lib/Analysis/IntervalPartition.cpp - llvm-project/clang - Git at Google

 //===- IntervalPartition.cpp - CFG Partitioning into Intervals --*- 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 functionality for partitioning a CFG into intervals.
 //
 //===----------------------------------------------------------------------===//

 #include "clang/Analysis/Analyses/IntervalPartition.h"
 #include "clang/Analysis/CFG.h"
 #include "llvm/ADT/BitVector.h"
 #include "llvm/ADT/STLExtras.h"
 #include <optional>
 #include <queue>
 #include <vector>

 namespace clang {

 // Intermediate data used in constructing a CFGIntervalNode.
 template <typename Node> struct BuildResult {
   // Use a vector to maintain the insertion order. Given the expected small
   // number of nodes, vector should be sufficiently efficient. Elements must not
   // be null.
   std::vector<const Node *> Nodes;
   // Elements must not be null.
   llvm::SmallDenseSet<const Node *> Successors;
 };

 namespace internal {
 static unsigned getID(const CFGBlock &B) { return B.getBlockID(); }
 static unsigned getID(const CFGIntervalNode &I) { return I.ID; }

 // `Node` must be one of `CFGBlock` or `CFGIntervalNode`.
 template <typename Node>
 BuildResult<Node> buildInterval(llvm::BitVector &Partitioned,
                                 const Node *Header) {
   assert(Header != nullptr);
   BuildResult<Node> Interval;
   Interval.Nodes.push_back(Header);
   Partitioned.set(getID(*Header));

   // FIXME: Compare performance against using RPO to consider nodes, rather than
   // following successors.
   //
   // Elements must not be null. Duplicates are prevented using `Workset`, below.
   std::queue<const Node *> Worklist;
   llvm::BitVector Workset(Partitioned.size(), false);
   for (const Node *S : Header->succs())
     if (S != nullptr)
       if (auto SID = getID(*S); !Partitioned.test(SID)) {
         // Successors are unique, so we don't test against `Workset` before
         // adding to `Worklist`.
         Worklist.push(S);
         Workset.set(SID);
       }

   // Contains successors of blocks in the interval that couldn't be added to the
   // interval on their first encounter. This occurs when they have a predecessor
   // that is either definitively outside the interval or hasn't been considered
   // yet. In the latter case, we'll revisit the block through some other path
   // from the interval. At the end of processing the worklist, we filter out any
   // that ended up in the interval to produce the output set of interval
   // successors. Elements are never null.
   std::vector<const Node *> MaybeSuccessors;

   while (!Worklist.empty()) {
     const auto *B = Worklist.front();
     auto ID = getID(*B);
     Worklist.pop();
     Workset.reset(ID);

     // Check whether all predecessors are in the interval, in which case `B`
     // is included as well.
     bool AllInInterval = llvm::all_of(B->preds(), [&](const Node *P) {
       return llvm::is_contained(Interval.Nodes, P);
     });
     if (AllInInterval) {
       Interval.Nodes.push_back(B);
       Partitioned.set(ID);
       for (const Node *S : B->succs())
         if (S != nullptr)
           if (auto SID = getID(*S);
               !Partitioned.test(SID) && !Workset.test(SID)) {
             Worklist.push(S);
             Workset.set(SID);
           }
     } else {
       MaybeSuccessors.push_back(B);
     }
   }

   // Any block successors not in the current interval are interval successors.
   for (const Node *B : MaybeSuccessors)
     if (!llvm::is_contained(Interval.Nodes, B))
       Interval.Successors.insert(B);

   return Interval;
 }

 template <typename Node>
 void fillIntervalNode(CFGIntervalGraph &Graph,
                       std::vector<CFGIntervalNode *> &Index,
                       std::queue<const Node *> &Successors,
                       llvm::BitVector &Partitioned, const Node *Header) {
   BuildResult<Node> Result = buildInterval(Partitioned, Header);
   for (const auto *S : Result.Successors)
     Successors.push(S);

   CFGIntervalNode &Interval = Graph.emplace_back(Graph.size());

