/// visitGraph - Visit the functions in the specified graph, updating the
/// specified lattice values for all of their uses.
///
void StructureFieldVisitorBase::
visitGraph(DSGraph &DSG, std::multimap<DSNode*, LatticeValue*> &NodeLVs) {
assert(!NodeLVs.empty() && "No lattice values to compute!");
// To visit a graph, first step, we visit the instruction making up each
// function in the graph, but ignore calls when processing them. We handle
// call nodes explicitly by looking at call nodes in the graph if needed. We
// handle instructions before calls to avoid interprocedural analysis if we
// can drive lattice values to bottom early.
//
SFVInstVisitor IV(DSG, Callbacks, NodeLVs);
for (DSGraph::retnodes_iterator FI = DSG.retnodes_begin(),
E = DSG.retnodes_end(); FI != E; ++FI)
for (Function::iterator BB = FI->first->begin(), E = FI->first->end();
BB != E; ++BB)
for (BasicBlock::iterator I = BB->begin(), E = BB->end(); I != E; ++I)
if (IV.visit(*I) && NodeLVs.empty())
return; // Nothing left to analyze.
// Keep track of which actual direct callees are handled.
std::set<Function*> CalleesHandled;
// Once we have visited all of the instructions in the function bodies, if
// there are lattice values that have not been driven to bottom, see if any of
// the nodes involved are passed into function calls. If so, we potentially
// have to recursively traverse the call graph.
for (DSGraph::fc_iterator CS = DSG.fc_begin(), E = DSG.fc_end();
CS != E; ++CS) {
// Figure out the mapping from a node in the caller (potentially several)
// nodes in the callee.
DSGraph::NodeMapTy CallNodeMap;
Instruction *TheCall = CS->getCallSite().getInstruction();
// If this is an indirect function call, assume nothing gets passed through
// it. FIXME: THIS IS BROKEN! Just get the ECG for the fn ptr if it's not
// direct.
if (CS->isIndirectCall())
continue;
// If this is an external function call, it cannot be involved with this
// node, because otherwise the node would be marked incomplete!
if (CS->getCalleeFunc()->isExternal())
continue;
// If we can handle this function call, remove it from the set of direct
// calls found by the visitor.
CalleesHandled.insert(CS->getCalleeFunc());
std::vector<DSNodeHandle> Args;
DSGraph *CG = &ECG.getDSGraph(*CS->getCalleeFunc());
CG->getFunctionArgumentsForCall(CS->getCalleeFunc(), Args);
if (!CS->getRetVal().isNull())
DSGraph::computeNodeMapping(Args[0], CS->getRetVal(), CallNodeMap);
for (unsigned i = 0, e = CS->getNumPtrArgs(); i != e; ++i) {
if (i == Args.size()-1) break;
DSGraph::computeNodeMapping(Args[i+1], CS->getPtrArg(i), CallNodeMap);
}
Args.clear();
// The mapping we just computed maps from nodes in the callee to nodes in
// the caller, so we can't query it efficiently. Instead of going through
// the trouble of inverting the map to do this (linear time with the size of
// the mapping), we just do a linear search to see if any affected nodes are
// passed into this call.
bool CallCanModifyDataFlow = false;
for (DSGraph::NodeMapTy::iterator MI = CallNodeMap.begin(),
E = CallNodeMap.end(); MI != E; ++MI)
if (NodeLVs.count(MI->second.getNode()))
// Okay, the node is passed in, check to see if the call might do
// something interesting to it (i.e. if analyzing the call can produce
// anything other than "top").
if ((CallCanModifyDataFlow = NodeCanPossiblyBeInteresting(MI->first,
Callbacks)))
break;
// If this function call cannot impact the analysis (either because the
// nodes we are tracking are not passed into the call, or the DSGraph for
// the callee tells us that analysis of the callee can't provide interesting
// information), ignore it.
if (!CallCanModifyDataFlow)
continue;
// Okay, either compute analysis results for the callee function, or reuse
// results previously computed.
std::multimap<DSNode*, LatticeValue*> &CalleeFacts = getCalleeFacts(*CG);
// Merge all of the facts for the callee into the facts for the caller. If
// this reduces anything in the caller to 'bottom', remove them.
for (DSGraph::NodeMapTy::iterator MI = CallNodeMap.begin(),
E = CallNodeMap.end(); MI != E; ++MI) {
// If we have Lattice facts in the caller for this node in the callee,
// merge any information from the callee into the caller.
