linux-x64/clang/include/llvm/Analysis/DomTreeUpdater.h - hafnium/prebuilts - Git at Google

 //===- DomTreeUpdater.h - DomTree/Post DomTree Updater ----------*- C++ -*-===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines the DomTreeUpdater class, which provides a uniform way to
 // update dominator tree related data structures.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_ANALYSIS_DOMTREEUPDATER_H
 #define LLVM_ANALYSIS_DOMTREEUPDATER_H

 #include "llvm/Analysis/PostDominators.h"
 #include "llvm/IR/Dominators.h"
 #include "llvm/IR/Instructions.h"
 #include "llvm/IR/ValueHandle.h"
 #include "llvm/Support/GenericDomTree.h"
 #include <functional>
 #include <vector>

 namespace llvm {
 class DomTreeUpdater {
 public:
   enum class UpdateStrategy : unsigned char { Eager = 0, Lazy = 1 };

   explicit DomTreeUpdater(UpdateStrategy Strategy_) : Strategy(Strategy_) {}
   DomTreeUpdater(DominatorTree &DT_, UpdateStrategy Strategy_)
       : DT(&DT_), Strategy(Strategy_) {}
   DomTreeUpdater(DominatorTree *DT_, UpdateStrategy Strategy_)
       : DT(DT_), Strategy(Strategy_) {}
   DomTreeUpdater(PostDominatorTree &PDT_, UpdateStrategy Strategy_)
       : PDT(&PDT_), Strategy(Strategy_) {}
   DomTreeUpdater(PostDominatorTree *PDT_, UpdateStrategy Strategy_)
       : PDT(PDT_), Strategy(Strategy_) {}
   DomTreeUpdater(DominatorTree &DT_, PostDominatorTree &PDT_,
                  UpdateStrategy Strategy_)
       : DT(&DT_), PDT(&PDT_), Strategy(Strategy_) {}
   DomTreeUpdater(DominatorTree *DT_, PostDominatorTree *PDT_,
                  UpdateStrategy Strategy_)
       : DT(DT_), PDT(PDT_), Strategy(Strategy_) {}

   ~DomTreeUpdater() { flush(); }

   /// Returns true if the current strategy is Lazy.
   bool isLazy() const { return Strategy == UpdateStrategy::Lazy; };

   /// Returns true if the current strategy is Eager.
   bool isEager() const { return Strategy == UpdateStrategy::Eager; };

   /// Returns true if it holds a DominatorTree.
   bool hasDomTree() const { return DT != nullptr; }

   /// Returns true if it holds a PostDominatorTree.
   bool hasPostDomTree() const { return PDT != nullptr; }

   /// Returns true if there is BasicBlock awaiting deletion.
   /// The deletion will only happen until a flush event and
   /// all available trees are up-to-date.
   /// Returns false under Eager UpdateStrategy.
   bool hasPendingDeletedBB() const { return !DeletedBBs.empty(); }

   /// Returns true if DelBB is awaiting deletion.
   /// Returns false under Eager UpdateStrategy.
   bool isBBPendingDeletion(BasicBlock *DelBB) const;

   /// Returns true if either of DT or PDT is valid and the tree has at
   /// least one update pending. If DT or PDT is nullptr it is treated
   /// as having no pending updates. This function does not check
   /// whether there is BasicBlock awaiting deletion.
   /// Returns false under Eager UpdateStrategy.
   bool hasPendingUpdates() const;

   /// Returns true if there are DominatorTree updates queued.
   /// Returns false under Eager UpdateStrategy or DT is nullptr.
   bool hasPendingDomTreeUpdates() const;

   /// Returns true if there are PostDominatorTree updates queued.
   /// Returns false under Eager UpdateStrategy or PDT is nullptr.
   bool hasPendingPostDomTreeUpdates() const;

