mlir/lib/IR/Block.cpp - llvm-project - Git at Google

 //===- Block.cpp - MLIR Block Class ---------------------------------------===//
 //
 // 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/IR/Block.h"
 #include "mlir/IR/Builders.h"
 #include "mlir/IR/Operation.h"
 #include "llvm/ADT/BitVector.h"
 using namespace mlir;

 //===----------------------------------------------------------------------===//
 // Block
 //===----------------------------------------------------------------------===//

 Block::~Block() {
   assert(!verifyOpOrder() && "Expected valid operation ordering.");
   clear();
   for (BlockArgument arg : arguments)
     arg.destroy();
 }

 Region *Block::getParent() const { return parentValidOpOrderPair.getPointer(); }

 /// Returns the closest surrounding operation that contains this block or
 /// nullptr if this block is unlinked.
 Operation *Block::getParentOp() {
   return getParent() ? getParent()->getParentOp() : nullptr;
 }

 /// Return if this block is the entry block in the parent region.
 bool Block::isEntryBlock() { return this == &getParent()->front(); }

 /// Insert this block (which must not already be in a region) right before the
 /// specified block.
 void Block::insertBefore(Block *block) {
   assert(!getParent() && "already inserted into a block!");
   assert(block->getParent() && "cannot insert before a block without a parent");
   block->getParent()->getBlocks().insert(block->getIterator(), this);
 }

 /// Unlink this block from its current region and insert it right before the
 /// specific block.
 void Block::moveBefore(Block *block) {
   assert(block->getParent() && "cannot insert before a block without a parent");
   block->getParent()->getBlocks().splice(
       block->getIterator(), getParent()->getBlocks(), getIterator());
 }

 /// Unlink this Block from its parent Region and delete it.
 void Block::erase() {
   assert(getParent() && "Block has no parent");
   getParent()->getBlocks().erase(this);
 }

 /// Returns 'op' if 'op' lies in this block, or otherwise finds the
 /// ancestor operation of 'op' that lies in this block. Returns nullptr if
 /// the latter fails.
 Operation *Block::findAncestorOpInBlock(Operation &op) {
   // Traverse up the operation hierarchy starting from the owner of operand to
   // find the ancestor operation that resides in the block of 'forOp'.
   auto *currOp = &op;
   while (currOp->getBlock() != this) {
     currOp = currOp->getParentOp();
     if (!currOp)
       return nullptr;
   }
   return currOp;
 }

 /// This drops all operand uses from operations within this block, which is
 /// an essential step in breaking cyclic dependences between references when
 /// they are to be deleted.
 void Block::dropAllReferences() {
   for (Operation &i : *this)
     i.dropAllReferences();
 }

 void Block::dropAllDefinedValueUses() {
   for (auto arg : getArguments())
     arg.dropAllUses();
   for (auto &op : *this)
     op.dropAllDefinedValueUses();
   dropAllUses();
 }

 /// Returns true if the ordering of the child operations is valid, false
 /// otherwise.
 bool Block::isOpOrderValid() { return parentValidOpOrderPair.getInt(); }

 /// Invalidates the current ordering of operations.
 void Block::invalidateOpOrder() {
   // Validate the current ordering.
   assert(!verifyOpOrder());
   parentValidOpOrderPair.setInt(false);
 }

 /// Verifies the current ordering of child operations. Returns false if the
 /// order is valid, true otherwise.
 bool Block::verifyOpOrder() {
   // The order is already known to be invalid.
   if (!isOpOrderValid())
     return false;
   // The order is valid if there are less than 2 operations.
   if (operations.empty() || std::next(operations.begin()) == operations.end())
     return false;

   Operation *prev = nullptr;
   for (auto &i : *this) {
     // The previous operation must have a smaller order index than the next as
     // it appears earlier in the list.
     if (prev && prev->orderIndex != Operation::kInvalidOrderIdx &&
         prev->orderIndex >= i.orderIndex)
       return true;
     prev = &i;
   }
   return false;
 }

 /// Recomputes the ordering of child operations within the block.
 void Block::recomputeOpOrder() {
   parentValidOpOrderPair.setInt(true);

   unsigned orderIndex = 0;
   for (auto &op : *this)
     op.orderIndex = (orderIndex += Operation::kOrderStride);
 }

 //===----------------------------------------------------------------------===//
 // Argument list management.
 //===----------------------------------------------------------------------===//

