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

 //===- Dominance.cpp - Dominator analysis for CFGs ------------------------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//
 //
 // Implementation of dominance related classes and instantiations of extern
 // templates.
 //
 //===----------------------------------------------------------------------===//

 #include "mlir/IR/Dominance.h"
 #include "mlir/IR/Operation.h"
 #include "mlir/IR/RegionKindInterface.h"
 #include "llvm/ADT/DenseMap.h"
 #include "llvm/Support/GenericDomTreeConstruction.h"

 using namespace mlir;
 using namespace mlir::detail;

 template class llvm::DominatorTreeBase<Block, /*IsPostDom=*/false>;
 template class llvm::DominatorTreeBase<Block, /*IsPostDom=*/true>;
 template class llvm::DomTreeNodeBase<Block>;

 /// Return true if the region with the given index inside the operation
 /// has SSA dominance.
 static bool hasSSADominance(Operation *op, unsigned index) {
   auto kindInterface = dyn_cast<RegionKindInterface>(op);
   return op->isRegistered() &&
          (!kindInterface || kindInterface.hasSSADominance(index));
 }

 //===----------------------------------------------------------------------===//
 // DominanceInfoBase
 //===----------------------------------------------------------------------===//

 template <bool IsPostDom>
 void DominanceInfoBase<IsPostDom>::recalculate(Operation *op) {
   dominanceInfos.clear();

   // Build the dominance for each of the operation regions.
   op->walk([&](Operation *op) {
     auto kindInterface = dyn_cast<RegionKindInterface>(op);
     unsigned numRegions = op->getNumRegions();
     for (unsigned i = 0; i < numRegions; i++) {
       Region &region = op->getRegion(i);
       // Don't compute dominance if the region is empty.
       if (region.empty())
         continue;

       // Dominance changes based on the region type. Avoid the helper
       // function here so we don't do the region cast repeatedly.
       bool hasSSADominance =
           op->isRegistered() &&
           (!kindInterface || kindInterface.hasSSADominance(i));
       // If a region has SSADominance, then compute detailed dominance
       // info.  Otherwise, all values in the region are live anywhere
       // in the region, which is represented as an empty entry in the
       // dominanceInfos map.
       if (hasSSADominance) {
         auto opDominance = std::make_unique<base>();
         opDominance->recalculate(region);
         dominanceInfos.try_emplace(&region, std::move(opDominance));
       }
     }
   });
 }

 /// Walks up the list of containers of the given block and calls the
 /// user-defined traversal function for every pair of a region and block that
 /// could be found during traversal. If the user-defined function returns true
 /// for a given pair, traverseAncestors will return the current block. Nullptr
 /// otherwise.
 template <typename FuncT>
 Block *traverseAncestors(Block *block, const FuncT &func) {
   // Invoke the user-defined traversal function in the beginning for the current
   // block.
   if (func(block))
     return block;

   Region *region = block->getParent();
   while (region) {
     Operation *ancestor = region->getParentOp();
     // If we have reached to top... return.
     if (!ancestor || !(block = ancestor->getBlock()))
       break;

     // Update the nested region using the new ancestor block.
     region = block->getParent();

     // Invoke the user-defined traversal function and check whether we can
     // already return.
     if (func(block))
       return block;
   }
   return nullptr;
 }

 /// Tries to update the given block references to live in the same region by
 /// exploring the relationship of both blocks with respect to their regions.
 static bool tryGetBlocksInSameRegion(Block *&a, Block *&b) {
   // If both block do not live in the same region, we will have to check their
   // parent operations.
   if (a->getParent() == b->getParent())
     return true;

   // Iterate over all ancestors of a and insert them into the map. This allows
   // for efficient lookups to find a commonly shared region.
   llvm::SmallDenseMap<Region *, Block *, 4> ancestors;
   traverseAncestors(a, [&](Block *block) {
     ancestors[block->getParent()] = block;
     return false;
   });

   // Try to find a common ancestor starting with regionB.
   b = traverseAncestors(
       b, [&](Block *block) { return ancestors.count(block->getParent()) > 0; });

   // If there is no match, we will not be able to find a common dominator since
   // both regions do not share a common parent region.
   if (!b)
     return false;

   // We have found a common parent region. Update block a to refer to this
   // region.
   auto it = ancestors.find(b->getParent());
   assert(it != ancestors.end());
   a = it->second;
   return true;
 }

 template <bool IsPostDom>
 Block *
 DominanceInfoBase<IsPostDom>::findNearestCommonDominator(Block *a,
                                                          Block *b) const {
   // If either a or b are null, then conservatively return nullptr.
   if (!a || !b)
     return nullptr;

