//===- ProfileInfo.cpp - Profile Info Interface ---------------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file implements the abstract ProfileInfo interface, and the default // "no profile" implementation. // //===----------------------------------------------------------------------===// #include "llvm/Analysis/Passes.h" #include "llvm/Analysis/ProfileInfo.h" #include "llvm/Pass.h" #include "llvm/Support/CFG.h" #include "llvm/Support/Compiler.h" #include "llvm/Support/Debug.h" #include "llvm/Support/raw_ostream.h" #include "llvm/Support/Format.h" #include using namespace llvm; // Register the ProfileInfo interface, providing a nice name to refer to. static RegisterAnalysisGroup Z("Profile Information"); char ProfileInfo::ID = 0; ProfileInfo::~ProfileInfo() {} const double ProfileInfo::MissingValue = -1; double ProfileInfo::getExecutionCount(const BasicBlock *BB) { std::map::iterator J = BlockInformation.find(BB->getParent()); if (J != BlockInformation.end()) { BlockCounts::iterator I = J->second.find(BB); if (I != J->second.end()) return I->second; } pred_const_iterator PI = pred_begin(BB), PE = pred_end(BB); // Are there zero predecessors of this block? if (PI == PE) { // If this is the entry block, look for the Null -> Entry edge. if (BB == &BB->getParent()->getEntryBlock()) return getEdgeWeight(getEdge(0, BB)); else return 0; // Otherwise, this is a dead block. } // Otherwise, if there are predecessors, the execution count of this block is // the sum of the edge frequencies from the incoming edges. std::set ProcessedPreds; double Count = 0; for (; PI != PE; ++PI) if (ProcessedPreds.insert(*PI).second) { double w = getEdgeWeight(getEdge(*PI, BB)); if (w == MissingValue) { Count = MissingValue; break; } Count += w; } if (Count != MissingValue) BlockInformation[BB->getParent()][BB] = Count; return Count; } double ProfileInfo::getExecutionCount(const Function *F) { std::map::iterator J = FunctionInformation.find(F); if (J != FunctionInformation.end()) return J->second; // isDeclaration() is checked here and not at start of function to allow // functions without a body still to have a execution count. if (F->isDeclaration()) return MissingValue; double Count = getExecutionCount(&F->getEntryBlock()); if (Count != MissingValue) FunctionInformation[F] = Count; return Count; } /// Replaces all occurences of RmBB in the ProfilingInfo with DestBB. /// This checks all edges of the function the blocks reside in and replaces the /// occurences of RmBB with DestBB. void ProfileInfo::replaceAllUses(const BasicBlock *RmBB, const BasicBlock *DestBB) { DEBUG(errs() << "Replacing " << RmBB->getNameStr() << " with " << DestBB->getNameStr() << "\n"); const Function *F = DestBB->getParent(); std::map::iterator J = EdgeInformation.find(F); if (J == EdgeInformation.end()) return; for (EdgeWeights::iterator I = J->second.begin(), E = J->second.end(); I != E; ++I) { Edge e = I->first; Edge newedge; bool foundedge = false; if (e.first == RmBB) { newedge = getEdge(DestBB, e.second); foundedge = true; } if (e.second == RmBB) { newedge = getEdge(e.first, DestBB); foundedge = true; } if (foundedge) { double w = getEdgeWeight(e); EdgeInformation[F][newedge] = w; DEBUG(errs() << "Replacing " << e << " with " << newedge << "\n"); J->second.erase(e); } } } /// Splits an edge in the ProfileInfo and redirects flow over NewBB. /// Since its possible that there is more than one edge in the CFG from FristBB /// to SecondBB its necessary to redirect the flow proporionally. void ProfileInfo::splitEdge(const BasicBlock *FirstBB, const BasicBlock *SecondBB, const BasicBlock *NewBB, bool MergeIdenticalEdges) { const Function *F = FirstBB->getParent(); std::map::iterator J = EdgeInformation.find(F); if (J == EdgeInformation.end()) return; // Generate edges and read current weight. Edge e = getEdge(FirstBB, SecondBB); Edge n1 = getEdge(FirstBB, NewBB); Edge n2 = getEdge(NewBB, SecondBB); EdgeWeights &ECs = J->second; double w = ECs[e]; int succ_count = 0; if (!MergeIdenticalEdges) { // First count the edges from FristBB to SecondBB, if there is more than // one, only slice out a proporional part for NewBB. for(succ_const_iterator BBI = succ_begin(FirstBB), BBE = succ_end(FirstBB); BBI != BBE; ++BBI) { if (*BBI == SecondBB) succ_count++; } // When the NewBB is completely new, increment the count by one so that // the counts are properly distributed. if (getExecutionCount(NewBB) == ProfileInfo::MissingValue) succ_count++; } else { // When the edges are merged anyway, then redirect all flow. succ_count = 1; } // We know now how many edges there are from FirstBB to SecondBB, reroute a // proportional part of the edge weight over NewBB. double neww = w / succ_count; ECs[n1] += neww; ECs[n2] += neww; BlockInformation[F][NewBB] += neww; if (succ_count == 1) { ECs.erase(e); } else { ECs[e] -= neww; } } raw_ostream& llvm::operator<<(raw_ostream &O, ProfileInfo::Edge E) { O << "("; O << (E.first ? E.first->getNameStr() : "0"); O << ","; O << (E.second ? E.second->getNameStr() : "0"); return O << ")"; } //===----------------------------------------------------------------------===// // NoProfile ProfileInfo implementation // namespace { struct NoProfileInfo : public ImmutablePass, public ProfileInfo { static char ID; // Class identification, replacement for typeinfo NoProfileInfo() : ImmutablePass(&ID) {} }; } // End of anonymous namespace char NoProfileInfo::ID = 0; // Register this pass... static RegisterPass X("no-profile", "No Profile Information", false, true); // Declare that we implement the ProfileInfo interface static RegisterAnalysisGroup Y(X); ImmutablePass *llvm::createNoProfileInfoPass() { return new NoProfileInfo(); }