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

 //===--------- LoopIterator.h - Iterate over loop blocks --------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 // This file defines iterators to visit the basic blocks within a loop.
 //
 // These iterators currently visit blocks within subloops as well.
 // Unfortunately we have no efficient way of summarizing loop exits which would
 // allow skipping subloops during traversal.
 //
 // If you want to visit all blocks in a loop and don't need an ordered traveral,
 // use Loop::block_begin() instead.
 //
 // This is intentionally designed to work with ill-formed loops in which the
 // backedge has been deleted. The only prerequisite is that all blocks
 // contained within the loop according to the most recent LoopInfo analysis are
 // reachable from the loop header.
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_ANALYSIS_LOOPITERATOR_H
 #define LLVM_ANALYSIS_LOOPITERATOR_H

 #include "llvm/ADT/PostOrderIterator.h"
 #include "llvm/Analysis/LoopInfo.h"

 namespace llvm {

 class LoopBlocksTraversal;

 // A traits type that is intended to be used in graph algorithms. The graph
 // traits starts at the loop header, and traverses the BasicBlocks that are in
 // the loop body, but not the loop header. Since the loop header is skipped,
 // the back edges are excluded.
 //
 // TODO: Explore the possibility to implement LoopBlocksTraversal in terms of
 //       LoopBodyTraits, so that insertEdge doesn't have to be specialized.
 struct LoopBodyTraits {
   using NodeRef = std::pair<const Loop *, BasicBlock *>;

   // This wraps a const Loop * into the iterator, so we know which edges to
   // filter out.
   class WrappedSuccIterator
       : public iterator_adaptor_base<
             WrappedSuccIterator, succ_iterator,
             typename std::iterator_traits<succ_iterator>::iterator_category,
             NodeRef, std::ptrdiff_t, NodeRef *, NodeRef> {
     using BaseT = iterator_adaptor_base<
         WrappedSuccIterator, succ_iterator,
         typename std::iterator_traits<succ_iterator>::iterator_category,
         NodeRef, std::ptrdiff_t, NodeRef *, NodeRef>;

     const Loop *L;

   public:
     WrappedSuccIterator(succ_iterator Begin, const Loop *L)
         : BaseT(Begin), L(L) {}

     NodeRef operator*() const { return {L, *I}; }
   };

   struct LoopBodyFilter {
     bool operator()(NodeRef N) const {
       const Loop *L = N.first;
       return N.second != L->getHeader() && L->contains(N.second);
     }
   };

   using ChildIteratorType =
       filter_iterator<WrappedSuccIterator, LoopBodyFilter>;

   static NodeRef getEntryNode(const Loop &G) { return {&G, G.getHeader()}; }

   static ChildIteratorType child_begin(NodeRef Node) {
     return make_filter_range(make_range<WrappedSuccIterator>(
                                  {succ_begin(Node.second), Node.first},
                                  {succ_end(Node.second), Node.first}),
                              LoopBodyFilter{})
         .begin();
   }

   static ChildIteratorType child_end(NodeRef Node) {
     return make_filter_range(make_range<WrappedSuccIterator>(
                                  {succ_begin(Node.second), Node.first},
                                  {succ_end(Node.second), Node.first}),
                              LoopBodyFilter{})
         .end();
   }
 };

 /// Store the result of a depth first search within basic blocks contained by a
 /// single loop.
 ///
 /// TODO: This could be generalized for any CFG region, or the entire CFG.
 class LoopBlocksDFS {
 public:
   /// Postorder list iterators.
   typedef std::vector<BasicBlock*>::const_iterator POIterator;
   typedef std::vector<BasicBlock*>::const_reverse_iterator RPOIterator;

   friend class LoopBlocksTraversal;

 private:
   Loop *L;

   /// Map each block to its postorder number. A block is only mapped after it is
   /// preorder visited by DFS. It's postorder number is initially zero and set
   /// to nonzero after it is finished by postorder traversal.
   DenseMap<BasicBlock*, unsigned> PostNumbers;
   std::vector<BasicBlock*> PostBlocks;

 public:
   LoopBlocksDFS(Loop *Container) :
     L(Container), PostNumbers(NextPowerOf2(Container->getNumBlocks())) {
     PostBlocks.reserve(Container->getNumBlocks());
   }

   Loop *getLoop() const { return L; }

   /// Traverse the loop blocks and store the DFS result.
   void perform(LoopInfo *LI);

   /// Return true if postorder numbers are assigned to all loop blocks.
   bool isComplete() const { return PostBlocks.size() == L->getNumBlocks(); }

   /// Iterate over the cached postorder blocks.
   POIterator beginPostorder() const {
     assert(isComplete() && "bad loop DFS");
     return PostBlocks.begin();
   }
   POIterator endPostorder() const { return PostBlocks.end(); }

