lib/Analysis/DataStructure/TopDownClosure.cpp - fp2-dev/platform/external/llvm - Gitiles

 //===- TopDownClosure.cpp - Compute the top-down interprocedure closure ---===//
 //
 // 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.h"
 #include "llvm/Module.h"
 #include "llvm/DerivedTypes.h"
 #include "Support/StatisticReporter.h"
 using std::map;

 static RegisterAnalysis<TDDataStructures>
 Y("tddatastructure", "Top-down Data Structure Analysis Closure");
 AnalysisID TDDataStructures::ID = Y;

 // releaseMemory - If the pass pipeline is done with this pass, we can release
 // our memory... here...
 //
 void TDDataStructures::releaseMemory() {
   for (map<const Function*, DSGraph*>::iterator I = DSInfo.begin(),
          E = DSInfo.end(); I != E; ++I)
     delete I->second;

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

 // run - Calculate the top down data structure graphs for each function in the
 // program.
 //
 bool TDDataStructures::run(Module &M) {
   // Simply calculate the graphs for each function...
   for (Module::reverse_iterator I = M.rbegin(), E = M.rend(); I != E; ++I)
     if (!I->isExternal())
       calculateGraph(*I);
   return false;
 }


 // ResolveArguments - Resolve the formal and actual arguments for a function
 // call by merging the nodes for the actual arguments at the call site Call[]
 // (these were copied over from the caller's graph into the callee's graph
 // by cloneInto, and the nodes can be found from OldNodeMap) with the
 // corresponding nodes for the formal arguments in the callee.
 //
 static void ResolveArguments(std::vector<DSNodeHandle> &Call,
                              Function &callee,
                              std::map<Value*, DSNodeHandle> &CalleeValueMap,
                              std::map<const DSNode*, DSNode*> OldNodeMap,
                              bool ignoreNodeMap) {
   // Resolve all of the function formal arguments...
   Function::aiterator AI = callee.abegin();
   for (unsigned i = 2, e = Call.size(); i != e; ++i) {
     // Advance the argument iterator to the first pointer argument...
     while (!isa<PointerType>(AI->getType())) ++AI;

     // TD ...Merge the formal arg scalar with the actual arg node
     DSNode* actualArg = Call[i];
     DSNode *nodeForActual = ignoreNodeMap? actualArg : OldNodeMap[actualArg];
     assert(nodeForActual && "No node found for actual arg in callee graph!");

     DSNode *nodeForFormal = CalleeValueMap[AI]->getLink(0);
     if (nodeForFormal)
       nodeForFormal->mergeWith(nodeForActual);
     ++AI;
   }
 }

 // MergeGlobalNodes - Merge all existing global nodes with globals
 // inlined from the callee or with globals from the GlobalsGraph.
 //
 static void MergeGlobalNodes(DSGraph& Graph,
                              map<Value*, DSNodeHandle> &OldValMap) {
   map<Value*, DSNodeHandle> &ValMap = Graph.getValueMap();
   for (map<Value*, DSNodeHandle>::iterator I = ValMap.begin(), E = ValMap.end();
        I != E; ++I)
     if (GlobalValue* GV = dyn_cast<GlobalValue>(I->first)) {
       map<Value*, DSNodeHandle>:: iterator NHI = OldValMap.find(GV);
       if (NHI != OldValMap.end())       // was it inlined from the callee?
         I->second->mergeWith(NHI->second);
       else                              // get it from the GlobalsGraph
         I->second->mergeWith(Graph.cloneGlobalInto(GV));
     }

   // Add unused inlined global nodes into the value map
   for (map<Value*, DSNodeHandle>::iterator I = OldValMap.begin(),
          E = OldValMap.end(); I != E; ++I)
     if (isa<GlobalValue>(I->first)) {
       DSNodeHandle &NH = ValMap[I->first];  // If global is not in ValMap...
       if (NH == 0)
         NH = I->second;                     // Add the one just inlined.
     }
 }

 // Helper function to push a caller's graph into the calleeGraph,
 // once per call between the caller and the callee.
 // Remove each such resolved call from the OrigFunctionCalls vector.
 // NOTE: This may produce O(N^2) behavior because it uses linear search
 // through the vector OrigFunctionCalls to find all calls to this callee.
 //
 void TDDataStructures::pushGraphIntoCallee(DSGraph &callerGraph,
                                            DSGraph &calleeGraph,
                                  std::map<Value*, DSNodeHandle> &OldValMap,
                                  std::map<const DSNode*, DSNode*> &OldNodeMap) {

   Function& caller = callerGraph.getFunction();

