CrateDebugContext<'tcx> { llcontext: ContextRef, llmod: ModuleRef, builder: DIBuilderRef, created_files: RefCell>, created_enum_disr_types: RefCell>, type_map: RefCell>, namespace_map: RefCell>, // This collection is used to assert that composite types (structs, enums, // ...) have their members only set once: composite_types_completed: RefCell>, } impl<'tcx> CrateDebugContext<'tcx> { pub fn new(llmod: ModuleRef) -> CrateDebugContext<'tcx> { debug!("CrateDebugContext::new"); let builder = unsafe { llvm::LLVMRustDIBuilderCreate(llmod) }; // DIBuilder inherits context from the module, so we'd better use the same one let llcontext = unsafe { llvm::LLVMGetModuleContext(llmod) }; CrateDebugContext { llcontext, llmod, builder, created_files: RefCell::new(FxHashMap()), created_enum_disr_types: RefCell::new(FxHashMap()), type_map: RefCell::new(TypeMap::new()), namespace_map: RefCell::new(DefIdMap()), composite_types_completed: RefCell::new(FxHashSet()), } } } pub enum FunctionDebugContext { RegularContext(FunctionDebugContextData), DebugInfoDisabled, FunctionWithoutDebugInfo, } impl FunctionDebugContext { pub fn get_ref<'a>(&'a self, span: Span) -> &'a FunctionDebugContextData { match *self { FunctionDebugContext::RegularContext(ref data) => data, FunctionDebugContext::DebugInfoDisabled => { span_bug!(span, "{}", FunctionDebugContext::debuginfo_disabled_message()); } FunctionDebugContext::FunctionWithoutDebugInfo => { span_bug!(span, "{}", FunctionDebugContext::should_be_ignored_message()); } } } fn debuginfo_disabled_message() -> &'static str { "debuginfo: Error trying to access FunctionDebugContext although debug info is disabled!" } fn should_be_ignored_message() -> &'static str { "debuginfo: Error trying to access FunctionDebugContext for function that should be \ ignored by debug info!" } } pub struct FunctionDebugContextData { fn_metadata: DISubprogram, source_locations_enabled: Cell, pub defining_crate: CrateNum, } pub enum VariableAccess<'a> { // The llptr given is an alloca containing the variable's value DirectVariable { alloca: ValueRef }, // The llptr given is an alloca containing the start of some pointer chain // leading to the variable's content. IndirectVariable { alloca: ValueRef, address_operations: &'a [i64] } } pub enum VariableKind { ArgumentVariable(usize /*index*/), LocalVariable, CapturedVariable, } /// Create any deferred debug metadata nodes pub fn finalize(cx: &CodegenCx) { if cx.dbg_cx.is_none() { return; } debug!("finalize"); if gdb::needs_gdb_debug_scripts_section(cx) { // Add a .debug_gdb_scripts section to this compile-unit. This will // cause GDB to try and load the gdb_load_rust_pretty_printers.py file, // which activates the Rust pretty printers for binary this section is // contained in. gdb::get_or_insert_gdb_debug_scripts_section_global(cx); } unsafe { llvm::LLVMRustDIBuilderFinalize(DIB(cx)); llvm::LLVMRustDIBuilderDispose(DIB(cx)); // Debuginfo generation in LLVM by default uses a higher // version of dwarf than macOS currently understands. We can // instruct LLVM to emit an older version of dwarf, however, // for macOS to understand. For more info see #11352 // This can be overridden using --llvm-opts -dwarf-version,N. // Android has the same issue (#22398) if cx.sess().target.target.options.is_like_osx || cx.sess().target.target.options.is_like_android { llvm::LLVMRustAddModuleFlag(cx.llmod, "Dwarf Version\0".as_ptr() as *const _, 2) } // Indicate that we want CodeView debug information on MSVC if cx.sess().target.target.options.is_like_msvc { llvm::LLVMRustAddModuleFlag(cx.llmod, "CodeView\0".as_ptr() as *const _, 1) } // Prevent bitcode readers from deleting the debug info. let ptr = "Debug Info Version\0".as_ptr(); llvm::LLVMRustAddModuleFlag(cx.llmod, ptr as *const _, llvm::LLVMRustDebugMetadataVersion()); }; } /// Creates the function-specific debug context. /// /// Returns the FunctionDebugContext for the function which holds state needed /// for debug info creation. The function may also return another variant of the /// FunctionDebugContext enum which indicates why no debuginfo should be created /// for the function. pub fn create_function_debug_context<'a, 'tcx>(cx: &CodegenCx<'a, 'tcx>, instance: Instance<'tcx>, sig: ty::FnSig<'tcx>, llfn: ValueRef, mir: &mir::Mir) -> FunctionDebugContext { if cx.sess().opts.debuginfo == NoDebugInfo { return FunctionDebugContext::DebugInfoDisabled; } for attr in