use crate::build; use crate::build::scope::DropKind; use crate::hair::cx::Cx; use crate::hair::{LintLevel, BindingMode, PatKind}; use crate::transform::MirSource; use crate::util as mir_util; use rustc::hir; use rustc::hir::{Node, GeneratorKind}; use rustc::hir::def_id::DefId; use rustc::middle::lang_items; use rustc::middle::region; use rustc::mir::*; use rustc::ty::{self, Ty, TyCtxt}; use rustc::ty::subst::Subst; use rustc::util::nodemap::HirIdMap; use rustc_target::spec::PanicStrategy; use rustc_index::vec::{IndexVec, Idx}; use std::u32; use rustc_target::spec::abi::Abi; use syntax::attr::{self, UnwindAttr}; use syntax::symbol::kw; use syntax_pos::Span; use super::lints; /// Construct the MIR for a given `DefId`. pub fn mir_build(tcx: TyCtxt<'_>, def_id: DefId) -> Body<'_> { let id = tcx.hir().as_local_hir_id(def_id).unwrap(); // Figure out what primary body this item has. let (body_id, return_ty_span) = match tcx.hir().get(id) { Node::Expr(hir::Expr { kind: hir::ExprKind::Closure(_, decl, body_id, _, _), .. }) | Node::Item( hir::Item { kind: hir::ItemKind::Fn(hir::FnSig { decl, .. }, _, body_id), .. } ) | Node::ImplItem( hir::ImplItem { kind: hir::ImplItemKind::Method(hir::FnSig { decl, .. }, body_id), .. } ) | Node::TraitItem( hir::TraitItem { kind: hir::TraitItemKind::Method( hir::FnSig { decl, .. }, hir::TraitMethod::Provided(body_id), ), .. } ) => { (*body_id, decl.output.span()) } Node::Item(hir::Item { kind: hir::ItemKind::Static(ty, _, body_id), .. }) | Node::Item(hir::Item { kind: hir::ItemKind::Const(ty, body_id), .. }) | Node::ImplItem(hir::ImplItem { kind: hir::ImplItemKind::Const(ty, body_id), .. }) | Node::TraitItem( hir::TraitItem { kind: hir::TraitItemKind::Const(ty, Some(body_id)), .. } ) => { (*body_id, ty.span) } Node::AnonConst(hir::AnonConst { body, hir_id, .. }) => { (*body, tcx.hir().span(*hir_id)) } _ => span_bug!(tcx.hir().span(id), "can't build MIR for {:?}", def_id), }; tcx.infer_ctxt().enter(|infcx| { let cx = Cx::new(&infcx, id); let body = if cx.tables().tainted_by_errors { build::construct_error(cx, body_id) } else if cx.body_owner_kind.is_fn_or_closure() { // fetch the fully liberated fn signature (that is, all bound // types/lifetimes replaced) let fn_sig = cx.tables().liberated_fn_sigs()[id].clone(); let fn_def_id = tcx.hir().local_def_id(id); let ty = tcx.type_of(fn_def_id); let mut abi = fn_sig.abi; let implicit_argument = match ty.kind { ty::Closure(..) => { // HACK(eddyb) Avoid having RustCall on closures, // as it adds unnecessary (and wrong) auto-tupling. abi = Abi::Rust; Some(ArgInfo(liberated_closure_env_ty(tcx, id, body_id), None, None, None)) } ty::Generator(..) => { let gen_ty = tcx.body_tables(body_id).node_type(id); Some(ArgInfo(gen_ty, None, None, None)) } _ => None, }; let safety = match fn_sig.unsafety { hir::Unsafety::Normal => Safety::Safe, hir::Unsafety::Unsafe => Safety::FnUnsafe, }; let body = tcx.hir().body(body_id); let explicit_arguments = body.params .iter() .enumerate() .map(|(index, arg)| { let owner_id = tcx.hir().body_owner(body_id); let opt_ty_info; let self_arg; if let Some(ref fn_decl) = tcx.hir().fn_decl_by_hir_id(owner_id) { opt_ty_info = fn_decl.inputs.get(index).map(|ty| ty.span); self_arg = if index == 0 && fn_decl.implicit_self.has_implicit_self() { match fn_decl.implicit_self { hir::ImplicitSelfKind::Imm => Some(ImplicitSelfKind::Imm), hir::ImplicitSelfKind::Mut => Some(ImplicitSelfKind::Mut), hir::ImplicitSelfKind::ImmRef => Some(ImplicitSelfKind::ImmRef), hir::ImplicitSelfKind::MutRef => Some(ImplicitSelfKind::MutRef), _ => None, } } else { None }; } else { opt_ty_info = None; self_arg = None; } // C-variadic fns also have a `VaList` input that's not listed in `fn_sig` // (as it's created inside the body itself, not passed in from outside). let ty = if fn_sig.c_variadic && index == fn_sig.inputs().len() { let va_list_did = tcx.require_lang_item( lang_items::VaListTypeLangItem, Some(arg.span), ); let region = tcx.mk_region(ty::ReScope(region::Scope { id: body.value.hir_id.local_id, data: region::ScopeData::CallSite })); tcx.type_of(va_list_did).subst(tcx, &[region.into()]) } else { fn_sig.inputs()[index] }; ArgInfo(ty, opt_ty_info, Some(&arg), self_arg) }); let arguments = implicit_argument.into_iter().chain(explicit_arguments); let (yield_ty, return_ty) = if body.generator_kind.is_some() { let gen_sig = match ty.kind { ty::Generator(gen_def_id, gen_substs, ..) => gen_substs.as_generator().sig(gen_def_id, tcx), _ => span_bug!(tcx.hir().span(id), "generator w/o generator type: {:?}", ty), }; (Some(gen_sig.yield_ty), gen_sig.return_ty) } else { (None, fn_sig.output()) }; let mut mir = build::construct_fn( cx, id, arguments, safety, abi, return_ty, return_ty_span, body, ); mir.yield_ty = yield_ty; mir } else { // Get the revealed type of this const. This is *not* the adjusted // type of its body, which may be a subtype of this type. For // example: // // fn foo(_: &()) {} // static X: fn(&'static ()) = foo; // // The adjusted type of the body of X is `for<'a> fn(&'a ())` which // is not the same as the type of X. We need the type of the return // place to be the type of the constant because NLL typeck will // equate them. let return_ty = cx.tables().node_type(id); build::construct_const(cx, body_id, return_ty, return_ty_span) }; mir_util::dump_mir(tcx, None, "mir_map", &0, MirSource::item(def_id), &body, |_, _| Ok(()) ); lints::check(tcx, &body, def_id); body }) } /////////////////////////////////////////////////////////////////////////// // BuildMir -- walks a crate, looking for fn items and methods to build MIR from fn liberated_closure_env_ty( tcx: TyCtxt<'_>, closure_expr_id: hir::HirId, body_id: hir::BodyId, ) -> Ty<'_> { let closure_ty = tcx.body_tables(body_id).node_type(closure_expr_id); let (closure_def_id, closure_substs) = match closure_ty.kind { ty::Closure(closure_def_id, closure_substs) => (closure_def_id, closure_substs), _ => bug!("closure expr does not have closure type: {:?}", closure_ty) }; let closure_env_ty = tcx.closure_env_ty(closure_def_id, closure_substs).unwrap(); tcx.liberate_late_bound_regions(closure_def_id, &closure_env_ty) } #[derive(Debug, PartialEq, Eq)] pub enum BlockFrame { /// Evaluation is currently within a statement. /// /// Examples include: /// 1. `EXPR;` /// 2. `let _ = EXPR;` /// 3. `let x = EXPR;` Statement { /// If true, then statement discards result from evaluating /// the expression (such as examples 1 and 2 above). ignores_expr_result: bool }, /// Evaluation is currently within the tail expression of a block. /// /// Example: `{ STMT_1; STMT_2; EXPR }` TailExpr { /// If true, then the surrounding context of the block ignores /// the result of evaluating the block's tail expression. /// /// Example: `let _ = { STMT_1; EXPR };` tail_result_is_ignored: bool }, /// Generic mark meaning that the block occurred as a subexpression /// where the result might be used. /// /// Examples: `foo(EXPR)`, `match EXPR { ... }` SubExpr, } impl BlockFrame { fn is_tail_expr(&self) -> bool { match *self { BlockFrame::TailExpr { .. } => true, BlockFrame::Statement { .. } | BlockFrame::SubExpr => false, } } fn is_statement(&self) -> bool { match *self { BlockFrame::Statement { .. } => true, BlockFrame::TailExpr { .. } | BlockFrame::SubExpr => false, } } } #[derive(Debug)] struct BlockContext(Vec); struct Builder<'a, 'tcx> { hir: Cx<'a, 'tcx>, cfg: CFG<'tcx>, fn_span: Span, arg_count: usize, generator_kind: Option, /// The current set of scopes, updated as we traverse; /// see the `scope` module for more details. scopes: scope::Scopes<'tcx>, /// The block-context: each time we build the code within an hair::Block, /// we push a frame here tracking whether we are building a statement or /// if we are