llvm/lib/Transforms/Instrumentation/ProfilePaths/RetracePath.cpp - toolchain/llvm-project - Gitiles

 //===----Instrumentation/ProfilePaths/RetracePath.cppTrigger.cpp--*- C++ -*--=//
 //
 // Retraces a path of BasicBlock, given a path number and a graph!
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/Module.h"
 #include "llvm/iTerminators.h"
 #include "llvm/iOther.h"
 #include "llvm/Support/CFG.h"
 #include "Graph.h"

 using std::vector;
 using std::map;
 using std::cerr;

 //Routines to get the path trace!

 void getPathFrmNode(Node *n, vector<BasicBlock*> &vBB, int pathNo, Graph g,
 		    vector<Edge> &stDummy, vector<Edge> &exDummy,
 		    vector<Edge> &be,
 		    double strand){
   Graph::nodeList nlist=g.getNodeList(n);

   int maxCount=-9999999;
   bool isStart=false;

   if(*n==*g.getRoot())//its root: so first node of path
     isStart=true;

   double edgeRnd=0;
   Node *nextRoot=n;
   for(Graph::nodeList::iterator NLI=nlist.begin(), NLE=nlist.end(); NLI!=NLE;
       ++NLI){
     if(NLI->weight>maxCount && NLI->weight<=pathNo){
       maxCount=NLI->weight;
       nextRoot=NLI->element;
       edgeRnd=NLI->randId;
       if(isStart)
 	strand=NLI->randId;
     }
   }

   if(!isStart)
     assert(strand!=-1 && "strand not assigned!");

   assert(!(*nextRoot==*n && pathNo>0) && "No more BBs to go");
   assert(!(*nextRoot==*g.getExit() && pathNo-maxCount!=0) && "Reached exit");

   vBB.push_back(n->getElement());

   if(pathNo-maxCount==0 && *nextRoot==*g.getExit()){

     //look for strnd and edgeRnd now:
     bool has1=false, has2=false;
     //check if exit has it
     for(vector<Edge>::iterator VI=exDummy.begin(), VE=exDummy.end(); VI!=VE;
 	++VI){
       if(VI->getRandId()==edgeRnd){
 	has2=true;
 	break;
       }
     }

     //check if start has it
     for(vector<Edge>::iterator VI=stDummy.begin(), VE=stDummy.end(); VI!=VE;
 	++VI){
       if(VI->getRandId()==strand){
 	has1=true;
 	break;
       }
     }

     if(has1){
       //find backedge with endpoint vBB[1]
       for(vector<Edge>::iterator VI=be.begin(), VE=be.end(); VI!=VE; ++VI){
 	assert(vBB.size()>0 && "vector too small");
 	if( VI->getSecond()->getElement() == vBB[1] ){
 	  //vBB[0]=VI->getFirst()->getElement();
           vBB.erase(vBB.begin());
 	  break;
 	}
       }
     }

     if(has2){
       //find backedge with startpoint vBB[vBB.size()-1]
       for(vector<Edge>::iterator VI=be.begin(), VE=be.end(); VI!=VE; ++VI){
 	assert(vBB.size()>0 && "vector too small");
 	if( VI->getFirst()->getElement() == vBB[vBB.size()-1] &&
             VI->getSecond()->getElement() == vBB[0]){
 	  //vBB.push_back(VI->getSecond()->getElement());
 	  break;
 	}
       }
     }
     else
       vBB.push_back(nextRoot->getElement());

     return;
   }

   assert(pathNo-maxCount>=0);

   return getPathFrmNode(nextRoot, vBB, pathNo-maxCount, g, stDummy,
 			exDummy, be, strand);
 }


 static Node *findBB(std::vector<Node *> &st, BasicBlock *BB){
   for(std::vector<Node *>::iterator si=st.begin(); si!=st.end(); ++si){
     if(((*si)->getElement())==BB){
       return *si;
     }
   }
   return NULL;
 }

 void getBBtrace(vector<BasicBlock *> &vBB, int pathNo, Function *M){
   //step 1: create graph
   //Transform the cfg s.t. we have just one exit node

   std::vector<Node *> nodes;
   std::vector<Edge> edges;
   Node *tmp;
   Node *exitNode=0, *startNode=0;
   static std::map<Function *, Graph *> graphMap;
   static std::map<Function *, vector<Edge> > stMap, exMap, beMap;

   if(!graphMap[M]){
     BasicBlock *ExitNode = 0;
     for (Function::iterator I = M->begin(), E = M->end(); I != E; ++I){
       if (isa<ReturnInst>(I->getTerminator())) {
         ExitNode = &*I;
         break;
       }
     }

     assert(ExitNode!=0 && "exitnode not found");

     //iterating over BBs and making graph
     //The nodes must be uniquely identified:
     //That is, no two nodes must hav same BB*

