| use rustc::ty::{self, Ty, TypeFoldable, Instance}; |
| use rustc::ty::layout::{TyLayout, HasTyCtxt, FnAbiExt}; |
| use rustc::mir; |
| use rustc_target::abi::call::{FnAbi, PassMode}; |
| use crate::base; |
| use crate::traits::*; |
| |
| use std::iter; |
| |
| use rustc_index::bit_set::BitSet; |
| use rustc_index::vec::IndexVec; |
| |
| use self::analyze::CleanupKind; |
| use self::debuginfo::FunctionDebugContext; |
| use self::place::PlaceRef; |
| use rustc::mir::traversal; |
| |
| use self::operand::{OperandRef, OperandValue}; |
| |
| /// Master context for codegenning from MIR. |
| pub struct FunctionCx<'a, 'tcx, Bx: BuilderMethods<'a, 'tcx>> { |
| instance: Instance<'tcx>, |
| |
| mir: mir::ReadOnlyBodyAndCache<'tcx, 'tcx>, |
| |
| debug_context: Option<FunctionDebugContext<Bx::DIScope>>, |
| |
| llfn: Bx::Function, |
| |
| cx: &'a Bx::CodegenCx, |
| |
| fn_abi: FnAbi<'tcx, Ty<'tcx>>, |
| |
| /// When unwinding is initiated, we have to store this personality |
| /// value somewhere so that we can load it and re-use it in the |
| /// resume instruction. The personality is (afaik) some kind of |
| /// value used for C++ unwinding, which must filter by type: we |
| /// don't really care about it very much. Anyway, this value |
| /// contains an alloca into which the personality is stored and |
| /// then later loaded when generating the DIVERGE_BLOCK. |
| personality_slot: Option<PlaceRef<'tcx, Bx::Value>>, |
| |
| /// A `Block` for each MIR `BasicBlock` |
| blocks: IndexVec<mir::BasicBlock, Bx::BasicBlock>, |
| |
| /// The funclet status of each basic block |
| cleanup_kinds: IndexVec<mir::BasicBlock, analyze::CleanupKind>, |
| |
| /// When targeting MSVC, this stores the cleanup info for each funclet |
| /// BB. This is initialized as we compute the funclets' head block in RPO. |
| funclets: IndexVec<mir::BasicBlock, Option<Bx::Funclet>>, |
| |
| /// This stores the landing-pad block for a given BB, computed lazily on GNU |
| /// and eagerly on MSVC. |
| landing_pads: IndexVec<mir::BasicBlock, Option<Bx::BasicBlock>>, |
| |
| /// Cached unreachable block |
| unreachable_block: Option<Bx::BasicBlock>, |
| |
| /// The location where each MIR arg/var/tmp/ret is stored. This is |
| /// usually an `PlaceRef` representing an alloca, but not always: |
| /// sometimes we can skip the alloca and just store the value |
| /// directly using an `OperandRef`, which makes for tighter LLVM |
| /// IR. The conditions for using an `OperandRef` are as follows: |
| /// |
| /// - the type of the local must be judged "immediate" by `is_llvm_immediate` |
| /// - the operand must never be referenced indirectly |
| /// - we should not take its address using the `&` operator |
| /// - nor should it appear in a place path like `tmp.a` |
| /// - the operand must be defined by an rvalue that can generate immediate |
| /// values |
| /// |
| /// Avoiding allocs can also be important for certain intrinsics, |
| /// notably `expect`. |
| locals: IndexVec<mir::Local, LocalRef<'tcx, Bx::Value>>, |
| |
| /// All `VarDebuginfo` from the MIR body, partitioned by `Local`. |
| /// This is `None` if no variable debuginfo/names are needed. |