   // Loop over all function calls in the caller to find those to this callee
   std::vector<std::vector<DSNodeHandle> >& FunctionCalls =
     callerGraph.getOrigFunctionCalls();

   for (unsigned i = 0, ei = FunctionCalls.size(); i != ei; ++i) {

     std::vector<DSNodeHandle>& Call = FunctionCalls[i];
     assert(Call.size() >= 2 && "No function pointer in Call?");
     DSNodeHandle& callee = Call[1];
     std::vector<GlobalValue*> funcPtrs(callee->getGlobals());

     // Loop over the function pointers in the call, looking for the callee
     for (unsigned f = 0; f != funcPtrs.size(); ++f) {

       // Must be a function type, so this cast MUST succeed.
       Function &callee = cast<Function>(*funcPtrs[f]);
       if (&callee != &calleeGraph.getFunction())
         continue;

       // Found a call to the callee.  Inline its graph
       // copy caller pointer because inlining may modify the callers vector

       // Merge actual arguments from the caller with formals in the callee.
       // Don't use the old->new node map if this is a self-recursive call.
       ResolveArguments(Call, callee, calleeGraph.getValueMap(), OldNodeMap,
                        /*ignoreNodeMap*/ &caller == &callee);

       // If its not a self-recursive call, merge global nodes in the inlined
       // graph with the corresponding global nodes in the current graph
       if (&caller != &callee)
         MergeGlobalNodes(calleeGraph, OldValMap);

       // Merge returned node in the caller with the "return" node in callee
       if (Call[0])
         calleeGraph.getRetNode()->mergeWith(OldNodeMap[Call[0]]);

       // Erase the entry in the globals vector
       funcPtrs.erase(funcPtrs.begin()+f--);

     } // for each function pointer in the call node
   } // for each original call node
 }


 DSGraph &TDDataStructures::calculateGraph(Function &F) {
   // Make sure this graph has not already been calculated, or that we don't get
   // into an infinite loop with mutually recursive functions.
   //
   DSGraph *&Graph = DSInfo[&F];
   if (Graph) return *Graph;

   // Copy the local version into DSInfo...
   DSGraph& BUGraph = getAnalysis<BUDataStructures>().getDSGraph(F);
   Graph = new DSGraph(BUGraph);

   // Find the callers of this function recorded during the BU pass
   std::set<Function*> &PendingCallers = BUGraph.getPendingCallers();

   DEBUG(cerr << "  [TD] Inlining callers for: " << F.getName() << "\n");

   for (std::set<Function*>::iterator I=PendingCallers.begin(),
          E=PendingCallers.end(); I != E; ++I) {
     Function& caller = **I;
     assert(! caller.isExternal() && "Externals unexpected in callers list");

     DEBUG(std::cerr << "\t [TD] Inlining " << caller.getName()
           << " into callee: " << F.getName() << "\n");

     // These two maps keep track of where scalars in the old graph _used_
     // to point to, and of new nodes matching nodes of the old graph.
     // These remain empty if no other graph is inlined (i.e., self-recursive).
     std::map<const DSNode*, DSNode*> OldNodeMap;
     std::map<Value*, DSNodeHandle> OldValMap;

     if (&caller == &F) {
       // Self-recursive call: this can happen after a cycle of calls is inlined.
       pushGraphIntoCallee(*Graph, *Graph, OldValMap, OldNodeMap);
     }
     else {
       // Recursively compute the graph for the caller.  That should
       // be fully resolved except if there is mutual recursion...
       //
       DSGraph &callerGraph = calculateGraph(caller);  // Graph to inline

       DEBUG(cerr << "\t\t[TD] Got graph for " << caller.getName() << " in: "
             << F.getName() << "\n");

       // Clone the caller's graph into the current graph, keeping
       // track of where scalars in the old graph _used_ to point...
       // Do this here because it only needs to happens once for each caller!
       // Strip scalars but not allocas since they are visible in callee.
       //
       DSNode *RetVal = Graph->cloneInto(callerGraph, OldValMap, OldNodeMap,
                                         /*StripScalars*/   true,
                                         /*StripAllocas*/   false,
                                         /*CopyCallers*/    true,
                                         /*CopyOrigCalls*/  false);

       pushGraphIntoCallee(callerGraph, *Graph, OldValMap, OldNodeMap);
     }
   }

   // Recompute the Incomplete markers and eliminate unreachable nodes.
   Graph->maskIncompleteMarkers();
   Graph->markIncompleteNodes(/*markFormals*/ ! F.hasInternalLinkage()
                              /*&& FIXME: NEED TO CHECK IF ALL CALLERS FOUND!*/);
   Graph->removeDeadNodes(/*KeepAllGlobals*/ false, /*KeepCalls*/ false);

