lib/Checker/ExplodedGraph.cpp - clang - Git at Google

 //=-- ExplodedGraph.cpp - Local, Path-Sens. "Exploded Graph" -*- 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 the template classes ExplodedNode and ExplodedGraph,
 //  which represent a path-sensitive, intra-procedural "exploded graph."
 //
 //===----------------------------------------------------------------------===//

 #include "clang/Checker/PathSensitive/ExplodedGraph.h"
 #include "clang/Checker/PathSensitive/GRState.h"
 #include "clang/AST/Stmt.h"
 #include "llvm/ADT/DenseSet.h"
 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/SmallVector.h"
 #include <vector>

 using namespace clang;

 //===----------------------------------------------------------------------===//
 // Node auditing.
 //===----------------------------------------------------------------------===//

 // An out of line virtual method to provide a home for the class vtable.
 ExplodedNode::Auditor::~Auditor() {}

 #ifndef NDEBUG
 static ExplodedNode::Auditor* NodeAuditor = 0;
 #endif

 void ExplodedNode::SetAuditor(ExplodedNode::Auditor* A) {
 #ifndef NDEBUG
   NodeAuditor = A;
 #endif
 }

 //===----------------------------------------------------------------------===//
 // ExplodedNode.
 //===----------------------------------------------------------------------===//

 static inline BumpVector<ExplodedNode*>& getVector(void* P) {
   return *reinterpret_cast<BumpVector<ExplodedNode*>*>(P);
 }

 void ExplodedNode::addPredecessor(ExplodedNode* V, ExplodedGraph &G) {
   assert (!V->isSink());
   Preds.addNode(V, G);
   V->Succs.addNode(this, G);
 #ifndef NDEBUG
   if (NodeAuditor) NodeAuditor->AddEdge(V, this);
 #endif
 }

 void ExplodedNode::NodeGroup::addNode(ExplodedNode* N, ExplodedGraph &G) {
   assert((reinterpret_cast<uintptr_t>(N) & Mask) == 0x0);
   assert(!getFlag());

   if (getKind() == Size1) {
     if (ExplodedNode* NOld = getNode()) {
       BumpVectorContext &Ctx = G.getNodeAllocator();
       BumpVector<ExplodedNode*> *V =
         G.getAllocator().Allocate<BumpVector<ExplodedNode*> >();
       new (V) BumpVector<ExplodedNode*>(Ctx, 4);

       assert((reinterpret_cast<uintptr_t>(V) & Mask) == 0x0);
       V->push_back(NOld, Ctx);
       V->push_back(N, Ctx);
       P = reinterpret_cast<uintptr_t>(V) | SizeOther;
       assert(getPtr() == (void*) V);
       assert(getKind() == SizeOther);
     }
     else {
       P = reinterpret_cast<uintptr_t>(N);
       assert(getKind() == Size1);
     }
   }
   else {
     assert(getKind() == SizeOther);
     getVector(getPtr()).push_back(N, G.getNodeAllocator());
   }
 }

 unsigned ExplodedNode::NodeGroup::size() const {
   if (getFlag())
     return 0;

   if (getKind() == Size1)
     return getNode() ? 1 : 0;
   else
     return getVector(getPtr()).size();
 }

 ExplodedNode **ExplodedNode::NodeGroup::begin() const {
   if (getFlag())
     return NULL;

   if (getKind() == Size1)
     return (ExplodedNode**) (getPtr() ? &P : NULL);
   else
     return const_cast<ExplodedNode**>(&*(getVector(getPtr()).begin()));
 }

 ExplodedNode** ExplodedNode::NodeGroup::end() const {
   if (getFlag())
     return NULL;

   if (getKind() == Size1)
     return (ExplodedNode**) (getPtr() ? &P+1 : NULL);
   else {
     // Dereferencing end() is undefined behaviour. The vector is not empty, so
     // we can dereference the last elem and then add 1 to the result.
     return const_cast<ExplodedNode**>(getVector(getPtr()).end());
   }
 }

 ExplodedNode *ExplodedGraph::getNode(const ProgramPoint& L,
                                      const GRState* State, bool* IsNew) {
   // Profile 'State' to determine if we already have an existing node.
   llvm::FoldingSetNodeID profile;
   void* InsertPos = 0;

   NodeTy::Profile(profile, L, State);
   NodeTy* V = Nodes.FindNodeOrInsertPos(profile, InsertPos);

   if (!V) {
     // Allocate a new node.
     V = (NodeTy*) getAllocator().Allocate<NodeTy>();
     new (V) NodeTy(L, State);

     // Insert the node into the node set and return it.
     Nodes.InsertNode(V, InsertPos);

