poolalloc/lib/DSA/TopDownClosure.cpp - llvm-archive - Git at Google

 //===- TopDownClosure.cpp - Compute the top-down interprocedure closure ---===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file was developed by the LLVM research group and is distributed under
 // the University of Illinois Open Source License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file implements the TDDataStructures class, which represents the
 // Top-down Interprocedural closure of the data structure graph over the
 // program.  This is useful (but not strictly necessary?) for applications
 // like pointer analysis.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/Analysis/DataStructure/DataStructure.h"
 #include "llvm/Module.h"
 #include "llvm/DerivedTypes.h"
 #include "llvm/Analysis/DataStructure/DSGraph.h"
 #include "llvm/Support/Debug.h"
 #include "llvm/ADT/Statistic.h"
 using namespace llvm;

 namespace {
   RegisterAnalysis<TDDataStructures>   // Register the pass
   Y("tddatastructure", "Top-down Data Structure Analysis");

   Statistic<> NumTDInlines("tddatastructures", "Number of graphs inlined");
 }

 void TDDataStructures::markReachableFunctionsExternallyAccessible(DSNode *N,
                                                    hash_set<DSNode*> &Visited) {
   if (!N || Visited.count(N)) return;
   Visited.insert(N);

   for (unsigned i = 0, e = N->getNumLinks(); i != e; ++i) {
     DSNodeHandle &NH = N->getLink(i*N->getPointerSize());
     if (DSNode *NN = NH.getNode()) {
       const std::vector<GlobalValue*> &Globals = NN->getGlobals();
       for (unsigned G = 0, e = Globals.size(); G != e; ++G)
         if (Function *F = dyn_cast<Function>(Globals[G]))
           ArgsRemainIncomplete.insert(F);

       markReachableFunctionsExternallyAccessible(NN, Visited);
     }
   }
 }


 // run - Calculate the top down data structure graphs for each function in the
 // program.
 //
 bool TDDataStructures::runOnModule(Module &M) {
   BUDataStructures &BU = getAnalysis<BUDataStructures>();
   GlobalsGraph = new DSGraph(BU.getGlobalsGraph());
   GlobalsGraph->setPrintAuxCalls();

   // Figure out which functions must not mark their arguments complete because
   // they are accessible outside this compilation unit.  Currently, these
   // arguments are functions which are reachable by global variables in the
   // globals graph.
   const DSScalarMap &GGSM = GlobalsGraph->getScalarMap();
   hash_set<DSNode*> Visited;
   for (DSScalarMap::global_iterator I=GGSM.global_begin(), E=GGSM.global_end();
        I != E; ++I)
     markReachableFunctionsExternallyAccessible(GGSM.find(*I)->second.getNode(),
                                                Visited);

   // Loop over unresolved call nodes.  Any functions passed into (but not
   // returned!) from unresolvable call nodes may be invoked outside of the
   // current module.
   const std::vector<DSCallSite> &Calls = GlobalsGraph->getAuxFunctionCalls();
   for (unsigned i = 0, e = Calls.size(); i != e; ++i) {
     const DSCallSite &CS = Calls[i];
     for (unsigned arg = 0, e = CS.getNumPtrArgs(); arg != e; ++arg)
       markReachableFunctionsExternallyAccessible(CS.getPtrArg(arg).getNode(),
                                                  Visited);
   }
   Visited.clear();

   // Functions without internal linkage also have unknown incoming arguments!
   for (Module::iterator I = M.begin(), E = M.end(); I != E; ++I)
     if (!I->isExternal() && !I->hasInternalLinkage())
       ArgsRemainIncomplete.insert(I);

   // We want to traverse the call graph in reverse post-order.  To do this, we
   // calculate a post-order traversal, then reverse it.
   hash_set<DSGraph*> VisitedGraph;
   std::vector<DSGraph*> PostOrder;
   const BUDataStructures::ActualCalleesTy &ActualCallees =
     getAnalysis<BUDataStructures>().getActualCallees();

   // Calculate top-down from main...
   if (Function *F = M.getMainFunction())
     ComputePostOrder(*F, VisitedGraph, PostOrder, ActualCallees);

   // Next calculate the graphs for each unreachable function...
   for (Module::iterator I = M.begin(), E = M.end(); I != E; ++I)
     ComputePostOrder(*I, VisitedGraph, PostOrder, ActualCallees);

   VisitedGraph.clear();   // Release memory!