   /// Reverse iterate over the cached postorder blocks.
   RPOIterator beginRPO() const {
     assert(isComplete() && "bad loop DFS");
     return PostBlocks.rbegin();
   }
   RPOIterator endRPO() const { return PostBlocks.rend(); }

   /// Return true if this block has been preorder visited.
   bool hasPreorder(BasicBlock *BB) const { return PostNumbers.count(BB); }

   /// Return true if this block has a postorder number.
   bool hasPostorder(BasicBlock *BB) const {
     DenseMap<BasicBlock*, unsigned>::const_iterator I = PostNumbers.find(BB);
     return I != PostNumbers.end() && I->second;
   }

   /// Get a block's postorder number.
   unsigned getPostorder(BasicBlock *BB) const {
     DenseMap<BasicBlock*, unsigned>::const_iterator I = PostNumbers.find(BB);
     assert(I != PostNumbers.end() && "block not visited by DFS");
     assert(I->second && "block not finished by DFS");
     return I->second;
   }

   /// Get a block's reverse postorder number.
   unsigned getRPO(BasicBlock *BB) const {
     return 1 + PostBlocks.size() - getPostorder(BB);
   }

   void clear() {
     PostNumbers.clear();
     PostBlocks.clear();
   }
 };

 /// Wrapper class to LoopBlocksDFS that provides a standard begin()/end()
 /// interface for the DFS reverse post-order traversal of blocks in a loop body.
 class LoopBlocksRPO {
 private:
   LoopBlocksDFS DFS;

 public:
   LoopBlocksRPO(Loop *Container) : DFS(Container) {}

   /// Traverse the loop blocks and store the DFS result.
   void perform(LoopInfo *LI) {
     DFS.perform(LI);
   }

   /// Reverse iterate over the cached postorder blocks.
   LoopBlocksDFS::RPOIterator begin() const { return DFS.beginRPO(); }
   LoopBlocksDFS::RPOIterator end() const { return DFS.endRPO(); }
 };

 /// Specialize po_iterator_storage to record postorder numbers.
 template<> class po_iterator_storage<LoopBlocksTraversal, true> {
   LoopBlocksTraversal &LBT;
 public:
   po_iterator_storage(LoopBlocksTraversal &lbs) : LBT(lbs) {}
   // These functions are defined below.
   bool insertEdge(Optional<BasicBlock *> From, BasicBlock *To);
   void finishPostorder(BasicBlock *BB);
 };

 /// Traverse the blocks in a loop using a depth-first search.
 class LoopBlocksTraversal {
 public:
   /// Graph traversal iterator.
   typedef po_iterator<BasicBlock*, LoopBlocksTraversal, true> POTIterator;

 private:
   LoopBlocksDFS &DFS;
   LoopInfo *LI;

 public:
   LoopBlocksTraversal(LoopBlocksDFS &Storage, LoopInfo *LInfo) :
     DFS(Storage), LI(LInfo) {}

   /// Postorder traversal over the graph. This only needs to be done once.
   /// po_iterator "automatically" calls back to visitPreorder and
   /// finishPostorder to record the DFS result.
   POTIterator begin() {
     assert(DFS.PostBlocks.empty() && "Need clear DFS result before traversing");
     assert(DFS.L->getNumBlocks() && "po_iterator cannot handle an empty graph");
     return po_ext_begin(DFS.L->getHeader(), *this);
   }
   POTIterator end() {
     // po_ext_end interface requires a basic block, but ignores its value.
     return po_ext_end(DFS.L->getHeader(), *this);
   }

   /// Called by po_iterator upon reaching a block via a CFG edge. If this block
   /// is contained in the loop and has not been visited, then mark it preorder
   /// visited and return true.
   ///
   /// TODO: If anyone is interested, we could record preorder numbers here.
   bool visitPreorder(BasicBlock *BB) {
     if (!DFS.L->contains(LI->getLoopFor(BB)))
       return false;

     return DFS.PostNumbers.insert(std::make_pair(BB, 0)).second;
   }

   /// Called by po_iterator each time it advances, indicating a block's
   /// postorder.
   void finishPostorder(BasicBlock *BB) {
     assert(DFS.PostNumbers.count(BB) && "Loop DFS skipped preorder");
     DFS.PostBlocks.push_back(BB);
     DFS.PostNumbers[BB] = DFS.PostBlocks.size();
   }
 };

 inline bool po_iterator_storage<LoopBlocksTraversal, true>::insertEdge(
     Optional<BasicBlock *> From, BasicBlock *To) {
   return LBT.visitPreorder(To);
 }

 inline void po_iterator_storage<LoopBlocksTraversal, true>::
 finishPostorder(BasicBlock *BB) {
   LBT.finishPostorder(BB);
 }

