mlir/lib/Interfaces/ControlFlowInterfaces.cpp - llvm-project - Git at Google

 //===- ControlFlowInterfaces.cpp - ControlFlow Interfaces -----------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include "mlir/Interfaces/ControlFlowInterfaces.h"
 #include "mlir/IR/BuiltinTypes.h"
 #include "llvm/ADT/SmallPtrSet.h"

 using namespace mlir;

 //===----------------------------------------------------------------------===//
 // ControlFlowInterfaces
 //===----------------------------------------------------------------------===//

 #include "mlir/Interfaces/ControlFlowInterfaces.cpp.inc"

 //===----------------------------------------------------------------------===//
 // BranchOpInterface
 //===----------------------------------------------------------------------===//

 /// Returns the `BlockArgument` corresponding to operand `operandIndex` in some
 /// successor if 'operandIndex' is within the range of 'operands', or None if
 /// `operandIndex` isn't a successor operand index.
 Optional<BlockArgument>
 detail::getBranchSuccessorArgument(Optional<OperandRange> operands,
                                    unsigned operandIndex, Block *successor) {
   // Check that the operands are valid.
   if (!operands || operands->empty())
     return llvm::None;

   // Check to ensure that this operand is within the range.
   unsigned operandsStart = operands->getBeginOperandIndex();
   if (operandIndex < operandsStart ||
       operandIndex >= (operandsStart + operands->size()))
     return llvm::None;

   // Index the successor.
   unsigned argIndex = operandIndex - operandsStart;
   return successor->getArgument(argIndex);
 }

 /// Verify that the given operands match those of the given successor block.
 LogicalResult
 detail::verifyBranchSuccessorOperands(Operation *op, unsigned succNo,
                                       Optional<OperandRange> operands) {
   if (!operands)
     return success();

   // Check the count.
   unsigned operandCount = operands->size();
   Block *destBB = op->getSuccessor(succNo);
   if (operandCount != destBB->getNumArguments())
     return op->emitError() << "branch has " << operandCount
                            << " operands for successor #" << succNo
                            << ", but target block has "
                            << destBB->getNumArguments();

   // Check the types.
   auto operandIt = operands->begin();
   for (unsigned i = 0; i != operandCount; ++i, ++operandIt) {
     if ((*operandIt).getType() != destBB->getArgument(i).getType())
       return op->emitError() << "type mismatch for bb argument #" << i
                              << " of successor #" << succNo;
   }
   return success();
 }

 //===----------------------------------------------------------------------===//
 // RegionBranchOpInterface
 //===----------------------------------------------------------------------===//

 // A constant value to represent unknown number of region invocations.
 const int64_t mlir::kUnknownNumRegionInvocations = -1;

 /// Verify that types match along all region control flow edges originating from
 /// `sourceNo` (region # if source is a region, llvm::None if source is parent
 /// op). `getInputsTypesForRegion` is a function that returns the types of the
 /// inputs that flow from `sourceIndex' to the given region, or llvm::None if
 /// the exact type match verification is not necessary (e.g., if the Op verifies
 /// the match itself).
 static LogicalResult
 verifyTypesAlongAllEdges(Operation *op, Optional<unsigned> sourceNo,
                          function_ref<Optional<TypeRange>(Optional<unsigned>)>
                              getInputsTypesForRegion) {
   auto regionInterface = cast<RegionBranchOpInterface>(op);

   SmallVector<RegionSuccessor, 2> successors;
   unsigned numInputs;
   if (sourceNo) {
     Region &srcRegion = op->getRegion(sourceNo.getValue());
     numInputs = srcRegion.getNumArguments();
   } else {
     numInputs = op->getNumOperands();
   }
   SmallVector<Attribute, 2> operands(numInputs, nullptr);
   regionInterface.getSuccessorRegions(sourceNo, operands, successors);

   for (RegionSuccessor &succ : successors) {
     Optional<unsigned> succRegionNo;
     if (!succ.isParent())
       succRegionNo = succ.getSuccessor()->getRegionNumber();

     auto printEdgeName = [&](InFlightDiagnostic &diag) -> InFlightDiagnostic & {
       diag << "from ";
       if (sourceNo)
         diag << "Region #" << sourceNo.getValue();
       else
         diag << "parent operands";

       diag << " to ";
       if (succRegionNo)
         diag << "Region #" << succRegionNo.getValue();
       else
         diag << "parent results";
       return diag;
     };