   /// Apply updates on all available trees. Under Eager UpdateStrategy with
   /// ForceRemoveDuplicates enabled or under Lazy UpdateStrategy, it will
   /// discard duplicated updates and self-dominance updates. If both DT and PDT
   /// are nullptrs, this function discards all updates. The Eager Strategy
   /// applies the updates immediately while the Lazy Strategy queues the
   /// updates. It is required for the state of the LLVM IR to be updated
   /// *before* applying the Updates because the internal update routine will
   /// analyze the current state of the relationship between a pair of (From, To)
   /// BasicBlocks to determine whether a single update needs to be discarded.
   void applyUpdates(ArrayRef<DominatorTree::UpdateType> Updates,
                     bool ForceRemoveDuplicates = false);

   /// Notify all available trees on an edge insertion. If both DT and PDT are
   /// nullptrs, this function discards the update. Under either Strategy,
   /// self-dominance update will be removed. The Eager Strategy applies
   /// the update immediately while the Lazy Strategy queues the update.
   /// It is recommended to only use this method when you have exactly one
   /// insertion (and no deletions). It is recommended to use applyUpdates() in
   /// all other cases. This function has to be called *after* making the update
   /// on the actual CFG. An internal functions checks if the edge exists in the
   /// CFG in DEBUG mode.
   void insertEdge(BasicBlock *From, BasicBlock *To);

   /// Notify all available trees on an edge insertion.
   /// Under either Strategy, the following updates will be discard silently
   /// 1. Invalid - Inserting an edge that does not exist in the CFG.
   /// 2. Self-dominance update.
   /// 3. Both DT and PDT are nullptrs.
   /// The Eager Strategy applies the update immediately while the Lazy Strategy
   /// queues the update. It is recommended to only use this method when you have
   /// exactly one insertion (and no deletions) and want to discard an invalid
   /// update.
   void insertEdgeRelaxed(BasicBlock *From, BasicBlock *To);

   /// Notify all available trees on an edge deletion. If both DT and PDT are
   /// nullptrs, this function discards the update. Under either Strategy,
   /// self-dominance update will be removed. The Eager Strategy applies
   /// the update immediately while the Lazy Strategy queues the update.
   /// It is recommended to only use this method when you have exactly one
   /// deletion (and no insertions). It is recommended to use applyUpdates() in
   /// all other cases. This function has to be called *after* making the update
   /// on the actual CFG. An internal functions checks if the edge doesn't exist
   /// in the CFG in DEBUG mode.
   void deleteEdge(BasicBlock *From, BasicBlock *To);

   /// Notify all available trees on an edge deletion.
   /// Under either Strategy, the following updates will be discard silently
   /// 1. Invalid - Deleting an edge that still exists in the CFG.
   /// 2. Self-dominance update.
   /// 3. Both DT and PDT are nullptrs.
   /// The Eager Strategy applies the update immediately while the Lazy Strategy
   /// queues the update. It is recommended to only use this method when you have
   /// exactly one deletion (and no insertions) and want to discard an invalid
   /// update.
   void deleteEdgeRelaxed(BasicBlock *From, BasicBlock *To);

   /// Delete DelBB. DelBB will be removed from its Parent and
   /// erased from available trees if it exists and finally get deleted.
   /// Under Eager UpdateStrategy, DelBB will be processed immediately.
   /// Under Lazy UpdateStrategy, DelBB will be queued until a flush event and
   /// all available trees are up-to-date. Assert if any instruction of DelBB is
   /// modified while awaiting deletion. When both DT and PDT are nullptrs, DelBB
   /// will be queued until flush() is called.
   void deleteBB(BasicBlock *DelBB);

   /// Delete DelBB. DelBB will be removed from its Parent and
   /// erased from available trees if it exists. Then the callback will
   /// be called. Finally, DelBB will be deleted.
   /// Under Eager UpdateStrategy, DelBB will be processed immediately.
   /// Under Lazy UpdateStrategy, DelBB will be queued until a flush event and
   /// all available trees are up-to-date. Assert if any instruction of DelBB is
   /// modified while awaiting deletion. Multiple callbacks can be queued for one
   /// DelBB under Lazy UpdateStrategy.
   void callbackDeleteBB(BasicBlock *DelBB,
                         std::function<void(BasicBlock *)> Callback);

