//! This module contains the `EvalContext` methods for executing a single step of the interpreter. //! //! The main entry point is the `step` method. use std::cell::Ref; use rustc::hir::def_id::DefId; use rustc::hir; use rustc::mir::visit::{Visitor, LvalueContext}; use rustc::mir; use rustc::ty::layout::Layout; use rustc::ty::{subst, self}; use error::{EvalResult, EvalError}; use eval_context::{EvalContext, StackPopCleanup, MirRef}; use lvalue::{Global, GlobalId, Lvalue}; use syntax::codemap::Span; impl<'a, 'tcx> EvalContext<'a, 'tcx> { pub fn inc_step_counter_and_check_limit(&mut self, n: u64) -> EvalResult<'tcx, ()> { self.steps_remaining = self.steps_remaining.saturating_sub(n); if self.steps_remaining > 0 { Ok(()) } else { Err(EvalError::ExecutionTimeLimitReached) } } /// Returns true as long as there are more things to do. pub fn step(&mut self) -> EvalResult<'tcx, bool> { // see docs on the `Memory::packed` field for why we do this self.memory.clear_packed(); self.inc_step_counter_and_check_limit(1)?; if self.stack.is_empty() { return Ok(false); } let block = self.frame().block; let stmt_id = self.frame().stmt; let mir = self.mir(); let basic_block = &mir.basic_blocks()[block]; if let Some(stmt) = basic_block.statements.get(stmt_id) { let mut new = Ok(0); ConstantExtractor { span: stmt.source_info.span, substs: self.substs(), def_id: self.frame().def_id, ecx: self, mir: Ref::clone(&mir), new_constants: &mut new, }.visit_statement(block, stmt, mir::Location { block, statement_index: stmt_id }); if new? == 0 { self.statement(stmt)?; } // if ConstantExtractor added new frames, we don't execute anything here // but await the next call to step return Ok(true); } let terminator = basic_block.terminator(); let mut new = Ok(0); ConstantExtractor { span: terminator.source_info.span, substs: self.substs(), def_id: self.frame().def_id, ecx: self, mir: Ref::clone(&mir), new_constants: &mut new, }.visit_terminator(block, terminator, mir::Location { block, statement_index: stmt_id }); if new? == 0 { self.terminator(terminator)?; } // if ConstantExtractor added new frames, we don't execute anything here // but await the next call to step Ok(true) } fn statement(&mut self, stmt: &mir::Statement<'tcx>) -> EvalResult<'tcx, ()> { trace!("{:?}", stmt); use rustc::mir::StatementKind::*; match stmt.kind { Assign(ref lvalue, ref rvalue) => self.eval_rvalue_into_lvalue(rvalue, lvalue)?, SetDiscriminant { ref lvalue, variant_index } => { let dest = self.eval_lvalue(lvalue)?; let dest_ty = self.lvalue_ty(lvalue); let dest_layout = self.type_layout(dest_ty)?; match *dest_layout { Layout::General { discr, ref variants, .. } => { let discr_size = discr.size().bytes(); let discr_offset = variants[variant_index].offsets[0].bytes(); // FIXME(solson) let dest = self.force_allocation(dest)?; let discr_dest = (dest.to_ptr()).offset(discr_offset); self.memory.write_uint(discr_dest, variant_index as u128, discr_size)?; } Layout::RawNullablePointer { nndiscr, .. } => { use value::PrimVal; if variant_index as u64 != nndiscr { self.write_primval(dest, PrimVal::Bytes(0), dest_ty)?; } } _ => bug!("SetDiscriminant on {} represented as {:#?}", dest_ty, dest_layout), } } // Miri can safely ignore these. Only translation needs it. StorageLive(_) | StorageDead(_) => {} // Defined to do nothing. These are added by optimization passes, to avoid changing the // size of MIR constantly. Nop => {} } self.frame_mut().stmt += 1; Ok(()) } fn terminator(&mut self, terminator: &mir::Terminator<'tcx>) -> EvalResult<'tcx, ()> { trace!