     Optional<TypeRange> sourceTypes = getInputsTypesForRegion(succRegionNo);
     if (!sourceTypes.hasValue())
       continue;

     TypeRange succInputsTypes = succ.getSuccessorInputs().getTypes();
     if (sourceTypes->size() != succInputsTypes.size()) {
       InFlightDiagnostic diag = op->emitOpError(" region control flow edge ");
       return printEdgeName(diag) << ": source has " << sourceTypes->size()
                                  << " operands, but target successor needs "
                                  << succInputsTypes.size();
     }

     for (auto typesIdx :
          llvm::enumerate(llvm::zip(*sourceTypes, succInputsTypes))) {
       Type sourceType = std::get<0>(typesIdx.value());
       Type inputType = std::get<1>(typesIdx.value());
       if (sourceType != inputType) {
         InFlightDiagnostic diag = op->emitOpError(" along control flow edge ");
         return printEdgeName(diag)
                << ": source type #" << typesIdx.index() << " " << sourceType
                << " should match input type #" << typesIdx.index() << " "
                << inputType;
       }
     }
   }
   return success();
 }

 /// Verify that types match along control flow edges described the given op.
 LogicalResult detail::verifyTypesAlongControlFlowEdges(Operation *op) {
   auto regionInterface = cast<RegionBranchOpInterface>(op);

   auto inputTypesFromParent = [&](Optional<unsigned> regionNo) -> TypeRange {
     if (regionNo.hasValue()) {
       return regionInterface.getSuccessorEntryOperands(regionNo.getValue())
           .getTypes();
     }

     // If the successor of a parent op is the parent itself
     // RegionBranchOpInterface does not have an API to query what the entry
     // operands will be in that case. Vend out the result types of the op in
     // that case so that type checking succeeds for this case.
     return op->getResultTypes();
   };

   // Verify types along control flow edges originating from the parent.
   if (failed(verifyTypesAlongAllEdges(op, llvm::None, inputTypesFromParent)))
     return failure();

   // RegionBranchOpInterface should not be implemented by Ops that do not have
   // attached regions.
   assert(op->getNumRegions() != 0);

   // Verify types along control flow edges originating from each region.
   for (unsigned regionNo : llvm::seq(0U, op->getNumRegions())) {
     Region &region = op->getRegion(regionNo);

     // Since there can be multiple `ReturnLike` terminators or others
     // implementing the `RegionBranchTerminatorOpInterface`, all should have the
     // same operand types when passing them to the same region.

     Optional<OperandRange> regionReturnOperands;
     for (Block &block : region) {
       Operation *terminator = block.getTerminator();
       auto terminatorOperands =
           getRegionBranchSuccessorOperands(terminator, regionNo);
       if (!terminatorOperands)
         continue;

       if (!regionReturnOperands) {
         regionReturnOperands = terminatorOperands;
         continue;
       }

       // Found more than one ReturnLike terminator. Make sure the operand types
       // match with the first one.
       if (regionReturnOperands->getTypes() != terminatorOperands->getTypes())
         return op->emitOpError("Region #")
                << regionNo
                << " operands mismatch between return-like terminators";
     }

     auto inputTypesFromRegion =
         [&](Optional<unsigned> regionNo) -> Optional<TypeRange> {
       // If there is no return-like terminator, the op itself should verify
       // type consistency.
       if (!regionReturnOperands)
         return llvm::None;

       // All successors get the same set of operand types.
       return TypeRange(regionReturnOperands->getTypes());
     };

     if (failed(verifyTypesAlongAllEdges(op, regionNo, inputTypesFromRegion)))
       return failure();
   }

   return success();
 }

 /// Return `true` if `a` and `b` are in mutually exclusive regions.
 ///
 /// 1. Find the first common of `a` and `b` (ancestor) that implements
 ///    RegionBranchOpInterface.
 /// 2. Determine the regions `regionA` and `regionB` in which `a` and `b` are
 ///    contained.
 /// 3. Check if `regionA` and `regionB` are mutually exclusive. They are
 ///    mutually exclusive if they are not reachable from each other as per
 ///    RegionBranchOpInterface::getSuccessorRegions.
 bool mlir::insideMutuallyExclusiveRegions(Operation *a, Operation *b) {
   assert(a && "expected non-empty operation");
   assert(b && "expected non-empty operation");

   auto branchOp = a->getParentOfType<RegionBranchOpInterface>();
   while (branchOp) {
     // Check if b is inside branchOp. (We already know that a is.)
     if (!branchOp->isProperAncestor(b)) {
       // Check next enclosing RegionBranchOpInterface.
       branchOp = branchOp->getParentOfType<RegionBranchOpInterface>();
       continue;
     }

