compiler/rustc_mir_transform/src/simplify_comparison_integral.rs - toolchain/rustc - Git at Google

 use std::iter;

 use super::MirPass;
 use rustc_middle::{
     mir::{
         interpret::Scalar, BasicBlock, BinOp, Body, Operand, Place, Rvalue, Statement,
         StatementKind, SwitchTargets, TerminatorKind,
     },
     ty::{Ty, TyCtxt},
 };

 /// Pass to convert `if` conditions on integrals into switches on the integral.
 /// For an example, it turns something like
 ///
 /// ```ignore (MIR)
 /// _3 = Eq(move _4, const 43i32);
 /// StorageDead(_4);
 /// switchInt(_3) -> [false: bb2, otherwise: bb3];
 /// ```
 ///
 /// into:
 ///
 /// ```ignore (MIR)
 /// switchInt(_4) -> [43i32: bb3, otherwise: bb2];
 /// ```
 pub struct SimplifyComparisonIntegral;

 impl<'tcx> MirPass<'tcx> for SimplifyComparisonIntegral {
     fn is_enabled(&self, sess: &rustc_session::Session) -> bool {
         sess.mir_opt_level() > 0
     }

     fn run_pass(&self, tcx: TyCtxt<'tcx>, body: &mut Body<'tcx>) {
         trace!("Running SimplifyComparisonIntegral on {:?}", body.source);

         let helper = OptimizationFinder { body };
         let opts = helper.find_optimizations();
         let mut storage_deads_to_insert = vec![];
         let mut storage_deads_to_remove: Vec<(usize, BasicBlock)> = vec![];
         let param_env = tcx.param_env_reveal_all_normalized(body.source.def_id());
         for opt in opts {
             trace!("SUCCESS: Applying {:?}", opt);
             // replace terminator with a switchInt that switches on the integer directly
             let bbs = &mut body.basic_blocks_mut();
             let bb = &mut bbs[opt.bb_idx];
             let new_value = match opt.branch_value_scalar {
                 Scalar::Int(int) => {
                     let layout = tcx
                         .layout_of(param_env.and(opt.branch_value_ty))
                         .expect("if we have an evaluated constant we must know the layout");
                     int.assert_bits(layout.size)
                 }
                 Scalar::Ptr(..) => continue,
             };
             const FALSE: u128 = 0;

             let mut new_targets = opt.targets;
             let first_value = new_targets.iter().next().unwrap().0;
             let first_is_false_target = first_value == FALSE;
             match opt.op {
                 BinOp::Eq => {
                     // if the assignment was Eq we want the true case to be first
                     if first_is_false_target {
                         new_targets.all_targets_mut().swap(0, 1);
                     }
                 }
                 BinOp::Ne => {
                     // if the assignment was Ne we want the false case to be first
                     if !first_is_false_target {
                         new_targets.all_targets_mut().swap(0, 1);
                     }
                 }
                 _ => unreachable!(),
             }

             // delete comparison statement if it the value being switched on was moved, which means it can not be user later on
             if opt.can_remove_bin_op_stmt {
                 bb.statements[opt.bin_op_stmt_idx].make_nop();
             } else {
                 // if the integer being compared to a const integral is being moved into the comparison,
                 // e.g `_2 = Eq(move _3, const 'x');`
                 // we want to avoid making a double move later on in the switchInt on _3.
                 // So to avoid `switchInt(move _3) -> ['x': bb2, otherwise: bb1];`,
                 // we convert the move in the comparison statement to a copy.

                 // unwrap is safe as we know this statement is an assign
                 let (_, rhs) = bb.statements[opt.bin_op_stmt_idx].kind.as_assign_mut().unwrap();

                 use Operand::*;
                 match rhs {
                     Rvalue::BinaryOp(_, box (ref mut left @ Move(_), Constant(_))) => {
                         *left = Copy(opt.to_switch_on);
                     }
                     Rvalue::BinaryOp(_, box (Constant(_), ref mut right @ Move(_))) => {
                         *right = Copy(opt.to_switch_on);
                     }
                     _ => (),
                 }
             }

             let terminator = bb.terminator();