   // Try to find blocks that are in the same region.
   if (!tryGetBlocksInSameRegion(a, b))
     return nullptr;

   // Get and verify dominance information of the common parent region.
   Region *parentRegion = a->getParent();
   auto infoAIt = dominanceInfos.find(parentRegion);
   if (infoAIt == dominanceInfos.end())
     return nullptr;

   // Since the blocks live in the same region, we can rely on already
   // existing dominance functionality.
   return infoAIt->second->findNearestCommonDominator(a, b);
 }

 template <bool IsPostDom>
 DominanceInfoNode *DominanceInfoBase<IsPostDom>::getNode(Block *a) {
   Region *region = a->getParent();
   assert(dominanceInfos.count(region) != 0);
   return dominanceInfos[region]->getNode(a);
 }

 /// Return true if the specified block A properly dominates block B.
 template <bool IsPostDom>
 bool DominanceInfoBase<IsPostDom>::properlyDominates(Block *a, Block *b) const {
   // A block dominates itself but does not properly dominate itself.
   if (a == b)
     return false;

   // If either a or b are null, then conservatively return false.
   if (!a || !b)
     return false;

   // If both blocks are not in the same region, 'a' properly dominates 'b' if
   // 'b' is defined in an operation region that (recursively) ends up being
   // dominated by 'a'. Walk up the list of containers enclosing B.
   Region *regionA = a->getParent();
   if (regionA != b->getParent()) {
     b = traverseAncestors(
         b, [&](Block *block) { return block->getParent() == regionA; });

     // If we could not find a valid block b then it is a not a dominator.
     if (!b)
       return false;

     // Check to see if the ancestor of 'b' is the same block as 'a'.
     if (a == b)
       return true;
   }

   // Otherwise, use the standard dominance functionality.

   // If we don't have a dominance information for this region, assume that b is
   // dominated by anything.
   auto baseInfoIt = dominanceInfos.find(regionA);
   if (baseInfoIt == dominanceInfos.end())
     return true;
   return baseInfoIt->second->properlyDominates(a, b);
 }

 /// Return true if the specified block is reachable from the entry block of its
 /// region.
 template <bool IsPostDom>
 bool DominanceInfoBase<IsPostDom>::isReachableFromEntry(Block *a) const {
   Region *regionA = a->getParent();
   auto baseInfoIt = dominanceInfos.find(regionA);
   if (baseInfoIt == dominanceInfos.end())
     return true;
   return baseInfoIt->second->isReachableFromEntry(a);
 }

 template class detail::DominanceInfoBase</*IsPostDom=*/true>;
 template class detail::DominanceInfoBase</*IsPostDom=*/false>;

 //===----------------------------------------------------------------------===//
 // DominanceInfo
 //===----------------------------------------------------------------------===//

 /// Return true if operation A properly dominates operation B.
 bool DominanceInfo::properlyDominates(Operation *a, Operation *b) const {
   Block *aBlock = a->getBlock(), *bBlock = b->getBlock();
   Region *aRegion = a->getParentRegion();
   unsigned aRegionNum = aRegion->getRegionNumber();
   Operation *ancestor = aRegion->getParentOp();

   // If a or b are not within a block, then a does not dominate b.
   if (!aBlock || !bBlock)
     return false;

   if (aBlock == bBlock) {
     // Dominance changes based on the region type. In a region with SSA
     // dominance, uses inside the same block must follow defs. In other
     // regions kinds, uses and defs can come in any order inside a block.
     if (hasSSADominance(ancestor, aRegionNum)) {
       // If the blocks are the same, then check if b is before a in the block.
       return a->isBeforeInBlock(b);
     }
     return true;
   }

   // Traverse up b's hierarchy to check if b's block is contained in a's.
   if (auto *bAncestor = aBlock->findAncestorOpInBlock(*b)) {
     // Since we already know that aBlock != bBlock, here bAncestor != b.
     // a and bAncestor are in the same block; check if 'a' dominates
     // bAncestor.
     return dominates(a, bAncestor);
   }

   // If the blocks are different, check if a's block dominates b's.
   return properlyDominates(aBlock, bBlock);
 }