 /// Return a range containing the types of the arguments for this block.
 auto Block::getArgumentTypes() -> ValueTypeRange<BlockArgListType> {
   return ValueTypeRange<BlockArgListType>(getArguments());
 }

 BlockArgument Block::addArgument(Type type, Optional<Location> loc) {
   // TODO: Require locations for BlockArguments.
   if (!loc.hasValue()) {
     // Use the location of the parent operation if the block is attached.
     if (Operation *parentOp = getParentOp())
       loc = parentOp->getLoc();
     else
       loc = UnknownLoc::get(type.getContext());
   }

   BlockArgument arg = BlockArgument::create(type, this, arguments.size(), *loc);
   arguments.push_back(arg);
   return arg;
 }

 /// Add one argument to the argument list for each type specified in the list.
 auto Block::addArguments(TypeRange types, ArrayRef<Location> locs)
     -> iterator_range<args_iterator> {
   // TODO: Require locations for BlockArguments.
   assert((locs.empty() || types.size() == locs.size()) &&
          "incorrect number of block argument locations");
   size_t initialSize = arguments.size();

   arguments.reserve(initialSize + types.size());

   // TODO: Require locations for BlockArguments.
   if (locs.empty()) {
     for (auto type : types)
       addArgument(type);
   } else {
     for (auto typeAndLoc : llvm::zip(types, locs))
       addArgument(std::get<0>(typeAndLoc), std::get<1>(typeAndLoc));
   }
   return {arguments.data() + initialSize, arguments.data() + arguments.size()};
 }

 BlockArgument Block::insertArgument(unsigned index, Type type,
                                     Optional<Location> loc) {
   // TODO: Require locations for BlockArguments.
   if (!loc.hasValue()) {
     // Use the location of the parent operation if the block is attached.
     if (Operation *parentOp = getParentOp())
       loc = parentOp->getLoc();
     else
       loc = UnknownLoc::get(type.getContext());
   }

   auto arg = BlockArgument::create(type, this, index, *loc);
   assert(index <= arguments.size());
   arguments.insert(arguments.begin() + index, arg);
   // Update the cached position for all the arguments after the newly inserted
   // one.
   ++index;
   for (BlockArgument arg : llvm::drop_begin(arguments, index))
     arg.setArgNumber(index++);
   return arg;
 }

 /// Insert one value to the given position of the argument list. The existing
 /// arguments are shifted. The block is expected not to have predecessors.
 BlockArgument Block::insertArgument(args_iterator it, Type type,
                                     Optional<Location> loc) {
   assert(llvm::empty(getPredecessors()) &&
          "cannot insert arguments to blocks with predecessors");
   return insertArgument(it->getArgNumber(), type, loc);
 }

 void Block::eraseArgument(unsigned index) {
   assert(index < arguments.size());
   arguments[index].destroy();
   arguments.erase(arguments.begin() + index);
   for (BlockArgument arg : llvm::drop_begin(arguments, index))
     arg.setArgNumber(index++);
 }

 void Block::eraseArguments(ArrayRef<unsigned> argIndices) {
   llvm::BitVector eraseIndices(getNumArguments());
   for (unsigned i : argIndices)
     eraseIndices.set(i);
   eraseArguments(eraseIndices);
 }

 void Block::eraseArguments(const llvm::BitVector &eraseIndices) {
   eraseArguments(
       [&](BlockArgument arg) { return eraseIndices.test(arg.getArgNumber()); });
 }

 void Block::eraseArguments(function_ref<bool(BlockArgument)> shouldEraseFn) {
   auto firstDead = llvm::find_if(arguments, shouldEraseFn);
   if (firstDead == arguments.end())
     return;

   // Destroy the first dead argument, this avoids reapplying the predicate to
   // it.
   unsigned index = firstDead->getArgNumber();
   firstDead->destroy();

   // Iterate the remaining arguments to remove any that are now dead.
   for (auto it = std::next(firstDead), e = arguments.end(); it != e; ++it) {
     // Destroy dead arguments, and shift those that are still live.
     if (shouldEraseFn(*it)) {
       it->destroy();
     } else {
       it->setArgNumber(index++);
       *firstDead++ = *it;
     }
   }
   arguments.erase(firstDead, arguments.end());
 }

 //===----------------------------------------------------------------------===//
 // Terminator management
 //===----------------------------------------------------------------------===//