   /// Recalculate all available trees and flush all BasicBlocks
   /// awaiting deletion immediately.
   void recalculate(Function &F);

   /// Flush DomTree updates and return DomTree.
   /// It also flush out of date updates applied by all available trees
   /// and flush Deleted BBs if both trees are up-to-date.
   /// It must only be called when it has a DomTree.
   DominatorTree &getDomTree();

   /// Flush PostDomTree updates and return PostDomTree.
   /// It also flush out of date updates applied by all available trees
   /// and flush Deleted BBs if both trees are up-to-date.
   /// It must only be called when it has a PostDomTree.
   PostDominatorTree &getPostDomTree();

   /// Apply all pending updates to available trees and flush all BasicBlocks
   /// awaiting deletion.
   /// Does nothing under Eager UpdateStrategy.
   void flush();

   /// Debug method to help view the internal state of this class.
   LLVM_DUMP_METHOD void dump() const;

 private:
   class CallBackOnDeletion final : public CallbackVH {
   public:
     CallBackOnDeletion(BasicBlock *V,
                        std::function<void(BasicBlock *)> Callback)
         : CallbackVH(V), DelBB(V), Callback_(Callback) {}

   private:
     BasicBlock *DelBB = nullptr;
     std::function<void(BasicBlock *)> Callback_;

     void deleted() override {
       Callback_(DelBB);
       CallbackVH::deleted();
     }
   };

   SmallVector<DominatorTree::UpdateType, 16> PendUpdates;
   size_t PendDTUpdateIndex = 0;
   size_t PendPDTUpdateIndex = 0;
   DominatorTree *DT = nullptr;
   PostDominatorTree *PDT = nullptr;
   const UpdateStrategy Strategy;
   SmallPtrSet<BasicBlock *, 8> DeletedBBs;
   std::vector<CallBackOnDeletion> Callbacks;
   bool IsRecalculatingDomTree = false;
   bool IsRecalculatingPostDomTree = false;

   /// First remove all the instructions of DelBB and then make sure DelBB has a
   /// valid terminator instruction which is necessary to have when DelBB still
   /// has to be inside of its parent Function while awaiting deletion under Lazy
   /// UpdateStrategy to prevent other routines from asserting the state of the
   /// IR is inconsistent. Assert if DelBB is nullptr or has predecessors.
   void validateDeleteBB(BasicBlock *DelBB);

   /// Returns true if at least one BasicBlock is deleted.
   bool forceFlushDeletedBB();

   /// Deduplicate and remove unnecessary updates (no-ops) when using Lazy
   /// UpdateStrategy. Returns true if the update is queued for update.
   bool applyLazyUpdate(DominatorTree::UpdateKind Kind, BasicBlock *From,
                        BasicBlock *To);

   /// Helper function to apply all pending DomTree updates.
   void applyDomTreeUpdates();

   /// Helper function to apply all pending PostDomTree updates.
   void applyPostDomTreeUpdates();

   /// Helper function to flush deleted BasicBlocks if all available
   /// trees are up-to-date.
   void tryFlushDeletedBB();

   /// Drop all updates applied by all available trees and delete BasicBlocks if
   /// all available trees are up-to-date.
   void dropOutOfDateUpdates();

   /// Erase Basic Block node that has been unlinked from Function
   /// in the DomTree and PostDomTree.
   void eraseDelBBNode(BasicBlock *DelBB);

   /// Returns true if the update appears in the LLVM IR.
   /// It is used to check whether an update is valid in
   /// insertEdge/deleteEdge or is unnecessary in the batch update.
   bool isUpdateValid(DominatorTree::UpdateType Update) const;

   /// Returns true if the update is self dominance.
   bool isSelfDominance(DominatorTree::UpdateType Update) const;
 };
 } // namespace llvm