 } // End namespace llvm

 #endif
	//===--------- LoopIterator.h - Iterate over loop blocks --------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	// This file defines iterators to visit the basic blocks within a loop.
	//
	// These iterators currently visit blocks within subloops as well.
	// Unfortunately we have no efficient way of summarizing loop exits which would
	// allow skipping subloops during traversal.
	//
	// If you want to visit all blocks in a loop and don't need an ordered traveral,
	// use Loop::block_begin() instead.
	//
	// This is intentionally designed to work with ill-formed loops in which the
	// backedge has been deleted. The only prerequisite is that all blocks
	// contained within the loop according to the most recent LoopInfo analysis are
	// reachable from the loop header.
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_ANALYSIS_LOOPITERATOR_H
	#define LLVM_ANALYSIS_LOOPITERATOR_H

	#include "llvm/ADT/PostOrderIterator.h"
	#include "llvm/Analysis/LoopInfo.h"

	namespace llvm {

	class LoopBlocksTraversal;

	// A traits type that is intended to be used in graph algorithms. The graph
	// traits starts at the loop header, and traverses the BasicBlocks that are in
	// the loop body, but not the loop header. Since the loop header is skipped,
	// the back edges are excluded.
	//
	// TODO: Explore the possibility to implement LoopBlocksTraversal in terms of
	// LoopBodyTraits, so that insertEdge doesn't have to be specialized.
	struct LoopBodyTraits {
	using NodeRef = std::pair<const Loop , BasicBlock >;

	// This wraps a const Loop * into the iterator, so we know which edges to
	// filter out.
	class WrappedSuccIterator
	: public iterator_adaptor_base<
	WrappedSuccIterator, succ_iterator,
	typename std::iterator_traits<succ_iterator>::iterator_category,
	NodeRef, std::ptrdiff_t, NodeRef *, NodeRef> {
	using BaseT = iterator_adaptor_base<
	WrappedSuccIterator, succ_iterator,
	typename std::iterator_traits<succ_iterator>::iterator_category,
	NodeRef, std::ptrdiff_t, NodeRef *, NodeRef>;

	const Loop *L;

	public:
	WrappedSuccIterator(succ_iterator Begin, const Loop *L)
	: BaseT(Begin), L(L) {}

	NodeRef operator() const { return {L, I}; }
	};

	struct LoopBodyFilter {
	bool operator()(NodeRef N) const {
	const Loop *L = N.first;
	return N.second != L->getHeader() && L->contains(N.second);
	}
	};

	using ChildIteratorType =
	filter_iterator<WrappedSuccIterator, LoopBodyFilter>;

	static NodeRef getEntryNode(const Loop &G) { return {&G, G.getHeader()}; }

	static ChildIteratorType child_begin(NodeRef Node) {
	return make_filter_range(make_range<WrappedSuccIterator>(
	{succ_begin(Node.second), Node.first},
	{succ_end(Node.second), Node.first}),
	LoopBodyFilter{})
	.begin();
	}

	static ChildIteratorType child_end(NodeRef Node) {
	return make_filter_range(make_range<WrappedSuccIterator>(
	{succ_begin(Node.second), Node.first},
	{succ_end(Node.second), Node.first}),
	LoopBodyFilter{})
	.end();
	}
	};

	/// Store the result of a depth first search within basic blocks contained by a
	/// single loop.
	///
	/// TODO: This could be generalized for any CFG region, or the entire CFG.
	class LoopBlocksDFS {
	public:
	/// Postorder list iterators.
	typedef std::vector<BasicBlock*>::const_iterator POIterator;
	typedef std::vector<BasicBlock*>::const_reverse_iterator RPOIterator;

	friend class LoopBlocksTraversal;

	private:
	Loop *L;

	/// Map each block to its postorder number. A block is only mapped after it is
	/// preorder visited by DFS. It's postorder number is initially zero and set
	/// to nonzero after it is finished by postorder traversal.
	DenseMap<BasicBlock*, unsigned> PostNumbers;
	std::vector<BasicBlock*> PostBlocks;

	public:
	LoopBlocksDFS(Loop *Container) :
	L(Container), PostNumbers(NextPowerOf2(Container->getNumBlocks())) {
	PostBlocks.reserve(Container->getNumBlocks());
	}

	Loop *getLoop() const { return L; }

	/// Traverse the loop blocks and store the DFS result.
	void perform(LoopInfo *LI);

	/// Return true if postorder numbers are assigned to all loop blocks.
	bool isComplete() const { return PostBlocks.size() == L->getNumBlocks(); }

	/// Iterate over the cached postorder blocks.
	POIterator beginPostorder() const {
	assert(isComplete() && "bad loop DFS");
	return PostBlocks.begin();
	}
	POIterator endPostorder() const { return PostBlocks.end(); }

