lib/StaticAnalyzer/Core/WorkList.cpp - clang - Git at Google

 //===- WorkList.cpp - Analyzer work-list implementation--------------------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//
 //
 // Defines different worklist implementations for the static analyzer.
 //
 //===----------------------------------------------------------------------===//

 #include "clang/StaticAnalyzer/Core/PathSensitive/WorkList.h"
 #include "llvm/ADT/PriorityQueue.h"
 #include "llvm/ADT/DenseSet.h"
 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/STLExtras.h"
 #include "llvm/ADT/Statistic.h"
 #include <deque>
 #include <vector>

 using namespace clang;
 using namespace ento;

 #define DEBUG_TYPE "WorkList"

 STATISTIC(MaxQueueSize, "Maximum size of the worklist");
 STATISTIC(MaxReachableSize, "Maximum size of auxiliary worklist set");

 //===----------------------------------------------------------------------===//
 // Worklist classes for exploration of reachable states.
 //===----------------------------------------------------------------------===//

 namespace {

 class DFS : public WorkList {
   SmallVector<WorkListUnit, 20> Stack;

 public:
   bool hasWork() const override {
     return !Stack.empty();
   }

   void enqueue(const WorkListUnit& U) override {
     Stack.push_back(U);
   }

   WorkListUnit dequeue() override {
     assert(!Stack.empty());
     const WorkListUnit& U = Stack.back();
     Stack.pop_back(); // This technically "invalidates" U, but we are fine.
     return U;
   }
 };

 class BFS : public WorkList {
   std::deque<WorkListUnit> Queue;

 public:
   bool hasWork() const override {
     return !Queue.empty();
   }

   void enqueue(const WorkListUnit& U) override {
     Queue.push_back(U);
   }

   WorkListUnit dequeue() override {
     WorkListUnit U = Queue.front();
     Queue.pop_front();
     return U;
   }
 };

 } // namespace

 // Place the dstor for WorkList here because it contains virtual member
 // functions, and we the code for the dstor generated in one compilation unit.
 WorkList::~WorkList() = default;

 std::unique_ptr<WorkList> WorkList::makeDFS() {
   return std::make_unique<DFS>();
 }

 std::unique_ptr<WorkList> WorkList::makeBFS() {
   return std::make_unique<BFS>();
 }

 namespace {

   class BFSBlockDFSContents : public WorkList {
     std::deque<WorkListUnit> Queue;
     SmallVector<WorkListUnit, 20> Stack;

   public:
     bool hasWork() const override {
       return !Queue.empty() || !Stack.empty();
     }

     void enqueue(const WorkListUnit& U) override {
       if (U.getNode()->getLocation().getAs<BlockEntrance>())
         Queue.push_front(U);
       else
         Stack.push_back(U);
     }

     WorkListUnit dequeue() override {
       // Process all basic blocks to completion.
       if (!Stack.empty()) {
         const WorkListUnit& U = Stack.back();
         Stack.pop_back(); // This technically "invalidates" U, but we are fine.
         return U;
       }

       assert(!Queue.empty());
       // Don't use const reference.  The subsequent pop_back() might make it
       // unsafe.
       WorkListUnit U = Queue.front();
       Queue.pop_front();
       return U;
     }
   };

 } // namespace

 std::unique_ptr<WorkList> WorkList::makeBFSBlockDFSContents() {
   return std::make_unique<BFSBlockDFSContents>();
 }

 namespace {

 class UnexploredFirstStack : public WorkList {
   /// Stack of nodes known to have statements we have not traversed yet.
   SmallVector<WorkListUnit, 20> StackUnexplored;

   /// Stack of all other nodes.
   SmallVector<WorkListUnit, 20> StackOthers;

   using BlockID = unsigned;
   using LocIdentifier = std::pair<BlockID, const StackFrameContext *>;

   llvm::DenseSet<LocIdentifier> Reachable;

 public:
   bool hasWork() const override {
     return !(StackUnexplored.empty() && StackOthers.empty());
   }

   void enqueue(const WorkListUnit &U) override {
     const ExplodedNode *N = U.getNode();
     auto BE = N->getLocation().getAs<BlockEntrance>();

     if (!BE) {
       // Assume the choice of the order of the preceding block entrance was
       // correct.
       StackUnexplored.push_back(U);
     } else {
       LocIdentifier LocId = std::make_pair(
           BE->getBlock()->getBlockID(),
           N->getLocationContext()->getStackFrame());
       auto InsertInfo = Reachable.insert(LocId);

       if (InsertInfo.second) {
         StackUnexplored.push_back(U);
       } else {
         StackOthers.push_back(U);
       }
     }
     MaxReachableSize.updateMax(Reachable.size());
     MaxQueueSize.updateMax(StackUnexplored.size() + StackOthers.size());
   }

