use super::{ CachedMir, ConstantId, GlobalEvalContext, ConstantKind, }; use error::EvalResult; use rustc::mir::repr as mir; use rustc::ty::{subst, self}; use rustc::hir::def_id::DefId; use rustc::mir::visit::{Visitor, LvalueContext}; use syntax::codemap::Span; use std::rc::Rc; use memory::Pointer; pub struct Stepper<'fncx, 'a: 'fncx, 'tcx: 'a>{ gecx: &'fncx mut GlobalEvalContext<'a, 'tcx>, // a cache of the constants to be computed before the next statement/terminator // this is an optimization, so we don't have to allocate a new vector for every statement constants: Vec<(ConstantId<'tcx>, Span, Pointer, CachedMir<'a, 'tcx>)>, } impl<'fncx, 'a, 'tcx> Stepper<'fncx, 'a, 'tcx> { pub(super) fn new(gecx: &'fncx mut GlobalEvalContext<'a, 'tcx>) -> Self { Stepper { gecx: gecx, constants: Vec::new(), } } fn statement(&mut self, stmt: &mir::Statement<'tcx>) -> EvalResult<()> { trace!("{:?}", stmt); let mir::StatementKind::Assign(ref lvalue, ref rvalue) = stmt.kind; self.gecx.eval_assignment(lvalue, rvalue)?; self.gecx.frame_mut().stmt += 1; Ok(()) } fn terminator(&mut self, terminator: &mir::Terminator<'tcx>) -> EvalResult<()> { // after a terminator we go to a new block self.gecx.frame_mut().stmt = 0; trace!("{:?}", terminator.kind); self.gecx.eval_terminator(terminator)?; if !self.gecx.stack.is_empty() { trace!("// {:?}", self.gecx.frame().next_block); } Ok(()) } // returns true as long as there are more things to do pub fn step(&mut self) -> EvalResult { if self.gecx.stack.is_empty() { return Ok(false); } let block = self.gecx.frame().next_block; let stmt = self.gecx.frame().stmt; let mir = self.gecx.mir(); let basic_block = mir.basic_block_data(block); if let Some(ref stmt) = basic_block.statements.get(stmt) { assert!(self.constants.is_empty()); ConstantExtractor { span: stmt.span, substs: self.gecx.substs(), def_id: self.gecx.frame().def_id, gecx: self.gecx, constants: &mut self.constants, mir: &mir, }.visit_statement(block, stmt); if self.constants.is_empty() { self.statement(stmt)?; } else { self.extract_constants()?; } return Ok(true); } let terminator = basic_block.terminator(); assert!(self.constants.is_empty()); ConstantExtractor { span: terminator.span, substs: self.gecx.substs(), def_id: self.gecx.frame().def_id, gecx: self.gecx, constants: &mut self.constants, mir: &mir, }.visit_terminator(block, terminator); if self.constants.is_empty() { self.terminator(terminator)?; } else { self.extract_constants()?; } Ok(true) } fn extract_constants(&mut self) -> EvalResult<()> { assert!(!self.constants.is_empty()); for (cid, span, return_ptr, mir) in self.constants.drain(..) { trace!("queuing a constant"); self.gecx.push_stack_frame(cid.def_id, span, mir, cid.substs, Some(return_ptr)); } // self.step() can't be "done", so it can't return false assert!(self.step()?); Ok(()) } } struct ConstantExtractor<'a, 'b: 'mir, 'mir: 'a, 'tcx: 'b> { span: Span, // FIXME: directly push the new stackframes instead of doing this intermediate caching constants: &'a mut Vec<(ConstantId<'tcx>, Span, Pointer, CachedMir<'mir, 'tcx>)>, gecx: &'a mut GlobalEvalContext<'b, 'tcx>, mir: &'a mir::Mir<'tcx>, def_id: DefId, substs: &'tcx subst::Substs<'tcx>, } impl<'a, 'b, 'mir, 'tcx> ConstantExtractor<'a, 'b, 'mir, 'tcx> { fn global_item(&mut self, def_id: DefId, substs: &'tcx subst::Substs<'tcx>, span: Span) { let cid = ConstantId { def_id: def_id, substs: substs, kind: ConstantKind::Global, }; if self.gecx.statics.contains_key(&cid) { return; } let mir = self.gecx.load_mir(def_id); let ptr = self.gecx.alloc_ret_ptr(mir.return_ty, substs).expect("there's no such thing as an unreachable static"); self.gecx.statics.insert(cid.clone(), ptr); self.constants.push((cid, span, ptr, mir)); } } impl<'a, 'b, 'mir, 'tcx> Visitor<'tcx> for ConstantExtractor<'a, 'b, 'mir, 'tcx> { fn visit_constant(&mut self, constant: &mir::Constant<'tcx>) { self.super_constant(constant); match constant.literal { // already computed by rustc mir::Literal::Value { .. } => {} mir::Literal::Item { def_id, substs } => { if let ty::TyFnDef(..) = constant.ty.sty { // No need to do anything here, even if function pointers are implemented, // because the type is the actual function, not the signature of the function. // Thus we can simply create a zero sized allocation in `evaluate_operand` } else { self.global_item(def_id, substs, constant.span); } }, mir::Literal::Promoted { index } => { let cid = ConstantId { def_id: self.def_id, substs: self.substs, kind: ConstantKind::Promoted(index), }; if self.gecx.statics.contains_key(&cid) { return; } let mir = self.mir.promoted[index].clone(); let return_ty = mir.return_ty; let return_ptr = self.gecx.alloc_ret_ptr(return_ty, cid.substs).expect("there's no such thing as an unreachable static"); let mir = CachedMir::Owned(Rc::new(mir)); self.gecx.statics.insert(cid.clone(), return_ptr); self.constants.push((cid, constant.span, return_ptr, mir)); } } } fn visit_lvalue(&mut self, lvalue: &mir::Lvalue<'tcx>, context: LvalueContext) { self.super_lvalue(lvalue, context); if let mir::Lvalue::Static(def_id) = *lvalue { let substs = self.gecx.tcx.mk_substs(subst::Substs::empty()); let span = self.span; self.global_item(def_id, substs, span); } } }