 #endif // LLVM_ANALYSIS_DOMTREEUPDATER_H
	//===- DomTreeUpdater.h - DomTree/Post DomTree Updater ----------- C++ --===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines the DomTreeUpdater class, which provides a uniform way to
	// update dominator tree related data structures.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_ANALYSIS_DOMTREEUPDATER_H
	#define LLVM_ANALYSIS_DOMTREEUPDATER_H

	#include "llvm/Analysis/PostDominators.h"
	#include "llvm/IR/Dominators.h"
	#include "llvm/IR/Instructions.h"
	#include "llvm/IR/ValueHandle.h"
	#include "llvm/Support/GenericDomTree.h"
	#include <functional>
	#include <vector>

	namespace llvm {
	class DomTreeUpdater {
	public:
	enum class UpdateStrategy : unsigned char { Eager = 0, Lazy = 1 };

	explicit DomTreeUpdater(UpdateStrategy Strategy_) : Strategy(Strategy_) {}
	DomTreeUpdater(DominatorTree &DT_, UpdateStrategy Strategy_)
	: DT(&DT_), Strategy(Strategy_) {}
	DomTreeUpdater(DominatorTree *DT_, UpdateStrategy Strategy_)
	: DT(DT_), Strategy(Strategy_) {}
	DomTreeUpdater(PostDominatorTree &PDT_, UpdateStrategy Strategy_)
	: PDT(&PDT_), Strategy(Strategy_) {}
	DomTreeUpdater(PostDominatorTree *PDT_, UpdateStrategy Strategy_)
	: PDT(PDT_), Strategy(Strategy_) {}
	DomTreeUpdater(DominatorTree &DT_, PostDominatorTree &PDT_,
	UpdateStrategy Strategy_)
	: DT(&DT_), PDT(&PDT_), Strategy(Strategy_) {}
	DomTreeUpdater(DominatorTree DT_, PostDominatorTree PDT_,
	UpdateStrategy Strategy_)
	: DT(DT_), PDT(PDT_), Strategy(Strategy_) {}

	~DomTreeUpdater() { flush(); }

	/// Returns true if the current strategy is Lazy.
	bool isLazy() const { return Strategy == UpdateStrategy::Lazy; };

	/// Returns true if the current strategy is Eager.
	bool isEager() const { return Strategy == UpdateStrategy::Eager; };

	/// Returns true if it holds a DominatorTree.
	bool hasDomTree() const { return DT != nullptr; }

	/// Returns true if it holds a PostDominatorTree.
	bool hasPostDomTree() const { return PDT != nullptr; }

	/// Returns true if there is BasicBlock awaiting deletion.
	/// The deletion will only happen until a flush event and
	/// all available trees are up-to-date.
	/// Returns false under Eager UpdateStrategy.
	bool hasPendingDeletedBB() const { return !DeletedBBs.empty(); }

	/// Returns true if DelBB is awaiting deletion.
	/// Returns false under Eager UpdateStrategy.
	bool isBBPendingDeletion(BasicBlock *DelBB) const;

	/// Returns true if either of DT or PDT is valid and the tree has at
	/// least one update pending. If DT or PDT is nullptr it is treated
	/// as having no pending updates. This function does not check
	/// whether there is BasicBlock awaiting deletion.
	/// Returns false under Eager UpdateStrategy.
	bool hasPendingUpdates() const;

	/// Returns true if there are DominatorTree updates queued.
	/// Returns false under Eager UpdateStrategy or DT is nullptr.
	bool hasPendingDomTreeUpdates() const;

	/// Returns true if there are PostDominatorTree updates queued.
	/// Returns false under Eager UpdateStrategy or PDT is nullptr.
	bool hasPendingPostDomTreeUpdates() const;