     //First enter just nodes: later enter edges
     for(Function::iterator BB = M->begin(), BE=M->end(); BB != BE; ++BB){
       if(BB->size()==2){
         const Instruction *inst = BB->getInstList().begin();
         if(isa<CallInst>(inst)){
           Instruction *ii1 = BB->getInstList().begin();
           CallInst *callInst = dyn_cast<CallInst>(ii1);
           if(callInst->getCalledFunction()->getName()=="trigger")
             continue;
         }
       }
       Node *nd=new Node(BB);
       nodes.push_back(nd);
       if(&*BB==ExitNode)
         exitNode=nd;
       if(&*BB==&M->front())
         startNode=nd;
     }

     assert(exitNode!=0 && startNode!=0 && "Start or exit not found!");

     for (Function::iterator BB = M->begin(), BE=M->end(); BB != BE; ++BB){
       if(BB->size()==2){
         const Instruction *inst = BB->getInstList().begin();
         if(isa<CallInst>(inst)){
           Instruction *ii1 = BB->getInstList().begin();
           CallInst *callInst = dyn_cast<CallInst>(ii1);
           if(callInst->getCalledFunction()->getName()=="trigger")
             continue;
         }
       }

       Node *nd=findBB(nodes, BB);
       assert(nd && "No node for this edge!");

       for(BasicBlock::succ_iterator s=succ_begin(&*BB), se=succ_end(&*BB);
           s!=se; ++s){
         if((*s)->size()==2){
           const Instruction *inst = (*s)->getInstList().begin();
           if(isa<CallInst>(inst)){
             Instruction *ii1 = (*s)->getInstList().begin();
             CallInst *callInst = dyn_cast<CallInst>(ii1);
             if(callInst->getCalledFunction()->getName()=="trigger")
               continue;
           }
         }

         Node *nd2=findBB(nodes,*s);
         assert(nd2 && "No node for this edge!");
         Edge ed(nd,nd2,0);
         edges.push_back(ed);
       }
     }

     graphMap[M]= new Graph(nodes,edges, startNode, exitNode);

     Graph *g = graphMap[M];

     if (M->size() <= 1) return; //uninstrumented

     //step 2: getBackEdges
     //vector<Edge> be;
     std::map<Node *, int> nodePriority;
     g->getBackEdges(beMap[M], nodePriority);

     //step 3: add dummy edges
     //vector<Edge> stDummy;
     //vector<Edge> exDummy;
     addDummyEdges(stMap[M], exMap[M], *g, beMap[M]);

     //step 4: value assgn to edges
     int numPaths = valueAssignmentToEdges(*g, nodePriority, beMap[M]);
   }

   //step 5: now travel from root, select max(edge) < pathNo,
   //and go on until reach the exit
   return getPathFrmNode(graphMap[M]->getRoot(), vBB, pathNo, *graphMap[M],
                         stMap[M], exMap[M], beMap[M], -1);
 }
	//===----Instrumentation/ProfilePaths/RetracePath.cppTrigger.cpp--- C++ ---=//
	//
	// Retraces a path of BasicBlock, given a path number and a graph!
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/Module.h"
	#include "llvm/iTerminators.h"
	#include "llvm/iOther.h"
	#include "llvm/Support/CFG.h"
	#include "Graph.h"

	using std::vector;
	using std::map;
	using std::cerr;

	//Routines to get the path trace!

	void getPathFrmNode(Node n, vector<BasicBlock> &vBB, int pathNo, Graph g,
	vector<Edge> &stDummy, vector<Edge> &exDummy,
	vector<Edge> &be,
	double strand){
	Graph::nodeList nlist=g.getNodeList(n);

	int maxCount=-9999999;
	bool isStart=false;

	if(n==g.getRoot())//its root: so first node of path
	isStart=true;

	double edgeRnd=0;
	Node *nextRoot=n;
	for(Graph::nodeList::iterator NLI=nlist.begin(), NLE=nlist.end(); NLI!=NLE;
	++NLI){
	if(NLI->weight>maxCount && NLI->weight<=pathNo){
	maxCount=NLI->weight;
	nextRoot=NLI->element;
	edgeRnd=NLI->randId;
	if(isStart)
	strand=NLI->randId;
	}
	}

	if(!isStart)
	assert(strand!=-1 && "strand not assigned!");

	assert(!(nextRoot==n && pathNo>0) && "No more BBs to go");
	assert(!(nextRoot==g.getExit() && pathNo-maxCount!=0) && "Reached exit");

	vBB.push_back(n->getElement());

	if(pathNo-maxCount==0 && nextRoot==g.getExit()){

	//look for strnd and edgeRnd now:
	bool has1=false, has2=false;
	//check if exit has it
	for(vector<Edge>::iterator VI=exDummy.begin(), VE=exDummy.end(); VI!=VE;
	++VI){
	if(VI->getRandId()==edgeRnd){
	has2=true;
	break;
	}
	}