instance.def.attrs(cx.tcx).iter() { if attr.check_name("no_debug") { return FunctionDebugContext::FunctionWithoutDebugInfo; } } let containing_scope = get_containing_scope(cx, instance); let span = mir.span; // This can be the case for functions inlined from another crate if span == syntax_pos::DUMMY_SP { // FIXME(simulacrum): Probably can't happen; remove. return FunctionDebugContext::FunctionWithoutDebugInfo; } let def_id = instance.def_id(); let loc = span_start(cx, span); let file_metadata = file_metadata(cx, &loc.file.name, def_id.krate); let function_type_metadata = unsafe { let fn_signature = get_function_signature(cx, sig); llvm::LLVMRustDIBuilderCreateSubroutineType(DIB(cx), file_metadata, fn_signature) }; // Find the enclosing function, in case this is a closure. let def_key = cx.tcx.def_key(def_id); let mut name = def_key.disambiguated_data.data.to_string(); let enclosing_fn_def_id = cx.tcx.closure_base_def_id(def_id); // Get_template_parameters() will append a `<...>` clause to the function // name if necessary. let generics = cx.tcx.generics_of(enclosing_fn_def_id); let substs = instance.substs.truncate_to(cx.tcx, generics); let template_parameters = get_template_parameters(cx, &generics, substs, file_metadata, &mut name); // Get the linkage_name, which is just the symbol name let linkage_name = mangled_name_of_instance(cx, instance); let scope_line = span_start(cx, span).line; let local_id = cx.tcx.hir.as_local_node_id(instance.def_id()); let is_local_to_unit = local_id.map_or(false, |id| is_node_local_to_unit(cx, id)); let function_name = CString::new(name).unwrap(); let linkage_name = CString::new(linkage_name.to_string()).unwrap(); let mut flags = DIFlags::FlagPrototyped; match *cx.sess().entry_fn.borrow() { Some((id, _)) => { if local_id == Some(id) { flags = flags | DIFlags::FlagMainSubprogram; } } None => {} }; let fn_metadata = unsafe { llvm::LLVMRustDIBuilderCreateFunction( DIB(cx), containing_scope, function_name.as_ptr(), linkage_name.as_ptr(), file_metadata, loc.line as c_uint, function_type_metadata, is_local_to_unit, true, scope_line as c_uint, flags, cx.sess().opts.optimize != config::OptLevel::No, llfn, template_parameters, ptr::null_mut()) }; // Initialize fn debug context (including scope map and namespace map) let fn_debug_context = FunctionDebugContextData { fn_metadata, source_locations_enabled: Cell::new(false), defining_crate: def_id.krate, }; return FunctionDebugContext::RegularContext(fn_debug_context); fn get_function_signature<'a, 'tcx>(cx: &CodegenCx<'a, 'tcx>, sig: ty::FnSig<'tcx>) -> DIArray { if cx.sess().opts.debuginfo == LimitedDebugInfo { return create_DIArray(DIB(cx), &[]); } let mut signature = Vec::with_capacity(sig.inputs().len() + 1); // Return type -- llvm::DIBuilder wants this at index 0 signature.push(match sig.output().sty { ty::TyTuple(ref tys, _) if tys.is_empty() => ptr::null_mut(), _ => type_metadata(cx, sig.output(), syntax_pos::DUMMY_SP) }); let inputs = if sig.abi == Abi::RustCall { &sig.inputs()[..sig.inputs().len() - 1] } else { sig.inputs() }; // Arguments types if cx.sess().target.target.options.is_like_msvc { // FIXME(#42800): // There is a bug in MSDIA that leads to a crash when it encounters // a fixed-size array of `u8` or something zero-sized in a // function-type (see #40477). // As a workaround, we replace those fixed-size arrays with a // pointer-type. So a function `fn foo(a: u8, b: [u8; 4])` would // appear as `fn foo(a: u8, b: *const u8)` in debuginfo, // and a function `fn bar(x: [(); 7])` as `fn bar(x: *const ())`. // This transformed type is wrong, but these function types are // already inaccurate due to ABI adjustments (see #42800). signature.extend(inputs.iter().map(|&t| { let t = match t.sty { ty::TyArray(ct, _) if (ct == cx.tcx.types.u8) || cx.layout_of(ct).is_zst() => { cx.tcx.mk_imm_ptr(ct) } _ => t }; type_metadata(cx, t, syntax_pos::DUMMY_SP) })); } else { signature.extend(inputs.iter().map(|t| { type_metadata(cx, t, syntax_pos::DUMMY_SP) })); } if sig.abi == Abi::RustCall && !sig.inputs().is_empty() { if let ty::TyTuple(args, _) = sig.inputs()[sig.inputs().len() - 1].sty { for &argument_type in args { signature.push(type_metadata(cx, argument_type, syntax_pos::DUMMY_SP)); } } } return create_DIArray(DIB(cx), &signature[..]); } fn get_template_parameters<'a, 'tcx>(cx: &CodegenCx<'a, 'tcx>, generics: &ty::Generics, substs: &Substs<'tcx>, file_metadata: DIFile, name_to_append_suffix_to: &mut String) -> DIArray { if substs.types().next().is_none() { return create_DIArray(DIB(cx), &[]); } name_to_append_suffix_to.push('<'); for (i, actual_type) in substs.types().enumerate() { if i != 0 { name_to_append_suffix_to.push_str(","); } let actual_type = cx.tcx.fully_normalize_associated_types_in(&actual_type); // Add actual type name to <...