// Copyright 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 docs in build/expr/mod.rs use build::{BlockAnd, BlockAndExtension, Builder}; use build::expr::category::{Category, RvalueFunc}; use hair::*; use rustc::ty; use rustc::mir::repr::*; impl<'a, 'gcx, 'tcx> Builder<'a, 'gcx, 'tcx> { /// Compile `expr`, storing the result into `destination`, which /// is assumed to be uninitialized. pub fn into_expr(&mut self, destination: &Lvalue<'tcx>, mut block: BasicBlock, expr: Expr<'tcx>) -> BlockAnd<()> { debug!("into_expr(destination={:?}, block={:?}, expr={:?})", destination, block, expr); // since we frequently have to reference `self` from within a // closure, where `self` would be shadowed, it's easier to // just use the name `this` uniformly let this = self; let expr_span = expr.span; let source_info = this.source_info(expr_span); match expr.kind { ExprKind::Scope { extent, value } => { this.in_scope(extent, block, |this| this.into(destination, block, value)) } ExprKind::Block { body: ast_block } => { this.ast_block(destination, expr.ty.is_nil(), block, ast_block) } ExprKind::Match { discriminant, arms } => { this.match_expr(destination, expr_span, block, discriminant, arms) } ExprKind::NeverToAny { source } => { let source = this.hir.mirror(source); let is_call = match source.kind { ExprKind::Call { .. } => true, _ => false, }; unpack!(block = this.as_rvalue(block, source)); // This is an optimization. If the expression was a call then we already have an // unreachable block. Don't bother to terminate it and create a new one. if is_call { block.unit() } else { this.cfg.terminate(block, source_info, TerminatorKind::Unreachable); let end_block = this.cfg.start_new_block(); end_block.unit() } } ExprKind::If { condition: cond_expr, then: then_expr, otherwise: else_expr } => { let operand = unpack!(block = this.as_operand(block, cond_expr)); let mut then_block = this.cfg.start_new_block(); let mut else_block = this.cfg.start_new_block(); this.cfg.terminate(block, source_info, TerminatorKind::If { cond: operand, targets: (then_block, else_block) }); unpack!(then_block = this.into(destination, then_block, then_expr)); else_block = if let Some(else_expr) = else_expr { unpack!(this.into(destination, else_block, else_expr)) } else { // Body of the `if` expression without an `else` clause must return `()`, thus // we implicitly generate a `else {}` if it is not specified. this.cfg.push_assign_unit(else_block, source_info, destination); else_block }; let join_block = this.cfg.start_new_block(); this.cfg.terminate(then_block, source_info, TerminatorKind::Goto { target: join_block }); this.cfg.terminate(else_block, source_info, TerminatorKind::Goto { target: join_block }); join_block.unit() } ExprKind::LogicalOp { op, lhs, rhs } => { // And: // // [block: If(lhs)] -true-> [else_block: If(rhs)] -true-> [true_block] // | | (false) // +----------false-----------+------------------> [false_block] // // Or: // // [block: If(lhs)] -false-> [else_block: If(rhs)] -true-> [true_block] // | | (false) // +----------true------------+-------------------> [false_block] let (true_block, false_block, mut else_block, join_block) = (this.cfg.start_new_block(), this.cfg.start_new_block(), this.cfg.start_new_block(), this.cfg.start_new_block()); let lhs = unpack!(block = this.as_operand(block, lhs)); let blocks = match op { LogicalOp::And => (else_block, false_block), LogicalOp::Or => (true_block, else_block), }; this.cfg.terminate(block, source_info, TerminatorKind::If { cond: lhs, targets: blocks }); let rhs = unpack!