	/// Apply updates on all available trees. Under Eager UpdateStrategy with
	/// ForceRemoveDuplicates enabled or under Lazy UpdateStrategy, it will
	/// discard duplicated updates and self-dominance updates. If both DT and PDT
	/// are nullptrs, this function discards all updates. The Eager Strategy
	/// applies the updates immediately while the Lazy Strategy queues the
	/// updates. It is required for the state of the LLVM IR to be updated
	/// before applying the Updates because the internal update routine will
	/// analyze the current state of the relationship between a pair of (From, To)
	/// BasicBlocks to determine whether a single update needs to be discarded.
	void applyUpdates(ArrayRef<DominatorTree::UpdateType> Updates,
	bool ForceRemoveDuplicates = false);

	/// Notify all available trees on an edge insertion. If both DT and PDT are
	/// nullptrs, this function discards the update. Under either Strategy,
	/// self-dominance update will be removed. The Eager Strategy applies
	/// the update immediately while the Lazy Strategy queues the update.
	/// It is recommended to only use this method when you have exactly one
	/// insertion (and no deletions). It is recommended to use applyUpdates() in
	/// all other cases. This function has to be called after making the update
	/// on the actual CFG. An internal functions checks if the edge exists in the
	/// CFG in DEBUG mode.
	void insertEdge(BasicBlock From, BasicBlock To);

	/// Notify all available trees on an edge insertion.
	/// Under either Strategy, the following updates will be discard silently
	/// 1. Invalid - Inserting an edge that does not exist in the CFG.
	/// 2. Self-dominance update.
	/// 3. Both DT and PDT are nullptrs.
	/// The Eager Strategy applies the update immediately while the Lazy Strategy
	/// queues the update. It is recommended to only use this method when you have
	/// exactly one insertion (and no deletions) and want to discard an invalid
	/// update.
	void insertEdgeRelaxed(BasicBlock From, BasicBlock To);

	/// Notify all available trees on an edge deletion. If both DT and PDT are
	/// nullptrs, this function discards the update. Under either Strategy,
	/// self-dominance update will be removed. The Eager Strategy applies
	/// the update immediately while the Lazy Strategy queues the update.
	/// It is recommended to only use this method when you have exactly one
	/// deletion (and no insertions). It is recommended to use applyUpdates() in
	/// all other cases. This function has to be called after making the update
	/// on the actual CFG. An internal functions checks if the edge doesn't exist
	/// in the CFG in DEBUG mode.
	void deleteEdge(BasicBlock From, BasicBlock To);

	/// Notify all available trees on an edge deletion.
	/// Under either Strategy, the following updates will be discard silently
	/// 1. Invalid - Deleting an edge that still exists in the CFG.
	/// 2. Self-dominance update.
	/// 3. Both DT and PDT are nullptrs.
	/// The Eager Strategy applies the update immediately while the Lazy Strategy
	/// queues the update. It is recommended to only use this method when you have
	/// exactly one deletion (and no insertions) and want to discard an invalid
	/// update.
	void deleteEdgeRelaxed(BasicBlock From, BasicBlock To);

	/// Delete DelBB. DelBB will be removed from its Parent and
	/// erased from available trees if it exists and finally get deleted.
	/// Under Eager UpdateStrategy, DelBB will be processed immediately.
	/// Under Lazy UpdateStrategy, DelBB will be queued until a flush event and
	/// all available trees are up-to-date. Assert if any instruction of DelBB is
	/// modified while awaiting deletion. When both DT and PDT are nullptrs, DelBB
	/// will be queued until flush() is called.
	void deleteBB(BasicBlock *DelBB);

	/// Delete DelBB. DelBB will be removed from its Parent and
	/// erased from available trees if it exists. Then the callback will
	/// be called. Finally, DelBB will be deleted.
	/// Under Eager UpdateStrategy, DelBB will be processed immediately.
	/// Under Lazy UpdateStrategy, DelBB will be queued until a flush event and
	/// all available trees are up-to-date. Assert if any instruction of DelBB is
	/// modified while awaiting deletion. Multiple callbacks can be queued for one
	/// DelBB under Lazy UpdateStrategy.
	void callbackDeleteBB(BasicBlock *DelBB,
	std::function<void(BasicBlock *)> Callback);