   WorkListUnit dequeue() override {
     if (!StackUnexplored.empty()) {
       WorkListUnit &U = StackUnexplored.back();
       StackUnexplored.pop_back();
       return U;
     } else {
       WorkListUnit &U = StackOthers.back();
       StackOthers.pop_back();
       return U;
     }
   }
 };

 } // namespace

 std::unique_ptr<WorkList> WorkList::makeUnexploredFirst() {
   return std::make_unique<UnexploredFirstStack>();
 }

 namespace {
 class UnexploredFirstPriorityQueue : public WorkList {
   using BlockID = unsigned;
   using LocIdentifier = std::pair<BlockID, const StackFrameContext *>;

   // How many times each location was visited.
   // Is signed because we negate it later in order to have a reversed
   // comparison.
   using VisitedTimesMap = llvm::DenseMap<LocIdentifier, int>;

   // Compare by number of times the location was visited first (negated
   // to prefer less often visited locations), then by insertion time (prefer
   // expanding nodes inserted sooner first).
   using QueuePriority = std::pair<int, unsigned long>;
   using QueueItem = std::pair<WorkListUnit, QueuePriority>;

   struct ExplorationComparator {
     bool operator() (const QueueItem &LHS, const QueueItem &RHS) {
       return LHS.second < RHS.second;
     }
   };

   // Number of inserted nodes, used to emulate DFS ordering in the priority
   // queue when insertions are equal.
   unsigned long Counter = 0;

   // Number of times a current location was reached.
   VisitedTimesMap NumReached;

   // The top item is the largest one.
   llvm::PriorityQueue<QueueItem, std::vector<QueueItem>, ExplorationComparator>
       queue;

 public:
   bool hasWork() const override {
     return !queue.empty();
   }

   void enqueue(const WorkListUnit &U) override {
     const ExplodedNode *N = U.getNode();
     unsigned NumVisited = 0;
     if (auto BE = N->getLocation().getAs<BlockEntrance>()) {
       LocIdentifier LocId = std::make_pair(
           BE->getBlock()->getBlockID(),
           N->getLocationContext()->getStackFrame());
       NumVisited = NumReached[LocId]++;
     }

     queue.push(std::make_pair(U, std::make_pair(-NumVisited, ++Counter)));
   }

   WorkListUnit dequeue() override {
     QueueItem U = queue.top();
     queue.pop();
     return U.first;
   }
 };
 } // namespace

 std::unique_ptr<WorkList> WorkList::makeUnexploredFirstPriorityQueue() {
   return std::make_unique<UnexploredFirstPriorityQueue>();
 }

 namespace {
 class UnexploredFirstPriorityLocationQueue : public WorkList {
   using LocIdentifier = const CFGBlock *;

   // How many times each location was visited.
   // Is signed because we negate it later in order to have a reversed
   // comparison.
   using VisitedTimesMap = llvm::DenseMap<LocIdentifier, int>;

   // Compare by number of times the location was visited first (negated
   // to prefer less often visited locations), then by insertion time (prefer
   // expanding nodes inserted sooner first).
   using QueuePriority = std::pair<int, unsigned long>;
   using QueueItem = std::pair<WorkListUnit, QueuePriority>;

   struct ExplorationComparator {
     bool operator() (const QueueItem &LHS, const QueueItem &RHS) {
       return LHS.second < RHS.second;
     }
   };

   // Number of inserted nodes, used to emulate DFS ordering in the priority
   // queue when insertions are equal.
   unsigned long Counter = 0;

   // Number of times a current location was reached.
   VisitedTimesMap NumReached;

   // The top item is the largest one.
   llvm::PriorityQueue<QueueItem, std::vector<QueueItem>, ExplorationComparator>
       queue;

 public:
   bool hasWork() const override {
     return !queue.empty();
   }

   void enqueue(const WorkListUnit &U) override {
     const ExplodedNode *N = U.getNode();
     unsigned NumVisited = 0;
     if (auto BE = N->getLocation().getAs<BlockEntrance>())
       NumVisited = NumReached[BE->getBlock()]++;

     queue.push(std::make_pair(U, std::make_pair(-NumVisited, ++Counter)));
   }

   WorkListUnit dequeue() override {
     QueueItem U = queue.top();
     queue.pop();
     return U.first;
   }

 };