// If the node is not accessed in the callee at all, don't update.
if (MI->first->getType() == Type::VoidTy)
continue;
// If there are no data-flow facts live in the caller for this node, don't
// both processing it.
std::multimap<DSNode*, LatticeValue*>::iterator NLVI =
NodeLVs.find(MI->second.getNode());
if (NLVI == NodeLVs.end()) continue;
// Iterate over all of the lattice values that have corresponding fields
// in the callee, merging in information as we go. Be careful about the
// fact that the callee may get passed the address of a substructure and
// other funny games.
//if (CalleeFacts.count(const_cast<DSNode*>(MI->first)) == 0) {
DSNode *CalleeNode = const_cast<DSNode*>(MI->first);
unsigned CalleeNodeOffset = MI->second.getOffset();
while (NLVI->first == MI->second.getNode()) {
// Figure out what offset in the callee this field would land.
unsigned FieldOff = NLVI->second->getFieldOffset()+CalleeNodeOffset;
// If the field is not within the callee node, ignore it.
if (FieldOff >= CalleeNode->getSize()) {
++NLVI;
continue;
}
// Okay, check to see if we have a lattice value for the field at offset
// FieldOff in the callee node.
const LatticeValue *CalleeLV = 0;
std::multimap<DSNode*, LatticeValue*>::iterator CFI =
CalleeFacts.lower_bound(CalleeNode);
for (; CFI != CalleeFacts.end() && CFI->first == CalleeNode; ++CFI)
if (CFI->second->getFieldOffset() == FieldOff) {
CalleeLV = CFI->second; // Found it!
break;
}
// If we don't, the lattice value hit bottom and we should remove the
// lattice value in the caller.
if (!CalleeLV) {
delete NLVI->second; // The lattice value hit bottom.
NodeLVs.erase(NLVI++);
continue;
}
// Finally, if we did find a corresponding entry, merge the information
// into the caller's lattice value and keep going.
if (NLVI->second->mergeInValue(CalleeLV)) {
// Okay, merging these two caused the caller value to hit bottom.
// Remove it.
delete NLVI->second; // The lattice value hit bottom.
NodeLVs.erase(NLVI++);
}
++NLVI; // We successfully merged in some information!
}
// If we ran out of facts to prove, just exit.
if (NodeLVs.empty()) return;
}
}
// The local analysis pass inconveniently discards many local function calls
// from the graph if they are to known functions. Loop over direct function
// calls not handled above and visit them as appropriate.
while (!IV.DirectCallSites.empty()) {
Instruction *Call = *IV.DirectCallSites.begin();
IV.DirectCallSites.erase(IV.DirectCallSites.begin());
// Is this one actually handled by DSA?
if (CalleesHandled.count(cast<Function>(Call->getOperand(0))))
continue;
// Collect the pointers involved in this call.
std::vector<Value*> Pointers;
if (isa<PointerType>(Call->getType()))
Pointers.push_back(Call);
for (unsigned i = 1, e = Call->getNumOperands(); i != e; ++i)
if (isa<PointerType>(Call->getOperand(i)->getType()))
Pointers.push_back(Call->getOperand(i));
// If this is an intrinsic function call, figure out which one.
unsigned IID = cast<Function>(Call->getOperand(0))->getIntrinsicID();
for (unsigned i = 0, e = Pointers.size(); i != e; ++i) {
// If any of our lattice values are passed into this call, which is
// specially handled by the local analyzer, inform the lattice function.
DSNode *N = DSG.getNodeForValue(Pointers[i]).getNode();
for (std::multimap<DSNode*, LatticeValue*>::iterator LVI =
NodeLVs.lower_bound(N); LVI != NodeLVs.end() && LVI->first == N;) {
bool AtBottom = false;
switch (IID) {
default:
AtBottom = LVI->second->visitRecognizedCall(*Call);
break;
case Intrinsic::memset:
if (Callbacks & Visit::Stores)
AtBottom = LVI->second->visitMemSet(*cast<CallInst>(Call));
break;
}
if (AtBottom) {
delete LVI->second;
NodeLVs.erase(LVI++);
} else {
++LVI;
}
}
}
}
}
void
PoolRegisterElimination::removeSingletonRegistrations (const char * name) {
//
// Scan through all uses of the registration function and see if it can be
// safely removed. If so, schedule it for removal.
//
std::vector<CallInst*> toBeRemoved;
Function * F = intrinsic->getIntrinsic(name).F;
//
// Look for and record all registrations that can be deleted.
//
for (Value::use_iterator UI=F->use_begin(), UE=F->use_end();
UI != UE;
++UI) {
//
// Get the pointer to the registered object.
//
CallInst * CI = cast<CallInst>(*UI);
Value * Ptr = intrinsic->getValuePointer(CI);
//
// Lookup the DSNode for the value in the function's DSGraph.
