//===- LazyCallGraph.cpp - Analysis of a Module's call graph --------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "llvm/Analysis/LazyCallGraph.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/ScopeExit.h" #include "llvm/ADT/Sequence.h" #include "llvm/ADT/SmallPtrSet.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/iterator_range.h" #include "llvm/Analysis/TargetLibraryInfo.h" #include "llvm/Analysis/VectorUtils.h" #include "llvm/Config/llvm-config.h" #include "llvm/IR/Function.h" #include "llvm/IR/GlobalVariable.h" #include "llvm/IR/Instruction.h" #include "llvm/IR/Module.h" #include "llvm/IR/PassManager.h" #include "llvm/Support/Casting.h" #include "llvm/Support/Compiler.h" #include "llvm/Support/Debug.h" #include "llvm/Support/GraphWriter.h" #include "llvm/Support/raw_ostream.h" #include #include #include #include #include #include #include using namespace llvm; #define DEBUG_TYPE "lcg" void LazyCallGraph::EdgeSequence::insertEdgeInternal(Node &TargetN, Edge::Kind EK) { EdgeIndexMap.insert({&TargetN, Edges.size()}); Edges.emplace_back(TargetN, EK); } void LazyCallGraph::EdgeSequence::setEdgeKind(Node &TargetN, Edge::Kind EK) { Edges[EdgeIndexMap.find(&TargetN)->second].setKind(EK); } bool LazyCallGraph::EdgeSequence::removeEdgeInternal(Node &TargetN) { auto IndexMapI = EdgeIndexMap.find(&TargetN); if (IndexMapI == EdgeIndexMap.end()) return false; Edges[IndexMapI->second] = Edge(); EdgeIndexMap.erase(IndexMapI); return true; } static void addEdge(SmallVectorImpl &Edges, DenseMap &EdgeIndexMap, LazyCallGraph::Node &N, LazyCallGraph::Edge::Kind EK) { if (!EdgeIndexMap.insert({&N, Edges.size()}).second) return; LLVM_DEBUG(dbgs() << " Added callable function: " << N.getName() << "\n"); Edges.emplace_back(LazyCallGraph::Edge(N, EK)); } LazyCallGraph::EdgeSequence &LazyCallGraph::Node::populateSlow() { assert(!Edges && "Must not have already populated the edges for this node!"); LLVM_DEBUG(dbgs() << " Adding functions called by '" << getName() << "' to the graph.\n"); Edges = EdgeSequence(); SmallVector Worklist; SmallPtrSet Callees; SmallPtrSet Visited; // Find all the potential call graph edges in this function. We track both // actual call edges and indirect references to functions. The direct calls // are trivially added, but to accumulate the latter we walk the instructions // and add every operand which is a constant to the worklist to process // afterward. // // Note that we consider *any* function with a definition to be a viable // edge. Even if the function's definition is subject to replacement by // some other module (say, a weak definition) there may still be // optimizations which essentially speculate based on the definition and // a way to check that the specific definition is in fact the one being // used. For example, this could be done by moving the weak definition to // a strong (internal) definition and making the weak definition be an // alias. Then a test of the address of the weak function against the new // strong definition's address would be an effective way to determine the // safety of optimizing a direct call edge. for (BasicBlock &BB : *F) for (Instruction &I : BB) { if (auto *CB = dyn_cast(&I)) if (Function *Callee = CB->getCalledFunction()) if (!Callee->isDeclaration()) if (Callees.insert(Callee).second) { Visited.insert(Callee); addEdge(Edges->Edges, Edges->EdgeIndexMap, G->get(*Callee), LazyCallGraph::Edge::Call); } for (Value *Op : I.operand_values()) if (Constant *C = dyn_cast(Op)) if (Visited.insert(C).second) Worklist.push_back(C); } // We've collected all the constant (and thus potentially function or // function containing) operands to all of the instructions in the function. // Process them (recursively) collecting every function found. visitReferences(Worklist, Visited, [&](Function &F) { addEdge(Edges->Edges, Edges->EdgeIndexMap, G->get(F), LazyCallGraph::Edge::Ref); }); // Add implicit reference edges to any defined libcall functions (if we // haven't found an explicit edge). for (auto *F : G->LibFunctions) if (!Visited.count(F)) addEdge(Edges->Edges, Edges->EdgeIndexMap, G->get(*F), LazyCallGraph::Edge::Ref); return *Edges; } void LazyCallGraph::Node::replaceFunction(Function &NewF) { assert(F != &NewF && "Must not replace a function with itself!"); F = &NewF; } #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP) LLVM_DUMP_METHOD void LazyCallGraph::Node::dump() const { dbgs() << *this << '\n'; } #endif static bool isKnownLibFunction(Function &F, TargetLibraryInfo &TLI) { LibFunc LF; // Either this is a normal library function or a "vectorizable" // function. Not using the VFDatabase here because this query // is related only to libraries handled via the TLI. return TLI.getLibFunc(F, LF) || TLI.isKnownVectorFunctionInLibrary(F.getName()); } LazyCallGraph::LazyCallGraph( Module &M, function_ref GetTLI) { LLVM_DEBUG(dbgs() << "Building CG for module: " << M.getModuleIdentifier() << "\n"); for (Function &F : M) { if (F.isDeclaration()) continue; // If this function is a known lib function to LLVM then we want to // synthesize reference edges to it to model the fact that LLVM can turn // arbitrary code into a library function call. if (isKnownLibFunction(F, GetTLI(F))) LibFunctions.insert(&F); if (F.hasLocalLinkage()) continue; // External linkage defined functions have edges to them from other // modules. LLVM_DEBUG(dbgs() << " Adding '" << F.getName() << "' to entry set of the graph.\n"); addEdge(EntryEdges.Edges, EntryEdges.EdgeIndexMap, get(F), Edge::Ref); } // Externally visible aliases of internal functions are also viable entry // edges to the module. for (auto &A : M.aliases()) { if (A.hasLocalLinkage()) continue; if (Function* F = dyn_cast(A.getAliasee())) { LLVM_DEBUG(dbgs() << " Adding '" << F->getName() << "' with alias '" << A.getName() << "' to entry set of the graph.\n"); addEdge(EntryEdges.Edges, EntryEdges.EdgeIndexMap, get(*F), Edge::Ref); } } // Now add entry nodes for functions reachable via initializers to globals. SmallVector Worklist; SmallPtrSet Visited; for (GlobalVariable &GV : M.globals()) if (GV.hasInitializer()) if (Visited.insert(GV.getInitializer()).second) Worklist.push_back(GV.getInitializer()); LLVM_DEBUG( dbgs() << " Adding functions referenced by global initializers to the " "entry set.\n"); visitReferences(Worklist, Visited, [&](Function &F) { addEdge(EntryEdges.Edges, EntryEdges.EdgeIndexMap, get(F), LazyCallGraph::Edge::Ref); }); } LazyCallGraph::LazyCallGraph(LazyCallGraph &&G) : BPA(std::move(G.BPA)), NodeMap(std::move(G.NodeMap)), EntryEdges(std::move(G.EntryEdges)), SCCBPA(std::move(G.SCCBPA)), SCCMap(std::move(G.SCCMap)), LibFunctions(std::move(G.LibFunctions)) { updateGraphPtrs(); } bool LazyCallGraph::invalidate(Module &, const PreservedAnalyses &PA, ModuleAnalysisManager::Invalidator &) { // Check whether the analysis, all analyses on functions, or the function's // CFG have been preserved. auto PAC = PA.getChecker(); return !