   // Visit each of the graphs in reverse post-order now!
   while (!PostOrder.empty()) {
     inlineGraphIntoCallees(*PostOrder.back());
     PostOrder.pop_back();
   }

   ArgsRemainIncomplete.clear();
   GlobalsGraph->removeTriviallyDeadNodes();

   return false;
 }


 DSGraph &TDDataStructures::getOrCreateDSGraph(Function &F) {
   DSGraph *&G = DSInfo[&F];
   if (G == 0) { // Not created yet?  Clone BU graph...
     G = new DSGraph(getAnalysis<BUDataStructures>().getDSGraph(F));
     G->getAuxFunctionCalls().clear();
     G->setPrintAuxCalls();
     G->setGlobalsGraph(GlobalsGraph);
   }
   return *G;
 }


 void TDDataStructures::ComputePostOrder(Function &F,hash_set<DSGraph*> &Visited,
                                         std::vector<DSGraph*> &PostOrder,
                       const BUDataStructures::ActualCalleesTy &ActualCallees) {
   if (F.isExternal()) return;
   DSGraph &G = getOrCreateDSGraph(F);
   if (Visited.count(&G)) return;
   Visited.insert(&G);

   // Recursively traverse all of the callee graphs.
   const std::vector<DSCallSite> &FunctionCalls = G.getFunctionCalls();

   for (unsigned i = 0, e = FunctionCalls.size(); i != e; ++i) {
     Instruction *CallI = FunctionCalls[i].getCallSite().getInstruction();
     std::pair<BUDataStructures::ActualCalleesTy::const_iterator,
       BUDataStructures::ActualCalleesTy::const_iterator>
          IP = ActualCallees.equal_range(CallI);

     for (BUDataStructures::ActualCalleesTy::const_iterator I = IP.first;
          I != IP.second; ++I)
       ComputePostOrder(*I->second, Visited, PostOrder, ActualCallees);
   }

   PostOrder.push_back(&G);
 }


 // releaseMemory - If the pass pipeline is done with this pass, we can release
 // our memory... here...
 //
 // FIXME: This should be releaseMemory and will work fine, except that LoadVN
 // has no way to extend the lifetime of the pass, which screws up ds-aa.
 //
 void TDDataStructures::releaseMyMemory() {
   for (hash_map<Function*, DSGraph*>::iterator I = DSInfo.begin(),
          E = DSInfo.end(); I != E; ++I) {
     I->second->getReturnNodes().erase(I->first);
     if (I->second->getReturnNodes().empty())
       delete I->second;
   }

   // Empty map so next time memory is released, data structures are not
   // re-deleted.
   DSInfo.clear();
   delete GlobalsGraph;
   GlobalsGraph = 0;
 }

 void TDDataStructures::inlineGraphIntoCallees(DSGraph &Graph) {
   // Recompute the Incomplete markers and eliminate unreachable nodes.
   Graph.maskIncompleteMarkers();

   // If any of the functions has incomplete incoming arguments, don't mark any
   // of them as complete.
   bool HasIncompleteArgs = false;
   const DSGraph::ReturnNodesTy &GraphReturnNodes = Graph.getReturnNodes();
   for (DSGraph::ReturnNodesTy::const_iterator I = GraphReturnNodes.begin(),
          E = GraphReturnNodes.end(); I != E; ++I)
     if (ArgsRemainIncomplete.count(I->first)) {
       HasIncompleteArgs = true;
       break;
     }

   // Now fold in the necessary globals from the GlobalsGraph.  A global G
   // must be folded in if it exists in the current graph (i.e., is not dead)
   // and it was not inlined from any of my callers.  If it was inlined from
   // a caller, it would have been fully consistent with the GlobalsGraph
   // in the caller so folding in is not necessary.  Otherwise, this node came
   // solely from this function's BU graph and so has to be made consistent.
   //
   Graph.updateFromGlobalGraph();

   // Recompute the Incomplete markers.  Depends on whether args are complete
   unsigned Flags
     = HasIncompleteArgs ? DSGraph::MarkFormalArgs : DSGraph::IgnoreFormalArgs;
   Graph.markIncompleteNodes(Flags | DSGraph::IgnoreGlobals);