             // remove StorageDead (if it exists) being used in the assign of the comparison
             for (stmt_idx, stmt) in bb.statements.iter().enumerate() {
                 if !matches!(stmt.kind, StatementKind::StorageDead(local) if local == opt.to_switch_on.local)
                 {
                     continue;
                 }
                 storage_deads_to_remove.push((stmt_idx, opt.bb_idx));
                 // if we have StorageDeads to remove then make sure to insert them at the top of each target
                 for bb_idx in new_targets.all_targets() {
                     storage_deads_to_insert.push((
                         *bb_idx,
                         Statement {
                             source_info: terminator.source_info,
                             kind: StatementKind::StorageDead(opt.to_switch_on.local),
                         },
                     ));
                 }
             }

             let [bb_cond, bb_otherwise] = match new_targets.all_targets() {
                 [a, b] => [*a, *b],
                 e => bug!("expected 2 switch targets, got: {:?}", e),
             };

             let targets = SwitchTargets::new(iter::once((new_value, bb_cond)), bb_otherwise);

             let terminator = bb.terminator_mut();
             terminator.kind =
                 TerminatorKind::SwitchInt { discr: Operand::Move(opt.to_switch_on), targets };
         }

         for (idx, bb_idx) in storage_deads_to_remove {
             body.basic_blocks_mut()[bb_idx].statements[idx].make_nop();
         }

         for (idx, stmt) in storage_deads_to_insert {
             body.basic_blocks_mut()[idx].statements.insert(0, stmt);
         }
     }
 }

 struct OptimizationFinder<'a, 'tcx> {
     body: &'a Body<'tcx>,
 }

 impl<'tcx> OptimizationFinder<'_, 'tcx> {
     fn find_optimizations(&self) -> Vec<OptimizationInfo<'tcx>> {
         self.body
             .basic_blocks
             .iter_enumerated()
             .filter_map(|(bb_idx, bb)| {
                 // find switch
                 let (place_switched_on, targets, place_switched_on_moved) =
                     match &bb.terminator().kind {
                         rustc_middle::mir::TerminatorKind::SwitchInt { discr, targets, .. } => {
                             Some((discr.place()?, targets, discr.is_move()))
                         }
                         _ => None,
                     }?;

                 // find the statement that assigns the place being switched on
                 bb.statements.iter().enumerate().rev().find_map(|(stmt_idx, stmt)| {
                     match &stmt.kind {
                         rustc_middle::mir::StatementKind::Assign(box (lhs, rhs))
                             if *lhs == place_switched_on =>
                         {
                             match rhs {
                                 Rvalue::BinaryOp(
                                     op @ (BinOp::Eq | BinOp::Ne),
                                     box (left, right),
                                 ) => {
                                     let (branch_value_scalar, branch_value_ty, to_switch_on) =
                                         find_branch_value_info(left, right)?;

                                     Some(OptimizationInfo {
                                         bin_op_stmt_idx: stmt_idx,
                                         bb_idx,
                                         can_remove_bin_op_stmt: place_switched_on_moved,
                                         to_switch_on,
                                         branch_value_scalar,
                                         branch_value_ty,
                                         op: *op,
                                         targets: targets.clone(),
                                     })
                                 }
                                 _ => None,
                             }
                         }
                         _ => None,
                     }
                 })
             })
             .collect()
     }
 }

 fn find_branch_value_info<'tcx>(
     left: &Operand<'tcx>,
     right: &Operand<'tcx>,
 ) -> Option<(Scalar, Ty<'tcx>, Place<'tcx>)> {
     // check that either left or right is a constant.
     // if any are, we can use the other to switch on, and the constant as a value in a switch
     use Operand::*;
     match (left, right) {
         (Constant(branch_value), Copy(to_switch_on) | Move(to_switch_on))
         | (Copy(to_switch_on) | Move(to_switch_on), Constant(branch_value)) => {
             let branch_value_ty = branch_value.literal.ty();
             // we only want to apply this optimization if we are matching on integrals (and chars), as it is not possible to switch on floats
             if !branch_value_ty.is_integral() && !branch_value_ty.is_char() {
                 return None;
             };
             let branch_value_scalar = branch_value.literal.try_to_scalar()?;
             Some((branch_value_scalar, branch_value_ty, *to_switch_on))
         }
         _ => None,
     }
 }

 #[derive(Debug)]
 struct OptimizationInfo<'tcx> {
     /// Basic block to apply the optimization
     bb_idx: BasicBlock,
     /// Statement index of Eq/Ne assignment that can be removed. None if the assignment can not be removed - i.e the statement is used later on
     bin_op_stmt_idx: usize,
     /// Can remove Eq/Ne assignment
     can_remove_bin_op_stmt: bool,
     /// Place that needs to be switched on. This place is of type integral
     to_switch_on: Place<'tcx>,
     /// Constant to use in switch target value
     branch_value_scalar: Scalar,
     /// Type of the constant value
     branch_value_ty: Ty<'tcx>,
     /// Either Eq or Ne
     op: BinOp,
     /// Current targets used in the switch
     targets: SwitchTargets,
 }
	use std::iter;

	use super::MirPass;
	use rustc_middle::{
	mir::{
	interpret::Scalar, BasicBlock, BinOp, Body, Operand, Place, Rvalue, Statement,
	StatementKind, SwitchTargets, TerminatorKind,
	},
	ty::{Ty, TyCtxt},
	};