(PAC.preserved() || PAC.preservedSet>() || PAC.preservedSet()); } LazyCallGraph &LazyCallGraph::operator=(LazyCallGraph &&G) { BPA = std::move(G.BPA); NodeMap = std::move(G.NodeMap); EntryEdges = std::move(G.EntryEdges); SCCBPA = std::move(G.SCCBPA); SCCMap = std::move(G.SCCMap); LibFunctions = std::move(G.LibFunctions); updateGraphPtrs(); return *this; } #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP) LLVM_DUMP_METHOD void LazyCallGraph::SCC::dump() const { dbgs() << *this << '\n'; } #endif #ifndef NDEBUG void LazyCallGraph::SCC::verify() { assert(OuterRefSCC && "Can't have a null RefSCC!"); assert(!Nodes.empty() && "Can't have an empty SCC!"); for (Node *N : Nodes) { assert(N && "Can't have a null node!"); assert(OuterRefSCC->G->lookupSCC(*N) == this && "Node does not map to this SCC!"); assert(N->DFSNumber == -1 && "Must set DFS numbers to -1 when adding a node to an SCC!"); assert(N->LowLink == -1 && "Must set low link to -1 when adding a node to an SCC!"); for (Edge &E : **N) assert(E.getNode().isPopulated() && "Can't have an unpopulated node!"); } } #endif bool LazyCallGraph::SCC::isParentOf(const SCC &C) const { if (this == &C) return false; for (Node &N : *this) for (Edge &E : N->calls()) if (OuterRefSCC->G->lookupSCC(E.getNode()) == &C) return true; // No edges found. return false; } bool LazyCallGraph::SCC::isAncestorOf(const SCC &TargetC) const { if (this == &TargetC) return false; LazyCallGraph &G = *OuterRefSCC->G; // Start with this SCC. SmallPtrSet Visited = {this}; SmallVector Worklist = {this}; // Walk down the graph until we run out of edges or find a path to TargetC. do { const SCC &C = *Worklist.pop_back_val(); for (Node &N : C) for (Edge &E : N->calls()) { SCC *CalleeC = G.lookupSCC(E.getNode()); if (!CalleeC) continue; // If the callee's SCC is the TargetC, we're done. if (CalleeC == &TargetC) return true; // If this is the first time we've reached this SCC, put it on the // worklist to recurse through. if (Visited.insert(CalleeC).second) Worklist.push_back(CalleeC); } } while (!Worklist.empty()); // No paths found. return false; } LazyCallGraph::RefSCC::RefSCC(LazyCallGraph &G) : G(&G) {} #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP) LLVM_DUMP_METHOD void LazyCallGraph::RefSCC::dump() const { dbgs() << *this << '\n'; } #endif #ifndef NDEBUG void LazyCallGraph::RefSCC::verify() { assert(G && "Can't have a null graph!"); assert(!SCCs.empty() && "Can't have an empty SCC!"); // Verify basic properties of the SCCs. SmallPtrSet SCCSet; for (SCC *C : SCCs) { assert(C && "Can't have a null SCC!"); C->verify(); assert(&C->getOuterRefSCC() == this && "SCC doesn't think it is inside this RefSCC!"); bool Inserted = SCCSet.insert(C).second; assert(Inserted && "Found a duplicate SCC!"); auto IndexIt = SCCIndices.find(C); assert(IndexIt != SCCIndices.end() && "Found an SCC that doesn't have an index!"); } // Check that our indices map correctly. for (auto &SCCIndexPair : SCCIndices) { SCC *C = SCCIndexPair.first; int i = SCCIndexPair.second; assert(C && "Can't have a null SCC in the indices!"); assert(SCCSet.count(C) && "Found an index for an SCC not in the RefSCC!"); assert(SCCs[i] == C && "Index doesn't point to SCC!"); } // Check that the SCCs are in fact in post-order. for (int i = 0, Size = SCCs.size(); i < Size; ++i) { SCC &SourceSCC = *SCCs[i]; for (Node &N : SourceSCC) for (Edge &E : *N) { if (!E.isCall()) continue; SCC &TargetSCC = *G->lookupSCC(E.getNode()); if (&TargetSCC.getOuterRefSCC() == this) { assert(SCCIndices.find(&TargetSCC)->second <= i && "Edge between SCCs violates post-order relationship."); continue; } } } } #endif bool LazyCallGraph::RefSCC::isParentOf(const RefSCC &RC) const { if (&RC == this) return false; // Search all edges to see if this is a parent. for (SCC &C : *this) for (Node &N : C) for (Edge &E : *N) if (G->lookupRefSCC(E.getNode()) == &RC) return true; return false; } bool LazyCallGraph::RefSCC::isAncestorOf(const RefSCC &RC) const { if (&RC == this) return false; // For each descendant of this RefSCC, see if one of its children is the // argument. If not, add that descendant to the worklist and continue // searching. SmallVector Worklist; SmallPtrSet Visited; Worklist.push_back(this); Visited.insert(this); do { const RefSCC &DescendantRC = *Worklist.pop_back_val(); for (SCC &C : DescendantRC) for (Node &N : C) for (Edge &E : *N) { auto *ChildRC = G->lookupRefSCC(E.getNode()); if (ChildRC == &RC) return true; if (!ChildRC || !Visited.insert(ChildRC).second) continue; Worklist.push_back(ChildRC); } } while (!Worklist.empty()); return false; } /// Generic helper that updates a postorder sequence of SCCs for a potentially /// cycle-introducing edge insertion. /// /// A postorder sequence of SCCs of a directed graph has one fundamental /// property: all deges in the DAG of SCCs point "up" the sequence. That is, /// all edges in the SCC DAG point to prior SCCs in the sequence. /// /// This routine both updates a postorder sequence and uses that sequence to /// compute the set of SCCs connected into a cycle. It should only be called to /// insert a "downward" edge which will require changing the sequence to /// restore it to a postorder. /// /// When inserting an edge from an earlier SCC to a later SCC in some postorder /// sequence, all of the SCCs which may be impacted are in the closed range of /// those two within the postorder sequence. The algorithm used here to restore /// the state is as follows: /// /// 1) Starting from the source SCC, construct a set of SCCs which reach the /// source SCC consisting of just the source SCC. Then scan toward the /// target SCC in postorder and for each SCC, if it has an edge to an SCC /// in the set, add it to the set. Otherwise, the source SCC is not /// a successor, move it in the postorder sequence to immediately before /// the source SCC, shifting the source SCC and all SCCs in the set one /// position toward the target SCC. Stop scanning after processing the /// target SCC. /// 2) If the source SCC is now past the target SCC in the postorder sequence, /// and thus the new edge will flow toward the start, we are done. /// 3) Otherwise, starting from the target SCC, walk all edges which reach an /// SCC between the source and the target, and add them to the set of /// connected SCCs, then recurse through them. Once a complete set of the /// SCCs the target connects to is known, hoist the remaining SCCs between /// the source and the target to be above the target. Note that there is no /// need to process the source SCC, it is already known to connect. /// 4) At this point, all of the SCCs in the closed range between the source /// SCC and the target SCC in the postorder sequence are connected, /// including the target SCC and the source SCC. Inserting the edge from /// the source SCC to the target SCC will form a cycle out of precisely /// these SCCs. Thus we can merge all of the SCCs in this closed range into /// a single SCC. /// /// This process has various important properties: /// - Only mutates the SCCs when adding the edge actually changes the SCC /// structure. /// - Never mutates SCCs which are unaffected by the change. /// - Updates the postorder sequence to correctly satisfy the postorder /// constraint after the edge is inserted. /// - Only reorders SCCs in the closed postorder sequence from the source to /// the target, so easy to bound how much has changed even in the ordering. /// - Big-O is the number of edges in the closed postorder range of SCCs from /// source to target. /// /// This helper routine, in addition to updating the postorder sequence itself /// will also update a map from SCCs to indices within that sequence. /// /// The sequence and the map must operate on pointers to the SCC type. /// /// Two callbacks must be provided. The first computes the subset of SCCs in /// the postorder closed range from the source to the target which connect to /// the source SCC via some (transitive) set