 }

 std::unique_ptr<WorkList> WorkList::makeUnexploredFirstPriorityLocationQueue() {
   return std::make_unique<UnexploredFirstPriorityLocationQueue>();
 }
	//===- WorkList.cpp - Analyzer work-list implementation--------------------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//
	//
	// Defines different worklist implementations for the static analyzer.
	//
	//===----------------------------------------------------------------------===//

	#include "clang/StaticAnalyzer/Core/PathSensitive/WorkList.h"
	#include "llvm/ADT/PriorityQueue.h"
	#include "llvm/ADT/DenseSet.h"
	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/STLExtras.h"
	#include "llvm/ADT/Statistic.h"
	#include <deque>
	#include <vector>

	using namespace clang;
	using namespace ento;

	#define DEBUG_TYPE "WorkList"

	STATISTIC(MaxQueueSize, "Maximum size of the worklist");
	STATISTIC(MaxReachableSize, "Maximum size of auxiliary worklist set");

	//===----------------------------------------------------------------------===//
	// Worklist classes for exploration of reachable states.
	//===----------------------------------------------------------------------===//

	namespace {

	class DFS : public WorkList {
	SmallVector<WorkListUnit, 20> Stack;

	public:
	bool hasWork() const override {
	return !Stack.empty();
	}

	void enqueue(const WorkListUnit& U) override {
	Stack.push_back(U);
	}

	WorkListUnit dequeue() override {
	assert(!Stack.empty());
	const WorkListUnit& U = Stack.back();
	Stack.pop_back(); // This technically "invalidates" U, but we are fine.
	return U;
	}
	};

	class BFS : public WorkList {
	std::deque<WorkListUnit> Queue;

	public:
	bool hasWork() const override {
	return !Queue.empty();
	}

	void enqueue(const WorkListUnit& U) override {
	Queue.push_back(U);
	}

	WorkListUnit dequeue() override {
	WorkListUnit U = Queue.front();
	Queue.pop_front();
	return U;
	}
	};

	} // namespace

	// Place the dstor for WorkList here because it contains virtual member
	// functions, and we the code for the dstor generated in one compilation unit.
	WorkList::~WorkList() = default;

	std::unique_ptr<WorkList> WorkList::makeDFS() {
	return std::make_unique<DFS>();
	}

	std::unique_ptr<WorkList> WorkList::makeBFS() {
	return std::make_unique<BFS>();
	}

	namespace {

	class BFSBlockDFSContents : public WorkList {
	std::deque<WorkListUnit> Queue;
	SmallVector<WorkListUnit, 20> Stack;

	public:
	bool hasWork() const override {
	return !Queue.empty() \|\| !Stack.empty();
	}

	void enqueue(const WorkListUnit& U) override {
	if (U.getNode()->getLocation().getAs<BlockEntrance>())
	Queue.push_front(U);
	else
	Stack.push_back(U);
	}

	WorkListUnit dequeue() override {
	// Process all basic blocks to completion.
	if (!Stack.empty()) {
	const WorkListUnit& U = Stack.back();
	Stack.pop_back(); // This technically "invalidates" U, but we are fine.
	return U;
	}

	assert(!Queue.empty());
	// Don't use const reference. The subsequent pop_back() might make it
	// unsafe.
	WorkListUnit U = Queue.front();
	Queue.pop_front();
	return U;
	}
	};

	} // namespace

	std::unique_ptr<WorkList> WorkList::makeBFSBlockDFSContents() {
	return std::make_unique<BFSBlockDFSContents>();
	}

	namespace {

	class UnexploredFirstStack : public WorkList {
	/// Stack of nodes known to have statements we have not traversed yet.
	SmallVector<WorkListUnit, 20> StackUnexplored;

	/// Stack of all other nodes.
	SmallVector<WorkListUnit, 20> StackOthers;

	using BlockID = unsigned;
	using LocIdentifier = std::pair<BlockID, const StackFrameContext *>;

	llvm::DenseSet<LocIdentifier> Reachable;

	public:
	bool hasWork() const override {
	return !(StackUnexplored.empty() && StackOthers.empty());
	}

	void enqueue(const WorkListUnit &U) override {
	const ExplodedNode *N = U.getNode();
	auto BE = N->getLocation().getAs<BlockEntrance>();

	if (!BE) {
	// Assume the choice of the order of the preceding block entrance was
	// correct.
	StackUnexplored.push_back(U);
	} else {
	LocIdentifier LocId = std::make_pair(
	BE->getBlock()->getBlockID(),
	N->getLocationContext()->getStackFrame());
	auto InsertInfo = Reachable.insert(LocId);

	if (InsertInfo.second) {
	StackUnexplored.push_back(U);
	} else {
	StackOthers.push_back(U);
	}
	}
	MaxReachableSize.updateMax(Reachable.size());
	MaxQueueSize.updateMax(StackUnexplored.size() + StackOthers.size());
	}