| per_local_var_debug_info: Option<IndexVec<mir::Local, Vec<&'tcx mir::VarDebugInfo<'tcx>>>>, |
| |
| /// Caller location propagated if this function has `#[track_caller]`. |
| caller_location: Option<OperandRef<'tcx, Bx::Value>>, |
| } |
| |
| impl<'a, 'tcx, Bx: BuilderMethods<'a, 'tcx>> FunctionCx<'a, 'tcx, Bx> { |
| pub fn monomorphize<T>(&self, value: &T) -> T |
| where T: TypeFoldable<'tcx> |
| { |
| self.cx.tcx().subst_and_normalize_erasing_regions( |
| self.instance.substs, |
| ty::ParamEnv::reveal_all(), |
| value, |
| ) |
| } |
| } |
| |
| enum LocalRef<'tcx, V> { |
| Place(PlaceRef<'tcx, V>), |
| /// `UnsizedPlace(p)`: `p` itself is a thin pointer (indirect place). |
| /// `*p` is the fat pointer that references the actual unsized place. |
| /// Every time it is initialized, we have to reallocate the place |
| /// and update the fat pointer. That's the reason why it is indirect. |
| UnsizedPlace(PlaceRef<'tcx, V>), |
| Operand(Option<OperandRef<'tcx, V>>), |
| } |
| |
| impl<'a, 'tcx, V: CodegenObject> LocalRef<'tcx, V> { |
| fn new_operand<Bx: BuilderMethods<'a, 'tcx, Value = V>>( |
| bx: &mut Bx, |
| layout: TyLayout<'tcx>, |
| ) -> LocalRef<'tcx, V> { |
| if layout.is_zst() { |
| // Zero-size temporaries aren't always initialized, which |
| // doesn't matter because they don't contain data, but |
| // we need something in the operand. |
| LocalRef::Operand(Some(OperandRef::new_zst(bx, layout))) |
| } else { |
| LocalRef::Operand(None) |
| } |
| } |
| } |
| |
| /////////////////////////////////////////////////////////////////////////// |
| |
| pub fn codegen_mir<'a, 'tcx, Bx: BuilderMethods<'a, 'tcx>>( |
| cx: &'a Bx::CodegenCx, |
| instance: Instance<'tcx>, |
| ) { |
| assert!(!instance.substs.needs_infer()); |
| |
| let llfn = cx.get_fn(instance); |
| |
| let mir = cx.tcx().instance_mir(instance.def); |
| |
| let fn_abi = FnAbi::of_instance(cx, instance, &[]); |
| debug!("fn_abi: {:?}", fn_abi); |
| |
| let debug_context = cx.create_function_debug_context(instance, &fn_abi, llfn, &mir); |
| |
| let mut bx = Bx::new_block(cx, llfn, "start"); |
| |
| if mir.basic_blocks().iter().any(|bb| bb.is_cleanup) { |
| bx.set_personality_fn(cx.eh_personality()); |
| } |
| |
| bx.sideeffect(); |
| |
| let cleanup_kinds = analyze::cleanup_kinds(&mir); |
| // Allocate a `Block` for every basic block, except |
| // the start block, if nothing loops back to it. |
| let reentrant_start_block = !mir.predecessors_for(mir::START_BLOCK).is_empty(); |
| let block_bxs: IndexVec<mir::BasicBlock, Bx::BasicBlock> = |
| mir.basic_blocks().indices().map(|bb| { |
| if bb == mir::START_BLOCK && !reentrant_start_block { |
| bx.llbb() |
| } else { |
| bx.build_sibling_block(&format!("{:?}", bb)).llbb() |
| } |
| }).collect(); |
| |
| let (landing_pads, funclets) = create_funclets(&mir, &mut bx, &cleanup_kinds, &block_bxs); |
| let mir_body: &mir::Body<'_> = *mir; |
| let mut fx = FunctionCx { |
| instance, |
| mir, |
| llfn, |
| fn_abi, |
| cx, |
| personality_slot: None, |
| blocks: block_bxs, |
| unreachable_block: None, |
| cleanup_kinds, |
| landing_pads, |