   // Delete dead nodes.  Treat globals that are unreachable as dead also.
   Graph.removeDeadNodes(DSGraph::RemoveUnreachableGlobals);

   // We are done with computing the current TD Graph! Now move on to
   // inlining the current graph into the graphs for its callees, if any.
   //
   const std::vector<DSCallSite> &FunctionCalls = Graph.getFunctionCalls();
   if (FunctionCalls.empty()) {
     DEBUG(std::cerr << "  [TD] No callees for: " << Graph.getFunctionNames()
                     << "\n");
     return;
   }

   // Now that we have information about all of the callees, propagate the
   // current graph into the callees.  Clone only the reachable subgraph at
   // each call-site, not the entire graph (even though the entire graph
   // would be cloned only once, this should still be better on average).
   //
   DEBUG(std::cerr << "  [TD] Inlining '" << Graph.getFunctionNames() <<"' into "
                   << FunctionCalls.size() << " call nodes.\n");

   const BUDataStructures::ActualCalleesTy &ActualCallees =
     getAnalysis<BUDataStructures>().getActualCallees();

   // Loop over all the call sites and all the callees at each call site.  Build
   // a mapping from called DSGraph's to the call sites in this function that
   // invoke them.  This is useful because we can be more efficient if there are
   // multiple call sites to the callees in the graph from this caller.
   std::multimap<DSGraph*, std::pair<Function*, const DSCallSite*> > CallSites;

   for (unsigned i = 0, e = FunctionCalls.size(); i != e; ++i) {
     Instruction *CallI = FunctionCalls[i].getCallSite().getInstruction();
     // For each function in the invoked function list at this call site...
     std::pair<BUDataStructures::ActualCalleesTy::const_iterator,
       BUDataStructures::ActualCalleesTy::const_iterator>
           IP = ActualCallees.equal_range(CallI);
     // Loop over each actual callee at this call site
     for (BUDataStructures::ActualCalleesTy::const_iterator I = IP.first;
          I != IP.second; ++I) {
       DSGraph& CalleeGraph = getDSGraph(*I->second);
       assert(&CalleeGraph != &Graph && "TD need not inline graph into self!");

       CallSites.insert(std::make_pair(&CalleeGraph,
                            std::make_pair(I->second, &FunctionCalls[i])));
     }
   }

   // Now that we built the mapping, actually perform the inlining a callee graph
   // at a time.
   std::multimap<DSGraph*,std::pair<Function*,const DSCallSite*> >::iterator CSI;
   for (CSI = CallSites.begin(); CSI != CallSites.end(); ) {
     DSGraph &CalleeGraph = *CSI->first;
     // Iterate through all of the call sites of this graph, cloning and merging
     // any nodes required by the call.
     ReachabilityCloner RC(CalleeGraph, Graph, DSGraph::StripModRefBits);

     // Clone over any global nodes that appear in both graphs.
     for (DSScalarMap::global_iterator
            SI = CalleeGraph.getScalarMap().global_begin(),
            SE = CalleeGraph.getScalarMap().global_end(); SI != SE; ++SI) {
       DSScalarMap::const_iterator GI = Graph.getScalarMap().find(*SI);
       if (GI != Graph.getScalarMap().end())
         RC.merge(CalleeGraph.getNodeForValue(*SI), GI->second);
     }

     // Loop over all of the distinct call sites in the caller of the callee.
     for (; CSI != CallSites.end() && CSI->first == &CalleeGraph; ++CSI) {
       Function &CF = *CSI->second.first;
       const DSCallSite &CS = *CSI->second.second;
       DEBUG(std::cerr << "     [TD] Resolving arguments for callee graph '"
             << CalleeGraph.getFunctionNames()
             << "': " << CF.getFunctionType()->getNumParams()
             << " args\n          at call site (DSCallSite*) 0x" << &CS << "\n");

       // Get the formal argument and return nodes for the called function and
       // merge them with the cloned subgraph.
       RC.mergeCallSite(CalleeGraph.getCallSiteForArguments(CF), CS);
       ++NumTDInlines;
     }
   }