     // b is contained in branchOp. Retrieve the regions in which `a` and `b`
     // are contained.
     Region *regionA = nullptr, *regionB = nullptr;
     for (Region &r : branchOp->getRegions()) {
       if (r.findAncestorOpInRegion(*a)) {
         assert(!regionA && "already found a region for a");
         regionA = &r;
       }
       if (r.findAncestorOpInRegion(*b)) {
         assert(!regionB && "already found a region for b");
         regionB = &r;
       }
     }
     assert(regionA && regionB && "could not find region of op");

     // Helper function that checks if region `r` is reachable from region
     // `begin`.
     std::function<bool(Region *, Region *)> isRegionReachable =
         [&](Region *begin, Region *r) {
           if (begin == r)
             return true;
           if (begin == nullptr)
             return false;
           // Compute index of region.
           int64_t beginIndex = -1;
           for (auto it : llvm::enumerate(branchOp->getRegions()))
             if (&it.value() == begin)
               beginIndex = it.index();
           assert(beginIndex != -1 && "could not find region in op");
           // Retrieve all successors of the region.
           SmallVector<RegionSuccessor> successors;
           branchOp.getSuccessorRegions(beginIndex, successors);
           // Call function recursively on all successors.
           for (RegionSuccessor successor : successors)
             if (isRegionReachable(successor.getSuccessor(), r))
               return true;
           return false;
         };

     // `a` and `b` are in mutually exclusive regions if neither region is
     // reachable from the other region.
     return !isRegionReachable(regionA, regionB) &&
            !isRegionReachable(regionB, regionA);
   }

   // Could not find a common RegionBranchOpInterface among a's and b's
   // ancestors.
   return false;
 }

 //===----------------------------------------------------------------------===//
 // RegionBranchTerminatorOpInterface
 //===----------------------------------------------------------------------===//

 /// Returns true if the given operation is either annotated with the
 /// `ReturnLike` trait or implements the `RegionBranchTerminatorOpInterface`.
 bool mlir::isRegionReturnLike(Operation *operation) {
   return dyn_cast<RegionBranchTerminatorOpInterface>(operation) ||
          operation->hasTrait<OpTrait::ReturnLike>();
 }

 /// Returns the mutable operands that are passed to the region with the given
 /// `regionIndex`. If the operation does not implement the
 /// `RegionBranchTerminatorOpInterface` and is not marked as `ReturnLike`, the
 /// result will be `llvm::None`. In all other cases, the resulting
 /// `OperandRange` represents all operands that are passed to the specified
 /// successor region. If `regionIndex` is `llvm::None`, all operands that are
 /// passed to the parent operation will be returned.
 Optional<MutableOperandRange>
 mlir::getMutableRegionBranchSuccessorOperands(Operation *operation,
                                               Optional<unsigned> regionIndex) {
   // Try to query a RegionBranchTerminatorOpInterface to determine
   // all successor operands that will be passed to the successor
   // input arguments.
   if (auto regionTerminatorInterface =
           dyn_cast<RegionBranchTerminatorOpInterface>(operation))
     return regionTerminatorInterface.getMutableSuccessorOperands(regionIndex);

   // TODO: The ReturnLike trait should imply a default implementation of the
   // RegionBranchTerminatorOpInterface. This would make this code significantly
   // easier. Furthermore, this may even make this function obsolete.
   if (operation->hasTrait<OpTrait::ReturnLike>())
     return MutableOperandRange(operation);
   return llvm::None;
 }

 /// Returns the read only operands that are passed to the region with the given
 /// `regionIndex`. See `getMutableRegionBranchSuccessorOperands` for more
 /// information.
 Optional<OperandRange>
 mlir::getRegionBranchSuccessorOperands(Operation *operation,
                                        Optional<unsigned> regionIndex) {
   auto range = getMutableRegionBranchSuccessorOperands(operation, regionIndex);
   return range ? Optional<OperandRange>(*range) : llvm::None;
 }
	//===- ControlFlowInterfaces.cpp - ControlFlow Interfaces -----------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include "mlir/Interfaces/ControlFlowInterfaces.h"
	#include "mlir/IR/BuiltinTypes.h"
	#include "llvm/ADT/SmallPtrSet.h"

	using namespace mlir;