| funclets, |
| locals: IndexVec::new(), |
| debug_context, |
| per_local_var_debug_info: debuginfo::per_local_var_debug_info(cx.tcx(), mir_body), |
| caller_location: None, |
| }; |
| |
| let memory_locals = analyze::non_ssa_locals(&fx); |
| |
| // Allocate variable and temp allocas |
| fx.locals = { |
| let args = arg_local_refs(&mut bx, &mut fx, &memory_locals); |
| |
| let mut allocate_local = |local| { |
| let decl = &mir_body.local_decls[local]; |
| let layout = bx.layout_of(fx.monomorphize(&decl.ty)); |
| assert!(!layout.ty.has_erasable_regions()); |
| |
| if local == mir::RETURN_PLACE && fx.fn_abi.ret.is_indirect() { |
| debug!("alloc: {:?} (return place) -> place", local); |
| let llretptr = bx.get_param(0); |
| return LocalRef::Place(PlaceRef::new_sized(llretptr, layout)); |
| } |
| |
| if memory_locals.contains(local) { |
| debug!("alloc: {:?} -> place", local); |
| if layout.is_unsized() { |
| LocalRef::UnsizedPlace(PlaceRef::alloca_unsized_indirect(&mut bx, layout)) |
| } else { |
| LocalRef::Place(PlaceRef::alloca(&mut bx, layout)) |
| } |
| } else { |
| debug!("alloc: {:?} -> operand", local); |
| LocalRef::new_operand(&mut bx, layout) |
| } |
| }; |
| |
| let retptr = allocate_local(mir::RETURN_PLACE); |
| iter::once(retptr) |
| .chain(args.into_iter()) |
| .chain(mir_body.vars_and_temps_iter().map(allocate_local)) |
| .collect() |
| }; |
| |
| // Apply debuginfo to the newly allocated locals. |
| fx.debug_introduce_locals(&mut bx); |
| |
| // Branch to the START block, if it's not the entry block. |
| if reentrant_start_block { |
| bx.br(fx.blocks[mir::START_BLOCK]); |
| } |
| |
| // Up until here, IR instructions for this function have explicitly not been annotated with |
| // source code location, so we don't step into call setup code. From here on, source location |
| // emitting should be enabled. |
| if let Some(debug_context) = &mut fx.debug_context { |
| debug_context.source_locations_enabled = true; |
| } |
| |
| let rpo = traversal::reverse_postorder(&mir_body); |
| let mut visited = BitSet::new_empty(mir_body.basic_blocks().len()); |
| |
| // Codegen the body of each block using reverse postorder |
| for (bb, _) in rpo { |
| visited.insert(bb.index()); |
| fx.codegen_block(bb); |
| } |
| |
| // Remove blocks that haven't been visited, or have no |
| // predecessors. |
| for bb in mir_body.basic_blocks().indices() { |
| // Unreachable block |
| if !visited.contains(bb.index()) { |
| debug!("codegen_mir: block {:?} was not visited", bb); |
| unsafe { |
| bx.delete_basic_block(fx.blocks[bb]); |
| } |
| } |
| } |
| } |
| |
| fn create_funclets<'a, 'tcx, Bx: BuilderMethods<'a, 'tcx>>( |
| mir: &'tcx mir::Body<'tcx>, |
| bx: &mut Bx, |
| cleanup_kinds: &IndexVec<mir::BasicBlock, CleanupKind>, |
| block_bxs: &IndexVec<mir::BasicBlock, Bx::BasicBlock>, |
| ) -> ( |
| IndexVec<mir::BasicBlock, Option<Bx::BasicBlock>>, |
| IndexVec<mir::BasicBlock, Option<Bx::Funclet>>, |
| ) { |
| block_bxs.iter_enumerated().zip(cleanup_kinds).map(|((bb, &llbb), cleanup_kind)| { |
| match *cleanup_kind { |
| CleanupKind::Funclet if base::wants_msvc_seh(bx.sess()) => {} |