   DEBUG(std::cerr << "  [TD] Done inlining into callees for: "
         << Graph.getFunctionNames() << " [" << Graph.getGraphSize() << "+"
         << Graph.getFunctionCalls().size() << "]\n");
 }
	//===- TopDownClosure.cpp - Compute the top-down interprocedure closure ---===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file was developed by the LLVM research group and is distributed under
	// the University of Illinois Open Source License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file implements the TDDataStructures class, which represents the
	// Top-down Interprocedural closure of the data structure graph over the
	// program. This is useful (but not strictly necessary?) for applications
	// like pointer analysis.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/Analysis/DataStructure/DataStructure.h"
	#include "llvm/Module.h"
	#include "llvm/DerivedTypes.h"
	#include "llvm/Analysis/DataStructure/DSGraph.h"
	#include "llvm/Support/Debug.h"
	#include "llvm/ADT/Statistic.h"
	using namespace llvm;

	namespace {
	RegisterAnalysis<TDDataStructures> // Register the pass
	Y("tddatastructure", "Top-down Data Structure Analysis");

	Statistic<> NumTDInlines("tddatastructures", "Number of graphs inlined");
	}

	void TDDataStructures::markReachableFunctionsExternallyAccessible(DSNode *N,
	hash_set<DSNode*> &Visited) {
	if (!N \|\| Visited.count(N)) return;
	Visited.insert(N);

	for (unsigned i = 0, e = N->getNumLinks(); i != e; ++i) {
	DSNodeHandle &NH = N->getLink(i*N->getPointerSize());
	if (DSNode *NN = NH.getNode()) {
	const std::vector<GlobalValue*> &Globals = NN->getGlobals();
	for (unsigned G = 0, e = Globals.size(); G != e; ++G)
	if (Function *F = dyn_cast<Function>(Globals[G]))
	ArgsRemainIncomplete.insert(F);

	markReachableFunctionsExternallyAccessible(NN, Visited);
	}
	}
	}


	// run - Calculate the top down data structure graphs for each function in the
	// program.
	//
	bool TDDataStructures::runOnModule(Module &M) {
	BUDataStructures &BU = getAnalysis<BUDataStructures>();
	GlobalsGraph = new DSGraph(BU.getGlobalsGraph());
	GlobalsGraph->setPrintAuxCalls();

	// Figure out which functions must not mark their arguments complete because
	// they are accessible outside this compilation unit. Currently, these
	// arguments are functions which are reachable by global variables in the
	// globals graph.
	const DSScalarMap &GGSM = GlobalsGraph->getScalarMap();
	hash_set<DSNode*> Visited;
	for (DSScalarMap::global_iterator I=GGSM.global_begin(), E=GGSM.global_end();
	I != E; ++I)
	markReachableFunctionsExternallyAccessible(GGSM.find(*I)->second.getNode(),
	Visited);

	// Loop over unresolved call nodes. Any functions passed into (but not
	// returned!) from unresolvable call nodes may be invoked outside of the
	// current module.
	const std::vector<DSCallSite> &Calls = GlobalsGraph->getAuxFunctionCalls();
	for (unsigned i = 0, e = Calls.size(); i != e; ++i) {
	const DSCallSite &CS = Calls[i];
	for (unsigned arg = 0, e = CS.getNumPtrArgs(); arg != e; ++arg)
	markReachableFunctionsExternallyAccessible(CS.getPtrArg(arg).getNode(),
	Visited);
	}
	Visited.clear();

	// Functions without internal linkage also have unknown incoming arguments!
	for (Module::iterator I = M.begin(), E = M.end(); I != E; ++I)
	if (!I->isExternal() && !I->hasInternalLinkage())
	ArgsRemainIncomplete.insert(I);

	// We want to traverse the call graph in reverse post-order. To do this, we
	// calculate a post-order traversal, then reverse it.
	hash_set<DSGraph*> VisitedGraph;
	std::vector<DSGraph*> PostOrder;
	const BUDataStructures::ActualCalleesTy &ActualCallees =
	getAnalysis<BUDataStructures>().getActualCallees();

	// Calculate top-down from main...
	if (Function *F = M.getMainFunction())
	ComputePostOrder(*F, VisitedGraph, PostOrder, ActualCallees);

	// Next calculate the graphs for each unreachable function...
	for (Module::iterator I = M.begin(), E = M.end(); I != E; ++I)
	ComputePostOrder(*I, VisitedGraph, PostOrder, ActualCallees);

	VisitedGraph.clear(); // Release memory!