   // Index the nodes of the new interval. The index maps nodes from the input
   // graph (specifically, `Result.Nodes`) to identifiers of nodes in the output
   // graph. In this case, the new interval has identifier `ID` so all of its
   // nodes (`Result.Nodes`) map to `ID`.
   for (const auto *N : Result.Nodes) {
     assert(N != nullptr);
     assert(getID(*N) < Index.size());
     Index[getID(*N)] = &Interval;
   }

   if constexpr (std::is_same_v<std::decay_t<Node>, CFGBlock>)
     Interval.Nodes = std::move(Result.Nodes);
   else {
     std::vector<const CFGBlock *> Nodes;
     // Flatten the sub vectors into a single list.
     size_t Count = 0;
     for (auto &N : Result.Nodes)
       Count += N->Nodes.size();
     Nodes.reserve(Count);
     for (auto &N : Result.Nodes)
       Nodes.insert(Nodes.end(), N->Nodes.begin(), N->Nodes.end());
     Interval.Nodes = std::move(Nodes);
   }
 }

 template <typename Node>
 CFGIntervalGraph partitionIntoIntervalsImpl(unsigned NumBlockIDs,
                                             const Node *EntryBlock) {
   assert(EntryBlock != nullptr);
   CFGIntervalGraph Graph;
   // `Index` maps all of the nodes of the input graph to the interval to which
   // they are assigned in the output graph. The values (interval pointers) are
   // never null.
   std::vector<CFGIntervalNode *> Index(NumBlockIDs, nullptr);

   // Lists header nodes (from the input graph) and their associated
   // interval. Since header nodes can vary in type and are only needed within
   // this function, we record them separately from `CFGIntervalNode`. This
   // choice enables to express `CFGIntervalNode` without using a variant.
   std::vector<std::pair<const Node *, CFGIntervalNode *>> Intervals;
   llvm::BitVector Partitioned(NumBlockIDs, false);
   std::queue<const Node *> Successors;

   fillIntervalNode(Graph, Index, Successors, Partitioned, EntryBlock);
   Intervals.emplace_back(EntryBlock, &Graph.back());

   while (!Successors.empty()) {
     const auto *B = Successors.front();
     Successors.pop();
     assert(B != nullptr);
     if (Partitioned.test(getID(*B)))
       continue;

     // B has not been partitioned, but it has a predecessor that has. Create a
     // new interval from `B`.
     fillIntervalNode(Graph, Index, Successors, Partitioned, B);
     Intervals.emplace_back(B, &Graph.back());
   }

   // Go back and patch up all the Intervals -- the successors and predecessors.
   for (auto [H, N] : Intervals) {
     // Map input-graph predecessors to output-graph nodes and mark those as
     // predecessors of `N`. Then, mark `N` as a successor of said predecessor.
     for (const Node *P : H->preds()) {
       if (P == nullptr)
         continue;

       assert(getID(*P) < NumBlockIDs);
       CFGIntervalNode *Pred = Index[getID(*P)];
       if (Pred == nullptr)
         // Unreachable node.
         continue;
       if (Pred != N // Not a backedge.
           && N->Predecessors.insert(Pred).second)
         // Note: given the guard above, which guarantees we only ever insert
         // unique elements, we could use a simple list (like `vector`) for
         // `Successors`, rather than a set.
         Pred->Successors.insert(N);
     }
   }

   return Graph;
 }

 std::vector<const CFGBlock *> buildInterval(const CFGBlock *Header) {
   llvm::BitVector Partitioned(Header->getParent()->getNumBlockIDs(), false);
   return buildInterval(Partitioned, Header).Nodes;
 }

 CFGIntervalGraph partitionIntoIntervals(const CFG &Cfg) {
   return partitionIntoIntervalsImpl(Cfg.getNumBlockIDs(), &Cfg.getEntry());
 }

 CFGIntervalGraph partitionIntoIntervals(const CFGIntervalGraph &Graph) {
   return partitionIntoIntervalsImpl(Graph.size(), &Graph[0]);
 }
 } // namespace internal

 std::optional<std::vector<const CFGBlock *>> getIntervalWTO(const CFG &Cfg) {
   // Backing storage for the allocated nodes in each graph.
   unsigned PrevSize = Cfg.size();
   if (PrevSize == 0)
     return {};
   internal::CFGIntervalGraph Graph = internal::partitionIntoIntervals(Cfg);
   unsigned Size = Graph.size();
   while (Size > 1 && Size < PrevSize) {
     PrevSize = Graph.size();
     Graph = internal::partitionIntoIntervals(Graph);
     Size = Graph.size();
   }
   if (Size > 1)
     // Not reducible.
     return std::nullopt;

   assert(Size != 0);
   return std::move(Graph[0].Nodes);
 }

 WTOCompare::WTOCompare(const WeakTopologicalOrdering &WTO) {
   if (WTO.empty())
     return;
   auto N = WTO[0]->getParent()->getNumBlockIDs();
   BlockOrder.resize(N, 0);
   for (unsigned I = 0, S = WTO.size(); I < S; ++I)
     BlockOrder[WTO[I]->getBlockID()] = I + 1;
 }
 } // namespace clang
	//===- IntervalPartition.cpp - CFG Partitioning into Intervals --- 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 functionality for partitioning a CFG into intervals.
	//
	//===----------------------------------------------------------------------===//