	//===----------------------------------------------------------------------===//
	// ControlFlowInterfaces
	//===----------------------------------------------------------------------===//

	#include "mlir/Interfaces/ControlFlowInterfaces.cpp.inc"

	//===----------------------------------------------------------------------===//
	// BranchOpInterface
	//===----------------------------------------------------------------------===//

	/// Returns the `BlockArgument` corresponding to operand `operandIndex` in some
	/// successor if 'operandIndex' is within the range of 'operands', or None if
	/// `operandIndex` isn't a successor operand index.
	Optional<BlockArgument>
	detail::getBranchSuccessorArgument(Optional<OperandRange> operands,
	unsigned operandIndex, Block *successor) {
	// Check that the operands are valid.
	if (!operands \|\| operands->empty())
	return llvm::None;

	// Check to ensure that this operand is within the range.
	unsigned operandsStart = operands->getBeginOperandIndex();
	if (operandIndex < operandsStart \|\|
	operandIndex >= (operandsStart + operands->size()))
	return llvm::None;

	// Index the successor.
	unsigned argIndex = operandIndex - operandsStart;
	return successor->getArgument(argIndex);
	}

	/// Verify that the given operands match those of the given successor block.
	LogicalResult
	detail::verifyBranchSuccessorOperands(Operation *op, unsigned succNo,
	Optional<OperandRange> operands) {
	if (!operands)
	return success();

	// Check the count.
	unsigned operandCount = operands->size();
	Block *destBB = op->getSuccessor(succNo);
	if (operandCount != destBB->getNumArguments())
	return op->emitError() << "branch has " << operandCount
	<< " operands for successor #" << succNo
	<< ", but target block has "
	<< destBB->getNumArguments();

	// Check the types.
	auto operandIt = operands->begin();
	for (unsigned i = 0; i != operandCount; ++i, ++operandIt) {
	if ((*operandIt).getType() != destBB->getArgument(i).getType())
	return op->emitError() << "type mismatch for bb argument #" << i
	<< " of successor #" << succNo;
	}
	return success();
	}

	//===----------------------------------------------------------------------===//
	// RegionBranchOpInterface
	//===----------------------------------------------------------------------===//

	// A constant value to represent unknown number of region invocations.
	const int64_t mlir::kUnknownNumRegionInvocations = -1;

	/// Verify that types match along all region control flow edges originating from
	/// `sourceNo` (region # if source is a region, llvm::None if source is parent
	/// op). `getInputsTypesForRegion` is a function that returns the types of the
	/// inputs that flow from `sourceIndex' to the given region, or llvm::None if
	/// the exact type match verification is not necessary (e.g., if the Op verifies
	/// the match itself).
	static LogicalResult
	verifyTypesAlongAllEdges(Operation *op, Optional<unsigned> sourceNo,
	function_ref<Optional<TypeRange>(Optional<unsigned>)>
	getInputsTypesForRegion) {
	auto regionInterface = cast<RegionBranchOpInterface>(op);

	SmallVector<RegionSuccessor, 2> successors;
	unsigned numInputs;
	if (sourceNo) {
	Region &srcRegion = op->getRegion(sourceNo.getValue());
	numInputs = srcRegion.getNumArguments();
	} else {
	numInputs = op->getNumOperands();
	}
	SmallVector<Attribute, 2> operands(numInputs, nullptr);
	regionInterface.getSuccessorRegions(sourceNo, operands, successors);

	for (RegionSuccessor &succ : successors) {
	Optional<unsigned> succRegionNo;
	if (!succ.isParent())
	succRegionNo = succ.getSuccessor()->getRegionNumber();

	auto printEdgeName = [&](InFlightDiagnostic &diag) -> InFlightDiagnostic & {
	diag << "from ";
	if (sourceNo)
	diag << "Region #" << sourceNo.getValue();
	else
	diag << "parent operands";

	diag << " to ";
	if (succRegionNo)
	diag << "Region #" << succRegionNo.getValue();
	else
	diag << "parent results";
	return diag;
	};