     ++NumNodes;

     if (IsNew) *IsNew = true;
   }
   else
     if (IsNew) *IsNew = false;

   return V;
 }

 std::pair<ExplodedGraph*, InterExplodedGraphMap*>
 ExplodedGraph::Trim(const NodeTy* const* NBeg, const NodeTy* const* NEnd,
                llvm::DenseMap<const void*, const void*> *InverseMap) const {

   if (NBeg == NEnd)
     return std::make_pair((ExplodedGraph*) 0,
                           (InterExplodedGraphMap*) 0);

   assert (NBeg < NEnd);

   llvm::OwningPtr<InterExplodedGraphMap> M(new InterExplodedGraphMap());

   ExplodedGraph* G = TrimInternal(NBeg, NEnd, M.get(), InverseMap);

   return std::make_pair(static_cast<ExplodedGraph*>(G), M.take());
 }

 ExplodedGraph*
 ExplodedGraph::TrimInternal(const ExplodedNode* const* BeginSources,
                             const ExplodedNode* const* EndSources,
                             InterExplodedGraphMap* M,
                    llvm::DenseMap<const void*, const void*> *InverseMap) const {

   typedef llvm::DenseSet<const ExplodedNode*> Pass1Ty;
   Pass1Ty Pass1;

   typedef llvm::DenseMap<const ExplodedNode*, ExplodedNode*> Pass2Ty;
   Pass2Ty& Pass2 = M->M;

   llvm::SmallVector<const ExplodedNode*, 10> WL1, WL2;

   // ===- Pass 1 (reverse DFS) -===
   for (const ExplodedNode* const* I = BeginSources; I != EndSources; ++I) {
     assert(*I);
     WL1.push_back(*I);
   }

   // Process the first worklist until it is empty.  Because it is a std::list
   // it acts like a FIFO queue.
   while (!WL1.empty()) {
     const ExplodedNode *N = WL1.back();
     WL1.pop_back();

     // Have we already visited this node?  If so, continue to the next one.
     if (Pass1.count(N))
       continue;

     // Otherwise, mark this node as visited.
     Pass1.insert(N);

     // If this is a root enqueue it to the second worklist.
     if (N->Preds.empty()) {
       WL2.push_back(N);
       continue;
     }

     // Visit our predecessors and enqueue them.
     for (ExplodedNode** I=N->Preds.begin(), **E=N->Preds.end(); I!=E; ++I)
       WL1.push_back(*I);
   }

   // We didn't hit a root? Return with a null pointer for the new graph.
   if (WL2.empty())
     return 0;

   // Create an empty graph.
   ExplodedGraph* G = MakeEmptyGraph();

   // ===- Pass 2 (forward DFS to construct the new graph) -===
   while (!WL2.empty()) {
     const ExplodedNode* N = WL2.back();
     WL2.pop_back();

     // Skip this node if we have already processed it.
     if (Pass2.find(N) != Pass2.end())
       continue;

     // Create the corresponding node in the new graph and record the mapping
     // from the old node to the new node.
     ExplodedNode* NewN = G->getNode(N->getLocation(), N->State, NULL);
     Pass2[N] = NewN;

     // Also record the reverse mapping from the new node to the old node.
     if (InverseMap) (*InverseMap)[NewN] = N;

     // If this node is a root, designate it as such in the graph.
     if (N->Preds.empty())
       G->addRoot(NewN);

     // In the case that some of the intended predecessors of NewN have already
     // been created, we should hook them up as predecessors.

     // Walk through the predecessors of 'N' and hook up their corresponding
     // nodes in the new graph (if any) to the freshly created node.
     for (ExplodedNode **I=N->Preds.begin(), **E=N->Preds.end(); I!=E; ++I) {
       Pass2Ty::iterator PI = Pass2.find(*I);
       if (PI == Pass2.end())
         continue;

       NewN->addPredecessor(PI->second, *G);
     }

     // In the case that some of the intended successors of NewN have already
     // been created, we should hook them up as successors.  Otherwise, enqueue
     // the new nodes from the original graph that should have nodes created
     // in the new graph.
     for (ExplodedNode **I=N->Succs.begin(), **E=N->Succs.end(); I!=E; ++I) {
       Pass2Ty::iterator PI = Pass2.find(*I);
       if (PI != Pass2.end()) {
         PI->second->addPredecessor(NewN, *G);
         continue;
       }

       // Enqueue nodes to the worklist that were marked during pass 1.
       if (Pass1.count(*I))
         WL2.push_back(*I);
     }