(else_block = this.as_operand(else_block, rhs)); this.cfg.terminate(else_block, source_info, TerminatorKind::If { cond: rhs, targets: (true_block, false_block) }); this.cfg.push_assign_constant( true_block, source_info, destination, Constant { span: expr_span, ty: this.hir.bool_ty(), literal: this.hir.true_literal(), }); this.cfg.push_assign_constant( false_block, source_info, destination, Constant { span: expr_span, ty: this.hir.bool_ty(), literal: this.hir.false_literal(), }); this.cfg.terminate(true_block, source_info, TerminatorKind::Goto { target: join_block }); this.cfg.terminate(false_block, source_info, TerminatorKind::Goto { target: join_block }); join_block.unit() } ExprKind::Loop { condition: opt_cond_expr, body } => { // [block] --> [loop_block] ~~> [loop_block_end] -1-> [exit_block] // ^ | // | 0 // | | // | v // [body_block_end] <~~~ [body_block] // // If `opt_cond_expr` is `None`, then the graph is somewhat simplified: // // [block] --> [loop_block / body_block ] ~~> [body_block_end] [exit_block] // ^ | // | | // +--------------------------+ // let loop_block = this.cfg.start_new_block(); let exit_block = this.cfg.start_new_block(); // start the loop this.cfg.terminate(block, source_info, TerminatorKind::Goto { target: loop_block }); let might_break = this.in_loop_scope(loop_block, exit_block, move |this| { // conduct the test, if necessary let body_block; if let Some(cond_expr) = opt_cond_expr { // This loop has a condition, ergo its exit_block is reachable. this.find_loop_scope(expr_span, None).might_break = true; let loop_block_end; let cond = unpack!(loop_block_end = this.as_operand(loop_block, cond_expr)); body_block = this.cfg.start_new_block(); this.cfg.terminate(loop_block_end, source_info, TerminatorKind::If { cond: cond, targets: (body_block, exit_block) }); } else { body_block = loop_block; } // The “return” value of the loop body must always be an unit, but we cannot // reuse that as a “return” value of the whole loop expressions, because some // loops are diverging (e.g. `loop {}`). Thus, we introduce a unit temporary as // the destination for the loop body and assign the loop’s own “return” value // immediately after the iteration is finished. let tmp = this.get_unit_temp(); // Execute the body, branching back to the test. let body_block_end = unpack!(this.into(&tmp, body_block, body)); this.cfg.terminate(body_block_end, source_info, TerminatorKind::Goto { target: loop_block }); }); // If the loop may reach its exit_block, we assign an empty tuple to the // destination to keep the MIR well-formed. if might_break { this.cfg.push_assign_unit(exit_block, source_info, destination); } exit_block.unit() } ExprKind::Call { ty, fun, args } => { let diverges = match ty.sty { ty::TyFnDef(_, _, ref f) | ty::TyFnPtr(ref f) => { // FIXME(canndrew): This is_never should probably be an is_uninhabited f.sig.0.output.is_never() } _ => false }; let fun = unpack!(block = this.as_operand(block, fun)); let args: Vec<_> = args.into_iter() .map(|arg| unpack!(block = this.as_operand(block, arg))) .collect(); let success = this.cfg.start_new_block(); let cleanup = this.diverge_cleanup(); this.cfg.terminate(block, source_info, TerminatorKind::Call { func: fun, args: args, cleanup: cleanup, destination: if diverges { None } else { Some ((destination.clone(), success)) } }); success.unit() } // These cases don't actually need a destination ExprKind::Assign { .. } | ExprKind::AssignOp { .. } | ExprKind::Continue { .. } | ExprKind::Break { .. } | ExprKind::Return {.. } => { this.stmt_expr(block, expr) } // these are the cases that are more naturally handled by some other mode ExprKind::Unary { .. } | ExprKind::Binary { .. } | ExprKind::Box { .. } | ExprKind::Cast { .. } | ExprKind::Use { .. } | ExprKind::ReifyFnPointer { .. } | ExprKind::UnsafeFnPointer { .. } | ExprKind::Unsize { .. } | ExprKind::Repeat { .. } | ExprKind::Borrow { .. } | ExprKind::VarRef { .. } | ExprKind::SelfRef | ExprKind::StaticRef { .. } | ExprKind::Vec { .. } | ExprKind::Tuple { .. } | ExprKind::Adt { .. } | ExprKind::Closure { .. } | ExprKind::Index { .. } | ExprKind::Deref { .. } | ExprKind::Literal { .. } | ExprKind::InlineAsm { .. } | ExprKind::Field { .. } => { debug_assert!(match Category::of(&expr.kind).unwrap() { Category::Rvalue(RvalueFunc::Into) => false, _ => true, }); let rvalue = unpack!(block = this.as_rvalue(block, expr)); this.cfg.push_assign(block, source_info, destination, rvalue); block.unit() } } } }