of edges. The second computes the /// subset of the same range which the target SCC connects to via some /// (transitive) set of edges. Both callbacks should populate the set argument /// provided. template static iterator_range updatePostorderSequenceForEdgeInsertion( SCCT &SourceSCC, SCCT &TargetSCC, PostorderSequenceT &SCCs, SCCIndexMapT &SCCIndices, ComputeSourceConnectedSetCallableT ComputeSourceConnectedSet, ComputeTargetConnectedSetCallableT ComputeTargetConnectedSet) { int SourceIdx = SCCIndices[&SourceSCC]; int TargetIdx = SCCIndices[&TargetSCC]; assert(SourceIdx < TargetIdx && "Cannot have equal indices here!"); SmallPtrSet ConnectedSet; // Compute the SCCs which (transitively) reach the source. ComputeSourceConnectedSet(ConnectedSet); // Partition the SCCs in this part of the port-order sequence so only SCCs // connecting to the source remain between it and the target. This is // a benign partition as it preserves postorder. auto SourceI = std::stable_partition( SCCs.begin() + SourceIdx, SCCs.begin() + TargetIdx + 1, [&ConnectedSet](SCCT *C) { return !ConnectedSet.count(C); }); for (int i = SourceIdx, e = TargetIdx + 1; i < e; ++i) SCCIndices.find(SCCs[i])->second = i; // If the target doesn't connect to the source, then we've corrected the // post-order and there are no cycles formed. if (!ConnectedSet.count(&TargetSCC)) { assert(SourceI > (SCCs.begin() + SourceIdx) && "Must have moved the source to fix the post-order."); assert(*std::prev(SourceI) == &TargetSCC && "Last SCC to move should have bene the target."); // Return an empty range at the target SCC indicating there is nothing to // merge. return make_range(std::prev(SourceI), std::prev(SourceI)); } assert(SCCs[TargetIdx] == &TargetSCC && "Should not have moved target if connected!"); SourceIdx = SourceI - SCCs.begin(); assert(SCCs[SourceIdx] == &SourceSCC && "Bad updated index computation for the source SCC!"); // See whether there are any remaining intervening SCCs between the source // and target. If so we need to make sure they all are reachable form the // target. if (SourceIdx + 1 < TargetIdx) { ConnectedSet.clear(); ComputeTargetConnectedSet(ConnectedSet); // Partition SCCs so that only SCCs reached from the target remain between // the source and the target. This preserves postorder. auto TargetI = std::stable_partition( SCCs.begin() + SourceIdx + 1, SCCs.begin() + TargetIdx + 1, [&ConnectedSet](SCCT *C) { return ConnectedSet.count(C); }); for (int i = SourceIdx + 1, e = TargetIdx + 1; i < e; ++i) SCCIndices.find(SCCs[i])->second = i; TargetIdx = std::prev(TargetI) - SCCs.begin(); assert(SCCs[TargetIdx] == &TargetSCC && "Should always end with the target!"); } // At this point, we know that connecting source to target forms a cycle // because target connects back to source, and we know that all of the SCCs // between the source and target in the postorder sequence participate in that // cycle. return make_range(SCCs.begin() + SourceIdx, SCCs.begin() + TargetIdx); } bool LazyCallGraph::RefSCC::switchInternalEdgeToCall( Node &SourceN, Node &TargetN, function_ref MergeSCCs)> MergeCB) { assert(!(*SourceN)[TargetN].isCall() && "Must start with a ref edge!"); SmallVector DeletedSCCs; #ifndef NDEBUG // In a debug build, verify the RefSCC is valid to start with and when this // routine finishes. verify(); auto VerifyOnExit = make_scope_exit([&]() { verify(); }); #endif SCC &SourceSCC = *G->lookupSCC(SourceN); SCC &TargetSCC = *G->lookupSCC(TargetN); // If the two nodes are already part of the same SCC, we're also done as // we've just added more connectivity. if (&SourceSCC == &TargetSCC) { SourceN->setEdgeKind(TargetN, Edge::Call); return false; // No new cycle. } // At this point we leverage the postorder list of SCCs to detect when the // insertion of an edge changes the SCC structure in any way. // // First and foremost, we can eliminate the need for any changes when the // edge is toward the beginning of the postorder sequence because all edges // flow in that direction already. Thus adding a new one cannot form a cycle. int SourceIdx = SCCIndices[&SourceSCC]; int TargetIdx = SCCIndices[&TargetSCC]; if (TargetIdx < SourceIdx) { SourceN->setEdgeKind(TargetN, Edge::Call); return false; // No new cycle. } // Compute the SCCs which (transitively) reach the source. auto ComputeSourceConnectedSet = [&](SmallPtrSetImpl &ConnectedSet) { #ifndef NDEBUG // Check that the RefSCC is still valid before computing this as the // results will be nonsensical of we've broken its invariants. verify(); #endif ConnectedSet.insert(&SourceSCC); auto IsConnected = [&](SCC &C) { for (Node &N : C) for (Edge &E : N->calls()) if (ConnectedSet.count(G->lookupSCC(E.getNode()))) return true; return false; }; for (SCC *C : make_range(SCCs.begin() + SourceIdx + 1, SCCs.begin() + TargetIdx + 1)) if (IsConnected(*C)) ConnectedSet.insert(C); }; // Use a normal worklist to find which SCCs the target connects to. We still // bound the search based on the range in the postorder list we care about, // but because this is forward connectivity we just "recurse" through the // edges. auto ComputeTargetConnectedSet = [&](SmallPtrSetImpl &ConnectedSet) { #ifndef NDEBUG // Check that the RefSCC is still valid before computing this as the // results will be nonsensical of we've broken its invariants. verify(); #endif ConnectedSet.insert(&TargetSCC); SmallVector Worklist; Worklist.push_back(&TargetSCC); do { SCC &C = *Worklist.pop_back_val(); for (Node &N : C) for (Edge &E : *N) { if (!E.isCall()) continue; SCC &EdgeC = *G->lookupSCC(E.getNode()); if (&EdgeC.getOuterRefSCC() != this) // Not in this RefSCC... continue; if (SCCIndices.find(&EdgeC)->second <= SourceIdx) // Not in the postorder sequence between source and target. continue; if (ConnectedSet.insert(&EdgeC).second) Worklist.push_back(&EdgeC); } } while (!Worklist.empty()); }; // Use a generic helper to update the postorder sequence of SCCs and return // a range of any SCCs connected into a cycle by inserting this edge. This // routine will also take care of updating the indices into the postorder // sequence. auto MergeRange = updatePostorderSequenceForEdgeInsertion( SourceSCC, TargetSCC, SCCs, SCCIndices, ComputeSourceConnectedSet, ComputeTargetConnectedSet); // Run the user's callback on the merged SCCs before we actually merge them. if (MergeCB) MergeCB(makeArrayRef(MergeRange.begin(), MergeRange.end())); // If the merge range is empty, then adding the edge didn't actually form any // new cycles. We're done. if (MergeRange.empty()) { // Now that the SCC structure is finalized, flip the kind to call. SourceN->setEdgeKind(TargetN, Edge::Call); return false; // No new cycle. } #ifndef NDEBUG // Before merging, check that the RefSCC remains valid after all the // postorder updates. verify(); #endif // Otherwise we need to merge all of the SCCs in the cycle into a single // result SCC. // // NB: We merge into the target because all of these functions were already // reachable from the target, meaning any SCC-wide properties deduced about it // other than the set of functions within it will not have changed. for (SCC *C : MergeRange) { assert(C != &TargetSCC && "We merge *into* the target and shouldn't process it here!"); SCCIndices.erase(C); TargetSCC.Nodes.append(C->Nodes.begin(), C->Nodes.end()); for (Node *N : C->Nodes) G->SCCMap[N] = &TargetSCC; C->clear(); DeletedSCCs.push_back(C); } // Erase the merged SCCs from the list and