pushing the tail expression of the block. This is used to /// embed information in generated temps about whether they were created /// for a block tail expression or not. /// /// It would be great if we could fold this into `self.scopes` /// somehow, but right now I think that is very tightly tied to /// the code generation in ways that we cannot (or should not) /// start just throwing new entries onto that vector in order to /// distinguish the context of EXPR1 from the context of EXPR2 in /// `{ STMTS; EXPR1 } + EXPR2`. block_context: BlockContext, /// The current unsafe block in scope, even if it is hidden by /// a `PushUnsafeBlock`. unpushed_unsafe: Safety, /// The number of `push_unsafe_block` levels in scope. push_unsafe_count: usize, /// The vector of all scopes that we have created thus far; /// we track this for debuginfo later. source_scopes: IndexVec, source_scope_local_data: IndexVec, source_scope: SourceScope, /// The guard-context: each time we build the guard expression for /// a match arm, we push onto this stack, and then pop when we /// finish building it. guard_context: Vec, /// Maps `HirId`s of variable bindings to the `Local`s created for them. /// (A match binding can have two locals; the 2nd is for the arm's guard.) var_indices: HirIdMap, local_decls: IndexVec>, canonical_user_type_annotations: ty::CanonicalUserTypeAnnotations<'tcx>, upvar_mutbls: Vec, unit_temp: Option>, var_debug_info: Vec>, /// Cached block with the `RESUME` terminator; this is created /// when first set of cleanups are built. cached_resume_block: Option, /// Cached block with the `RETURN` terminator. cached_return_block: Option, /// Cached block with the `UNREACHABLE` terminator. cached_unreachable_block: Option, } impl<'a, 'tcx> Builder<'a, 'tcx> { fn is_bound_var_in_guard(&self, id: hir::HirId) -> bool { self.guard_context.iter().any(|frame| frame.locals.iter().any(|local| local.id == id)) } fn var_local_id(&self, id: hir::HirId, for_guard: ForGuard) -> Local { self.var_indices[&id].local_id(for_guard) } } impl BlockContext { fn new() -> Self { BlockContext(vec![]) } fn push(&mut self, bf: BlockFrame) { self.0.push(bf); } fn pop(&mut self) -> Option { self.0.pop() } /// Traverses the frames on the `BlockContext`, searching for either /// the first block-tail expression frame with no intervening /// statement frame. /// /// Notably, this skips over `SubExpr` frames; this method is /// meant to be used in the context of understanding the /// relationship of a temp (created within some complicated /// expression) with its containing expression, and whether the /// value of that *containing expression* (not the temp!) is /// ignored. fn currently_in_block_tail(&self) -> Option { for bf in self.0.iter().rev() { match bf { BlockFrame::SubExpr => continue, BlockFrame::Statement { .. } => break, &BlockFrame::TailExpr { tail_result_is_ignored } => return Some(BlockTailInfo { tail_result_is_ignored }) } } return None; } /// Looks at the topmost frame on the BlockContext and reports /// whether its one that would discard a block tail result. /// /// Unlike `currently_within_ignored_tail_expression`, this does /// *not* skip over `SubExpr` frames: here, we want to know /// whether the block result itself is discarded. fn currently_ignores_tail_results(&self) -> bool { match self.0.last() { // no context: conservatively assume result is read None => false, // sub-expression: block result feeds into some computation Some(BlockFrame::SubExpr) => false, // otherwise: use accumulated is_ignored state. Some(BlockFrame::TailExpr { tail_result_is_ignored: ignored }) | Some(BlockFrame::Statement { ignores_expr_result: ignored }) => *ignored, } } } #[derive(Debug)] enum LocalsForNode { /// In the usual case, a `HirId` for an identifier maps to at most /// one `Local` declaration. One(Local), /// The exceptional case is identifiers