 /// Return true if value A properly dominates operation B.
 bool DominanceInfo::properlyDominates(Value a, Operation *b) const {
   if (auto *aOp = a.getDefiningOp()) {
     // Dominance changes based on the region type.
     auto *aRegion = aOp->getParentRegion();
     unsigned aRegionNum = aRegion->getRegionNumber();
     Operation *ancestor = aRegion->getParentOp();
     // Dominance changes based on the region type. In a region with SSA
     // dominance, values defined by an operation cannot be used by the
     // operation. In other regions kinds they can be used the operation.
     if (hasSSADominance(ancestor, aRegionNum)) {
       // The values defined by an operation do *not* dominate any nested
       // operations.
       if (aOp->getParentRegion() != b->getParentRegion() && aOp->isAncestor(b))
         return false;
     }
     return properlyDominates(aOp, b);
   }

   // block arguments properly dominate all operations in their own block, so
   // we use a dominates check here, not a properlyDominates check.
   return dominates(a.cast<BlockArgument>().getOwner(), b->getBlock());
 }

 void DominanceInfo::updateDFSNumbers() {
   for (auto &iter : dominanceInfos)
     iter.second->updateDFSNumbers();
 }

 //===----------------------------------------------------------------------===//
 // PostDominanceInfo
 //===----------------------------------------------------------------------===//

 /// Returns true if statement 'a' properly postdominates statement b.
 bool PostDominanceInfo::properlyPostDominates(Operation *a, Operation *b) {
   auto *aBlock = a->getBlock(), *bBlock = b->getBlock();
   auto *aRegion = a->getParentRegion();
   unsigned aRegionNum = aRegion->getRegionNumber();
   Operation *ancestor = aRegion->getParentOp();

   // If a or b are not within a block, then a does not post dominate b.
   if (!aBlock || !bBlock)
     return false;

   // If the blocks are the same, check if b is before a in the block.
   if (aBlock == bBlock) {
     // Dominance changes based on the region type.
     if (hasSSADominance(ancestor, aRegionNum)) {
       // If the blocks are the same, then check if b is before a in the block.
       return b->isBeforeInBlock(a);
     }
     return true;
   }

   // Traverse up b's hierarchy to check if b's block is contained in a's.
   if (auto *bAncestor = a->getBlock()->findAncestorOpInBlock(*b))
     // Since we already know that aBlock != bBlock, here bAncestor != b.
     // a and bAncestor are in the same block; check if 'a' postdominates
     // bAncestor.
     return postDominates(a, bAncestor);

   // If the blocks are different, check if a's block post dominates b's.
   return properlyDominates(aBlock, bBlock);
 }
	//===- Dominance.cpp - Dominator analysis for CFGs ------------------------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//
	//
	// Implementation of dominance related classes and instantiations of extern
	// templates.
	//
	//===----------------------------------------------------------------------===//

	#include "mlir/IR/Dominance.h"
	#include "mlir/IR/Operation.h"
	#include "mlir/IR/RegionKindInterface.h"
	#include "llvm/ADT/DenseMap.h"
	#include "llvm/Support/GenericDomTreeConstruction.h"

	using namespace mlir;
	using namespace mlir::detail;

	template class llvm::DominatorTreeBase<Block, /IsPostDom=/false>;
	template class llvm::DominatorTreeBase<Block, /IsPostDom=/true>;
	template class llvm::DomTreeNodeBase<Block>;

	/// Return true if the region with the given index inside the operation
	/// has SSA dominance.
	static bool hasSSADominance(Operation *op, unsigned index) {
	auto kindInterface = dyn_cast<RegionKindInterface>(op);
	return op->isRegistered() &&
	(!kindInterface \|\| kindInterface.hasSSADominance(index));
	}

	//===----------------------------------------------------------------------===//
	// DominanceInfoBase
	//===----------------------------------------------------------------------===//

	template <bool IsPostDom>
	void DominanceInfoBase<IsPostDom>::recalculate(Operation *op) {
	dominanceInfos.clear();

	// Build the dominance for each of the operation regions.
	op->walk([&](Operation *op) {
	auto kindInterface = dyn_cast<RegionKindInterface>(op);
	unsigned numRegions = op->getNumRegions();
	for (unsigned i = 0; i < numRegions; i++) {
	Region &region = op->getRegion(i);
	// Don't compute dominance if the region is empty.
	if (region.empty())
	continue;

	// Dominance changes based on the region type. Avoid the helper
	// function here so we don't do the region cast repeatedly.
	bool hasSSADominance =
	op->isRegistered() &&
	(!kindInterface \|\| kindInterface.hasSSADominance(i));
	// If a region has SSADominance, then compute detailed dominance
	// info. Otherwise, all values in the region are live anywhere
	// in the region, which is represented as an empty entry in the
	// dominanceInfos map.
	if (hasSSADominance) {
	auto opDominance = std::make_unique<base>();
	opDominance->recalculate(region);
	dominanceInfos.try_emplace(&region, std::move(opDominance));
	}
	}
	});
	}