update the indices of the // remaining SCCs. int IndexOffset = MergeRange.end() - MergeRange.begin(); auto EraseEnd = SCCs.erase(MergeRange.begin(), MergeRange.end()); for (SCC *C : make_range(EraseEnd, SCCs.end())) SCCIndices[C] -= IndexOffset; // Now that the SCC structure is finalized, flip the kind to call. SourceN->setEdgeKind(TargetN, Edge::Call); // And we're done, but we did form a new cycle. return true; } void LazyCallGraph::RefSCC::switchTrivialInternalEdgeToRef(Node &SourceN, Node &TargetN) { assert((*SourceN)[TargetN].isCall() && "Must start with a call edge!"); #ifndef NDEBUG // In a debug build, verify the RefSCC is valid to start with and when this // routine finishes. verify(); auto VerifyOnExit = make_scope_exit([&]() { verify(); }); #endif assert(G->lookupRefSCC(SourceN) == this && "Source must be in this RefSCC."); assert(G->lookupRefSCC(TargetN) == this && "Target must be in this RefSCC."); assert(G->lookupSCC(SourceN) != G->lookupSCC(TargetN) && "Source and Target must be in separate SCCs for this to be trivial!"); // Set the edge kind. SourceN->setEdgeKind(TargetN, Edge::Ref); } iterator_range LazyCallGraph::RefSCC::switchInternalEdgeToRef(Node &SourceN, Node &TargetN) { assert((*SourceN)[TargetN].isCall() && "Must start with a call edge!"); #ifndef NDEBUG // In a debug build, verify the RefSCC is valid to start with and when this // routine finishes. verify(); auto VerifyOnExit = make_scope_exit([&]() { verify(); }); #endif assert(G->lookupRefSCC(SourceN) == this && "Source must be in this RefSCC."); assert(G->lookupRefSCC(TargetN) == this && "Target must be in this RefSCC."); SCC &TargetSCC = *G->lookupSCC(TargetN); assert(G->lookupSCC(SourceN) == &TargetSCC && "Source and Target must be in " "the same SCC to require the " "full CG update."); // Set the edge kind. SourceN->setEdgeKind(TargetN, Edge::Ref); // Otherwise we are removing a call edge from a single SCC. This may break // the cycle. In order to compute the new set of SCCs, we need to do a small // DFS over the nodes within the SCC to form any sub-cycles that remain as // distinct SCCs and compute a postorder over the resulting SCCs. // // However, we specially handle the target node. The target node is known to // reach all other nodes in the original SCC by definition. This means that // we want the old SCC to be replaced with an SCC containing that node as it // will be the root of whatever SCC DAG results from the DFS. Assumptions // about an SCC such as the set of functions called will continue to hold, // etc. SCC &OldSCC = TargetSCC; SmallVector, 16> DFSStack; SmallVector PendingSCCStack; SmallVector NewSCCs; // Prepare the nodes for a fresh DFS. SmallVector Worklist; Worklist.swap(OldSCC.Nodes); for (Node *N : Worklist) { N->DFSNumber = N->LowLink = 0; G->SCCMap.erase(N); } // Force the target node to be in the old SCC. This also enables us to take // a very significant short-cut in the standard Tarjan walk to re-form SCCs // below: whenever we build an edge that reaches the target node, we know // that the target node eventually connects back to all other nodes in our // walk. As a consequence, we can detect and handle participants in that // cycle without walking all the edges that form this connection, and instead // by relying on the fundamental guarantee coming into this operation (all // nodes are reachable from the target due to previously forming an SCC). TargetN.DFSNumber = TargetN.LowLink = -1; OldSCC.Nodes.push_back(&TargetN); G->SCCMap[&TargetN] = &OldSCC; // Scan down the stack and DFS across the call edges. for (Node *RootN : Worklist) { assert(DFSStack.empty() && "Cannot begin a new root with a non-empty DFS stack!"); assert(PendingSCCStack.empty() && "Cannot begin a new root with pending nodes for an SCC!"); // Skip any nodes we've already reached in the DFS. if (RootN->DFSNumber != 0) { assert(RootN->DFSNumber == -1 && "Shouldn't have any mid-DFS root nodes!"); continue; } RootN->DFSNumber = RootN->LowLink = 1; int NextDFSNumber = 2; DFSStack.push_back({RootN, (*RootN)->call_begin()}); do { Node *N; EdgeSequence::call_iterator I; std::tie(N, I) = DFSStack.pop_back_val(); auto E = (*N)->call_end(); while (I != E) { Node &ChildN = I->getNode(); if (ChildN.DFSNumber == 0) { // We haven't yet visited this child, so descend, pushing the current // node onto the stack. DFSStack.push_back({N, I}); assert(!G->SCCMap.count(&ChildN) && "Found a node with 0 DFS number but already in an SCC!"); ChildN.DFSNumber = ChildN.LowLink = NextDFSNumber++; N = &ChildN; I = (*N)->call_begin(); E = (*N)->call_end(); continue; } // Check for the child already being part of some component. if (ChildN.DFSNumber == -1) { if (G->lookupSCC(ChildN) == &OldSCC) { // If the child is part of the old SCC, we know that it can reach // every other node, so we have formed a cycle. Pull the entire DFS // and pending stacks into it. See the comment above about setting // up the old SCC for why we do this. int OldSize = OldSCC.size(); OldSCC.Nodes.push_back(N); OldSCC.Nodes.append(PendingSCCStack.begin(), PendingSCCStack.end()); PendingSCCStack.clear(); while (!DFSStack.empty()) OldSCC.Nodes.push_back(DFSStack.pop_back_val().first); for (Node &N : make_range(OldSCC.begin() + OldSize, OldSCC.end())) { N.DFSNumber = N.LowLink = -1; G->SCCMap[&N] = &OldSCC; } N = nullptr; break; } // If the child has already been added to some child component, it // couldn't impact the low-link of this parent because it isn't // connected, and thus its low-link isn't relevant so skip it. ++I; continue; } // Track the lowest linked child as the lowest link for this node. assert(ChildN.LowLink > 0 && "Must have a positive low-link number!"); if (ChildN.LowLink < N->LowLink) N->LowLink = ChildN.LowLink; // Move to the next edge. ++I; } if (!N) // Cleared the DFS early, start another round. break; // We've finished processing N and its descendants, put it on our pending // SCC stack to eventually get merged into an SCC of nodes. PendingSCCStack.push_back(N); // If this node is linked to some lower entry, continue walking up the // stack. if (N->LowLink != N->DFSNumber) continue; // Otherwise, we've completed an SCC. Append it to our post order list of // SCCs. int RootDFSNumber = N->DFSNumber; // Find the range of the node stack by walking down until we pass the // root DFS number. auto SCCNodes = make_range( PendingSCCStack.rbegin(), find_if(reverse(PendingSCCStack), [RootDFSNumber](const Node *N) { return N->DFSNumber < RootDFSNumber; })); // Form a new SCC out of these nodes and then clear them off our pending // stack. NewSCCs.push_back(G->createSCC(*this, SCCNodes)); for (Node &N : *NewSCCs.back()) { N.DFSNumber = N.LowLink = -1; G->SCCMap[&N] = NewSCCs.back(); } PendingSCCStack.erase(SCCNodes.end().base(), PendingSCCStack.end()); } while (!DFSStack.empty()); } // Insert the remaining SCCs before the old one. The old SCC can reach all // other SCCs we form because it contains the target node of the removed edge // of the old SCC. This means that we will have edges into all of the new // SCCs, which means the old one must come last for postorder. int OldIdx = SCCIndices[&OldSCC]; SCCs.insert(SCCs.begin() + OldIdx, NewSCCs.begin(), NewSCCs.end()); // Update the mapping from SCC* to index to use the new SCC*s, and remove the // old SCC from the mapping. for (int Idx = OldIdx, Size = SCCs.size(); Idx < Size; ++Idx) SCCIndices[SCCs[Idx]] = Idx; return make_range(SCCs.begin() + OldIdx, SCCs.begin() + OldIdx + NewSCCs.size()); } void LazyCallGraph::RefSCC::switchOutgoingEdgeToCall(Node &SourceN, Node &TargetN) { assert(!