in a match arm's pattern /// that are referenced in a guard of that match arm. For these, /// we have `2` Locals. /// /// * `for_arm_body` is the Local used in the arm body (which is /// just like the `One` case above), /// /// * `ref_for_guard` is the Local used in the arm's guard (which /// is a reference to a temp that is an alias of /// `for_arm_body`). ForGuard { ref_for_guard: Local, for_arm_body: Local }, } #[derive(Debug)] struct GuardFrameLocal { id: hir::HirId, } impl GuardFrameLocal { fn new(id: hir::HirId, _binding_mode: BindingMode) -> Self { GuardFrameLocal { id: id, } } } #[derive(Debug)] struct GuardFrame { /// These are the id's of names that are bound by patterns of the /// arm of *this* guard. /// /// (Frames higher up the stack will have the id's bound in arms /// further out, such as in a case like: /// /// match E1 { /// P1(id1) if (... (match E2 { P2(id2) if ... => B2 })) => B1, /// } /// /// here, when building for FIXME. locals: Vec, } /// `ForGuard` indicates whether we are talking about: /// 1. The variable for use outside of guard expressions, or /// 2. The temp that holds reference to (1.), which is actually what the /// guard expressions see. #[derive(Copy, Clone, Debug, PartialEq, Eq)] enum ForGuard { RefWithinGuard, OutsideGuard, } impl LocalsForNode { fn local_id(&self, for_guard: ForGuard) -> Local { match (self, for_guard) { (&LocalsForNode::One(local_id), ForGuard::OutsideGuard) | (&LocalsForNode::ForGuard { ref_for_guard: local_id, .. }, ForGuard::RefWithinGuard) | (&LocalsForNode::ForGuard { for_arm_body: local_id, .. }, ForGuard::OutsideGuard) => local_id, (&LocalsForNode::One(_), ForGuard::RefWithinGuard) => bug!("anything with one local should never be within a guard."), } } } struct CFG<'tcx> { basic_blocks: IndexVec>, } rustc_index::newtype_index! { pub struct ScopeId { .. } } /////////////////////////////////////////////////////////////////////////// /// The `BlockAnd` "monad" packages up the new basic block along with a /// produced value (sometimes just unit, of course). The `unpack!` /// macro (and methods below) makes working with `BlockAnd` much more /// convenient. #[must_use = "if you don't use one of these results, you're leaving a dangling edge"] struct BlockAnd(BasicBlock, T); trait BlockAndExtension { fn and(self, v: T) -> BlockAnd; fn unit(self) -> BlockAnd<()>; } impl BlockAndExtension for BasicBlock { fn and(self, v: T) -> BlockAnd { BlockAnd(self, v) } fn unit(self) -> BlockAnd<()> { BlockAnd(self, ()) } } /// Update a block pointer and return the value. /// Use it like `let x = unpack!(block = self.foo(block, foo))`. macro_rules! unpack { ($x:ident = $c:expr) => { { let BlockAnd(b, v) = $c; $x = b; v } }; ($c:expr) => { { let BlockAnd(b, ()) = $c; b } }; } fn should_abort_on_panic(tcx: TyCtxt<'_>, fn_def_id: DefId, _abi: Abi) -> bool { // Validate `#[unwind]` syntax regardless of platform-specific panic strategy. let attrs = &tcx.get_attrs(fn_def_id); let unwind_attr = attr::find_unwind_attr(Some(tcx.sess.diagnostic()), attrs); // We never unwind, so it's not relevant to stop an unwind. if tcx.sess.panic_strategy() != PanicStrategy::Unwind { return false; } // We cannot add landing pads, so don't add one. if tcx.sess.no_landing_pads() { return false; } // This is a special case: some functions have a C abi but are meant to // unwind anyway. Don't stop them. match unwind_attr { None => false, // FIXME(#58794); should be `!