	/// Walks up the list of containers of the given block and calls the
	/// user-defined traversal function for every pair of a region and block that
	/// could be found during traversal. If the user-defined function returns true
	/// for a given pair, traverseAncestors will return the current block. Nullptr
	/// otherwise.
	template <typename FuncT>
	Block traverseAncestors(Block block, const FuncT &func) {
	// Invoke the user-defined traversal function in the beginning for the current
	// block.
	if (func(block))
	return block;

	Region *region = block->getParent();
	while (region) {
	Operation *ancestor = region->getParentOp();
	// If we have reached to top... return.
	if (!ancestor \|\| !(block = ancestor->getBlock()))
	break;

	// Update the nested region using the new ancestor block.
	region = block->getParent();

	// Invoke the user-defined traversal function and check whether we can
	// already return.
	if (func(block))
	return block;
	}
	return nullptr;
	}

	/// Tries to update the given block references to live in the same region by
	/// exploring the relationship of both blocks with respect to their regions.
	static bool tryGetBlocksInSameRegion(Block &a, Block &b) {
	// If both block do not live in the same region, we will have to check their
	// parent operations.
	if (a->getParent() == b->getParent())
	return true;

	// Iterate over all ancestors of a and insert them into the map. This allows
	// for efficient lookups to find a commonly shared region.
	llvm::SmallDenseMap<Region , Block , 4> ancestors;
	traverseAncestors(a, [&](Block *block) {
	ancestors[block->getParent()] = block;
	return false;
	});

	// Try to find a common ancestor starting with regionB.
	b = traverseAncestors(
	b, [&](Block *block) { return ancestors.count(block->getParent()) > 0; });

	// If there is no match, we will not be able to find a common dominator since
	// both regions do not share a common parent region.
	if (!b)
	return false;

	// We have found a common parent region. Update block a to refer to this
	// region.
	auto it = ancestors.find(b->getParent());
	assert(it != ancestors.end());
	a = it->second;
	return true;
	}

	template <bool IsPostDom>
	Block *
	DominanceInfoBase<IsPostDom>::findNearestCommonDominator(Block *a,
	Block *b) const {
	// If either a or b are null, then conservatively return nullptr.
	if (!a \|\| !b)
	return nullptr;

	// Try to find blocks that are in the same region.
	if (!tryGetBlocksInSameRegion(a, b))
	return nullptr;

	// Get and verify dominance information of the common parent region.
	Region *parentRegion = a->getParent();
	auto infoAIt = dominanceInfos.find(parentRegion);
	if (infoAIt == dominanceInfos.end())
	return nullptr;

	// Since the blocks live in the same region, we can rely on already
	// existing dominance functionality.
	return infoAIt->second->findNearestCommonDominator(a, b);
	}

	template <bool IsPostDom>
	DominanceInfoNode DominanceInfoBase<IsPostDom>::getNode(Block a) {
	Region *region = a->getParent();
	assert(dominanceInfos.count(region) != 0);
	return dominanceInfos[region]->getNode(a);
	}

	/// Return true if the specified block A properly dominates block B.
	template <bool IsPostDom>
	bool DominanceInfoBase<IsPostDom>::properlyDominates(Block a, Block b) const {
	// A block dominates itself but does not properly dominate itself.
	if (a == b)
	return false;

	// If either a or b are null, then conservatively return false.
	if (!a \|\| !b)
	return false;

	// If both blocks are not in the same region, 'a' properly dominates 'b' if
	// 'b' is defined in an operation region that (recursively) ends up being
	// dominated by 'a'. Walk up the list of containers enclosing B.
	Region *regionA = a->getParent();
	if (regionA != b->getParent()) {
	b = traverseAncestors(
	b, [&](Block *block) { return block->getParent() == regionA; });

	// If we could not find a valid block b then it is a not a dominator.
	if (!b)
	return false;

	// Check to see if the ancestor of 'b' is the same block as 'a'.
	if (a == b)
	return true;
	}

	// Otherwise, use the standard dominance functionality.