	/// Recalculate all available trees and flush all BasicBlocks
	/// awaiting deletion immediately.
	void recalculate(Function &F);

	/// Flush DomTree updates and return DomTree.
	/// It also flush out of date updates applied by all available trees
	/// and flush Deleted BBs if both trees are up-to-date.
	/// It must only be called when it has a DomTree.
	DominatorTree &getDomTree();

	/// Flush PostDomTree updates and return PostDomTree.
	/// It also flush out of date updates applied by all available trees
	/// and flush Deleted BBs if both trees are up-to-date.
	/// It must only be called when it has a PostDomTree.
	PostDominatorTree &getPostDomTree();

	/// Apply all pending updates to available trees and flush all BasicBlocks
	/// awaiting deletion.
	/// Does nothing under Eager UpdateStrategy.
	void flush();

	/// Debug method to help view the internal state of this class.
	LLVM_DUMP_METHOD void dump() const;

	private:
	class CallBackOnDeletion final : public CallbackVH {
	public:
	CallBackOnDeletion(BasicBlock *V,
	std::function<void(BasicBlock *)> Callback)
	: CallbackVH(V), DelBB(V), Callback_(Callback) {}

	private:
	BasicBlock *DelBB = nullptr;
	std::function<void(BasicBlock *)> Callback_;

	void deleted() override {
	Callback_(DelBB);
	CallbackVH::deleted();
	}
	};

	SmallVector<DominatorTree::UpdateType, 16> PendUpdates;
	size_t PendDTUpdateIndex = 0;
	size_t PendPDTUpdateIndex = 0;
	DominatorTree *DT = nullptr;
	PostDominatorTree *PDT = nullptr;
	const UpdateStrategy Strategy;
	SmallPtrSet<BasicBlock *, 8> DeletedBBs;
	std::vector<CallBackOnDeletion> Callbacks;
	bool IsRecalculatingDomTree = false;
	bool IsRecalculatingPostDomTree = false;

	/// First remove all the instructions of DelBB and then make sure DelBB has a
	/// valid terminator instruction which is necessary to have when DelBB still
	/// has to be inside of its parent Function while awaiting deletion under Lazy
	/// UpdateStrategy to prevent other routines from asserting the state of the
	/// IR is inconsistent. Assert if DelBB is nullptr or has predecessors.
	void validateDeleteBB(BasicBlock *DelBB);

	/// Returns true if at least one BasicBlock is deleted.
	bool forceFlushDeletedBB();

	/// Deduplicate and remove unnecessary updates (no-ops) when using Lazy
	/// UpdateStrategy. Returns true if the update is queued for update.
	bool applyLazyUpdate(DominatorTree::UpdateKind Kind, BasicBlock *From,
	BasicBlock *To);

	/// Helper function to apply all pending DomTree updates.
	void applyDomTreeUpdates();

	/// Helper function to apply all pending PostDomTree updates.
	void applyPostDomTreeUpdates();

	/// Helper function to flush deleted BasicBlocks if all available
	/// trees are up-to-date.
	void tryFlushDeletedBB();

	/// Drop all updates applied by all available trees and delete BasicBlocks if
	/// all available trees are up-to-date.
	void dropOutOfDateUpdates();

	/// Erase Basic Block node that has been unlinked from Function
	/// in the DomTree and PostDomTree.
	void eraseDelBBNode(BasicBlock *DelBB);

	/// Returns true if the update appears in the LLVM IR.
	/// It is used to check whether an update is valid in
	/// insertEdge/deleteEdge or is unnecessary in the batch update.
	bool isUpdateValid(DominatorTree::UpdateType Update) const;

	/// Returns true if the update is self dominance.
	bool isSelfDominance(DominatorTree::UpdateType Update) const;
	};
	} // namespace llvm

	#endif // LLVM_ANALYSIS_DOMTREEUPDATER_H