(abi == Abi::Rust || abi == Abi::RustCall)` Some(UnwindAttr::Allowed) => false, Some(UnwindAttr::Aborts) => true, } } /////////////////////////////////////////////////////////////////////////// /// the main entry point for building MIR for a function struct ArgInfo<'tcx>(Ty<'tcx>, Option, Option<&'tcx hir::Param>, Option); fn construct_fn<'a, 'tcx, A>( hir: Cx<'a, 'tcx>, fn_id: hir::HirId, arguments: A, safety: Safety, abi: Abi, return_ty: Ty<'tcx>, return_ty_span: Span, body: &'tcx hir::Body, ) -> Body<'tcx> where A: Iterator> { let arguments: Vec<_> = arguments.collect(); let tcx = hir.tcx(); let tcx_hir = tcx.hir(); let span = tcx_hir.span(fn_id); let fn_def_id = tcx_hir.local_def_id(fn_id); let mut builder = Builder::new(hir, span, arguments.len(), safety, return_ty, return_ty_span, body.generator_kind); let call_site_scope = region::Scope { id: body.value.hir_id.local_id, data: region::ScopeData::CallSite }; let arg_scope = region::Scope { id: body.value.hir_id.local_id, data: region::ScopeData::Arguments }; let mut block = START_BLOCK; let source_info = builder.source_info(span); let call_site_s = (call_site_scope, source_info); unpack!(block = builder.in_scope(call_site_s, LintLevel::Inherited, |builder| { if should_abort_on_panic(tcx, fn_def_id, abi) { builder.schedule_abort(); } let arg_scope_s = (arg_scope, source_info); // `return_block` is called when we evaluate a `return` expression, so // we just use `START_BLOCK` here. unpack!(block = builder.in_breakable_scope( None, START_BLOCK, Place::return_place(), |builder| { builder.in_scope(arg_scope_s, LintLevel::Inherited, |builder| { builder.args_and_body(block, fn_def_id, &arguments, arg_scope, &body.value) }) }, )); // Attribute epilogue to function's closing brace let fn_end = span.shrink_to_hi(); let source_info = builder.source_info(fn_end); let return_block = builder.return_block(); builder.cfg.terminate(block, source_info, TerminatorKind::Goto { target: return_block }); builder.cfg.terminate(return_block, source_info, TerminatorKind::Return); // Attribute any unreachable codepaths to the function's closing brace if let Some(unreachable_block) = builder.cached_unreachable_block { builder.cfg.terminate(unreachable_block, source_info, TerminatorKind::Unreachable); } return_block.unit() })); assert_eq!(block, builder.return_block()); let mut spread_arg = None; if abi == Abi::RustCall { // RustCall pseudo-ABI untuples the last argument. spread_arg = Some(Local::new(arguments.len())); } info!("fn_id {:?} has attrs {:?}", fn_def_id, tcx.get_attrs(fn_def_id)); let mut body = builder.finish(); body.spread_arg = spread_arg; body } fn construct_const<'a, 'tcx>( hir: Cx<'a, 'tcx>, body_id: hir::BodyId, const_ty: Ty<'tcx>, const_ty_span: Span, ) -> Body<'tcx> { let tcx = hir.tcx(); let owner_id = tcx.hir().body_owner(body_id); let span = tcx.hir().span(owner_id); let mut builder = Builder::new( hir, span, 0, Safety::Safe, const_ty, const_ty_span, None, ); let mut block = START_BLOCK; let ast_expr = &tcx.hir().body(body_id).value; let expr = builder.hir.mirror(ast_expr); unpack!(block = builder.into_expr(&Place::return_place(), block, expr)); let source_info = builder.source_info(span); builder.cfg.terminate(block, source_info, TerminatorKind::Return); // Constants can't `return` so a return block should not be created. assert_eq!(builder.cached_return_block, None); // Constants may be match expressions in which case an unreachable block may // be created, so terminate it properly. if let Some(unreachable_block) = builder.cached_unreachable_block { builder.cfg.terminate(unreachable_block, source_info, TerminatorKind::Unreachable); } builder.finish() } fn construct_error<'a, 'tcx>( hir: Cx<'a, 'tcx>, body_id: hir::BodyId ) -> Body<'tcx> { let owner_id = hir.tcx().hir().body_owner(body_id); let span = hir.tcx().hir().span(owner_id); let ty = hir.tcx().types.err; let mut builder = Builder::new(hir, span, 0, Safety::Safe, ty, span, None); let source_info = builder.source_info(span); builder.cfg.terminate(START_BLOCK, source_info, TerminatorKind::Unreachable); builder.finish() } impl<'a, 'tcx> Builder<'a, 'tcx> { fn new(hir: Cx<'a, 'tcx>, span: Span, arg_count: usize, safety: Safety, return_ty: Ty<'tcx>, return_span: Span, generator_kind: Option) -> Builder<'a, 'tcx> { let