	/// Pass to convert `if` conditions on integrals into switches on the integral.
	/// For an example, it turns something like
	///
	/// ```ignore (MIR)
	/// _3 = Eq(move _4, const 43i32);
	/// StorageDead(_4);
	/// switchInt(_3) -> [false: bb2, otherwise: bb3];
	/// ```
	///
	/// into:
	///
	/// ```ignore (MIR)
	/// switchInt(_4) -> [43i32: bb3, otherwise: bb2];
	/// ```
	pub struct SimplifyComparisonIntegral;

	impl<'tcx> MirPass<'tcx> for SimplifyComparisonIntegral {
	fn is_enabled(&self, sess: &rustc_session::Session) -> bool {
	sess.mir_opt_level() > 0
	}

	fn run_pass(&self, tcx: TyCtxt<'tcx>, body: &mut Body<'tcx>) {
	trace!("Running SimplifyComparisonIntegral on {:?}", body.source);

	let helper = OptimizationFinder { body };
	let opts = helper.find_optimizations();
	let mut storage_deads_to_insert = vec![];
	let mut storage_deads_to_remove: Vec<(usize, BasicBlock)> = vec![];
	let param_env = tcx.param_env_reveal_all_normalized(body.source.def_id());
	for opt in opts {
	trace!("SUCCESS: Applying {:?}", opt);
	// replace terminator with a switchInt that switches on the integer directly
	let bbs = &mut body.basic_blocks_mut();
	let bb = &mut bbs[opt.bb_idx];
	let new_value = match opt.branch_value_scalar {
	Scalar::Int(int) => {
	let layout = tcx
	.layout_of(param_env.and(opt.branch_value_ty))
	.expect("if we have an evaluated constant we must know the layout");
	int.assert_bits(layout.size)
	}
	Scalar::Ptr(..) => continue,
	};
	const FALSE: u128 = 0;

	let mut new_targets = opt.targets;
	let first_value = new_targets.iter().next().unwrap().0;
	let first_is_false_target = first_value == FALSE;
	match opt.op {
	BinOp::Eq => {
	// if the assignment was Eq we want the true case to be first
	if first_is_false_target {
	new_targets.all_targets_mut().swap(0, 1);
	}
	}
	BinOp::Ne => {
	// if the assignment was Ne we want the false case to be first
	if !first_is_false_target {
	new_targets.all_targets_mut().swap(0, 1);
	}
	}
	_ => unreachable!(),
	}

	// delete comparison statement if it the value being switched on was moved, which means it can not be user later on
	if opt.can_remove_bin_op_stmt {
	bb.statements[opt.bin_op_stmt_idx].make_nop();
	} else {
	// if the integer being compared to a const integral is being moved into the comparison,
	// e.g `_2 = Eq(move _3, const 'x');`
	// we want to avoid making a double move later on in the switchInt on _3.
	// So to avoid `switchInt(move _3) -> ['x': bb2, otherwise: bb1];`,
	// we convert the move in the comparison statement to a copy.

	// unwrap is safe as we know this statement is an assign
	let (_, rhs) = bb.statements[opt.bin_op_stmt_idx].kind.as_assign_mut().unwrap();

	use Operand::*;
	match rhs {
	Rvalue::BinaryOp(_, box (ref mut left @ Move(_), Constant(_))) => {
	*left = Copy(opt.to_switch_on);
	}
	Rvalue::BinaryOp(_, box (Constant(_), ref mut right @ Move(_))) => {
	*right = Copy(opt.to_switch_on);
	}
	_ => (),
	}
	}

	let terminator = bb.terminator();