	Optional<TypeRange> sourceTypes = getInputsTypesForRegion(succRegionNo);
	if (!sourceTypes.hasValue())
	continue;

	TypeRange succInputsTypes = succ.getSuccessorInputs().getTypes();
	if (sourceTypes->size() != succInputsTypes.size()) {
	InFlightDiagnostic diag = op->emitOpError(" region control flow edge ");
	return printEdgeName(diag) << ": source has " << sourceTypes->size()
	<< " operands, but target successor needs "
	<< succInputsTypes.size();
	}

	for (auto typesIdx :
	llvm::enumerate(llvm::zip(*sourceTypes, succInputsTypes))) {
	Type sourceType = std::get<0>(typesIdx.value());
	Type inputType = std::get<1>(typesIdx.value());
	if (sourceType != inputType) {
	InFlightDiagnostic diag = op->emitOpError(" along control flow edge ");
	return printEdgeName(diag)
	<< ": source type #" << typesIdx.index() << " " << sourceType
	<< " should match input type #" << typesIdx.index() << " "
	<< inputType;
	}
	}
	}
	return success();
	}

	/// Verify that types match along control flow edges described the given op.
	LogicalResult detail::verifyTypesAlongControlFlowEdges(Operation *op) {
	auto regionInterface = cast<RegionBranchOpInterface>(op);

	auto inputTypesFromParent = [&](Optional<unsigned> regionNo) -> TypeRange {
	if (regionNo.hasValue()) {
	return regionInterface.getSuccessorEntryOperands(regionNo.getValue())
	.getTypes();
	}

	// If the successor of a parent op is the parent itself
	// RegionBranchOpInterface does not have an API to query what the entry
	// operands will be in that case. Vend out the result types of the op in
	// that case so that type checking succeeds for this case.
	return op->getResultTypes();
	};

	// Verify types along control flow edges originating from the parent.
	if (failed(verifyTypesAlongAllEdges(op, llvm::None, inputTypesFromParent)))
	return failure();

	// RegionBranchOpInterface should not be implemented by Ops that do not have
	// attached regions.
	assert(op->getNumRegions() != 0);

	// Verify types along control flow edges originating from each region.
	for (unsigned regionNo : llvm::seq(0U, op->getNumRegions())) {
	Region &region = op->getRegion(regionNo);

	// Since there can be multiple `ReturnLike` terminators or others
	// implementing the `RegionBranchTerminatorOpInterface`, all should have the
	// same operand types when passing them to the same region.

	Optional<OperandRange> regionReturnOperands;
	for (Block &block : region) {
	Operation *terminator = block.getTerminator();
	auto terminatorOperands =
	getRegionBranchSuccessorOperands(terminator, regionNo);
	if (!terminatorOperands)
	continue;

	if (!regionReturnOperands) {
	regionReturnOperands = terminatorOperands;
	continue;
	}

	// Found more than one ReturnLike terminator. Make sure the operand types
	// match with the first one.
	if (regionReturnOperands->getTypes() != terminatorOperands->getTypes())
	return op->emitOpError("Region #")
	<< regionNo
	<< " operands mismatch between return-like terminators";
	}

	auto inputTypesFromRegion =
	[&](Optional<unsigned> regionNo) -> Optional<TypeRange> {
	// If there is no return-like terminator, the op itself should verify
	// type consistency.
	if (!regionReturnOperands)
	return llvm::None;

	// All successors get the same set of operand types.
	return TypeRange(regionReturnOperands->getTypes());
	};

	if (failed(verifyTypesAlongAllEdges(op, regionNo, inputTypesFromRegion)))
	return failure();
	}

	return success();
	}

	/// Return `true` if `a` and `b` are in mutually exclusive regions.
	///
	/// 1. Find the first common of `a` and `b` (ancestor) that implements
	/// RegionBranchOpInterface.
	/// 2. Determine the regions `regionA` and `regionB` in which `a` and `b` are
	/// contained.
	/// 3. Check if `regionA` and `regionB` are mutually exclusive. They are
	/// mutually exclusive if they are not reachable from each other as per
	/// RegionBranchOpInterface::getSuccessorRegions.
	bool mlir::insideMutuallyExclusiveRegions(Operation a, Operation b) {
	assert(a && "expected non-empty operation");
	assert(b && "expected non-empty operation");

	auto branchOp = a->getParentOfType<RegionBranchOpInterface>();
	while (branchOp) {
	// Check if b is inside branchOp. (We already know that a is.)
	if (!branchOp->isProperAncestor(b)) {
	// Check next enclosing RegionBranchOpInterface.
	branchOp = branchOp->getParentOfType<RegionBranchOpInterface>();
	continue;
	}