	#include "clang/Analysis/Analyses/IntervalPartition.h"
	#include "clang/Analysis/CFG.h"
	#include "llvm/ADT/BitVector.h"
	#include "llvm/ADT/STLExtras.h"
	#include <optional>
	#include <queue>
	#include <vector>

	namespace clang {

	// Intermediate data used in constructing a CFGIntervalNode.
	template <typename Node> struct BuildResult {
	// Use a vector to maintain the insertion order. Given the expected small
	// number of nodes, vector should be sufficiently efficient. Elements must not
	// be null.
	std::vector<const Node *> Nodes;
	// Elements must not be null.
	llvm::SmallDenseSet<const Node *> Successors;
	};

	namespace internal {
	static unsigned getID(const CFGBlock &B) { return B.getBlockID(); }
	static unsigned getID(const CFGIntervalNode &I) { return I.ID; }

	// `Node` must be one of `CFGBlock` or `CFGIntervalNode`.
	template <typename Node>
	BuildResult<Node> buildInterval(llvm::BitVector &Partitioned,
	const Node *Header) {
	assert(Header != nullptr);
	BuildResult<Node> Interval;
	Interval.Nodes.push_back(Header);
	Partitioned.set(getID(*Header));

	// FIXME: Compare performance against using RPO to consider nodes, rather than
	// following successors.
	//
	// Elements must not be null. Duplicates are prevented using `Workset`, below.
	std::queue<const Node *> Worklist;
	llvm::BitVector Workset(Partitioned.size(), false);
	for (const Node *S : Header->succs())
	if (S != nullptr)
	if (auto SID = getID(*S); !Partitioned.test(SID)) {
	// Successors are unique, so we don't test against `Workset` before
	// adding to `Worklist`.
	Worklist.push(S);
	Workset.set(SID);
	}

	// Contains successors of blocks in the interval that couldn't be added to the
	// interval on their first encounter. This occurs when they have a predecessor
	// that is either definitively outside the interval or hasn't been considered
	// yet. In the latter case, we'll revisit the block through some other path
	// from the interval. At the end of processing the worklist, we filter out any
	// that ended up in the interval to produce the output set of interval
	// successors. Elements are never null.
	std::vector<const Node *> MaybeSuccessors;

	while (!Worklist.empty()) {
	const auto *B = Worklist.front();
	auto ID = getID(*B);
	Worklist.pop();
	Workset.reset(ID);

	// Check whether all predecessors are in the interval, in which case `B`
	// is included as well.
	bool AllInInterval = llvm::all_of(B->preds(), [&](const Node *P) {
	return llvm::is_contained(Interval.Nodes, P);
	});
	if (AllInInterval) {
	Interval.Nodes.push_back(B);
	Partitioned.set(ID);
	for (const Node *S : B->succs())
	if (S != nullptr)
	if (auto SID = getID(*S);
	!Partitioned.test(SID) && !Workset.test(SID)) {
	Worklist.push(S);
	Workset.set(SID);
	}
	} else {
	MaybeSuccessors.push_back(B);
	}
	}

	// Any block successors not in the current interval are interval successors.
	for (const Node *B : MaybeSuccessors)
	if (!llvm::is_contained(Interval.Nodes, B))
	Interval.Successors.insert(B);

	return Interval;
	}

	template <typename Node>
	void fillIntervalNode(CFGIntervalGraph &Graph,
	std::vector<CFGIntervalNode *> &Index,
	std::queue<const Node *> &Successors,
	llvm::BitVector &Partitioned, const Node *Header) {
	BuildResult<Node> Result = buildInterval(Partitioned, Header);
	for (const auto *S : Result.Successors)
	Successors.push(S);

	CFGIntervalNode &Interval = Graph.emplace_back(Graph.size());