> clause of function name let actual_type_name = compute_debuginfo_type_name(cx, actual_type, true); name_to_append_suffix_to.push_str(&actual_type_name[..]); } name_to_append_suffix_to.push('>'); // Again, only create type information if full debuginfo is enabled let template_params: Vec<_> = if cx.sess().opts.debuginfo == FullDebugInfo { let names = get_type_parameter_names(cx, generics); substs.types().zip(names).map(|(ty, name)| { let actual_type = cx.tcx.fully_normalize_associated_types_in(&ty); let actual_type_metadata = type_metadata(cx, actual_type, syntax_pos::DUMMY_SP); let name = CString::new(name.as_str().as_bytes()).unwrap(); unsafe { llvm::LLVMRustDIBuilderCreateTemplateTypeParameter( DIB(cx), ptr::null_mut(), name.as_ptr(), actual_type_metadata, file_metadata, 0, 0) } }).collect() } else { vec![] }; return create_DIArray(DIB(cx), &template_params[..]); } fn get_type_parameter_names(cx: &CodegenCx, generics: &ty::Generics) -> Vec { let mut names = generics.parent.map_or(vec![], |def_id| { get_type_parameter_names(cx, cx.tcx.generics_of(def_id)) }); names.extend(generics.types.iter().map(|param| param.name)); names } fn get_containing_scope<'cx, 'tcx>(cx: &CodegenCx<'cx, 'tcx>, instance: Instance<'tcx>) -> DIScope { // First, let's see if this is a method within an inherent impl. Because // if yes, we want to make the result subroutine DIE a child of the // subroutine's self-type. let self_type = cx.tcx.impl_of_method(instance.def_id()).and_then(|impl_def_id| { // If the method does *not* belong to a trait, proceed if cx.tcx.trait_id_of_impl(impl_def_id).is_none() { let impl_self_ty = cx.tcx.trans_impl_self_ty(impl_def_id, instance.substs); // Only "class" methods are generally understood by LLVM, // so avoid methods on other types (e.g. `<*mut T>::null`). match impl_self_ty.sty { ty::TyAdt(def, ..) if !def.is_box() => { Some(type_metadata(cx, impl_self_ty, syntax_pos::DUMMY_SP)) } _ => None } } else { // For trait method impls we still use the "parallel namespace" // strategy None } }); self_type.unwrap_or_else(|| { namespace::item_namespace(cx, DefId { krate: instance.def_id().krate, index: cx.tcx .def_key(instance.def_id()) .parent .expect("get_containing_scope: missing parent?") }) }) } } pub fn declare_local<'a, 'tcx>(bx: &Builder<'a, 'tcx>, dbg_context: &FunctionDebugContext, variable_name: ast::Name, variable_type: Ty<'tcx>, scope_metadata: DIScope, variable_access: VariableAccess, variable_kind: VariableKind, span: Span) { let cx = bx.cx; let file = span_start(cx, span).file; let file_metadata = file_metadata(cx, &file.name, dbg_context.get_ref(span).defining_crate); let loc = span_start(cx, span); let type_metadata = type_metadata(cx, variable_type, span); let (argument_index, dwarf_tag) = match variable_kind { ArgumentVariable(index) => (index as c_uint, DW_TAG_arg_variable), LocalVariable | CapturedVariable => (0, DW_TAG_auto_variable) }; let align = cx.align_of(variable_type); let name = CString::new(variable_name.as_str().as_bytes()).unwrap(); match (variable_access, &[][..]) { (DirectVariable { alloca }, address_operations) | (IndirectVariable {alloca, address_operations}, _) => { let metadata = unsafe { llvm::LLVMRustDIBuilderCreateVariable( DIB(cx), dwarf_tag, scope_metadata, name.as_ptr(), file_metadata, loc.line as c_uint, type_metadata, cx.sess().opts.optimize != config::OptLevel::No, DIFlags::FlagZero, argument_index, align.abi() as u32, ) }; source_loc::set_debug_location(bx, InternalDebugLocation::new(scope_metadata, loc.line, loc.col.to_usize())); unsafe { let debug_loc = llvm::LLVMGetCurrentDebugLocation(bx.llbuilder); let instr = llvm::LLVMRustDIBuilderInsertDeclareAtEnd( DIB(cx), alloca, metadata, address_operations.as_ptr(), address_operations.len() as c_uint, debug_loc, bx.llbb()); llvm::LLVMSetInstDebugLocation(bx.llbuilder, instr); } } } match variable_kind { ArgumentVariable(_) | CapturedVariable => { assert!(!dbg_context.get_ref(span).source_locations_enabled.get()); source_loc::set_debug_location(bx, UnknownLocation); } _ => { /* nothing to do */ } } }