(*SourceN)[TargetN].isCall() && "Must start with a ref edge!"); assert(G->lookupRefSCC(SourceN) == this && "Source must be in this RefSCC."); assert(G->lookupRefSCC(TargetN) != this && "Target must not be in this RefSCC."); #ifdef EXPENSIVE_CHECKS assert(G->lookupRefSCC(TargetN)->isDescendantOf(*this) && "Target must be a descendant of the Source."); #endif // Edges between RefSCCs are the same regardless of call or ref, so we can // just flip the edge here. SourceN->setEdgeKind(TargetN, Edge::Call); #ifndef NDEBUG // Check that the RefSCC is still valid. verify(); #endif } void LazyCallGraph::RefSCC::switchOutgoingEdgeToRef(Node &SourceN, Node &TargetN) { assert((*SourceN)[TargetN].isCall() && "Must start with a call edge!"); assert(G->lookupRefSCC(SourceN) == this && "Source must be in this RefSCC."); assert(G->lookupRefSCC(TargetN) != this && "Target must not be in this RefSCC."); #ifdef EXPENSIVE_CHECKS assert(G->lookupRefSCC(TargetN)->isDescendantOf(*this) && "Target must be a descendant of the Source."); #endif // Edges between RefSCCs are the same regardless of call or ref, so we can // just flip the edge here. SourceN->setEdgeKind(TargetN, Edge::Ref); #ifndef NDEBUG // Check that the RefSCC is still valid. verify(); #endif } void LazyCallGraph::RefSCC::insertInternalRefEdge(Node &SourceN, Node &TargetN) { assert(G->lookupRefSCC(SourceN) == this && "Source must be in this RefSCC."); assert(G->lookupRefSCC(TargetN) == this && "Target must be in this RefSCC."); SourceN->insertEdgeInternal(TargetN, Edge::Ref); #ifndef NDEBUG // Check that the RefSCC is still valid. verify(); #endif } void LazyCallGraph::RefSCC::insertOutgoingEdge(Node &SourceN, Node &TargetN, Edge::Kind EK) { // First insert it into the caller. SourceN->insertEdgeInternal(TargetN, EK); assert(G->lookupRefSCC(SourceN) == this && "Source must be in this RefSCC."); assert(G->lookupRefSCC(TargetN) != this && "Target must not be in this RefSCC."); #ifdef EXPENSIVE_CHECKS assert(G->lookupRefSCC(TargetN)->isDescendantOf(*this) && "Target must be a descendant of the Source."); #endif #ifndef NDEBUG // Check that the RefSCC is still valid. verify(); #endif } SmallVector LazyCallGraph::RefSCC::insertIncomingRefEdge(Node &SourceN, Node &TargetN) { assert(G->lookupRefSCC(TargetN) == this && "Target must be in this RefSCC."); RefSCC &SourceC = *G->lookupRefSCC(SourceN); assert(&SourceC != this && "Source must not be in this RefSCC."); #ifdef EXPENSIVE_CHECKS assert(SourceC.isDescendantOf(*this) && "Source must be a descendant of the Target."); #endif SmallVector DeletedRefSCCs; #ifndef NDEBUG // In a debug build, verify the RefSCC is valid to start with and when this // routine finishes. verify(); auto VerifyOnExit = make_scope_exit([&]() { verify(); }); #endif int SourceIdx = G->RefSCCIndices[&SourceC]; int TargetIdx = G->RefSCCIndices[this]; assert(SourceIdx < TargetIdx && "Postorder list doesn't see edge as incoming!"); // Compute the RefSCCs which (transitively) reach the source. We do this by // working backwards from the source using the parent set in each RefSCC, // skipping any RefSCCs that don't fall in the postorder range. This has the // advantage of walking the sparser parent edge (in high fan-out graphs) but // more importantly this removes examining all forward edges in all RefSCCs // within the postorder range which aren't in fact connected. Only connected // RefSCCs (and their edges) are visited here. auto ComputeSourceConnectedSet = [&](SmallPtrSetImpl &Set) { Set.insert(&SourceC); auto IsConnected = [&](RefSCC &RC) { for (SCC &C : RC) for (Node &N : C) for (Edge &E : *N) if (Set.count(G->lookupRefSCC(E.getNode()))) return true; return false; }; for (RefSCC *C : make_range(G->PostOrderRefSCCs.begin() + SourceIdx + 1, G->PostOrderRefSCCs.begin() + TargetIdx + 1)) if (IsConnected(*C)) Set.insert(C); }; // Use a normal worklist to find which SCCs the target connects to. We still // bound the search based on the range in the postorder list we care about, // but because this is forward connectivity we just "recurse" through the // edges. auto ComputeTargetConnectedSet = [&](SmallPtrSetImpl &Set) { Set.insert(this); SmallVector Worklist; Worklist.push_back(this); do { RefSCC &RC = *Worklist.pop_back_val(); for (SCC &C : RC) for (Node &N : C) for (Edge &E : *N) { RefSCC &EdgeRC = *G->lookupRefSCC(E.getNode()); if (G->getRefSCCIndex(EdgeRC) <= SourceIdx) // Not in the postorder sequence between source and target. continue; if (Set.insert(&EdgeRC).second) Worklist.push_back(&EdgeRC); } } while (!Worklist.empty()); }; // Use a generic helper to update the postorder sequence of RefSCCs and return // a range of any RefSCCs connected into a cycle by inserting this edge. This // routine will also take care of updating the indices into the postorder // sequence. iterator_range::iterator> MergeRange = updatePostorderSequenceForEdgeInsertion( SourceC, *this, G->PostOrderRefSCCs, G->RefSCCIndices, ComputeSourceConnectedSet, ComputeTargetConnectedSet); // Build a set so we can do fast tests for whether a RefSCC will end up as // part of the merged RefSCC. SmallPtrSet MergeSet(MergeRange.begin(), MergeRange.end()); // This RefSCC will always be part of that set, so just insert it here. MergeSet.insert(this); // Now that we have identified all of the SCCs which need to be merged into // a connected set with the inserted edge, merge all of them into this SCC. SmallVector MergedSCCs; int SCCIndex = 0; for (RefSCC *RC : MergeRange) { assert(RC != this && "We're merging into the target RefSCC, so it " "shouldn't be in the range."); // Walk the inner SCCs to update their up-pointer and walk all the edges to // update any parent sets. // FIXME: We should try to find a way to avoid this (rather expensive) edge // walk by updating the parent sets in some other manner. for (SCC &InnerC : *RC) { InnerC.OuterRefSCC = this; SCCIndices[&InnerC] = SCCIndex++; for (Node &N : InnerC) G->SCCMap[&N] = &InnerC; } // Now merge in the SCCs. We can actually move here so try to reuse storage // the first time through. if (MergedSCCs.empty()) MergedSCCs = std::move(RC->SCCs); else MergedSCCs.append(RC->SCCs.begin(), RC->SCCs.end()); RC->SCCs.clear(); DeletedRefSCCs.push_back(RC); } // Append our original SCCs to the merged list and move it into place. for (SCC &InnerC : *this) SCCIndices[&InnerC] = SCCIndex++; MergedSCCs.append(SCCs.begin(), SCCs.end()); SCCs = std::move(MergedSCCs); // Remove the merged away RefSCCs from the post order sequence. for (RefSCC *RC : MergeRange) G->RefSCCIndices.erase(RC); int IndexOffset = MergeRange.end() - MergeRange.begin(); auto EraseEnd = G->PostOrderRefSCCs.erase(MergeRange.begin(), MergeRange.end()); for (RefSCC *RC : make_range(EraseEnd, G->PostOrderRefSCCs.end())) G->RefSCCIndices[RC] -= IndexOffset; // At this point we have a merged RefSCC with a post-order SCCs list, just // connect the nodes to form the new edge. SourceN->insertEdgeInternal(TargetN, Edge::Ref); // We return the list of SCCs which were merged so that callers can // invalidate any data they have associated with those SCCs. Note that these // SCCs are no longer in an interesting state (they are totally empty) but // the pointers will remain stable for the life of the graph itself. return DeletedRefSCCs; } void LazyCallGraph::RefSCC::removeOutgoingEdge(Node &SourceN, Node &TargetN) { assert(G->lookupRefSCC(SourceN) == this && "The source must be a member of this RefSCC."); assert(G->lookupRefSCC(TargetN) != this && "The target must not be a member of this RefSCC"); #ifndef NDEBUG // In a debug build, verify the RefSCC is valid to start with and when this // routine finishes. verify(); auto VerifyOnExit = make_scope_exit([&]() { verify(); }); #endif // First remove it from the node. bool Removed = SourceN->removeEdgeInternal(TargetN); (void)Removed; assert(Removed && "Target not in the edge set for this caller?"); } SmallVector LazyCallGraph::RefSCC::removeInternalRefEdge(Node &SourceN, ArrayRef TargetNs) { // We return a list of the resulting *new* RefSCCs in post-order. SmallVector Result; #ifndef NDEBUG // In a debug build, verify the RefSCC is valid to start with and that either // we return an empty list of result RefSCCs and this RefSCC remains valid, // or we return new RefSCCs and this RefSCC is dead. verify(); auto VerifyOnExit = make_scope_exit([&]() { // If we didn't replace our RefSCC with new ones, check that this one // remains valid. if (G) verify(); }); #endif // First remove the actual edges. for (Node *TargetN : TargetNs) { assert(!(*SourceN)[*TargetN].isCall() && "Cannot remove a call edge, it must first be made a ref edge"); bool Removed = SourceN->removeEdgeInternal(*TargetN); (void)Removed; assert(Removed && "Target not in the edge set for this caller?"); } // Direct self references don't impact the ref graph at all. if (llvm::all_of(TargetNs, [&](Node *TargetN) { return &SourceN == TargetN; })) return Result; // If all targets are in the same SCC as the source, because no call edges // were removed there is no RefSCC structure change. SCC &SourceC = *G->lookupSCC(SourceN); if (llvm::all_of(TargetNs, [&](Node *TargetN) { return G->lookupSCC(*TargetN) == &SourceC; })) return Result; // We build somewhat synthetic new RefSCCs by providing a postorder mapping // for each inner SCC. We store these inside the low-link field of the nodes // rather than associated with SCCs because this saves a round-trip through // the node->SCC map and in the common case, SCCs are small. We will verify // that we always give the same number to every node in the SCC such that // these are equivalent. int PostOrderNumber = 0; // Reset all the other nodes to prepare for a DFS over them, and add them to // our worklist. SmallVector Worklist; for (SCC *C : SCCs) { for (Node &N : *C) N.DFSNumber = N.LowLink = 0; Worklist.append(C->Nodes.begin(), C->Nodes.end()); } // Track the number of nodes in this RefSCC so that we can quickly recognize // an important special case of the edge removal not breaking the cycle of // this RefSCC. const int NumRefSCCNodes = Worklist.size(); SmallVector, 4> DFSStack; SmallVector PendingRefSCCStack; do { assert(DFSStack.empty() && "Cannot begin a new root with a non-empty DFS stack!"); assert(PendingRefSCCStack.empty() && "Cannot begin a new root with pending nodes for an SCC!"); Node *RootN = Worklist.pop_back_val(); // Skip any nodes we've already reached in the DFS. if (RootN->DFSNumber != 0) { assert(RootN->DFSNumber == -1 && "Shouldn't have any mid-DFS root nodes!"); continue; } RootN->DFSNumber = RootN->LowLink = 1; int NextDFSNumber = 2; DFSStack.push_back({RootN, (*RootN)->begin()}); do { Node *N; EdgeSequence::iterator I; std::tie(N, I) = DFSStack.pop_back_val(); auto E = (*N)->end(); assert(N->DFSNumber != 0 && "We should always assign a DFS number " "before processing a node."); while (I != E) { Node &ChildN = I->getNode(); if (ChildN.DFSNumber == 0) { // Mark that we should start at this child when next this node is the // top of the stack. We don't start at the next child to ensure this // child's lowlink is reflected. DFSStack.push_back({N, I}); // Continue, resetting to the child node. ChildN.LowLink = ChildN.DFSNumber = NextDFSNumber++; N = &ChildN; I = ChildN->begin(); E = ChildN->end(); continue; } if (ChildN.DFSNumber == -1) { // If this child isn't currently in this RefSCC, no need to process // it. ++I; continue; } // Track the lowest link of the children, if any are still in the stack. // Any child not on the stack will have a LowLink of -1. assert(ChildN.LowLink != 0 && "Low-link must not be zero with a non-zero DFS number."); if (ChildN.LowLink >= 0 && ChildN.LowLink < N->LowLink) N->LowLink = ChildN.LowLink; ++I; } // We've finished processing N and its descendants, put it on our pending // stack to eventually get merged into a RefSCC. PendingRefSCCStack.push_back(N); // If this node is linked to some lower entry, continue walking up the // stack. if (N->LowLink != N->DFSNumber) { assert(!DFSStack.empty() && "We never found a viable root for a RefSCC to pop off!"); continue; } // Otherwise, form a new RefSCC from the top of the pending node stack. int RefSCCNumber = PostOrderNumber++; int RootDFSNumber = N->DFSNumber; // Find the range of the node stack by walking down until we pass the // root DFS number. Update the DFS numbers and low link numbers in the // process to avoid re-walking this list where possible. auto StackRI = find_if(reverse(PendingRefSCCStack), [&](Node *N) { if (N->DFSNumber < RootDFSNumber) // We've found the bottom. return true; // Update this node and keep scanning. N->DFSNumber = -1; // Save the post-order number in the lowlink field so that we can use // it to map SCCs into new RefSCCs after we finish the DFS. N->LowLink = RefSCCNumber; return false; }); auto RefSCCNodes = make_range(StackRI.base(), PendingRefSCCStack.end()); // If we find a cycle containing all nodes originally in this RefSCC then // the removal hasn't changed the structure at all. This is an important // special case and we can directly exit the entire routine more // efficiently as soon as we discover it. if (llvm::size(RefSCCNodes) == NumRefSCCNodes) { // Clear out the low link field as we won't need it. for (Node *N : RefSCCNodes) N->LowLink = -1; // Return the empty result immediately. return Result; } // We've already marked the nodes internally with the RefSCC number so // just clear them off the stack and continue. PendingRefSCCStack.erase(RefSCCNodes.begin(), PendingRefSCCStack.end()); } while (!DFSStack.empty()); assert(DFSStack.empty() && "Didn't flush the entire DFS stack!"); assert(PendingRefSCCStack.empty() && "Didn't flush all pending nodes!"); } while (!Worklist.empty()); assert(PostOrderNumber > 1 && "Should never finish the DFS when the existing RefSCC remains valid!"); // Otherwise we create a collection of new RefSCC nodes and build // a radix-sort style map from postorder number to these new RefSCCs. We then // append SCCs to each of these RefSCCs in the order they occurred in the // original SCCs container. for (int i = 0; i < PostOrderNumber; ++i) Result.push_back(G->createRefSCC(*G)); // Insert the resulting postorder sequence into the global graph postorder // sequence before the current RefSCC in that sequence, and then remove the // current one. // // FIXME: It'd be nice to change the APIs so that we returned an iterator // range over the global postorder sequence and generally use that sequence // rather than building a separate result vector here. int Idx = G->getRefSCCIndex(*this); G->PostOrderRefSCCs.erase(G->PostOrderRefSCCs.begin() + Idx); G->PostOrderRefSCCs.insert(G->PostOrderRefSCCs.begin() + Idx, Result.begin(), Result.end()); for (int i : seq(Idx, G->PostOrderRefSCCs.size())) G->RefSCCIndices[G->PostOrderRefSCCs[i]] = i; for (SCC *C : SCCs) { // We store the SCC number in the node's low-link field above. int SCCNumber = C->begin()->LowLink; // Clear out all of the SCC's node's low-link fields now that we're done // using them as side-storage. for (Node &N : *C) { assert(N.LowLink == SCCNumber && "Cannot have different numbers for nodes in the same SCC!"); N.LowLink = -1; } RefSCC &RC = *Result[SCCNumber]; int SCCIndex = RC.SCCs.size(); RC.SCCs.push_back(C); RC.SCCIndices[C] = SCCIndex; C->OuterRefSCC = &RC; } // Now that we've moved things into the new RefSCCs, clear out our current // one. G = nullptr; SCCs.clear(); SCCIndices.clear(); #ifndef NDEBUG // Verify the new RefSCCs we've built. for (RefSCC *RC : Result) RC->verify(); #endif // Return the new list of SCCs. return Result; } void LazyCallGraph::RefSCC::handleTrivialEdgeInsertion(Node &SourceN, Node &TargetN) { // The only trivial case that requires any graph updates is when we add new // ref edge and may connect different RefSCCs along that path. This is only // because of the parents set. Every other part of the graph remains constant // after this edge insertion. assert(G->lookupRefSCC(SourceN) == this && "Source must be in this RefSCC."); RefSCC &TargetRC = *G->lookupRefSCC(TargetN); if (&TargetRC == this) return; #ifdef EXPENSIVE_CHECKS assert(TargetRC.isDescendantOf(*this) && "Target must be a descendant of the Source."); #endif } void LazyCallGraph::RefSCC::insertTrivialCallEdge(Node &SourceN, Node &TargetN) { #ifndef NDEBUG // Check that the RefSCC is still valid when we finish. auto ExitVerifier = make_scope_exit([this] { verify(); }); #ifdef EXPENSIVE_CHECKS // Check that we aren't breaking some invariants of the SCC graph. Note that // this is quadratic in the number of edges in the call graph! SCC &SourceC = *G->lookupSCC(SourceN); SCC &TargetC = *G->lookupSCC(TargetN); if (&SourceC != &TargetC) assert(SourceC.isAncestorOf(TargetC) && "Call edge is not trivial in the SCC graph!"); #endif // EXPENSIVE_CHECKS #endif // NDEBUG // First insert it into the source or find the existing edge. auto InsertResult = SourceN->EdgeIndexMap.insert({&TargetN, SourceN->Edges.size()}); if (!InsertResult.second) { // Already an edge, just update it. Edge &E = SourceN->Edges[InsertResult.first->second]; if (E.isCall()) return; // Nothing to do! E.setKind(Edge::Call); } else { // Create the new edge. SourceN->Edges.emplace_back(TargetN, Edge::Call); } // Now that we have the edge, handle the graph fallout. handleTrivialEdgeInsertion(SourceN, TargetN); } void LazyCallGraph::RefSCC::insertTrivialRefEdge(Node &SourceN, Node &TargetN) { #ifndef NDEBUG // Check that the RefSCC is still valid when we finish. auto ExitVerifier = make_scope_exit([this] { verify(); }); #ifdef EXPENSIVE_CHECKS // Check that we aren't breaking some invariants of the RefSCC graph. RefSCC &SourceRC = *G->lookupRefSCC(SourceN); RefSCC &TargetRC = *G->lookupRefSCC(TargetN); if (&SourceRC != &TargetRC) assert(SourceRC.isAncestorOf(TargetRC) && "Ref edge is not trivial in the RefSCC graph!"); #endif // EXPENSIVE_CHECKS #endif // NDEBUG // First insert it into the source or find the existing edge. auto InsertResult = SourceN->EdgeIndexMap.insert({&TargetN, SourceN->Edges.size()}); if (!InsertResult.second) // Already an edge, we're done. return; // Create the new edge. SourceN->Edges.emplace_back(TargetN, Edge::Ref); // Now that we have the edge, handle the graph fallout. handleTrivialEdgeInsertion(SourceN, TargetN); } void LazyCallGraph::RefSCC::replaceNodeFunction(Node &N, Function &NewF) { Function &OldF = N.getFunction(); #ifndef NDEBUG // Check that the RefSCC is still valid when we finish. auto ExitVerifier = make_scope_exit([this] { verify(); }); assert(G->lookupRefSCC(N) == this && "Cannot replace the function of a node outside this RefSCC."); assert(G->NodeMap.find(&NewF) == G->NodeMap.end() && "Must not have already walked the new function!'"); // It is important that this replacement not introduce graph changes so we // insist that the caller has already removed every use of the original // function and that all uses of the new function correspond to existing // edges in the graph. The common and expected way to use this is when // replacing the function itself in the IR without changing the call graph // shape and just updating the analysis based on that. assert(&OldF != &NewF && "Cannot replace a function with itself!"); assert(OldF.use_empty() && "Must have moved all uses from the old function to the new!"); #endif N.replaceFunction(NewF); // Update various call graph maps. G->NodeMap.erase(&OldF); G->NodeMap[&NewF] = &N; } void LazyCallGraph::insertEdge(Node &SourceN, Node &TargetN, Edge::Kind EK) { assert(SCCMap.empty() && "This method cannot be called after SCCs have been formed!"); return SourceN->insertEdgeInternal(TargetN, EK); } void LazyCallGraph::removeEdge(Node &SourceN, Node &TargetN) { assert(SCCMap.empty() && "This method cannot be called after SCCs have been formed!"); bool Removed = SourceN->removeEdgeInternal(TargetN); (void)Removed; assert(Removed && "Target not in the edge set for this caller?"); } void LazyCallGraph::removeDeadFunction(Function &F) { // FIXME: This is unnecessarily restrictive. We should be able to remove // functions which recursively call themselves. assert(F.use_empty() && "This routine should only be called on trivially dead functions!"); // We shouldn't remove library functions as they are never really dead while // the call graph is in use -- every function definition refers to them. assert(!isLibFunction(F) && "Must not remove lib functions from the call graph!"); auto NI = NodeMap.find(&F); if (NI == NodeMap.end()) // Not in the graph at all! return; Node &N = *NI->second; NodeMap.erase(NI); // Remove this from the entry edges if present. EntryEdges.removeEdgeInternal(N); if (SCCMap.empty()) { // No SCCs have been formed, so removing this is fine and there is nothing // else necessary at this point but clearing out the node. N.clear(); return; } // Cannot remove a function which has yet to be visited in the DFS walk, so // if we have a node at all then we must have an SCC and RefSCC. auto CI = SCCMap.find(&N); assert(CI != SCCMap.end() && "Tried to remove a node without an SCC after DFS walk started!"); SCC &C = *CI->second; SCCMap.erase(CI); RefSCC &RC = C.getOuterRefSCC(); // This node must be the only member of its SCC as it has no callers, and // that SCC must be the only member of a RefSCC as it has no references. // Validate these properties first. assert(C.size() == 1 && "Dead functions must be in a singular SCC"); assert(RC.size() == 1 && "Dead functions must be in a singular RefSCC"); auto RCIndexI = RefSCCIndices.find(&RC); int RCIndex = RCIndexI->second; PostOrderRefSCCs.erase(PostOrderRefSCCs.begin() + RCIndex); RefSCCIndices.erase(RCIndexI); for (int i = RCIndex, Size = PostOrderRefSCCs.size(); i < Size; ++i) RefSCCIndices[PostOrderRefSCCs[i]] = i; // Finally clear out all the data structures from the node down through the // components. N.clear(); N.G = nullptr; N.F = nullptr; C.clear(); RC.clear(); RC.G = nullptr; // Nothing to delete as all the objects are allocated in stable bump pointer // allocators. } LazyCallGraph::Node &LazyCallGraph::insertInto(Function &F, Node *&MappedN) { return *new (MappedN = BPA.Allocate()) Node(*this, F); } void LazyCallGraph::updateGraphPtrs() { // Walk the node map to update their graph