     // Finally, explictly mark all nodes without any successors as sinks.
     if (N->isSink())
       NewN->markAsSink();
   }

   return G;
 }

 ExplodedNode*
 InterExplodedGraphMap::getMappedNode(const ExplodedNode* N) const {
   llvm::DenseMap<const ExplodedNode*, ExplodedNode*>::const_iterator I =
     M.find(N);

   return I == M.end() ? 0 : I->second;
 }
	//=-- ExplodedGraph.cpp - Local, Path-Sens. "Exploded Graph" -- 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 the template classes ExplodedNode and ExplodedGraph,
	// which represent a path-sensitive, intra-procedural "exploded graph."
	//
	//===----------------------------------------------------------------------===//

	#include "clang/Checker/PathSensitive/ExplodedGraph.h"
	#include "clang/Checker/PathSensitive/GRState.h"
	#include "clang/AST/Stmt.h"
	#include "llvm/ADT/DenseSet.h"
	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/SmallVector.h"
	#include <vector>

	using namespace clang;

	//===----------------------------------------------------------------------===//
	// Node auditing.
	//===----------------------------------------------------------------------===//

	// An out of line virtual method to provide a home for the class vtable.
	ExplodedNode::Auditor::~Auditor() {}

	#ifndef NDEBUG
	static ExplodedNode::Auditor* NodeAuditor = 0;
	#endif

	void ExplodedNode::SetAuditor(ExplodedNode::Auditor* A) {
	#ifndef NDEBUG
	NodeAuditor = A;
	#endif
	}

	//===----------------------------------------------------------------------===//
	// ExplodedNode.
	//===----------------------------------------------------------------------===//

	static inline BumpVector<ExplodedNode>& getVector(void P) {
	return reinterpret_cast<BumpVector<ExplodedNode>*>(P);
	}

	void ExplodedNode::addPredecessor(ExplodedNode* V, ExplodedGraph &G) {
	assert (!V->isSink());
	Preds.addNode(V, G);
	V->Succs.addNode(this, G);
	#ifndef NDEBUG
	if (NodeAuditor) NodeAuditor->AddEdge(V, this);
	#endif
	}

	void ExplodedNode::NodeGroup::addNode(ExplodedNode* N, ExplodedGraph &G) {
	assert((reinterpret_cast<uintptr_t>(N) & Mask) == 0x0);
	assert(!getFlag());

	if (getKind() == Size1) {
	if (ExplodedNode* NOld = getNode()) {
	BumpVectorContext &Ctx = G.getNodeAllocator();
	BumpVector<ExplodedNode> V =
	G.getAllocator().Allocate<BumpVector<ExplodedNode*> >();
	new (V) BumpVector<ExplodedNode*>(Ctx, 4);

	assert((reinterpret_cast<uintptr_t>(V) & Mask) == 0x0);
	V->push_back(NOld, Ctx);
	V->push_back(N, Ctx);
	P = reinterpret_cast<uintptr_t>(V) \| SizeOther;
	assert(getPtr() == (void*) V);
	assert(getKind() == SizeOther);
	}
	else {
	P = reinterpret_cast<uintptr_t>(N);
	assert(getKind() == Size1);
	}
	}
	else {
	assert(getKind() == SizeOther);
	getVector(getPtr()).push_back(N, G.getNodeAllocator());
	}
	}

	unsigned ExplodedNode::NodeGroup::size() const {
	if (getFlag())
	return 0;

	if (getKind() == Size1)
	return getNode() ? 1 : 0;
	else
	return getVector(getPtr()).size();
	}

	ExplodedNode **ExplodedNode::NodeGroup::begin() const {
	if (getFlag())
	return NULL;

	if (getKind() == Size1)
	return (ExplodedNode**) (getPtr() ? &P : NULL);
	else
	return const_cast<ExplodedNode*>(&(getVector(getPtr()).begin()));
	}

	ExplodedNode** ExplodedNode::NodeGroup::end() const {
	if (getFlag())
	return NULL;

	if (getKind() == Size1)
	return (ExplodedNode**) (getPtr() ? &P+1 : NULL);
	else {
	// Dereferencing end() is undefined behaviour. The vector is not empty, so
	// we can dereference the last elem and then add 1 to the result.
	return const_cast<ExplodedNode**>(getVector(getPtr()).end());
	}
	}

	ExplodedNode *ExplodedGraph::getNode(const ProgramPoint& L,
	const GRState* State, bool* IsNew) {
	// Profile 'State' to determine if we already have an existing node.
	llvm::FoldingSetNodeID profile;
	void* InsertPos = 0;

	NodeTy::Profile(profile, L, State);
	NodeTy* V = Nodes.FindNodeOrInsertPos(profile, InsertPos);

	if (!V) {
	// Allocate a new node.
	V = (NodeTy*) getAllocator().Allocate<NodeTy>();
	new (V) NodeTy(L, State);

	// Insert the node into the node set and return it.
	Nodes.InsertNode(V, InsertPos);