   DEBUG(cerr << "  [TD] Done inlining callers for: " << F.getName() << "\n");

   return *Graph;
 }
	//===- TopDownClosure.cpp - Compute the top-down interprocedure closure ---===//
	//
	// 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.h"
	#include "llvm/Module.h"
	#include "llvm/DerivedTypes.h"
	#include "Support/StatisticReporter.h"
	using std::map;

	static RegisterAnalysis<TDDataStructures>
	Y("tddatastructure", "Top-down Data Structure Analysis Closure");
	AnalysisID TDDataStructures::ID = Y;

	// releaseMemory - If the pass pipeline is done with this pass, we can release
	// our memory... here...
	//
	void TDDataStructures::releaseMemory() {
	for (map<const Function, DSGraph>::iterator I = DSInfo.begin(),
	E = DSInfo.end(); I != E; ++I)
	delete I->second;

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

	// run - Calculate the top down data structure graphs for each function in the
	// program.
	//
	bool TDDataStructures::run(Module &M) {
	// Simply calculate the graphs for each function...
	for (Module::reverse_iterator I = M.rbegin(), E = M.rend(); I != E; ++I)
	if (!I->isExternal())
	calculateGraph(*I);
	return false;
	}


	// ResolveArguments - Resolve the formal and actual arguments for a function
	// call by merging the nodes for the actual arguments at the call site Call[]
	// (these were copied over from the caller's graph into the callee's graph
	// by cloneInto, and the nodes can be found from OldNodeMap) with the
	// corresponding nodes for the formal arguments in the callee.
	//
	static void ResolveArguments(std::vector<DSNodeHandle> &Call,
	Function &callee,
	std::map<Value*, DSNodeHandle> &CalleeValueMap,
	std::map<const DSNode, DSNode> OldNodeMap,
	bool ignoreNodeMap) {
	// Resolve all of the function formal arguments...
	Function::aiterator AI = callee.abegin();
	for (unsigned i = 2, e = Call.size(); i != e; ++i) {
	// Advance the argument iterator to the first pointer argument...
	while (!isa<PointerType>(AI->getType())) ++AI;

	// TD ...Merge the formal arg scalar with the actual arg node
	DSNode* actualArg = Call[i];
	DSNode *nodeForActual = ignoreNodeMap? actualArg : OldNodeMap[actualArg];
	assert(nodeForActual && "No node found for actual arg in callee graph!");

	DSNode *nodeForFormal = CalleeValueMap[AI]->getLink(0);
	if (nodeForFormal)
	nodeForFormal->mergeWith(nodeForActual);
	++AI;
	}
	}

	// MergeGlobalNodes - Merge all existing global nodes with globals
	// inlined from the callee or with globals from the GlobalsGraph.
	//
	static void MergeGlobalNodes(DSGraph& Graph,
	map<Value*, DSNodeHandle> &OldValMap) {
	map<Value*, DSNodeHandle> &ValMap = Graph.getValueMap();
	for (map<Value*, DSNodeHandle>::iterator I = ValMap.begin(), E = ValMap.end();
	I != E; ++I)
	if (GlobalValue* GV = dyn_cast<GlobalValue>(I->first)) {
	map<Value*, DSNodeHandle>:: iterator NHI = OldValMap.find(GV);
	if (NHI != OldValMap.end()) // was it inlined from the callee?
	I->second->mergeWith(NHI->second);
	else // get it from the GlobalsGraph
	I->second->mergeWith(Graph.cloneGlobalInto(GV));
	}

	// Add unused inlined global nodes into the value map
	for (map<Value*, DSNodeHandle>::iterator I = OldValMap.begin(),
	E = OldValMap.end(); I != E; ++I)
	if (isa<GlobalValue>(I->first)) {
	DSNodeHandle &NH = ValMap[I->first]; // If global is not in ValMap...
	if (NH == 0)
	NH = I->second; // Add the one just inlined.
	}
	}

	// Helper function to push a caller's graph into the calleeGraph,
	// once per call between the caller and the callee.
	// Remove each such resolved call from the OrigFunctionCalls vector.
	// NOTE: This may produce O(N^2) behavior because it uses linear search
	// through the vector OrigFunctionCalls to find all calls to this callee.
	//
	void TDDataStructures::pushGraphIntoCallee(DSGraph &callerGraph,
	DSGraph &calleeGraph,
	std::map<Value*, DSNodeHandle> &OldValMap,
	std::map<const DSNode, DSNode> &OldNodeMap) {

	Function& caller = callerGraph.getFunction();