	// If we don't have a dominance information for this region, assume that b is
	// dominated by anything.
	auto baseInfoIt = dominanceInfos.find(regionA);
	if (baseInfoIt == dominanceInfos.end())
	return true;
	return baseInfoIt->second->properlyDominates(a, b);
	}

	/// Return true if the specified block is reachable from the entry block of its
	/// region.
	template <bool IsPostDom>
	bool DominanceInfoBase<IsPostDom>::isReachableFromEntry(Block *a) const {
	Region *regionA = a->getParent();
	auto baseInfoIt = dominanceInfos.find(regionA);
	if (baseInfoIt == dominanceInfos.end())
	return true;
	return baseInfoIt->second->isReachableFromEntry(a);
	}

	template class detail::DominanceInfoBase</IsPostDom=/true>;
	template class detail::DominanceInfoBase</IsPostDom=/false>;

	//===----------------------------------------------------------------------===//
	// DominanceInfo
	//===----------------------------------------------------------------------===//

	/// Return true if operation A properly dominates operation B.
	bool DominanceInfo::properlyDominates(Operation a, Operation b) const {
	Block aBlock = a->getBlock(), bBlock = b->getBlock();
	Region *aRegion = a->getParentRegion();
	unsigned aRegionNum = aRegion->getRegionNumber();
	Operation *ancestor = aRegion->getParentOp();

	// If a or b are not within a block, then a does not dominate b.
	if (!aBlock \|\| !bBlock)
	return false;

	if (aBlock == bBlock) {
	// Dominance changes based on the region type. In a region with SSA
	// dominance, uses inside the same block must follow defs. In other
	// regions kinds, uses and defs can come in any order inside a block.
	if (hasSSADominance(ancestor, aRegionNum)) {
	// If the blocks are the same, then check if b is before a in the block.
	return a->isBeforeInBlock(b);
	}
	return true;
	}

	// Traverse up b's hierarchy to check if b's block is contained in a's.
	if (auto bAncestor = aBlock->findAncestorOpInBlock(b)) {
	// Since we already know that aBlock != bBlock, here bAncestor != b.
	// a and bAncestor are in the same block; check if 'a' dominates
	// bAncestor.
	return dominates(a, bAncestor);
	}

	// If the blocks are different, check if a's block dominates b's.
	return properlyDominates(aBlock, bBlock);
	}

	/// Return true if value A properly dominates operation B.
	bool DominanceInfo::properlyDominates(Value a, Operation *b) const {
	if (auto *aOp = a.getDefiningOp()) {
	// Dominance changes based on the region type.
	auto *aRegion = aOp->getParentRegion();
	unsigned aRegionNum = aRegion->getRegionNumber();
	Operation *ancestor = aRegion->getParentOp();
	// Dominance changes based on the region type. In a region with SSA
	// dominance, values defined by an operation cannot be used by the
	// operation. In other regions kinds they can be used the operation.
	if (hasSSADominance(ancestor, aRegionNum)) {
	// The values defined by an operation do not dominate any nested
	// operations.
	if (aOp->getParentRegion() != b->getParentRegion() && aOp->isAncestor(b))
	return false;
	}
	return properlyDominates(aOp, b);
	}

	// block arguments properly dominate all operations in their own block, so
	// we use a dominates check here, not a properlyDominates check.
	return dominates(a.cast<BlockArgument>().getOwner(), b->getBlock());
	}

	void DominanceInfo::updateDFSNumbers() {
	for (auto &iter : dominanceInfos)
	iter.second->updateDFSNumbers();
	}

	//===----------------------------------------------------------------------===//
	// PostDominanceInfo
	//===----------------------------------------------------------------------===//

	/// Returns true if statement 'a' properly postdominates statement b.
	bool PostDominanceInfo::properlyPostDominates(Operation a, Operation b) {
	auto aBlock = a->getBlock(), bBlock = b->getBlock();
	auto *aRegion = a->getParentRegion();
	unsigned aRegionNum = aRegion->getRegionNumber();
	Operation *ancestor = aRegion->getParentOp();

	// If a or b are not within a block, then a does not post dominate b.
	if (!aBlock \|\| !bBlock)
	return false;

	// If the blocks are the same, check if b is before a in the block.
	if (aBlock == bBlock) {
	// Dominance changes based on the region type.
	if (hasSSADominance(ancestor, aRegionNum)) {
	// If the blocks are the same, then check if b is before a in the block.
	return b->isBeforeInBlock(a);
	}
	return true;
	}

	// Traverse up b's hierarchy to check if b's block is contained in a's.
	if (auto bAncestor = a->getBlock()->findAncestorOpInBlock(b))
	// Since we already know that aBlock != bBlock, here bAncestor != b.
	// a and bAncestor are in the same block; check if 'a' postdominates
	// bAncestor.
	return postDominates(a, bAncestor);

	// If the blocks are different, check if a's block post dominates b's.
	return properlyDominates(aBlock, bBlock);
	}