 /// Get the terminator operation of this block. This function asserts that
 /// the block has a valid terminator operation.
 Operation *Block::getTerminator() {
   assert(!empty() && back().mightHaveTrait<OpTrait::IsTerminator>());
   return &back();
 }

 // Indexed successor access.
 unsigned Block::getNumSuccessors() {
   return empty() ? 0 : back().getNumSuccessors();
 }

 Block *Block::getSuccessor(unsigned i) {
   assert(i < getNumSuccessors());
   return getTerminator()->getSuccessor(i);
 }

 /// If this block has exactly one predecessor, return it.  Otherwise, return
 /// null.
 ///
 /// Note that multiple edges from a single block (e.g. if you have a cond
 /// branch with the same block as the true/false destinations) is not
 /// considered to be a single predecessor.
 Block *Block::getSinglePredecessor() {
   auto it = pred_begin();
   if (it == pred_end())
     return nullptr;
   auto *firstPred = *it;
   ++it;
   return it == pred_end() ? firstPred : nullptr;
 }

 /// If this block has a unique predecessor, i.e., all incoming edges originate
 /// from one block, return it. Otherwise, return null.
 Block *Block::getUniquePredecessor() {
   auto it = pred_begin(), e = pred_end();
   if (it == e)
     return nullptr;

   // Check for any conflicting predecessors.
   auto *firstPred = *it;
   for (++it; it != e; ++it)
     if (*it != firstPred)
       return nullptr;
   return firstPred;
 }

 //===----------------------------------------------------------------------===//
 // Other
 //===----------------------------------------------------------------------===//

 /// Split the block into two blocks before the specified operation or
 /// iterator.
 ///
 /// Note that all operations BEFORE the specified iterator stay as part of
 /// the original basic block, and the rest of the operations in the original
 /// block are moved to the new block, including the old terminator.  The
 /// original block is left without a terminator.
 ///
 /// The newly formed Block is returned, and the specified iterator is
 /// invalidated.
 Block *Block::splitBlock(iterator splitBefore) {
   // Start by creating a new basic block, and insert it immediate after this
   // one in the containing region.
   auto newBB = new Block();
   getParent()->getBlocks().insert(std::next(Region::iterator(this)), newBB);

   // Move all of the operations from the split point to the end of the region
   // into the new block.
   newBB->getOperations().splice(newBB->end(), getOperations(), splitBefore,
                                 end());
   return newBB;
 }

 //===----------------------------------------------------------------------===//
 // Predecessors
 //===----------------------------------------------------------------------===//

 Block *PredecessorIterator::unwrap(BlockOperand &value) {
   return value.getOwner()->getBlock();
 }

 /// Get the successor number in the predecessor terminator.
 unsigned PredecessorIterator::getSuccessorIndex() const {
   return I->getOperandNumber();
 }

 //===----------------------------------------------------------------------===//
 // SuccessorRange
 //===----------------------------------------------------------------------===//

 SuccessorRange::SuccessorRange() : SuccessorRange(nullptr, 0) {}

 SuccessorRange::SuccessorRange(Block *block) : SuccessorRange() {
  if (block->empty() || llvm::hasSingleElement(*block->getParent()))
   return;
  Operation *term = &block->back();
  if ((count = term->getNumSuccessors()))
    base = term->getBlockOperands().data();
 }

 SuccessorRange::SuccessorRange(Operation *term) : SuccessorRange() {
   if ((count = term->getNumSuccessors()))
     base = term->getBlockOperands().data();
 }

 //===----------------------------------------------------------------------===//
 // BlockRange
 //===----------------------------------------------------------------------===//

 BlockRange::BlockRange(ArrayRef<Block *> blocks) : BlockRange(nullptr, 0) {
   if ((count = blocks.size()))
     base = blocks.data();
 }

 BlockRange::BlockRange(SuccessorRange successors)
     : BlockRange(successors.begin().getBase(), successors.size()) {}

 /// See `llvm::detail::indexed_accessor_range_base` for details.
 BlockRange::OwnerT BlockRange::offset_base(OwnerT object, ptrdiff_t index) {
   if (auto *operand = object.dyn_cast<BlockOperand *>())
     return {operand + index};
   return {object.dyn_cast<Block *const *>() + index};
 }