| _ => return (None, None) |
| } |
| |
| let funclet; |
| let ret_llbb; |
| match mir[bb].terminator.as_ref().map(|t| &t.kind) { |
| // This is a basic block that we're aborting the program for, |
| // notably in an `extern` function. These basic blocks are inserted |
| // so that we assert that `extern` functions do indeed not panic, |
| // and if they do we abort the process. |
| // |
| // On MSVC these are tricky though (where we're doing funclets). If |
| // we were to do a cleanuppad (like below) the normal functions like |
| // `longjmp` would trigger the abort logic, terminating the |
| // program. Instead we insert the equivalent of `catch(...)` for C++ |
| // which magically doesn't trigger when `longjmp` files over this |
| // frame. |
| // |
| // Lots more discussion can be found on #48251 but this codegen is |
| // modeled after clang's for: |
| // |
| // try { |
| // foo(); |
| // } catch (...) { |
| // bar(); |
| // } |
| Some(&mir::TerminatorKind::Abort) => { |
| let mut cs_bx = bx.build_sibling_block(&format!("cs_funclet{:?}", bb)); |
| let mut cp_bx = bx.build_sibling_block(&format!("cp_funclet{:?}", bb)); |
| ret_llbb = cs_bx.llbb(); |
| |
| let cs = cs_bx.catch_switch(None, None, 1); |
| cs_bx.add_handler(cs, cp_bx.llbb()); |
| |
| // The "null" here is actually a RTTI type descriptor for the |
| // C++ personality function, but `catch (...)` has no type so |
| // it's null. The 64 here is actually a bitfield which |
| // represents that this is a catch-all block. |
| let null = bx.const_null(bx.type_i8p()); |
| let sixty_four = bx.const_i32(64); |
| funclet = cp_bx.catch_pad(cs, &[null, sixty_four, null]); |
| cp_bx.br(llbb); |
| } |
| _ => { |
| let mut cleanup_bx = bx.build_sibling_block(&format!("funclet_{:?}", bb)); |
| ret_llbb = cleanup_bx.llbb(); |
| funclet = cleanup_bx.cleanup_pad(None, &[]); |
| cleanup_bx.br(llbb); |
| } |
| }; |
| |
| (Some(ret_llbb), Some(funclet)) |
| }).unzip() |
| } |
| |
| /// Produces, for each argument, a `Value` pointing at the |
| /// argument's value. As arguments are places, these are always |
| /// indirect. |
| fn arg_local_refs<'a, 'tcx, Bx: BuilderMethods<'a, 'tcx>>( |
| bx: &mut Bx, |
| fx: &mut FunctionCx<'a, 'tcx, Bx>, |
| memory_locals: &BitSet<mir::Local>, |
| ) -> Vec<LocalRef<'tcx, Bx::Value>> { |
| let mir = fx.mir; |
| let mut idx = 0; |
| let mut llarg_idx = fx.fn_abi.ret.is_indirect() as usize; |
| |
| let args = mir.args_iter().enumerate().map(|(arg_index, local)| { |
| let arg_decl = &mir.local_decls[local]; |
| |
| if Some(local) == mir.spread_arg { |
| // This argument (e.g., the last argument in the "rust-call" ABI) |
| // is a tuple that was spread at the ABI level and now we have |
| // to reconstruct it into a tuple local variable, from multiple |
| // individual LLVM function arguments. |
| |
| let arg_ty = fx.monomorphize(&arg_decl.ty); |
| let tupled_arg_tys = match arg_ty.kind { |
| ty::Tuple(ref tys) => tys, |
| _ => bug!("spread argument isn't a tuple?!") |
| }; |
| |
| let place = PlaceRef::alloca(bx, bx.layout_of(arg_ty)); |
| for i in 0..tupled_arg_tys.len() { |
| let arg = &fx.fn_abi.args[idx]; |
