use rustc::mir; use rustc::ty::{self, Ty, layout}; use syntax::ast::FloatTy; use rustc::ty::layout::LayoutOf; use rustc_apfloat::ieee::{Double, Single}; use rustc_apfloat::Float; use super::{EvalContext, Place, Machine, ValTy}; use rustc::mir::interpret::{EvalResult, Scalar, Value}; impl<'a, 'mir, 'tcx, M: Machine<'mir, 'tcx>> EvalContext<'a, 'mir, 'tcx, M> { fn binop_with_overflow( &mut self, op: mir::BinOp, left: ValTy<'tcx>, right: ValTy<'tcx>, ) -> EvalResult<'tcx, (Scalar, bool)> { let left_val = self.value_to_scalar(left)?; let right_val = self.value_to_scalar(right)?; self.binary_op(op, left_val, left.ty, right_val, right.ty) } /// Applies the binary operation `op` to the two operands and writes a tuple of the result /// and a boolean signifying the potential overflow to the destination. pub fn intrinsic_with_overflow( &mut self, op: mir::BinOp, left: ValTy<'tcx>, right: ValTy<'tcx>, dest: Place, dest_ty: Ty<'tcx>, ) -> EvalResult<'tcx> { let (val, overflowed) = self.binop_with_overflow(op, left, right)?; let val = Value::ScalarPair(val, Scalar::from_bool(overflowed)); let valty = ValTy { value: val, ty: dest_ty, }; self.write_value(valty, dest) } /// Applies the binary operation `op` to the arguments and writes the result to the /// destination. Returns `true` if the operation overflowed. pub fn intrinsic_overflowing( &mut self, op: mir::BinOp, left: ValTy<'tcx>, right: ValTy<'tcx>, dest: Place, dest_ty: Ty<'tcx>, ) -> EvalResult<'tcx, bool> { let (val, overflowed) = self.binop_with_overflow(op, left, right)?; self.write_scalar(dest, val, dest_ty)?; Ok(overflowed) } } impl<'a, 'mir, 'tcx, M: Machine<'mir, 'tcx>> EvalContext<'a, 'mir, 'tcx, M> { /// Returns the result of the specified operation and whether it overflowed. pub fn binary_op( &self, bin_op: mir::BinOp, left: Scalar, left_ty: Ty<'tcx>, right: Scalar, right_ty: Ty<'tcx>, ) -> EvalResult<'tcx, (Scalar, bool)> { use rustc::mir::BinOp::*; let left_layout = self.layout_of(left_ty)?; let right_layout = self.layout_of(right_ty)?; let left_kind = match left_layout.abi { layout::Abi::Scalar(ref scalar) => scalar.value, _ => return err!(TypeNotPrimitive(left_ty)), }; let right_kind = match right_layout.abi { layout::Abi::Scalar(ref scalar) => scalar.value, _ => return err!(TypeNotPrimitive(right_ty)), }; trace!("Running binary op {:?}: {:?} ({:?}), {:?} ({:?})", bin_op, left, left_kind, right, right_kind); // I: Handle operations that support pointers if !left_kind.is_float() && !right_kind.is_float() { if let Some(handled) = M::try_ptr_op(self, bin_op, left, left_ty, right, right_ty)? { return Ok(handled); } } // II: From now on, everything must be bytes, no pointers let l = left.to_bits(left_layout.size)?; let r = right.to_bits(right_layout.size)?; // These ops can have an RHS with a different numeric type. if right_kind.is_int() && (bin_op == Shl || bin_op == Shr) { let signed = left_layout.abi.is_signed(); let mut r = r as u32; let size = left_layout.size.bits() as u32; let oflo = r >= size; if oflo { r %= size; } let result = if signed { let l = self.sign_extend(l, left_ty)? as i128; let result = match bin_op { Shl => l << r, Shr => l >> r, _ => bug!("it has already been checked that this is a shift op"), }; result as u128 } else { match bin_op { Shl => l << r, Shr => l >> r, _ => bug!("it has already been checked that this is a shift op"), } }; let truncated = self.truncate(result, left_ty)?; return Ok((Scalar::Bits { bits: truncated, defined: size as u8, }, oflo)); } if left_kind != right_kind { let msg = format!( "unimplemented binary op {:?}: {:?} ({:?}), {:?} ({:?})", bin_op, left, left_kind, right, right_kind ); return err!(Unimplemented(msg)); } if left_layout.abi.is_signed() { let op: Option bool> = match bin_op { Lt => Some(i128::lt), Le => Some(i128::le), Gt => Some(i128::gt), Ge => Some(i128::ge), _ => None, }; if let Some(op) = op { let l = self.sign_extend(l, left_ty)? as i128; let r = self.sign_extend(r, right_ty)? as i128; return Ok((Scalar::from_bool(op(&l, &r)), false)); } let op: Option (i128, bool)> = match bin_op { Div if r == 0 => return err!