//
DSGraph * TDG = dsaPass->getDSGraph(*(CI->getParent()->getParent()));
DSNodeHandle DSH = TDG->getNodeForValue(Ptr);
assert ((!(DSH.isNull())) && "No DSNode for Value!\n");
//
// If the object being registered is the same size as that found in the
// DSNode, then we know it's a singleton object. The run-time doesn't need
// such objects registered in the splay trees, so we can remove the
// registration function.
//
DSNode * N = DSH.getNode();
Value * Size = intrinsic->getObjectSize (Ptr->stripPointerCasts());
if (Size) {
if (ConstantInt * C = dyn_cast<ConstantInt>(Size)) {
unsigned long size = C->getZExtValue();
if (size == N->getSize()) {
toBeRemoved.push_back(CI);
continue;
}
}
}
}
//
// Update the statistics.
//
if (toBeRemoved.size()) {
RemovedRegistration += toBeRemoved.size();
SingletonRegistrations += toBeRemoved.size();
}
//
// Remove the unnecesary registrations.
//
std::vector<CallInst*>::iterator it, end;
for (it = toBeRemoved.begin(), end = toBeRemoved.end(); it != end; ++it) {
(*it)->eraseFromParent();
}
}
/// ProcessNodesReachableFromGlobals - If we inferred anything about nodes
/// reachable from globals, we have to make sure that we incorporate data for
/// all graphs that include those globals due to the nature of the globals
/// graph.
///
void StructureFieldVisitorBase::
ProcessNodesReachableFromGlobals(DSGraph &DSG,
std::multimap<DSNode*,LatticeValue*> &NodeLVs){
// Start by marking all nodes reachable from globals.
DSScalarMap &SM = DSG.getScalarMap();
if (SM.global_begin() == SM.global_end()) return;
hash_set<const DSNode*> Reachable;
for (DSScalarMap::global_iterator GI = SM.global_begin(),
E = SM.global_end(); GI != E; ++GI)
SM[*GI].getNode()->markReachableNodes(Reachable);
if (Reachable.empty()) return;
// If any of the nodes with dataflow facts are reachable from the globals
// graph, we have to do the GG processing step.
bool MustProcessThroughGlobalsGraph = false;
for (std::multimap<DSNode*, LatticeValue*>::iterator I = NodeLVs.begin(),
E = NodeLVs.end(); I != E; ++I)
if (Reachable.count(I->first)) {
MustProcessThroughGlobalsGraph = true;
break;
}
if (!MustProcessThroughGlobalsGraph) return;
Reachable.clear();
// Compute the mapping from DSG to the globals graph.
DSGraph::NodeMapTy DSGToGGMap;
DSG.computeGToGGMapping(DSGToGGMap);
// Most of the times when we find facts about things reachable from globals we
// we are in the main graph. This means that we have *all* of the globals
// graph in this DSG. To be efficient, we compute the minimum set of globals
// that can reach any of the NodeLVs facts.
//
// I'm not aware of any wonderful way of computing the set of globals that
// points to the set of nodes in NodeLVs that is not N^2 in either NodeLVs or
// the number of globals, except to compute the inverse of DSG. As such, we
// compute the inverse graph of DSG, which basically has the edges going from
// pointed to nodes to pointing nodes. Because we only care about one
// connectedness properties, we ignore field info. In addition, we only
// compute inverse of the portion of the graph reachable from the globals.
std::set<std::pair<DSNode*,DSNode*> > InverseGraph;
for (DSScalarMap::global_iterator GI = SM.global_begin(),
E = SM.global_end(); GI != E; ++GI)
ComputeInverseGraphFrom(SM[*GI].getNode(), InverseGraph);
// Okay, now that we have our bastardized inverse graph, compute the set of
// globals nodes reachable from our lattice nodes.
for (std::multimap<DSNode*, LatticeValue*>::iterator I = NodeLVs.begin(),
E = NodeLVs.end(); I != E; ++I)
ComputeNodesReachableFrom(I->first, InverseGraph, Reachable);
// Now that we know which nodes point to the data flow facts, figure out which
// globals point to the data flow facts.
std::set<GlobalValue*> Globals;
for (hash_set<const DSNode*>::iterator I = Reachable.begin(),
E = Reachable.end(); I != E; ++I)
Globals.insert((*I)->globals_begin(), (*I)->globals_end());
// Finally, loop over all of the DSGraphs for the program, computing
// information for the graph if not done already, mapping the result into our
// context.
for (hash_map<const Function*, DSGraph*>::iterator GI = ECG.DSInfo.begin(),
E = ECG.DSInfo.end(); GI != E; ++GI) {
DSGraph &FG = *GI->second;
// Graphs can contain multiple functions, only process the graph once.
if (GI->first != FG.retnodes_begin()->first ||
// Also, do not bother reprocessing DSG.