 /// See `llvm::detail::indexed_accessor_range_base` for details.
 Block *BlockRange::dereference_iterator(OwnerT object, ptrdiff_t index) {
   if (const auto *operand = object.dyn_cast<BlockOperand *>())
     return operand[index].get();
   return object.dyn_cast<Block *const *>()[index];
 }
	//===- Block.cpp - MLIR Block Class ---------------------------------------===//
	//
	// 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/IR/Block.h"
	#include "mlir/IR/Builders.h"
	#include "mlir/IR/Operation.h"
	#include "llvm/ADT/BitVector.h"
	using namespace mlir;

	//===----------------------------------------------------------------------===//
	// Block
	//===----------------------------------------------------------------------===//

	Block::~Block() {
	assert(!verifyOpOrder() && "Expected valid operation ordering.");
	clear();
	for (BlockArgument arg : arguments)
	arg.destroy();
	}

	Region *Block::getParent() const { return parentValidOpOrderPair.getPointer(); }

	/// Returns the closest surrounding operation that contains this block or
	/// nullptr if this block is unlinked.
	Operation *Block::getParentOp() {
	return getParent() ? getParent()->getParentOp() : nullptr;
	}

	/// Return if this block is the entry block in the parent region.
	bool Block::isEntryBlock() { return this == &getParent()->front(); }

	/// Insert this block (which must not already be in a region) right before the
	/// specified block.
	void Block::insertBefore(Block *block) {
	assert(!getParent() && "already inserted into a block!");
	assert(block->getParent() && "cannot insert before a block without a parent");
	block->getParent()->getBlocks().insert(block->getIterator(), this);
	}

	/// Unlink this block from its current region and insert it right before the
	/// specific block.
	void Block::moveBefore(Block *block) {
	assert(block->getParent() && "cannot insert before a block without a parent");
	block->getParent()->getBlocks().splice(
	block->getIterator(), getParent()->getBlocks(), getIterator());
	}

	/// Unlink this Block from its parent Region and delete it.
	void Block::erase() {
	assert(getParent() && "Block has no parent");
	getParent()->getBlocks().erase(this);
	}

	/// Returns 'op' if 'op' lies in this block, or otherwise finds the
	/// ancestor operation of 'op' that lies in this block. Returns nullptr if
	/// the latter fails.
	Operation *Block::findAncestorOpInBlock(Operation &op) {
	// Traverse up the operation hierarchy starting from the owner of operand to
	// find the ancestor operation that resides in the block of 'forOp'.
	auto *currOp = &op;
	while (currOp->getBlock() != this) {
	currOp = currOp->getParentOp();
	if (!currOp)
	return nullptr;
	}
	return currOp;
	}

	/// This drops all operand uses from operations within this block, which is
	/// an essential step in breaking cyclic dependences between references when
	/// they are to be deleted.
	void Block::dropAllReferences() {
	for (Operation &i : *this)
	i.dropAllReferences();
	}

	void Block::dropAllDefinedValueUses() {
	for (auto arg : getArguments())
	arg.dropAllUses();
	for (auto &op : *this)
	op.dropAllDefinedValueUses();
	dropAllUses();
	}

	/// Returns true if the ordering of the child operations is valid, false
	/// otherwise.
	bool Block::isOpOrderValid() { return parentValidOpOrderPair.getInt(); }

	/// Invalidates the current ordering of operations.
	void Block::invalidateOpOrder() {
	// Validate the current ordering.
	assert(!verifyOpOrder());
	parentValidOpOrderPair.setInt(false);
	}

	/// Verifies the current ordering of child operations. Returns false if the
	/// order is valid, true otherwise.
	bool Block::verifyOpOrder() {
	// The order is already known to be invalid.
	if (!isOpOrderValid())
	return false;
	// The order is valid if there are less than 2 operations.
	if (operations.empty() \|\| std::next(operations.begin()) == operations.end())
	return false;

	Operation *prev = nullptr;
	for (auto &i : *this) {
	// The previous operation must have a smaller order index than the next as
	// it appears earlier in the list.
	if (prev && prev->orderIndex != Operation::kInvalidOrderIdx &&
	prev->orderIndex >= i.orderIndex)
	return true;
	prev = &i;
	}
	return false;
	}

	/// Recomputes the ordering of child operations within the block.
	void Block::recomputeOpOrder() {
	parentValidOpOrderPair.setInt(true);

	unsigned orderIndex = 0;
	for (auto &op : *this)
	op.orderIndex = (orderIndex += Operation::kOrderStride);
	}

	//===----------------------------------------------------------------------===//
	// Argument list management.
	//===----------------------------------------------------------------------===//