	// Visit each of the graphs in reverse post-order now!
	while (!PostOrder.empty()) {
	inlineGraphIntoCallees(*PostOrder.back());
	PostOrder.pop_back();
	}

	ArgsRemainIncomplete.clear();
	GlobalsGraph->removeTriviallyDeadNodes();

	return false;
	}


	DSGraph &TDDataStructures::getOrCreateDSGraph(Function &F) {
	DSGraph *&G = DSInfo[&F];
	if (G == 0) { // Not created yet? Clone BU graph...
	G = new DSGraph(getAnalysis<BUDataStructures>().getDSGraph(F));
	G->getAuxFunctionCalls().clear();
	G->setPrintAuxCalls();
	G->setGlobalsGraph(GlobalsGraph);
	}
	return *G;
	}


	void TDDataStructures::ComputePostOrder(Function &F,hash_set<DSGraph*> &Visited,
	std::vector<DSGraph*> &PostOrder,
	const BUDataStructures::ActualCalleesTy &ActualCallees) {
	if (F.isExternal()) return;
	DSGraph &G = getOrCreateDSGraph(F);
	if (Visited.count(&G)) return;
	Visited.insert(&G);

	// Recursively traverse all of the callee graphs.
	const std::vector<DSCallSite> &FunctionCalls = G.getFunctionCalls();

	for (unsigned i = 0, e = FunctionCalls.size(); i != e; ++i) {
	Instruction *CallI = FunctionCalls[i].getCallSite().getInstruction();
	std::pair<BUDataStructures::ActualCalleesTy::const_iterator,
	BUDataStructures::ActualCalleesTy::const_iterator>
	IP = ActualCallees.equal_range(CallI);

	for (BUDataStructures::ActualCalleesTy::const_iterator I = IP.first;
	I != IP.second; ++I)
	ComputePostOrder(*I->second, Visited, PostOrder, ActualCallees);
	}

	PostOrder.push_back(&G);
	}





	// releaseMemory - If the pass pipeline is done with this pass, we can release
	// our memory... here...
	//
	// FIXME: This should be releaseMemory and will work fine, except that LoadVN
	// has no way to extend the lifetime of the pass, which screws up ds-aa.
	//
	void TDDataStructures::releaseMyMemory() {
	for (hash_map<Function, DSGraph>::iterator I = DSInfo.begin(),
	E = DSInfo.end(); I != E; ++I) {
	I->second->getReturnNodes().erase(I->first);
	if (I->second->getReturnNodes().empty())
	delete I->second;
	}

	// Empty map so next time memory is released, data structures are not
	// re-deleted.
	DSInfo.clear();
	delete GlobalsGraph;
	GlobalsGraph = 0;
	}

	void TDDataStructures::inlineGraphIntoCallees(DSGraph &Graph) {
	// Recompute the Incomplete markers and eliminate unreachable nodes.
	Graph.maskIncompleteMarkers();

	// If any of the functions has incomplete incoming arguments, don't mark any
	// of them as complete.
	bool HasIncompleteArgs = false;
	const DSGraph::ReturnNodesTy &GraphReturnNodes = Graph.getReturnNodes();
	for (DSGraph::ReturnNodesTy::const_iterator I = GraphReturnNodes.begin(),
	E = GraphReturnNodes.end(); I != E; ++I)
	if (ArgsRemainIncomplete.count(I->first)) {
	HasIncompleteArgs = true;
	break;
	}

	// Now fold in the necessary globals from the GlobalsGraph. A global G
	// must be folded in if it exists in the current graph (i.e., is not dead)
	// and it was not inlined from any of my callers. If it was inlined from
	// a caller, it would have been fully consistent with the GlobalsGraph
	// in the caller so folding in is not necessary. Otherwise, this node came
	// solely from this function's BU graph and so has to be made consistent.
	//
	Graph.updateFromGlobalGraph();

	// Recompute the Incomplete markers. Depends on whether args are complete
	unsigned Flags
	= HasIncompleteArgs ? DSGraph::MarkFormalArgs : DSGraph::IgnoreFormalArgs;
	Graph.markIncompleteNodes(Flags \| DSGraph::IgnoreGlobals);