	// b is contained in branchOp. Retrieve the regions in which `a` and `b`
	// are contained.
	Region regionA = nullptr, regionB = nullptr;
	for (Region &r : branchOp->getRegions()) {
	if (r.findAncestorOpInRegion(*a)) {
	assert(!regionA && "already found a region for a");
	regionA = &r;
	}
	if (r.findAncestorOpInRegion(*b)) {
	assert(!regionB && "already found a region for b");
	regionB = &r;
	}
	}
	assert(regionA && regionB && "could not find region of op");

	// Helper function that checks if region `r` is reachable from region
	// `begin`.
	std::function<bool(Region , Region )> isRegionReachable =
	[&](Region begin, Region r) {
	if (begin == r)
	return true;
	if (begin == nullptr)
	return false;
	// Compute index of region.
	int64_t beginIndex = -1;
	for (auto it : llvm::enumerate(branchOp->getRegions()))
	if (&it.value() == begin)
	beginIndex = it.index();
	assert(beginIndex != -1 && "could not find region in op");
	// Retrieve all successors of the region.
	SmallVector<RegionSuccessor> successors;
	branchOp.getSuccessorRegions(beginIndex, successors);
	// Call function recursively on all successors.
	for (RegionSuccessor successor : successors)
	if (isRegionReachable(successor.getSuccessor(), r))
	return true;
	return false;
	};

	// `a` and `b` are in mutually exclusive regions if neither region is
	// reachable from the other region.
	return !isRegionReachable(regionA, regionB) &&
	!isRegionReachable(regionB, regionA);
	}

	// Could not find a common RegionBranchOpInterface among a's and b's
	// ancestors.
	return false;
	}

	//===----------------------------------------------------------------------===//
	// RegionBranchTerminatorOpInterface
	//===----------------------------------------------------------------------===//

	/// Returns true if the given operation is either annotated with the
	/// `ReturnLike` trait or implements the `RegionBranchTerminatorOpInterface`.
	bool mlir::isRegionReturnLike(Operation *operation) {
	return dyn_cast<RegionBranchTerminatorOpInterface>(operation) \|\|
	operation->hasTrait<OpTrait::ReturnLike>();
	}

	/// Returns the mutable operands that are passed to the region with the given
	/// `regionIndex`. If the operation does not implement the
	/// `RegionBranchTerminatorOpInterface` and is not marked as `ReturnLike`, the
	/// result will be `llvm::None`. In all other cases, the resulting
	/// `OperandRange` represents all operands that are passed to the specified
	/// successor region. If `regionIndex` is `llvm::None`, all operands that are
	/// passed to the parent operation will be returned.
	Optional<MutableOperandRange>
	mlir::getMutableRegionBranchSuccessorOperands(Operation *operation,
	Optional<unsigned> regionIndex) {
	// Try to query a RegionBranchTerminatorOpInterface to determine
	// all successor operands that will be passed to the successor
	// input arguments.
	if (auto regionTerminatorInterface =
	dyn_cast<RegionBranchTerminatorOpInterface>(operation))
	return regionTerminatorInterface.getMutableSuccessorOperands(regionIndex);

	// TODO: The ReturnLike trait should imply a default implementation of the
	// RegionBranchTerminatorOpInterface. This would make this code significantly
	// easier. Furthermore, this may even make this function obsolete.
	if (operation->hasTrait<OpTrait::ReturnLike>())
	return MutableOperandRange(operation);
	return llvm::None;
	}

	/// Returns the read only operands that are passed to the region with the given
	/// `regionIndex`. See `getMutableRegionBranchSuccessorOperands` for more
	/// information.
	Optional<OperandRange>
	mlir::getRegionBranchSuccessorOperands(Operation *operation,
	Optional<unsigned> regionIndex) {
	auto range = getMutableRegionBranchSuccessorOperands(operation, regionIndex);
	return range ? Optional<OperandRange>(*range) : llvm::None;
	}