| idx += 1; |
| if arg.pad.is_some() { |
| llarg_idx += 1; |
| } |
| let pr_field = place.project_field(bx, i); |
| bx.store_fn_arg(arg, &mut llarg_idx, pr_field); |
| } |
| |
| return LocalRef::Place(place); |
| } |
| |
| if fx.fn_abi.c_variadic && arg_index == fx.fn_abi.args.len() { |
| let arg_ty = fx.monomorphize(&arg_decl.ty); |
| |
| let va_list = PlaceRef::alloca(bx, bx.layout_of(arg_ty)); |
| bx.va_start(va_list.llval); |
| |
| return LocalRef::Place(va_list); |
| } |
| |
| let arg = &fx.fn_abi.args[idx]; |
| idx += 1; |
| if arg.pad.is_some() { |
| llarg_idx += 1; |
| } |
| |
| if !memory_locals.contains(local) { |
| // We don't have to cast or keep the argument in the alloca. |
| // FIXME(eddyb): We should figure out how to use llvm.dbg.value instead |
| // of putting everything in allocas just so we can use llvm.dbg.declare. |
| let local = |op| LocalRef::Operand(Some(op)); |
| match arg.mode { |
| PassMode::Ignore => { |
| return local(OperandRef::new_zst(bx, arg.layout)); |
| } |
| PassMode::Direct(_) => { |
| let llarg = bx.get_param(llarg_idx); |
| llarg_idx += 1; |
| return local( |
| OperandRef::from_immediate_or_packed_pair(bx, llarg, arg.layout)); |
| } |
| PassMode::Pair(..) => { |
| let (a, b) = (bx.get_param(llarg_idx), bx.get_param(llarg_idx + 1)); |
| llarg_idx += 2; |
| |
| return local(OperandRef { |
| val: OperandValue::Pair(a, b), |
| layout: arg.layout |
| }); |
| } |
| _ => {} |
| } |
| } |
| |
| if arg.is_sized_indirect() { |
| // Don't copy an indirect argument to an alloca, the caller |
| // already put it in a temporary alloca and gave it up. |
| // FIXME: lifetimes |
| let llarg = bx.get_param(llarg_idx); |
| llarg_idx += 1; |
| LocalRef::Place(PlaceRef::new_sized(llarg, arg.layout)) |
| } else if arg.is_unsized_indirect() { |
| // As the storage for the indirect argument lives during |
| // the whole function call, we just copy the fat pointer. |
| let llarg = bx.get_param(llarg_idx); |
| llarg_idx += 1; |
| let llextra = bx.get_param(llarg_idx); |
| llarg_idx += 1; |
| let indirect_operand = OperandValue::Pair(llarg, llextra); |
| |
| let tmp = PlaceRef::alloca_unsized_indirect(bx, arg.layout); |
| indirect_operand.store(bx, tmp); |
| LocalRef::UnsizedPlace(tmp) |
| } else { |
| let tmp = PlaceRef::alloca(bx, arg.layout); |
| bx.store_fn_arg(arg, &mut llarg_idx, tmp); |
| LocalRef::Place(tmp) |
| } |
| }).collect::<Vec<_>>(); |
| |
| if fx.instance.def.requires_caller_location(bx.tcx()) { |
| assert_eq!( |
| fx.fn_abi.args.len(), args.len() + 1, |
| "#[track_caller] fn's must have 1 more argument in their ABI than in their MIR", |
| ); |
| |
| let arg = fx.fn_abi.args.last().unwrap(); |
| match arg.mode { |
| PassMode::Direct(_) => (), |
| _ => bug!("caller location must be PassMode::Direct, found {:?}", arg.mode), |
| } |
| |
| fx.caller_location = Some(OperandRef { |
| val: OperandValue::Immediate(bx.get_param(llarg_idx)), |
| layout: arg.layout, |
| }); |
| } |
| |
| args |
| } |
| |
| mod analyze; |
| mod block; |
| pub mod constant; |
| pub mod debuginfo; |
| pub mod place; |
| pub mod operand; |
| mod rvalue; |
| mod statement; |