lint_level = LintLevel::Explicit(hir.root_lint_level); let mut builder = Builder { hir, cfg: CFG { basic_blocks: IndexVec::new() }, fn_span: span, arg_count, generator_kind, scopes: Default::default(), block_context: BlockContext::new(), source_scopes: IndexVec::new(), source_scope: OUTERMOST_SOURCE_SCOPE, source_scope_local_data: IndexVec::new(), guard_context: vec![], push_unsafe_count: 0, unpushed_unsafe: safety, local_decls: IndexVec::from_elem_n( LocalDecl::new_return_place(return_ty, return_span), 1, ), canonical_user_type_annotations: IndexVec::new(), upvar_mutbls: vec![], var_indices: Default::default(), unit_temp: None, var_debug_info: vec![], cached_resume_block: None, cached_return_block: None, cached_unreachable_block: None, }; assert_eq!(builder.cfg.start_new_block(), START_BLOCK); assert_eq!( builder.new_source_scope(span, lint_level, Some(safety)), OUTERMOST_SOURCE_SCOPE); builder.source_scopes[OUTERMOST_SOURCE_SCOPE].parent_scope = None; builder } fn finish(self) -> Body<'tcx> { for (index, block) in self.cfg.basic_blocks.iter().enumerate() { if block.terminator.is_none() { span_bug!(self.fn_span, "no terminator on block {:?}", index); } } Body::new( self.cfg.basic_blocks, self.source_scopes, ClearCrossCrate::Set(self.source_scope_local_data), self.local_decls, self.canonical_user_type_annotations, self.arg_count, self.var_debug_info, self.fn_span, self.hir.control_flow_destroyed(), self.generator_kind ) } fn args_and_body(&mut self, mut block: BasicBlock, fn_def_id: DefId, arguments: &[ArgInfo<'tcx>], argument_scope: region::Scope, ast_body: &'tcx hir::Expr) -> BlockAnd<()> { // Allocate locals for the function arguments for &ArgInfo(ty, _, arg_opt, _) in arguments.iter() { let source_info = SourceInfo { scope: OUTERMOST_SOURCE_SCOPE, span: arg_opt.map_or(self.fn_span, |arg| arg.pat.span) }; let arg_local = self.local_decls.push(LocalDecl { mutability: Mutability::Mut, ty, user_ty: UserTypeProjections::none(), source_info, internal: false, local_info: LocalInfo::Other, is_block_tail: None, }); // If this is a simple binding pattern, give debuginfo a nice name. if let Some(arg) = arg_opt { if let Some(ident) = arg.pat.simple_ident() { self.var_debug_info.push(VarDebugInfo { name: ident.name, source_info, place: arg_local.into(), }); } } } let tcx = self.hir.tcx(); let tcx_hir = tcx.hir(); let hir_tables = self.hir.tables(); // In analyze_closure() in upvar.rs we gathered a list of upvars used by a // closure and we stored in a map called upvar_list in TypeckTables indexed // with the closure's DefId. Here, we run through that vec of UpvarIds for // the given closure and use the necessary information to create upvar // debuginfo and to fill `self.upvar_mutbls`. if let Some(upvars) = hir_tables.upvar_list.get(&fn_def_id) { let closure_env_arg = Local::new(1); let mut closure_env_projs = vec![]; let mut closure_ty = self.local_decls[closure_env_arg].ty; if let ty::Ref(_, ty, _) = closure_ty.kind { closure_env_projs.push(ProjectionElem::Deref); closure_ty = ty; } let (def_id, upvar_substs) = match closure_ty.kind { ty::Closure(def_id, substs) => (def_id, ty::UpvarSubsts::Closure(substs)), ty::Generator(def_id, substs, _) => (def_id, ty::UpvarSubsts::Generator(substs)), _ => span_bug!(self.fn_span, "upvars with non-closure env ty {:?