	// Loop over all function calls in the caller to find those to this callee
	std::vector<std::vector<DSNodeHandle> >& FunctionCalls =
	callerGraph.getOrigFunctionCalls();

	for (unsigned i = 0, ei = FunctionCalls.size(); i != ei; ++i) {

	std::vector<DSNodeHandle>& Call = FunctionCalls[i];
	assert(Call.size() >= 2 && "No function pointer in Call?");
	DSNodeHandle& callee = Call[1];
	std::vector<GlobalValue*> funcPtrs(callee->getGlobals());

	// Loop over the function pointers in the call, looking for the callee
	for (unsigned f = 0; f != funcPtrs.size(); ++f) {

	// Must be a function type, so this cast MUST succeed.
	Function &callee = cast<Function>(*funcPtrs[f]);
	if (&callee != &calleeGraph.getFunction())
	continue;

	// Found a call to the callee. Inline its graph
	// copy caller pointer because inlining may modify the callers vector

	// Merge actual arguments from the caller with formals in the callee.
	// Don't use the old->new node map if this is a self-recursive call.
	ResolveArguments(Call, callee, calleeGraph.getValueMap(), OldNodeMap,
	/ignoreNodeMap/ &caller == &callee);

	// If its not a self-recursive call, merge global nodes in the inlined
	// graph with the corresponding global nodes in the current graph
	if (&caller != &callee)
	MergeGlobalNodes(calleeGraph, OldValMap);

	// Merge returned node in the caller with the "return" node in callee
	if (Call[0])
	calleeGraph.getRetNode()->mergeWith(OldNodeMap[Call[0]]);

	// Erase the entry in the globals vector
	funcPtrs.erase(funcPtrs.begin()+f--);

	} // for each function pointer in the call node
	} // for each original call node
	}


	DSGraph &TDDataStructures::calculateGraph(Function &F) {
	// Make sure this graph has not already been calculated, or that we don't get
	// into an infinite loop with mutually recursive functions.
	//
	DSGraph *&Graph = DSInfo[&F];
	if (Graph) return *Graph;

	// Copy the local version into DSInfo...
	DSGraph& BUGraph = getAnalysis<BUDataStructures>().getDSGraph(F);
	Graph = new DSGraph(BUGraph);

	// Find the callers of this function recorded during the BU pass
	std::set<Function*> &PendingCallers = BUGraph.getPendingCallers();

	DEBUG(cerr << " [TD] Inlining callers for: " << F.getName() << "\n");

	for (std::set<Function*>::iterator I=PendingCallers.begin(),
	E=PendingCallers.end(); I != E; ++I) {
	Function& caller = **I;
	assert(! caller.isExternal() && "Externals unexpected in callers list");

	DEBUG(std::cerr << "\t [TD] Inlining " << caller.getName()
	<< " into callee: " << F.getName() << "\n");

	// These two maps keep track of where scalars in the old graph _used_
	// to point to, and of new nodes matching nodes of the old graph.
	// These remain empty if no other graph is inlined (i.e., self-recursive).
	std::map<const DSNode, DSNode> OldNodeMap;
	std::map<Value*, DSNodeHandle> OldValMap;

	if (&caller == &F) {
	// Self-recursive call: this can happen after a cycle of calls is inlined.
	pushGraphIntoCallee(Graph, Graph, OldValMap, OldNodeMap);
	}
	else {
	// Recursively compute the graph for the caller. That should
	// be fully resolved except if there is mutual recursion...
	//
	DSGraph &callerGraph = calculateGraph(caller); // Graph to inline

	DEBUG(cerr << "\t\t[TD] Got graph for " << caller.getName() << " in: "
	<< F.getName() << "\n");

	// Clone the caller's graph into the current graph, keeping
	// track of where scalars in the old graph _used_ to point...
	// Do this here because it only needs to happens once for each caller!
	// Strip scalars but not allocas since they are visible in callee.
	//
	DSNode *RetVal = Graph->cloneInto(callerGraph, OldValMap, OldNodeMap,
	/StripScalars/ true,
	/StripAllocas/ false,
	/CopyCallers/ true,
	/CopyOrigCalls/ false);

	pushGraphIntoCallee(callerGraph, *Graph, OldValMap, OldNodeMap);
	}
	}

	// Recompute the Incomplete markers and eliminate unreachable nodes.
	Graph->maskIncompleteMarkers();
	Graph->markIncompleteNodes(/markFormals/ ! F.hasInternalLinkage()
	/&& FIXME: NEED TO CHECK IF ALL CALLERS FOUND!/);
	Graph->removeDeadNodes(/KeepAllGlobals/ false, /KeepCalls/ false);

	DEBUG(cerr << " [TD] Done inlining callers for: " << F.getName() << "\n");

	return *Graph;
	}