	/// Return a range containing the types of the arguments for this block.
	auto Block::getArgumentTypes() -> ValueTypeRange<BlockArgListType> {
	return ValueTypeRange<BlockArgListType>(getArguments());
	}

	BlockArgument Block::addArgument(Type type, Optional<Location> loc) {
	// TODO: Require locations for BlockArguments.
	if (!loc.hasValue()) {
	// Use the location of the parent operation if the block is attached.
	if (Operation *parentOp = getParentOp())
	loc = parentOp->getLoc();
	else
	loc = UnknownLoc::get(type.getContext());
	}

	BlockArgument arg = BlockArgument::create(type, this, arguments.size(), *loc);
	arguments.push_back(arg);
	return arg;
	}

	/// Add one argument to the argument list for each type specified in the list.
	auto Block::addArguments(TypeRange types, ArrayRef<Location> locs)
	-> iterator_range<args_iterator> {
	// TODO: Require locations for BlockArguments.
	assert((locs.empty() \|\| types.size() == locs.size()) &&
	"incorrect number of block argument locations");
	size_t initialSize = arguments.size();

	arguments.reserve(initialSize + types.size());

	// TODO: Require locations for BlockArguments.
	if (locs.empty()) {
	for (auto type : types)
	addArgument(type);
	} else {
	for (auto typeAndLoc : llvm::zip(types, locs))
	addArgument(std::get<0>(typeAndLoc), std::get<1>(typeAndLoc));
	}
	return {arguments.data() + initialSize, arguments.data() + arguments.size()};
	}

	BlockArgument Block::insertArgument(unsigned index, Type type,
	Optional<Location> loc) {
	// TODO: Require locations for BlockArguments.
	if (!loc.hasValue()) {
	// Use the location of the parent operation if the block is attached.
	if (Operation *parentOp = getParentOp())
	loc = parentOp->getLoc();
	else
	loc = UnknownLoc::get(type.getContext());
	}

	auto arg = BlockArgument::create(type, this, index, *loc);
	assert(index <= arguments.size());
	arguments.insert(arguments.begin() + index, arg);
	// Update the cached position for all the arguments after the newly inserted
	// one.
	++index;
	for (BlockArgument arg : llvm::drop_begin(arguments, index))
	arg.setArgNumber(index++);
	return arg;
	}

	/// Insert one value to the given position of the argument list. The existing
	/// arguments are shifted. The block is expected not to have predecessors.
	BlockArgument Block::insertArgument(args_iterator it, Type type,
	Optional<Location> loc) {
	assert(llvm::empty(getPredecessors()) &&
	"cannot insert arguments to blocks with predecessors");
	return insertArgument(it->getArgNumber(), type, loc);
	}

	void Block::eraseArgument(unsigned index) {
	assert(index < arguments.size());
	arguments[index].destroy();
	arguments.erase(arguments.begin() + index);
	for (BlockArgument arg : llvm::drop_begin(arguments, index))
	arg.setArgNumber(index++);
	}

	void Block::eraseArguments(ArrayRef<unsigned> argIndices) {
	llvm::BitVector eraseIndices(getNumArguments());
	for (unsigned i : argIndices)
	eraseIndices.set(i);
	eraseArguments(eraseIndices);
	}

	void Block::eraseArguments(const llvm::BitVector &eraseIndices) {
	eraseArguments(
	[&](BlockArgument arg) { return eraseIndices.test(arg.getArgNumber()); });
	}

	void Block::eraseArguments(function_ref<bool(BlockArgument)> shouldEraseFn) {
	auto firstDead = llvm::find_if(arguments, shouldEraseFn);
	if (firstDead == arguments.end())
	return;

	// Destroy the first dead argument, this avoids reapplying the predicate to
	// it.
	unsigned index = firstDead->getArgNumber();
	firstDead->destroy();

	// Iterate the remaining arguments to remove any that are now dead.
	for (auto it = std::next(firstDead), e = arguments.end(); it != e; ++it) {
	// Destroy dead arguments, and shift those that are still live.
	if (shouldEraseFn(*it)) {
	it->destroy();
	} else {
	it->setArgNumber(index++);
	firstDead++ = it;
	}
	}
	arguments.erase(firstDead, arguments.end());
	}

	//===----------------------------------------------------------------------===//
	// Terminator management
	//===----------------------------------------------------------------------===//