	++NumNodes;

	if (IsNew) *IsNew = true;
	}
	else
	if (IsNew) *IsNew = false;

	return V;
	}

	std::pair<ExplodedGraph, InterExplodedGraphMap>
	ExplodedGraph::Trim(const NodeTy* const* NBeg, const NodeTy* const* NEnd,
	llvm::DenseMap<const void, const void> *InverseMap) const {

	if (NBeg == NEnd)
	return std::make_pair((ExplodedGraph*) 0,
	(InterExplodedGraphMap*) 0);

	assert (NBeg < NEnd);

	llvm::OwningPtr<InterExplodedGraphMap> M(new InterExplodedGraphMap());

	ExplodedGraph* G = TrimInternal(NBeg, NEnd, M.get(), InverseMap);

	return std::make_pair(static_cast<ExplodedGraph*>(G), M.take());
	}

	ExplodedGraph*
	ExplodedGraph::TrimInternal(const ExplodedNode* const* BeginSources,
	const ExplodedNode* const* EndSources,
	InterExplodedGraphMap* M,
	llvm::DenseMap<const void, const void> *InverseMap) const {

	typedef llvm::DenseSet<const ExplodedNode*> Pass1Ty;
	Pass1Ty Pass1;

	typedef llvm::DenseMap<const ExplodedNode, ExplodedNode> Pass2Ty;
	Pass2Ty& Pass2 = M->M;

	llvm::SmallVector<const ExplodedNode*, 10> WL1, WL2;

	// ===- Pass 1 (reverse DFS) -===
	for (const ExplodedNode* const* I = BeginSources; I != EndSources; ++I) {
	assert(*I);
	WL1.push_back(*I);
	}

	// Process the first worklist until it is empty. Because it is a std::list
	// it acts like a FIFO queue.
	while (!WL1.empty()) {
	const ExplodedNode *N = WL1.back();
	WL1.pop_back();

	// Have we already visited this node? If so, continue to the next one.
	if (Pass1.count(N))
	continue;

	// Otherwise, mark this node as visited.
	Pass1.insert(N);

	// If this is a root enqueue it to the second worklist.
	if (N->Preds.empty()) {
	WL2.push_back(N);
	continue;
	}

	// Visit our predecessors and enqueue them.
	for (ExplodedNode I=N->Preds.begin(), E=N->Preds.end(); I!=E; ++I)
	WL1.push_back(*I);
	}

	// We didn't hit a root? Return with a null pointer for the new graph.
	if (WL2.empty())
	return 0;

	// Create an empty graph.
	ExplodedGraph* G = MakeEmptyGraph();

	// ===- Pass 2 (forward DFS to construct the new graph) -===
	while (!WL2.empty()) {
	const ExplodedNode* N = WL2.back();
	WL2.pop_back();

	// Skip this node if we have already processed it.
	if (Pass2.find(N) != Pass2.end())
	continue;

	// Create the corresponding node in the new graph and record the mapping
	// from the old node to the new node.
	ExplodedNode* NewN = G->getNode(N->getLocation(), N->State, NULL);
	Pass2[N] = NewN;

	// Also record the reverse mapping from the new node to the old node.
	if (InverseMap) (*InverseMap)[NewN] = N;

	// If this node is a root, designate it as such in the graph.
	if (N->Preds.empty())
	G->addRoot(NewN);

	// In the case that some of the intended predecessors of NewN have already
	// been created, we should hook them up as predecessors.

	// Walk through the predecessors of 'N' and hook up their corresponding
	// nodes in the new graph (if any) to the freshly created node.
	for (ExplodedNode I=N->Preds.begin(), E=N->Preds.end(); I!=E; ++I) {
	Pass2Ty::iterator PI = Pass2.find(*I);
	if (PI == Pass2.end())
	continue;

	NewN->addPredecessor(PI->second, *G);
	}

	// In the case that some of the intended successors of NewN have already
	// been created, we should hook them up as successors. Otherwise, enqueue
	// the new nodes from the original graph that should have nodes created
	// in the new graph.
	for (ExplodedNode I=N->Succs.begin(), E=N->Succs.end(); I!=E; ++I) {
	Pass2Ty::iterator PI = Pass2.find(*I);
	if (PI != Pass2.end()) {
	PI->second->addPredecessor(NewN, *G);
	continue;
	}

	// Enqueue nodes to the worklist that were marked during pass 1.
	if (Pass1.count(*I))
	WL2.push_back(*I);
	}

	// Finally, explictly mark all nodes without any successors as sinks.
	if (N->isSink())
	NewN->markAsSink();
	}

	return G;
	}

	ExplodedNode*
	InterExplodedGraphMap::getMappedNode(const ExplodedNode* N) const {
	llvm::DenseMap<const ExplodedNode, ExplodedNode>::const_iterator I =
	M.find(N);

	return I == M.end() ? 0 : I->second;
	}