	// Delete dead nodes. Treat globals that are unreachable as dead also.
	Graph.removeDeadNodes(DSGraph::RemoveUnreachableGlobals);

	// We are done with computing the current TD Graph! Now move on to
	// inlining the current graph into the graphs for its callees, if any.
	//
	const std::vector<DSCallSite> &FunctionCalls = Graph.getFunctionCalls();
	if (FunctionCalls.empty()) {
	DEBUG(std::cerr << " [TD] No callees for: " << Graph.getFunctionNames()
	<< "\n");
	return;
	}

	// Now that we have information about all of the callees, propagate the
	// current graph into the callees. Clone only the reachable subgraph at
	// each call-site, not the entire graph (even though the entire graph
	// would be cloned only once, this should still be better on average).
	//
	DEBUG(std::cerr << " [TD] Inlining '" << Graph.getFunctionNames() <<"' into "
	<< FunctionCalls.size() << " call nodes.\n");

	const BUDataStructures::ActualCalleesTy &ActualCallees =
	getAnalysis<BUDataStructures>().getActualCallees();

	// Loop over all the call sites and all the callees at each call site. Build
	// a mapping from called DSGraph's to the call sites in this function that
	// invoke them. This is useful because we can be more efficient if there are
	// multiple call sites to the callees in the graph from this caller.
	std::multimap<DSGraph, std::pair<Function, const DSCallSite*> > CallSites;

	for (unsigned i = 0, e = FunctionCalls.size(); i != e; ++i) {
	Instruction *CallI = FunctionCalls[i].getCallSite().getInstruction();
	// For each function in the invoked function list at this call site...
	std::pair<BUDataStructures::ActualCalleesTy::const_iterator,
	BUDataStructures::ActualCalleesTy::const_iterator>
	IP = ActualCallees.equal_range(CallI);
	// Loop over each actual callee at this call site
	for (BUDataStructures::ActualCalleesTy::const_iterator I = IP.first;
	I != IP.second; ++I) {
	DSGraph& CalleeGraph = getDSGraph(*I->second);
	assert(&CalleeGraph != &Graph && "TD need not inline graph into self!");

	CallSites.insert(std::make_pair(&CalleeGraph,
	std::make_pair(I->second, &FunctionCalls[i])));
	}
	}

	// Now that we built the mapping, actually perform the inlining a callee graph
	// at a time.
	std::multimap<DSGraph,std::pair<Function,const DSCallSite*> >::iterator CSI;
	for (CSI = CallSites.begin(); CSI != CallSites.end(); ) {
	DSGraph &CalleeGraph = *CSI->first;
	// Iterate through all of the call sites of this graph, cloning and merging
	// any nodes required by the call.
	ReachabilityCloner RC(CalleeGraph, Graph, DSGraph::StripModRefBits);

	// Clone over any global nodes that appear in both graphs.
	for (DSScalarMap::global_iterator
	SI = CalleeGraph.getScalarMap().global_begin(),
	SE = CalleeGraph.getScalarMap().global_end(); SI != SE; ++SI) {
	DSScalarMap::const_iterator GI = Graph.getScalarMap().find(*SI);
	if (GI != Graph.getScalarMap().end())
	RC.merge(CalleeGraph.getNodeForValue(*SI), GI->second);
	}

	// Loop over all of the distinct call sites in the caller of the callee.
	for (; CSI != CallSites.end() && CSI->first == &CalleeGraph; ++CSI) {
	Function &CF = *CSI->second.first;
	const DSCallSite &CS = *CSI->second.second;
	DEBUG(std::cerr << " [TD] Resolving arguments for callee graph '"
	<< CalleeGraph.getFunctionNames()
	<< "': " << CF.getFunctionType()->getNumParams()
	<< " args\n at call site (DSCallSite*) 0x" << &CS << "\n");

	// Get the formal argument and return nodes for the called function and
	// merge them with the cloned subgraph.
	RC.mergeCallSite(CalleeGraph.getCallSiteForArguments(CF), CS);
	++NumTDInlines;
	}
	}

	DEBUG(std::cerr << " [TD] Done inlining into callees for: "
	<< Graph.getFunctionNames() << " [" << Graph.getGraphSize() << "+"
	<< Graph.getFunctionCalls().size() << "]\n");
	}