("{:?}", terminator.kind); self.eval_terminator(terminator)?; if !self.stack.is_empty() { trace!("// {:?}", self.frame().block); } Ok(()) } } // WARNING: make sure that any methods implemented on this type don't ever access ecx.stack // this includes any method that might access the stack // basically don't call anything other than `load_mir`, `alloc_ptr`, `push_stack_frame` // The reason for this is, that `push_stack_frame` modifies the stack out of obvious reasons struct ConstantExtractor<'a, 'b: 'a, 'tcx: 'b> { span: Span, ecx: &'a mut EvalContext<'b, 'tcx>, mir: MirRef<'tcx>, def_id: DefId, substs: &'tcx subst::Substs<'tcx>, new_constants: &'a mut EvalResult<'tcx, u64>, } impl<'a, 'b, 'tcx> ConstantExtractor<'a, 'b, 'tcx> { fn global_item(&mut self, def_id: DefId, substs: &'tcx subst::Substs<'tcx>, span: Span, immutable: bool) { let cid = GlobalId { def_id, substs, promoted: None }; if self.ecx.globals.contains_key(&cid) { return; } self.try(|this| { let mir = this.ecx.load_mir(def_id)?; this.ecx.globals.insert(cid, Global::uninitialized(mir.return_ty)); let cleanup = if immutable && !mir.return_ty.type_contents(this.ecx.tcx).interior_unsafe() { StackPopCleanup::Freeze } else { StackPopCleanup::None }; this.ecx.push_stack_frame(def_id, span, mir, substs, Lvalue::Global(cid), cleanup, Vec::new()) }); } fn try EvalResult<'tcx, ()>>(&mut self, f: F) { if let Ok(ref mut n) = *self.new_constants { *n += 1; } else { return; } if let Err(e) = f(self) { *self.new_constants = Err(e); } } } impl<'a, 'b, 'tcx> Visitor<'tcx> for ConstantExtractor<'a, 'b, 'tcx> { fn visit_constant(&mut self, constant: &mir::Constant<'tcx>, location: mir::Location) { self.super_constant(constant, location); 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, // 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, true); } }, mir::Literal::Promoted { index } => { let cid = GlobalId { def_id: self.def_id, substs: self.substs, promoted: Some(index), }; if self.ecx.globals.contains_key(&cid) { return; } let mir = Ref::clone(&self.mir); let mir = Ref::map(mir, |mir| &mir.promoted[index]); self.try(|this| { let ty = this.ecx.monomorphize(mir.return_ty, this.substs); this.ecx.globals.insert(cid, Global::uninitialized(ty)); this.ecx.push_stack_frame(this.def_id, constant.span, mir, this.substs, Lvalue::Global(cid), StackPopCleanup::Freeze, Vec::new()) }); } } } fn visit_lvalue( &mut self, lvalue: &mir::Lvalue<'tcx>, context: LvalueContext<'tcx>, location: mir::Location ) { self.super_lvalue(lvalue, context, location); if let mir::Lvalue::Static(def_id) = *lvalue { let substs = self.ecx.tcx.intern_substs(&[]); let span = self.span; if let Some(node_item) = self.ecx.tcx.map.get_if_local(def_id) { if let hir::map::Node::NodeItem(&hir::Item { ref node, .. }) = node_item { if let hir::ItemStatic(_, m, _) = *node { self.global_item(def_id, substs, span, m == hir::MutImmutable); return; } else { bug!("static def id doesn't point to static"); } } else { bug!("static def id doesn't point to item"); } } else { let def = self.ecx.tcx.sess.cstore.describe_def(def_id).expect("static not found"); if let hir::def::Def::Static(_, mutable) = def { self.global_item(def_id, substs, span, !mutable); } else { bug!("static found but isn't a static: {:?}", def); } } } } }