(DivisionByZero), Rem if r == 0 => return err!(RemainderByZero), Div => Some(i128::overflowing_div), Rem => Some(i128::overflowing_rem), Add => Some(i128::overflowing_add), Sub => Some(i128::overflowing_sub), Mul => Some(i128::overflowing_mul), _ => None, }; if let Some(op) = op { let l128 = self.sign_extend(l, left_ty)? as i128; let r = self.sign_extend(r, right_ty)? as i128; let size = left_layout.size.bits(); match bin_op { Rem | Div => { // int_min / -1 if r == -1 && l == (1 << (size - 1)) { return Ok((Scalar::Bits { bits: l, defined: size as u8 }, true)); } }, _ => {}, } trace!("{}, {}, {}", l, l128, r); let (result, mut oflo) = op(l128, r); trace!("{}, {}", result, oflo); if !oflo && size != 128 { let max = 1 << (size - 1); oflo = result >= max || result < -max; } let result = result as u128; let truncated = self.truncate(result, left_ty)?; return Ok((Scalar::Bits { bits: truncated, defined: size as u8, }, oflo)); } } if let ty::TyFloat(fty) = left_ty.sty { macro_rules! float_math { ($ty:path, $bitsize:expr) => {{ let l = <$ty>::from_bits(l); let r = <$ty>::from_bits(r); let bitify = |res: ::rustc_apfloat::StatusAnd<$ty>| Scalar::Bits { bits: res.value.to_bits(), defined: $bitsize, }; let val = match bin_op { Eq => Scalar::from_bool(l == r), Ne => Scalar::from_bool(l != r), Lt => Scalar::from_bool(l < r), Le => Scalar::from_bool(l <= r), Gt => Scalar::from_bool(l > r), Ge => Scalar::from_bool(l >= r), Add => bitify(l + r), Sub => bitify(l - r), Mul => bitify(l * r), Div => bitify(l / r), Rem => bitify(l % r), _ => bug!("invalid float op: `{:?}`", bin_op), }; return Ok((val, false)); }}; } match fty { FloatTy::F32 => float_math!(Single, 32), FloatTy::F64 => float_math!(Double, 64), } } let bit_width = self.layout_of(left_ty).unwrap().size.bits() as u8; // only ints left let val = match bin_op { Eq => Scalar::from_bool(l == r), Ne => Scalar::from_bool(l != r), Lt => Scalar::from_bool(l < r), Le => Scalar::from_bool(l <= r), Gt => Scalar::from_bool(l > r), Ge => Scalar::from_bool(l >= r), BitOr => Scalar::Bits { bits: l | r, defined: bit_width }, BitAnd => Scalar::Bits { bits: l & r, defined: bit_width }, BitXor => Scalar::Bits { bits: l ^ r, defined: bit_width }, Add | Sub | Mul | Rem | Div => { let op: fn(u128, u128) -> (u128, bool) = match bin_op { Add => u128::overflowing_add, Sub => u128::overflowing_sub, Mul => u128::overflowing_mul, Div if r == 0 => return err!(DivisionByZero), Rem if r == 0 => return err!(RemainderByZero), Div => u128::overflowing_div, Rem => u128::overflowing_rem, _ => bug!(), }; let (result, oflo) = op(l, r); let truncated = self.truncate(result, left_ty)?; return Ok((Scalar::Bits { bits: truncated, defined: bit_width, }, oflo || truncated != result)); } _ => { let msg = format!( "unimplemented binary op {:?}: {:?} ({:?}), {:?} ({:?})", bin_op, left, left_ty, right, right_ty, ); return err!(Unimplemented(msg)); } }; Ok((val, false)) } pub fn unary_op( &self, un_op: mir::UnOp, val: Scalar, ty: Ty<'tcx>, ) -> EvalResult<'tcx, Scalar> { use rustc::mir::UnOp::*; use rustc_apfloat::ieee::{Single, Double}; use rustc_apfloat::Float; let size = self.layout_of(ty)?.size; let bytes = val.to_bits(size)?; let size = size.bits(); let result_bytes = match (un_op, &ty.sty) { (Not, ty::TyBool) => !val.to_bool()? as u128, (Not, _) => !bytes, (Neg, ty::TyFloat(FloatTy::F32)) => Single::to_bits(-Single::from_bits(bytes)), (Neg, ty::TyFloat(FloatTy::F64)) => Double::to_bits(-Double::from_bits(bytes)), (Neg, _) if bytes == (1 << (size - 1)) => return err!(OverflowNeg), (Neg, _) => (-(bytes as i128)) as u128, }; Ok(Scalar::Bits { bits: self.truncate(result_bytes, ty)?, defined: size as u8, }) } }