	//check if start has it
	for(vector<Edge>::iterator VI=stDummy.begin(), VE=stDummy.end(); VI!=VE;
	++VI){
	if(VI->getRandId()==strand){
	has1=true;
	break;
	}
	}

	if(has1){
	//find backedge with endpoint vBB[1]
	for(vector<Edge>::iterator VI=be.begin(), VE=be.end(); VI!=VE; ++VI){
	assert(vBB.size()>0 && "vector too small");
	if( VI->getSecond()->getElement() == vBB[1] ){
	//vBB[0]=VI->getFirst()->getElement();
	vBB.erase(vBB.begin());
	break;
	}
	}
	}

	if(has2){
	//find backedge with startpoint vBB[vBB.size()-1]
	for(vector<Edge>::iterator VI=be.begin(), VE=be.end(); VI!=VE; ++VI){
	assert(vBB.size()>0 && "vector too small");
	if( VI->getFirst()->getElement() == vBB[vBB.size()-1] &&
	VI->getSecond()->getElement() == vBB[0]){
	//vBB.push_back(VI->getSecond()->getElement());
	break;
	}
	}
	}
	else
	vBB.push_back(nextRoot->getElement());

	return;
	}

	assert(pathNo-maxCount>=0);

	return getPathFrmNode(nextRoot, vBB, pathNo-maxCount, g, stDummy,
	exDummy, be, strand);
	}


	static Node findBB(std::vector<Node > &st, BasicBlock *BB){
	for(std::vector<Node *>::iterator si=st.begin(); si!=st.end(); ++si){
	if(((*si)->getElement())==BB){
	return *si;
	}
	}
	return NULL;
	}

	void getBBtrace(vector<BasicBlock > &vBB, int pathNo, Function M){
	//step 1: create graph
	//Transform the cfg s.t. we have just one exit node

	std::vector<Node *> nodes;
	std::vector<Edge> edges;
	Node *tmp;
	Node exitNode=0, startNode=0;
	static std::map<Function , Graph > graphMap;
	static std::map<Function *, vector<Edge> > stMap, exMap, beMap;

	if(!graphMap[M]){
	BasicBlock *ExitNode = 0;
	for (Function::iterator I = M->begin(), E = M->end(); I != E; ++I){
	if (isa<ReturnInst>(I->getTerminator())) {
	ExitNode = &*I;
	break;
	}
	}

	assert(ExitNode!=0 && "exitnode not found");

	//iterating over BBs and making graph
	//The nodes must be uniquely identified:
	//That is, no two nodes must hav same BB*

	//First enter just nodes: later enter edges
	for(Function::iterator BB = M->begin(), BE=M->end(); BB != BE; ++BB){
	if(BB->size()==2){
	const Instruction *inst = BB->getInstList().begin();
	if(isa<CallInst>(inst)){
	Instruction *ii1 = BB->getInstList().begin();
	CallInst *callInst = dyn_cast<CallInst>(ii1);
	if(callInst->getCalledFunction()->getName()=="trigger")
	continue;
	}
	}
	Node *nd=new Node(BB);
	nodes.push_back(nd);
	if(&*BB==ExitNode)
	exitNode=nd;
	if(&*BB==&M->front())
	startNode=nd;
	}

	assert(exitNode!=0 && startNode!=0 && "Start or exit not found!");

	for (Function::iterator BB = M->begin(), BE=M->end(); BB != BE; ++BB){
	if(BB->size()==2){
	const Instruction *inst = BB->getInstList().begin();
	if(isa<CallInst>(inst)){
	Instruction *ii1 = BB->getInstList().begin();
	CallInst *callInst = dyn_cast<CallInst>(ii1);
	if(callInst->getCalledFunction()->getName()=="trigger")
	continue;
	}
	}

	Node *nd=findBB(nodes, BB);
	assert(nd && "No node for this edge!");

	for(BasicBlock::succ_iterator s=succ_begin(&BB), se=succ_end(&BB);
	s!=se; ++s){
	if((*s)->size()==2){
	const Instruction inst = (s)->getInstList().begin();
	if(isa<CallInst>(inst)){
	Instruction ii1 = (s)->getInstList().begin();
	CallInst *callInst = dyn_cast<CallInst>(ii1);
	if(callInst->getCalledFunction()->getName()=="trigger")
	continue;
	}
	}

	Node nd2=findBB(nodes,s);
	assert(nd2 && "No node for this edge!");
	Edge ed(nd,nd2,0);
	edges.push_back(ed);
	}
	}

	graphMap[M]= new Graph(nodes,edges, startNode, exitNode);

	Graph *g = graphMap[M];

	if (M->size() <= 1) return; //uninstrumented

	//step 2: getBackEdges
	//vector<Edge> be;
	std::map<Node *, int> nodePriority;
	g->getBackEdges(beMap[M], nodePriority);

	//step 3: add dummy edges
	//vector<Edge> stDummy;
	//vector<Edge> exDummy;
	addDummyEdges(stMap[M], exMap[M], *g, beMap[M]);

	//step 4: value assgn to edges
	int numPaths = valueAssignmentToEdges(*g, nodePriority, beMap[M]);
	}

	//step 5: now travel from root, select max(edge) < pathNo,
	//and go on until reach the exit
	return getPathFrmNode(graphMap[M]->getRoot(), vBB, pathNo, *graphMap[M],
	stMap[M], exMap[M], beMap[M], -1);
	}