	WorkListUnit dequeue() override {
	if (!StackUnexplored.empty()) {
	WorkListUnit &U = StackUnexplored.back();
	StackUnexplored.pop_back();
	return U;
	} else {
	WorkListUnit &U = StackOthers.back();
	StackOthers.pop_back();
	return U;
	}
	}
	};

	} // namespace

	std::unique_ptr<WorkList> WorkList::makeUnexploredFirst() {
	return std::make_unique<UnexploredFirstStack>();
	}

	namespace {
	class UnexploredFirstPriorityQueue : public WorkList {
	using BlockID = unsigned;
	using LocIdentifier = std::pair<BlockID, const StackFrameContext *>;

	// How many times each location was visited.
	// Is signed because we negate it later in order to have a reversed
	// comparison.
	using VisitedTimesMap = llvm::DenseMap<LocIdentifier, int>;

	// Compare by number of times the location was visited first (negated
	// to prefer less often visited locations), then by insertion time (prefer
	// expanding nodes inserted sooner first).
	using QueuePriority = std::pair<int, unsigned long>;
	using QueueItem = std::pair<WorkListUnit, QueuePriority>;

	struct ExplorationComparator {
	bool operator() (const QueueItem &LHS, const QueueItem &RHS) {
	return LHS.second < RHS.second;
	}
	};

	// Number of inserted nodes, used to emulate DFS ordering in the priority
	// queue when insertions are equal.
	unsigned long Counter = 0;

	// Number of times a current location was reached.
	VisitedTimesMap NumReached;

	// The top item is the largest one.
	llvm::PriorityQueue<QueueItem, std::vector<QueueItem>, ExplorationComparator>
	queue;

	public:
	bool hasWork() const override {
	return !queue.empty();
	}

	void enqueue(const WorkListUnit &U) override {
	const ExplodedNode *N = U.getNode();
	unsigned NumVisited = 0;
	if (auto BE = N->getLocation().getAs<BlockEntrance>()) {
	LocIdentifier LocId = std::make_pair(
	BE->getBlock()->getBlockID(),
	N->getLocationContext()->getStackFrame());
	NumVisited = NumReached[LocId]++;
	}

	queue.push(std::make_pair(U, std::make_pair(-NumVisited, ++Counter)));
	}

	WorkListUnit dequeue() override {
	QueueItem U = queue.top();
	queue.pop();
	return U.first;
	}
	};
	} // namespace

	std::unique_ptr<WorkList> WorkList::makeUnexploredFirstPriorityQueue() {
	return std::make_unique<UnexploredFirstPriorityQueue>();
	}

	namespace {
	class UnexploredFirstPriorityLocationQueue : public WorkList {
	using LocIdentifier = const CFGBlock *;

	// How many times each location was visited.
	// Is signed because we negate it later in order to have a reversed
	// comparison.
	using VisitedTimesMap = llvm::DenseMap<LocIdentifier, int>;

	// Compare by number of times the location was visited first (negated
	// to prefer less often visited locations), then by insertion time (prefer
	// expanding nodes inserted sooner first).
	using QueuePriority = std::pair<int, unsigned long>;
	using QueueItem = std::pair<WorkListUnit, QueuePriority>;

	struct ExplorationComparator {
	bool operator() (const QueueItem &LHS, const QueueItem &RHS) {
	return LHS.second < RHS.second;
	}
	};

	// Number of inserted nodes, used to emulate DFS ordering in the priority
	// queue when insertions are equal.
	unsigned long Counter = 0;

	// Number of times a current location was reached.
	VisitedTimesMap NumReached;

	// The top item is the largest one.
	llvm::PriorityQueue<QueueItem, std::vector<QueueItem>, ExplorationComparator>
	queue;

	public:
	bool hasWork() const override {
	return !queue.empty();
	}

	void enqueue(const WorkListUnit &U) override {
	const ExplodedNode *N = U.getNode();
	unsigned NumVisited = 0;
	if (auto BE = N->getLocation().getAs<BlockEntrance>())
	NumVisited = NumReached[BE->getBlock()]++;

	queue.push(std::make_pair(U, std::make_pair(-NumVisited, ++Counter)));
	}

	WorkListUnit dequeue() override {
	QueueItem U = queue.top();
	queue.pop();
	return U.first;
	}

	};

	}

	std::unique_ptr<WorkList> WorkList::makeUnexploredFirstPriorityLocationQueue() {
	return std::make_unique<UnexploredFirstPriorityLocationQueue>();
	}