&FG == &DSG)
continue;
bool GraphUsesGlobal = false;
for (std::set<GlobalValue*>::iterator I = Globals.begin(),
E = Globals.end(); I != E; ++I)
if (FG.getScalarMap().count(*I)) {
GraphUsesGlobal = true;
break;
}
// If this graph does not contain the global at all, there is no reason to
// even think about it.
if (!GraphUsesGlobal) continue;
// Otherwise, compute the full set of dataflow effects of the function.
std::multimap<DSNode*, LatticeValue*> &FGF = getCalleeFacts(FG);
//std::cerr << "Computed: " << FG.getFunctionNames() << "\n";
#if 0
for (std::multimap<DSNode*, LatticeValue*>::iterator I = FGF.begin(),
E = FGF.end(); I != E; ++I)
I->second->dump();
#endif
// Compute the mapping of nodes in the globals graph to the function's
// graph. Note that this function graph may not have nodes (or may have
// fragments of full nodes) in the globals graph, and we don't want this to
// pessimize the analysis.
std::multimap<const DSNode*, std::pair<DSNode*,int> > GraphMap;
DSGraph::NodeMapTy GraphToGGMap;
FG.computeGToGGMapping(GraphToGGMap);
// "Invert" the mapping. We compute the mapping from the start of a global
// graph node to a place in the graph's node. Note that not all of the GG
// node may be present in the graphs node, so there may be a negative offset
// involved.
while (!GraphToGGMap.empty()) {
DSNode *GN = const_cast<DSNode*>(GraphToGGMap.begin()->first);
DSNodeHandle &GGNH = GraphToGGMap.begin()->second;
GraphMap.insert(std::make_pair(GGNH.getNode(),
std::make_pair(GN, -GGNH.getOffset())));
GraphToGGMap.erase(GraphToGGMap.begin());
}
// Loop over all of the dataflow facts that we have computed, mapping them
// to the globals graph.
for (std::multimap<DSNode*, LatticeValue*>::iterator I = NodeLVs.begin(),
E = NodeLVs.end(); I != E; ) {
bool FactHitBottom = false;
//I->second->dump();
assert(I->first->getParentGraph() == &DSG);
assert(I->second->getNode()->getParentGraph() == &DSG);
// Node is in the GG?
DSGraph::NodeMapTy::iterator DSGToGGMapI = DSGToGGMap.find(I->first);
if (DSGToGGMapI != DSGToGGMap.end()) {
DSNodeHandle &GGNH = DSGToGGMapI->second;
const DSNode *GGNode = GGNH.getNode();
unsigned DSGToGGOffset = GGNH.getOffset();
// See if there is a node in FG that corresponds to this one. If not,
// no information will be computed in this scope, as the memory is not
// accessed.
std::multimap<const DSNode*, std::pair<DSNode*,int> >::iterator GMI =
GraphMap.find(GGNode);
// LatticeValOffset - The offset from the start of the GG Node to the
// start of the field we are interested in.
unsigned LatticeValOffset = I->second->getFieldOffset()+DSGToGGOffset;
// Loop over all of the nodes in FG that correspond to this single node
// in the GG.
for (; GMI != GraphMap.end() && GMI->first == GGNode; ++GMI) {
// Compute the offset to the field in the user graph.
unsigned FieldOffset = LatticeValOffset - GMI->second.second;
// If the field is within the amount of memory accessed by this scope,
// then there must be a corresponding lattice value.
DSNode *FGNode = GMI->second.first;
if (FieldOffset < FGNode->getSize()) {
LatticeValue *CorrespondingLV = 0;
std::multimap<DSNode*, LatticeValue*>::iterator FGFI =
FGF.find(FGNode);
for (; FGFI != FGF.end() && FGFI->first == FGNode; ++FGFI)
if (FGFI->second->getFieldOffset() == FieldOffset) {
CorrespondingLV = FGFI->second;
break;
}
// Finally, if either there was no corresponding fact (because it
// hit bottom in this scope), or if merging the two pieces of
// information makes it hit bottom, remember this.
if (CorrespondingLV == 0 ||
I->second->mergeInValue(CorrespondingLV))
FactHitBottom = true;
}
}
}
if (FactHitBottom) {
delete I->second;
NodeLVs.erase(I++);
if (NodeLVs.empty()) return;
} else {
++I;
}
}
}
}
