// Copyright 2012-2014 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. use libc::c_uint; use llvm::{self, ValueRef}; use rustc::mir::repr as mir; use rustc::mir::tcx::LvalueTy; use trans::base; use trans::build; use trans::common::{self, Block}; use trans::debuginfo::DebugLoc; use trans::expr; use trans::type_of; use self::lvalue::LvalueRef; use self::operand::OperandRef; // FIXME DebugLoc is always None right now /// Master context for translating MIR. pub struct MirContext<'bcx, 'tcx:'bcx> { mir: &'bcx mir::Mir<'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. llpersonalityslot: Option, /// A `Block` for each MIR `BasicBlock` blocks: Vec>, /// An LLVM alloca for each MIR `VarDecl` vars: Vec>, /// The location where each MIR `TempDecl` is stored. This is /// usually an `LvalueRef` 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 temporary must be judged "immediate" by `type_is_immediate` /// - the operand must never be referenced indirectly /// - we should not take its address using the `&` operator /// - nor should it appear in an lvalue 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`. temps: Vec>, /// The arguments to the function; as args are lvalues, these are /// always indirect, though we try to avoid creating an alloca /// when we can (and just reuse the pointer the caller provided). args: Vec>, } enum TempRef<'tcx> { Lvalue(LvalueRef<'tcx>), Operand(Option>), } /////////////////////////////////////////////////////////////////////////// pub fn trans_mir<'bcx, 'tcx>(bcx: Block<'bcx, 'tcx>) { let fcx = bcx.fcx; let mir = bcx.mir(); let mir_blocks = bcx.mir().all_basic_blocks(); // Analyze the temps to determine which must be lvalues // FIXME let lvalue_temps = analyze::lvalue_temps(bcx, mir); // Allocate variable and temp allocas let vars = mir.var_decls.iter() .map(|decl| (bcx.monomorphize(&decl.ty), decl.name)) .map(|(mty, name)| LvalueRef::alloca(bcx, mty, &name.as_str())) .collect(); let temps = mir.temp_decls.iter() .map(|decl| bcx.monomorphize(&decl.ty)) .enumerate() .map(|(i, mty)| if lvalue_temps.contains(&i) { TempRef::Lvalue(LvalueRef::alloca(bcx, mty, &format!("temp{:?}", i))) } else { // If this is an immediate temp, we do not create an // alloca in advance. Instead we wait until we see the // definition and update the operand there. TempRef::Operand(None) }) .collect(); let args = arg_value_refs(bcx, mir); // Allocate a `Block` for every basic block let block_bcxs: Vec> = mir_blocks.iter() .map(|&bb| fcx.new_block(false, &format!("{:?}", bb), None)) .collect(); // Branch to the START block let start_bcx = block_bcxs[mir::START_BLOCK.index()]; build::Br(bcx, start_bcx.llbb, DebugLoc::None); let mut mircx = MirContext { mir: mir, llpersonalityslot: None, blocks: block_bcxs, vars: vars, temps: temps, args: args, }; // Translate the body of each block for &bb in &mir_blocks { if bb != mir::DIVERGE_BLOCK { mircx.trans_block(bb); } } // Total hack: translate DIVERGE_BLOCK last. This is so that any // panics which the fn may do can initialize the // `llpersonalityslot` cell. We don't do this up front because the // LLVM type of it is (frankly) annoying to compute. mircx.trans_block(mir::DIVERGE_BLOCK); } /// Produce, for each argument, a `ValueRef` pointing at the /// argument's value. As arguments are lvalues, these are always /// indirect. fn arg_value_refs<'bcx, 'tcx>(bcx: Block<'bcx, 'tcx>, mir: &mir::Mir<'tcx>) -> Vec> { // FIXME tupled_args? I think I'd rather that mapping is done in MIR land though let fcx = bcx.fcx; let tcx = bcx.tcx(); let mut idx = fcx.arg_offset() as c_uint; mir.arg_decls .iter() .enumerate() .map(|(arg_index, arg_decl)| { let arg_ty = bcx.monomorphize(&arg_decl.ty); let llval = if type_of::arg_is_indirect(bcx.ccx(), arg_ty) { // Don't copy an indirect argument to an alloca, the caller // already put it in a temporary alloca and gave it up, unless // we emit extra-debug-info, which requires local allocas :(. // FIXME: lifetimes, debug info let llarg = llvm::get_param(fcx.llfn, idx); idx += 1; llarg } else if common::type_is_fat_ptr(tcx, arg_ty) { // we pass fat pointers as two words, but we want to // represent them internally as a pointer to two words, // so make an alloca to store them in. let lldata = llvm::get_param(fcx.llfn, idx); let llextra = llvm::get_param(fcx.llfn, idx + 1); idx += 2; let lltemp = base::alloc_ty(bcx, arg_ty, &format!("arg{}", arg_index)); build::Store(bcx, lldata, expr::get_dataptr(bcx, lltemp)); build::Store(bcx, llextra, expr::get_meta(bcx, lltemp)); lltemp } else { // otherwise, arg is passed by value, so make a // temporary and store it there let llarg = llvm::get_param(fcx.llfn, idx); idx += 1; let lltemp = base::alloc_ty(bcx, arg_ty, &format!("arg{}", arg_index)); base::store_ty(bcx, llarg, lltemp, arg_ty); lltemp }; LvalueRef::new_sized(llval, LvalueTy::from_ty(arg_ty)) }) .collect() } mod analyze; mod block; mod constant; mod lvalue; mod rvalue; mod operand; mod statement; mod did;