	/// Reverse iterate over the cached postorder blocks.
	RPOIterator beginRPO() const {
	assert(isComplete() && "bad loop DFS");
	return PostBlocks.rbegin();
	}
	RPOIterator endRPO() const { return PostBlocks.rend(); }

	/// Return true if this block has been preorder visited.
	bool hasPreorder(BasicBlock *BB) const { return PostNumbers.count(BB); }

	/// Return true if this block has a postorder number.
	bool hasPostorder(BasicBlock *BB) const {
	DenseMap<BasicBlock*, unsigned>::const_iterator I = PostNumbers.find(BB);
	return I != PostNumbers.end() && I->second;
	}

	/// Get a block's postorder number.
	unsigned getPostorder(BasicBlock *BB) const {
	DenseMap<BasicBlock*, unsigned>::const_iterator I = PostNumbers.find(BB);
	assert(I != PostNumbers.end() && "block not visited by DFS");
	assert(I->second && "block not finished by DFS");
	return I->second;
	}

	/// Get a block's reverse postorder number.
	unsigned getRPO(BasicBlock *BB) const {
	return 1 + PostBlocks.size() - getPostorder(BB);
	}

	void clear() {
	PostNumbers.clear();
	PostBlocks.clear();
	}
	};

	/// Wrapper class to LoopBlocksDFS that provides a standard begin()/end()
	/// interface for the DFS reverse post-order traversal of blocks in a loop body.
	class LoopBlocksRPO {
	private:
	LoopBlocksDFS DFS;

	public:
	LoopBlocksRPO(Loop *Container) : DFS(Container) {}

	/// Traverse the loop blocks and store the DFS result.
	void perform(LoopInfo *LI) {
	DFS.perform(LI);
	}

	/// Reverse iterate over the cached postorder blocks.
	LoopBlocksDFS::RPOIterator begin() const { return DFS.beginRPO(); }
	LoopBlocksDFS::RPOIterator end() const { return DFS.endRPO(); }
	};

	/// Specialize po_iterator_storage to record postorder numbers.
	template<> class po_iterator_storage<LoopBlocksTraversal, true> {
	LoopBlocksTraversal &LBT;
	public:
	po_iterator_storage(LoopBlocksTraversal &lbs) : LBT(lbs) {}
	// These functions are defined below.
	bool insertEdge(Optional<BasicBlock > From, BasicBlock To);
	void finishPostorder(BasicBlock *BB);
	};

	/// Traverse the blocks in a loop using a depth-first search.
	class LoopBlocksTraversal {
	public:
	/// Graph traversal iterator.
	typedef po_iterator<BasicBlock*, LoopBlocksTraversal, true> POTIterator;

	private:
	LoopBlocksDFS &DFS;
	LoopInfo *LI;

	public:
	LoopBlocksTraversal(LoopBlocksDFS &Storage, LoopInfo *LInfo) :
	DFS(Storage), LI(LInfo) {}

	/// Postorder traversal over the graph. This only needs to be done once.
	/// po_iterator "automatically" calls back to visitPreorder and
	/// finishPostorder to record the DFS result.
	POTIterator begin() {
	assert(DFS.PostBlocks.empty() && "Need clear DFS result before traversing");
	assert(DFS.L->getNumBlocks() && "po_iterator cannot handle an empty graph");
	return po_ext_begin(DFS.L->getHeader(), *this);
	}
	POTIterator end() {
	// po_ext_end interface requires a basic block, but ignores its value.
	return po_ext_end(DFS.L->getHeader(), *this);
	}

	/// Called by po_iterator upon reaching a block via a CFG edge. If this block
	/// is contained in the loop and has not been visited, then mark it preorder
	/// visited and return true.
	///
	/// TODO: If anyone is interested, we could record preorder numbers here.
	bool visitPreorder(BasicBlock *BB) {
	if (!DFS.L->contains(LI->getLoopFor(BB)))
	return false;

	return DFS.PostNumbers.insert(std::make_pair(BB, 0)).second;
	}

	/// Called by po_iterator each time it advances, indicating a block's
	/// postorder.
	void finishPostorder(BasicBlock *BB) {
	assert(DFS.PostNumbers.count(BB) && "Loop DFS skipped preorder");
	DFS.PostBlocks.push_back(BB);
	DFS.PostNumbers[BB] = DFS.PostBlocks.size();
	}
	};

	inline bool po_iterator_storage<LoopBlocksTraversal, true>::insertEdge(
	Optional<BasicBlock > From, BasicBlock To) {
	return LBT.visitPreorder(To);
	}

	inline void po_iterator_storage<LoopBlocksTraversal, true>::
	finishPostorder(BasicBlock *BB) {
	LBT.finishPostorder(BB);
	}

	} // End namespace llvm

	#endif