	/// Get the terminator operation of this block. This function asserts that
	/// the block has a valid terminator operation.
	Operation *Block::getTerminator() {
	assert(!empty() && back().mightHaveTrait<OpTrait::IsTerminator>());
	return &back();
	}

	// Indexed successor access.
	unsigned Block::getNumSuccessors() {
	return empty() ? 0 : back().getNumSuccessors();
	}

	Block *Block::getSuccessor(unsigned i) {
	assert(i < getNumSuccessors());
	return getTerminator()->getSuccessor(i);
	}

	/// If this block has exactly one predecessor, return it. Otherwise, return
	/// null.
	///
	/// Note that multiple edges from a single block (e.g. if you have a cond
	/// branch with the same block as the true/false destinations) is not
	/// considered to be a single predecessor.
	Block *Block::getSinglePredecessor() {
	auto it = pred_begin();
	if (it == pred_end())
	return nullptr;
	auto firstPred = it;
	++it;
	return it == pred_end() ? firstPred : nullptr;
	}

	/// If this block has a unique predecessor, i.e., all incoming edges originate
	/// from one block, return it. Otherwise, return null.
	Block *Block::getUniquePredecessor() {
	auto it = pred_begin(), e = pred_end();
	if (it == e)
	return nullptr;

	// Check for any conflicting predecessors.
	auto firstPred = it;
	for (++it; it != e; ++it)
	if (*it != firstPred)
	return nullptr;
	return firstPred;
	}

	//===----------------------------------------------------------------------===//
	// Other
	//===----------------------------------------------------------------------===//

	/// Split the block into two blocks before the specified operation or
	/// iterator.
	///
	/// Note that all operations BEFORE the specified iterator stay as part of
	/// the original basic block, and the rest of the operations in the original
	/// block are moved to the new block, including the old terminator. The
	/// original block is left without a terminator.
	///
	/// The newly formed Block is returned, and the specified iterator is
	/// invalidated.
	Block *Block::splitBlock(iterator splitBefore) {
	// Start by creating a new basic block, and insert it immediate after this
	// one in the containing region.
	auto newBB = new Block();
	getParent()->getBlocks().insert(std::next(Region::iterator(this)), newBB);

	// Move all of the operations from the split point to the end of the region
	// into the new block.
	newBB->getOperations().splice(newBB->end(), getOperations(), splitBefore,
	end());
	return newBB;
	}

	//===----------------------------------------------------------------------===//
	// Predecessors
	//===----------------------------------------------------------------------===//

	Block *PredecessorIterator::unwrap(BlockOperand &value) {
	return value.getOwner()->getBlock();
	}

	/// Get the successor number in the predecessor terminator.
	unsigned PredecessorIterator::getSuccessorIndex() const {
	return I->getOperandNumber();
	}

	//===----------------------------------------------------------------------===//
	// SuccessorRange
	//===----------------------------------------------------------------------===//

	SuccessorRange::SuccessorRange() : SuccessorRange(nullptr, 0) {}

	SuccessorRange::SuccessorRange(Block *block) : SuccessorRange() {
	if (block->empty() \|\| llvm::hasSingleElement(*block->getParent()))
	return;
	Operation *term = &block->back();
	if ((count = term->getNumSuccessors()))
	base = term->getBlockOperands().data();
	}

	SuccessorRange::SuccessorRange(Operation *term) : SuccessorRange() {
	if ((count = term->getNumSuccessors()))
	base = term->getBlockOperands().data();
	}

	//===----------------------------------------------------------------------===//
	// BlockRange
	//===----------------------------------------------------------------------===//

	BlockRange::BlockRange(ArrayRef<Block *> blocks) : BlockRange(nullptr, 0) {
	if ((count = blocks.size()))
	base = blocks.data();
	}

	BlockRange::BlockRange(SuccessorRange successors)
	: BlockRange(successors.begin().getBase(), successors.size()) {}

	/// See `llvm::detail::indexed_accessor_range_base` for details.
	BlockRange::OwnerT BlockRange::offset_base(OwnerT object, ptrdiff_t index) {
	if (auto operand = object.dyn_cast<BlockOperand >())
	return {operand + index};
	return {object.dyn_cast<Block const >() + index};
	}

	/// See `llvm::detail::indexed_accessor_range_base` for details.
	Block *BlockRange::dereference_iterator(OwnerT object, ptrdiff_t index) {
	if (const auto operand = object.dyn_cast<BlockOperand >())
	return operand[index].get();
	return object.dyn_cast<Block const >()[index];
	}