	// remove StorageDead (if it exists) being used in the assign of the comparison
	for (stmt_idx, stmt) in bb.statements.iter().enumerate() {
	if !matches!(stmt.kind, StatementKind::StorageDead(local) if local == opt.to_switch_on.local)
	{
	continue;
	}
	storage_deads_to_remove.push((stmt_idx, opt.bb_idx));
	// if we have StorageDeads to remove then make sure to insert them at the top of each target
	for bb_idx in new_targets.all_targets() {
	storage_deads_to_insert.push((
	*bb_idx,
	Statement {
	source_info: terminator.source_info,
	kind: StatementKind::StorageDead(opt.to_switch_on.local),
	},
	));
	}
	}

	let [bb_cond, bb_otherwise] = match new_targets.all_targets() {
	[a, b] => [a, b],
	e => bug!("expected 2 switch targets, got: {:?}", e),
	};

	let targets = SwitchTargets::new(iter::once((new_value, bb_cond)), bb_otherwise);

	let terminator = bb.terminator_mut();
	terminator.kind =
	TerminatorKind::SwitchInt { discr: Operand::Move(opt.to_switch_on), targets };
	}

	for (idx, bb_idx) in storage_deads_to_remove {
	body.basic_blocks_mut()[bb_idx].statements[idx].make_nop();
	}

	for (idx, stmt) in storage_deads_to_insert {
	body.basic_blocks_mut()[idx].statements.insert(0, stmt);
	}
	}
	}

	struct OptimizationFinder<'a, 'tcx> {
	body: &'a Body<'tcx>,
	}

	impl<'tcx> OptimizationFinder<'_, 'tcx> {
	fn find_optimizations(&self) -> Vec<OptimizationInfo<'tcx>> {
	self.body
	.basic_blocks
	.iter_enumerated()
	.filter_map(\|(bb_idx, bb)\| {
	// find switch
	let (place_switched_on, targets, place_switched_on_moved) =
	match &bb.terminator().kind {
	rustc_middle::mir::TerminatorKind::SwitchInt { discr, targets, .. } => {
	Some((discr.place()?, targets, discr.is_move()))
	}
	_ => None,
	}?;

	// find the statement that assigns the place being switched on
	bb.statements.iter().enumerate().rev().find_map(\|(stmt_idx, stmt)\| {
	match &stmt.kind {
	rustc_middle::mir::StatementKind::Assign(box (lhs, rhs))
	if *lhs == place_switched_on =>
	{
	match rhs {
	Rvalue::BinaryOp(
	op @ (BinOp::Eq \| BinOp::Ne),
	box (left, right),
	) => {
	let (branch_value_scalar, branch_value_ty, to_switch_on) =
	find_branch_value_info(left, right)?;

	Some(OptimizationInfo {
	bin_op_stmt_idx: stmt_idx,
	bb_idx,
	can_remove_bin_op_stmt: place_switched_on_moved,
	to_switch_on,
	branch_value_scalar,
	branch_value_ty,
	op: *op,
	targets: targets.clone(),
	})
	}
	_ => None,
	}
	}
	_ => None,
	}
	})
	})
	.collect()
	}
	}

	fn find_branch_value_info<'tcx>(
	left: &Operand<'tcx>,
	right: &Operand<'tcx>,
	) -> Option<(Scalar, Ty<'tcx>, Place<'tcx>)> {
	// check that either left or right is a constant.
	// if any are, we can use the other to switch on, and the constant as a value in a switch
	use Operand::*;
	match (left, right) {
	(Constant(branch_value), Copy(to_switch_on) \| Move(to_switch_on))
	\| (Copy(to_switch_on) \| Move(to_switch_on), Constant(branch_value)) => {
	let branch_value_ty = branch_value.literal.ty();
	// we only want to apply this optimization if we are matching on integrals (and chars), as it is not possible to switch on floats
	if !branch_value_ty.is_integral() && !branch_value_ty.is_char() {
	return None;
	};
	let branch_value_scalar = branch_value.literal.try_to_scalar()?;
	Some((branch_value_scalar, branch_value_ty, *to_switch_on))
	}
	_ => None,
	}
	}

	#[derive(Debug)]
	struct OptimizationInfo<'tcx> {
	/// Basic block to apply the optimization
	bb_idx: BasicBlock,
	/// Statement index of Eq/Ne assignment that can be removed. None if the assignment can not be removed - i.e the statement is used later on
	bin_op_stmt_idx: usize,
	/// Can remove Eq/Ne assignment
	can_remove_bin_op_stmt: bool,
	/// Place that needs to be switched on. This place is of type integral
	to_switch_on: Place<'tcx>,
	/// Constant to use in switch target value
	branch_value_scalar: Scalar,
	/// Type of the constant value
	branch_value_ty: Ty<'tcx>,
	/// Either Eq or Ne
	op: BinOp,
	/// Current targets used in the switch
	targets: SwitchTargets,
	}