}", closure_ty) }; let upvar_tys = upvar_substs.upvar_tys(def_id, tcx); let upvars_with_tys = upvars.iter().zip(upvar_tys); self.upvar_mutbls = upvars_with_tys.enumerate().map(|(i, ((&var_id, &upvar_id), ty))| { let capture = hir_tables.upvar_capture(upvar_id); let mut mutability = Mutability::Not; let mut name = kw::Invalid; if let Some(Node::Binding(pat)) = tcx_hir.find(var_id) { if let hir::PatKind::Binding(_, _, ident, _) = pat.kind { name = ident.name; if let Some(&bm) = hir_tables.pat_binding_modes().get(pat.hir_id) { if bm == ty::BindByValue(hir::Mutability::Mutable) { mutability = Mutability::Mut; } else { mutability = Mutability::Not; } } else { tcx.sess.delay_span_bug(pat.span, "missing binding mode"); } } } let mut projs = closure_env_projs.clone(); projs.push(ProjectionElem::Field(Field::new(i), ty)); match capture { ty::UpvarCapture::ByValue => {} ty::UpvarCapture::ByRef(..) => { projs.push(ProjectionElem::Deref); } }; self.var_debug_info.push(VarDebugInfo { name, source_info: SourceInfo { scope: OUTERMOST_SOURCE_SCOPE, span: tcx_hir.span(var_id), }, place: Place { base: closure_env_arg.into(), projection: tcx.intern_place_elems(&projs), }, }); mutability }).collect(); } let mut scope = None; // Bind the argument patterns for (index, arg_info) in arguments.iter().enumerate() { // Function arguments always get the first Local indices after the return place let local = Local::new(index + 1); let place = Place::from(local); let &ArgInfo(_, opt_ty_info, arg_opt, ref self_binding) = arg_info; // Make sure we drop (parts of) the argument even when not matched on. self.schedule_drop( arg_opt.as_ref().map_or(ast_body.span, |arg| arg.pat.span), argument_scope, local, DropKind::Value, ); if let Some(arg) = arg_opt { let pattern = self.hir.pattern_from_hir(&arg.pat); let original_source_scope = self.source_scope; let span = pattern.span; self.set_correct_source_scope_for_arg(arg.hir_id, original_source_scope, span); match *pattern.kind { // Don't introduce extra copies for simple bindings PatKind::Binding { mutability, var, mode: BindingMode::ByValue, subpattern: None, .. } => { self.local_decls[local].mutability = mutability; self.local_decls[local].source_info.scope = self.source_scope; self.local_decls[local].local_info = if let Some(kind) = self_binding { LocalInfo::User(ClearCrossCrate::Set( BindingForm::ImplicitSelf(*kind), )) } else { let binding_mode = ty::BindingMode::BindByValue(mutability.into()); LocalInfo::User(ClearCrossCrate::Set(BindingForm::Var( VarBindingForm { binding_mode, opt_ty_info, opt_match_place: Some((Some(place.clone()), span)), pat_span: span, }, ))) }; self.var_indices.insert(var, LocalsForNode::One(local)); } _ => { scope = self.declare_bindings( scope, ast_body.span, &pattern, matches::ArmHasGuard(false), Some((Some(&place), span)), ); unpack!(block = self.place_into_pattern(block, pattern, &place, false)); } } self.source_scope = original_source_scope; } } // Enter the argument pattern bindings source scope, if it exists. if let Some(source_scope) = scope { self.source_scope = source_scope; } let body = self.hir.mirror(ast_body); self.into(&Place::return_place(), block, body) } fn set_correct_source_scope_for_arg( &mut self, arg_hir_id: hir::HirId, original_source_scope: SourceScope, pattern_span: Span ) { let tcx = self.hir.tcx(); let current_root = tcx.maybe_lint_level_root_bounded( arg_hir_id, self.hir.root_lint_level ); let parent_root = tcx.maybe_lint_level_root_bounded( self.source_scope_local_data[original_source_scope].lint_root, self.hir.root_lint_level, ); if current_root != parent_root { self.source_scope = self.new_source_scope( pattern_span, LintLevel::Explicit(current_root), None ); } } fn get_unit_temp(&mut self) -> Place<'tcx> { match self.unit_temp { Some(ref tmp) => tmp.clone(), None => { let ty = self.hir.unit_ty(); let fn_span = self.fn_span; let tmp = self.temp(ty, fn_span); self.unit_temp = Some(tmp.clone()); tmp } } } fn return_block(&mut self) -> BasicBlock { match self.cached_return_block { Some(rb) => rb, None => { let rb = self.cfg.start_new_block(); self.cached_return_block = Some(rb); rb } } } } /////////////////////////////////////////////////////////////////////////// // Builder methods are broken up into modules, depending on what kind // of thing is being lowered. Note that they use the `unpack` macro // above extensively. mod block; mod cfg; mod expr; mod into; mod matches; mod misc; mod scope;