pointers. While this iterates in // an unstable order, the order has no effect so it remains correct. for (auto &FunctionNodePair : NodeMap) FunctionNodePair.second->G = this; for (auto *RC : PostOrderRefSCCs) RC->G = this; } LazyCallGraph::Node &LazyCallGraph::initNode(Node &N, LazyCallGraph::SCC &C) { NodeMap[&N.getFunction()] = &N; N.DFSNumber = N.LowLink = -1; N.populate(); C.Nodes.push_back(&N); SCCMap[&N] = &C; return N; } template void LazyCallGraph::buildGenericSCCs(RootsT &&Roots, GetBeginT &&GetBegin, GetEndT &&GetEnd, GetNodeT &&GetNode, FormSCCCallbackT &&FormSCC) { using EdgeItT = decltype(GetBegin(std::declval())); SmallVector, 16> DFSStack; SmallVector PendingSCCStack; // Scan down the stack and DFS across the call edges. for (Node *RootN : Roots) { assert(DFSStack.empty() && "Cannot begin a new root with a non-empty DFS stack!"); assert(PendingSCCStack.empty() && "Cannot begin a new root with pending nodes for an SCC!"); // Skip any nodes we've already reached in the DFS. if (RootN->DFSNumber != 0) { assert(RootN->DFSNumber == -1 && "Shouldn't have any mid-DFS root nodes!"); continue; } RootN->DFSNumber = RootN->LowLink = 1; int NextDFSNumber = 2; DFSStack.push_back({RootN, GetBegin(*RootN)}); do { Node *N; EdgeItT I; std::tie(N, I) = DFSStack.pop_back_val(); auto E = GetEnd(*N); while (I != E) { Node &ChildN = GetNode(I); if (ChildN.DFSNumber == 0) { // We haven't yet visited this child, so descend, pushing the current // node onto the stack. DFSStack.push_back({N, I}); ChildN.DFSNumber = ChildN.LowLink = NextDFSNumber++; N = &ChildN; I = GetBegin(*N); E = GetEnd(*N); continue; } // If the child has already been added to some child component, it // couldn't impact the low-link of this parent because it isn't // connected, and thus its low-link isn't relevant so skip it. if (ChildN.DFSNumber == -1) { ++I; continue; } // Track the lowest linked child as the lowest link for this node. assert(ChildN.LowLink > 0 && "Must have a positive low-link number!"); if (ChildN.LowLink < N->LowLink) N->LowLink = ChildN.LowLink; // Move to the next edge. ++I; } // We've finished processing N and its descendants, put it on our pending // SCC stack to eventually get merged into an SCC of nodes. PendingSCCStack.push_back(N); // If this node is linked to some lower entry, continue walking up the // stack. if (N->LowLink != N->DFSNumber) continue; // Otherwise, we've completed an SCC. Append it to our post order list of // SCCs. int RootDFSNumber = N->DFSNumber; // Find the range of the node stack by walking down until we pass the // root DFS number. auto SCCNodes = make_range( PendingSCCStack.rbegin(), find_if(reverse(PendingSCCStack), [RootDFSNumber](const Node *N) { return N->DFSNumber < RootDFSNumber; })); // Form a new SCC out of these nodes and then clear them off our pending // stack. FormSCC(SCCNodes); PendingSCCStack.erase(SCCNodes.end().base(), PendingSCCStack.end()); } while (!DFSStack.empty()); } } /// Build the internal SCCs for a RefSCC from a sequence of nodes. /// /// Appends the SCCs to the provided vector and updates the map with their /// indices. Both the vector and map must be empty when passed into this /// routine. void LazyCallGraph::buildSCCs(RefSCC &RC, node_stack_range Nodes) { assert(RC.SCCs.empty() && "Already built SCCs!"); assert(RC.SCCIndices.empty() && "Already mapped SCC indices!"); for (Node *N : Nodes) { assert(N->LowLink >= (*Nodes.begin())->LowLink && "We cannot have a low link in an SCC lower than its root on the " "stack!"); // This node will go into the next RefSCC, clear out its DFS and low link // as we scan. N->DFSNumber = N->LowLink = 0; } // Each RefSCC contains a DAG of the call SCCs. To build these, we do // a direct walk of the call edges using Tarjan's algorithm. We reuse the // internal storage as we won't need it for the outer graph's DFS any longer. buildGenericSCCs( Nodes, [](Node &N) { return N->call_begin(); }, [](Node &N) { return N->call_end(); }, [](EdgeSequence::call_iterator I) -> Node & { return I->getNode(); }, [this, &RC](node_stack_range Nodes) { RC.SCCs.push_back(createSCC(RC, Nodes)); for (Node &N : *RC.SCCs.back()) { N.DFSNumber = N.LowLink = -1; SCCMap[&N] = RC.SCCs.back(); } }); // Wire up the SCC indices. for (int i = 0, Size = RC.SCCs.size(); i < Size; ++i) RC.SCCIndices[RC.SCCs[i]] = i; } void LazyCallGraph::buildRefSCCs() { if (EntryEdges.empty() || !PostOrderRefSCCs.empty()) // RefSCCs are either non-existent or already built! return; assert(RefSCCIndices.empty() && "Already mapped RefSCC indices!"); SmallVector Roots; for (Edge &E : *this) Roots.push_back(&E.getNode()); // The roots will be popped of a stack, so use reverse to get a less // surprising order. This doesn't change any of the semantics anywhere. std::reverse(Roots.begin(), Roots.end()); buildGenericSCCs( Roots, [](Node &N) { // We need to populate each node as we begin to walk its edges. N.populate(); return N->begin(); }, [](Node &N) { return N->end(); }, [](EdgeSequence::iterator I) -> Node & { return I->getNode(); }, [this](node_stack_range Nodes) { RefSCC *NewRC = createRefSCC(*this); buildSCCs(*NewRC, Nodes); // Push the new node into the postorder list and remember its position // in the index map. bool Inserted = RefSCCIndices.insert({NewRC, PostOrderRefSCCs.size()}).second; (void)Inserted; assert(Inserted && "Cannot already have this RefSCC in the index map!"); PostOrderRefSCCs.push_back(NewRC); #ifndef NDEBUG NewRC->verify(); #endif }); } AnalysisKey LazyCallGraphAnalysis::Key; LazyCallGraphPrinterPass::LazyCallGraphPrinterPass(raw_ostream &OS) : OS(OS) {} static void printNode(raw_ostream &OS, LazyCallGraph::Node &N) { OS << " Edges in function: " << N.getFunction().getName() << "\n"; for (LazyCallGraph::Edge &E : N.populate()) OS << " " << (E.isCall() ? "call" : "ref ") << " -> " << E.getFunction().getName() << "\n"; OS << "\n"; } static void printSCC(raw_ostream &OS, LazyCallGraph::SCC &C) { OS << " SCC with " << C.size() << " functions:\n"; for (LazyCallGraph::Node &N : C) OS << " " << N.getFunction().getName() << "\n"; } static void printRefSCC(raw_ostream &OS, LazyCallGraph::RefSCC &C) { OS << " RefSCC with " << C.size() << " call SCCs:\n"; for (LazyCallGraph::SCC &InnerC : C) printSCC(OS, InnerC); OS << "\n"; } PreservedAnalyses LazyCallGraphPrinterPass::run(Module &M, ModuleAnalysisManager &AM) { LazyCallGraph &G = AM.getResult(M); OS << "Printing the call graph for module: " << M.getModuleIdentifier() << "\n\n"; for (Function &F : M) printNode(OS, G.get(F)); G.buildRefSCCs(); for (LazyCallGraph::RefSCC &C : G.postorder_ref_sccs()) printRefSCC(OS, C); return PreservedAnalyses::all(); } LazyCallGraphDOTPrinterPass::LazyCallGraphDOTPrinterPass(raw_ostream &OS) : OS(OS) {} static void printNodeDOT(raw_ostream &OS, LazyCallGraph::Node &N) { std::string Name = "\"" + DOT::EscapeString(std::string(N.getFunction().getName())) + "\""; for (LazyCallGraph::Edge &E : N.populate()) { OS << " " << Name << " -> \"" << DOT::EscapeString(std::string(E.getFunction().getName())) << "\""; if (!E.isCall()) // It is a ref edge. OS << " [style=dashed,label=\"ref\"]"; OS << ";\n"; } OS << "\n"; } PreservedAnalyses LazyCallGraphDOTPrinterPass::run(Module &M, ModuleAnalysisManager &AM) { LazyCallGraph &G = AM.getResult(M); OS << "digraph \"" << DOT::EscapeString(M.getModuleIdentifier()) << "\" {\n"; for (Function &F : M) printNodeDOT(OS, G.get(F)); OS << "}\n"; return PreservedAnalyses::all(); }