	// Index the nodes of the new interval. The index maps nodes from the input
	// graph (specifically, `Result.Nodes`) to identifiers of nodes in the output
	// graph. In this case, the new interval has identifier `ID` so all of its
	// nodes (`Result.Nodes`) map to `ID`.
	for (const auto *N : Result.Nodes) {
	assert(N != nullptr);
	assert(getID(*N) < Index.size());
	Index[getID(*N)] = &Interval;
	}

	if constexpr (std::is_same_v<std::decay_t<Node>, CFGBlock>)
	Interval.Nodes = std::move(Result.Nodes);
	else {
	std::vector<const CFGBlock *> Nodes;
	// Flatten the sub vectors into a single list.
	size_t Count = 0;
	for (auto &N : Result.Nodes)
	Count += N->Nodes.size();
	Nodes.reserve(Count);
	for (auto &N : Result.Nodes)
	Nodes.insert(Nodes.end(), N->Nodes.begin(), N->Nodes.end());
	Interval.Nodes = std::move(Nodes);
	}
	}

	template <typename Node>
	CFGIntervalGraph partitionIntoIntervalsImpl(unsigned NumBlockIDs,
	const Node *EntryBlock) {
	assert(EntryBlock != nullptr);
	CFGIntervalGraph Graph;
	// `Index` maps all of the nodes of the input graph to the interval to which
	// they are assigned in the output graph. The values (interval pointers) are
	// never null.
	std::vector<CFGIntervalNode *> Index(NumBlockIDs, nullptr);

	// Lists header nodes (from the input graph) and their associated
	// interval. Since header nodes can vary in type and are only needed within
	// this function, we record them separately from `CFGIntervalNode`. This
	// choice enables to express `CFGIntervalNode` without using a variant.
	std::vector<std::pair<const Node , CFGIntervalNode >> Intervals;
	llvm::BitVector Partitioned(NumBlockIDs, false);
	std::queue<const Node *> Successors;

	fillIntervalNode(Graph, Index, Successors, Partitioned, EntryBlock);
	Intervals.emplace_back(EntryBlock, &Graph.back());

	while (!Successors.empty()) {
	const auto *B = Successors.front();
	Successors.pop();
	assert(B != nullptr);
	if (Partitioned.test(getID(*B)))
	continue;

	// B has not been partitioned, but it has a predecessor that has. Create a
	// new interval from `B`.
	fillIntervalNode(Graph, Index, Successors, Partitioned, B);
	Intervals.emplace_back(B, &Graph.back());
	}

	// Go back and patch up all the Intervals -- the successors and predecessors.
	for (auto [H, N] : Intervals) {
	// Map input-graph predecessors to output-graph nodes and mark those as
	// predecessors of `N`. Then, mark `N` as a successor of said predecessor.
	for (const Node *P : H->preds()) {
	if (P == nullptr)
	continue;

	assert(getID(*P) < NumBlockIDs);
	CFGIntervalNode Pred = Index[getID(P)];
	if (Pred == nullptr)
	// Unreachable node.
	continue;
	if (Pred != N // Not a backedge.
	&& N->Predecessors.insert(Pred).second)
	// Note: given the guard above, which guarantees we only ever insert
	// unique elements, we could use a simple list (like `vector`) for
	// `Successors`, rather than a set.
	Pred->Successors.insert(N);
	}
	}

	return Graph;
	}

	std::vector<const CFGBlock > buildInterval(const CFGBlock Header) {
	llvm::BitVector Partitioned(Header->getParent()->getNumBlockIDs(), false);
	return buildInterval(Partitioned, Header).Nodes;
	}

	CFGIntervalGraph partitionIntoIntervals(const CFG &Cfg) {
	return partitionIntoIntervalsImpl(Cfg.getNumBlockIDs(), &Cfg.getEntry());
	}

	CFGIntervalGraph partitionIntoIntervals(const CFGIntervalGraph &Graph) {
	return partitionIntoIntervalsImpl(Graph.size(), &Graph[0]);
	}
	} // namespace internal

	std::optional<std::vector<const CFGBlock *>> getIntervalWTO(const CFG &Cfg) {
	// Backing storage for the allocated nodes in each graph.
	unsigned PrevSize = Cfg.size();
	if (PrevSize == 0)
	return {};
	internal::CFGIntervalGraph Graph = internal::partitionIntoIntervals(Cfg);
	unsigned Size = Graph.size();
	while (Size > 1 && Size < PrevSize) {
	PrevSize = Graph.size();
	Graph = internal::partitionIntoIntervals(Graph);
	Size = Graph.size();
	}
	if (Size > 1)
	// Not reducible.
	return std::nullopt;

	assert(Size != 0);
	return std::move(Graph[0].Nodes);
	}

	WTOCompare::WTOCompare(const WeakTopologicalOrdering &WTO) {
	if (WTO.empty())
	return;
	auto N = WTO[0]->getParent()->getNumBlockIDs();
	BlockOrder.resize(N, 0);
	for (unsigned I = 0, S = WTO.size(); I < S; ++I)
	BlockOrder[WTO[I]->getBlockID()] = I + 1;
	}
	} // namespace clang