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//===---- BlockFrequencyImpl.h - Machine Block Frequency Implementation ---===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // Shared implementation of BlockFrequency for IR and Machine Instructions. // //===----------------------------------------------------------------------===// #ifndef LLVM_ANALYSIS_BLOCKFREQUENCYIMPL_H #define LLVM_ANALYSIS_BLOCKFREQUENCYIMPL_H #include "llvm/BasicBlock.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/PostOrderIterator.h" #include "llvm/CodeGen/MachineBasicBlock.h" #include "llvm/CodeGen/MachineFunction.h" #include "llvm/Support/BlockFrequency.h" #include "llvm/Support/BranchProbability.h" #include "llvm/Support/Debug.h" #include "llvm/Support/raw_ostream.h" #include <vector> #include <string> namespace llvm { class BlockFrequencyInfo; class MachineBlockFrequencyInfo; /// BlockFrequencyImpl implements block frequency algorithm for IR and /// Machine Instructions. Algorithm starts with value 1024 (START_FREQ) /// for the entry block and then propagates frequencies using branch weights /// from (Machine)BranchProbabilityInfo. LoopInfo is not required because /// algorithm can find "backedges" by itself. template<class BlockT, class FunctionT, class BlockProbInfoT> class BlockFrequencyImpl { DenseMap<const BlockT *, BlockFrequency> Freqs; BlockProbInfoT *BPI; FunctionT *Fn; typedef GraphTraits< Inverse<BlockT *> > GT; const uint32_t EntryFreq; std::string getBlockName(BasicBlock *BB) const { return BB->getName().str(); } std::string getBlockName(MachineBasicBlock *MBB) const { std::string str; raw_string_ostream ss(str); ss << "BB#" << MBB->getNumber(); if (const BasicBlock *BB = MBB->getBasicBlock()) ss << " derived from LLVM BB " << BB->getName(); return ss.str(); } void setBlockFreq(BlockT *BB, BlockFrequency Freq) { Freqs[BB] = Freq; DEBUG(dbgs() << "Frequency(" << getBlockName(BB) << ") = " << Freq << "\n"); } /// getEdgeFreq - Return edge frequency based on SRC frequency and Src -> Dst /// edge probability. BlockFrequency getEdgeFreq(BlockT *Src, BlockT *Dst) const { BranchProbability Prob = BPI->getEdgeProbability(Src, Dst); return getBlockFreq(Src) * Prob; } /// incBlockFreq - Increase BB block frequency by FREQ. /// void incBlockFreq(BlockT *BB, BlockFrequency Freq) { Freqs[BB] += Freq; DEBUG(dbgs() << "Frequency(" << getBlockName(BB) << ") += " << Freq << " --> " << Freqs[BB] << "\n"); } /// divBlockFreq - Divide BB block frequency by PROB. If Prob = 0 do nothing. /// void divBlockFreq(BlockT *BB, BranchProbability Prob) { uint64_t N = Prob.getNumerator(); assert(N && "Illegal division by zero!"); uint64_t D = Prob.getDenominator(); uint64_t Freq = (Freqs[BB].getFrequency() * D) / N; // Should we assert it? if (Freq > UINT32_MAX) Freq = UINT32_MAX; Freqs[BB] = BlockFrequency(Freq); DEBUG(dbgs() << "Frequency(" << getBlockName(BB) << ") /= (" << Prob << ") --> " << Freqs[BB] << "\n"); } // All blocks in postorder. std::vector<BlockT *> POT; // Map Block -> Position in reverse-postorder list. DenseMap<BlockT *, unsigned> RPO; // Cycle Probability for each bloch. DenseMap<BlockT *, uint32_t> CycleProb; // (reverse-)postorder traversal iterators. typedef typename std::vector<BlockT *>::iterator pot_iterator; typedef typename std::vector<BlockT *>::reverse_iterator rpot_iterator; pot_iterator pot_begin() { return POT.begin(); } pot_iterator pot_end() { return POT.end(); } rpot_iterator rpot_begin() { return POT.rbegin(); } rpot_iterator rpot_end() { return POT.rend(); } rpot_iterator rpot_at(BlockT *BB) { rpot_iterator I = rpot_begin(); unsigned idx = RPO[BB]; assert(idx); std::advance(I, idx - 1); assert(*I == BB); return I; } /// isReachable - Returns if BB block is reachable from the entry. /// bool isReachable(BlockT *BB) { return RPO.count(BB); } /// isBackedge - Return if edge Src -> Dst is a backedge. /// bool isBackedge(BlockT *Src, BlockT *Dst) { assert(isReachable(Src)); assert(isReachable(Dst)); unsigned a = RPO[Src]; unsigned b = RPO[Dst]; return a >= b; } /// getSingleBlockPred - return single BB block predecessor or NULL if /// BB has none or more predecessors. BlockT *getSingleBlockPred(BlockT *BB) { typename GT::ChildIteratorType PI = GraphTraits< Inverse<BlockT *> >::child_begin(BB), PE = GraphTraits< Inverse<BlockT *> >::child_end(BB); if (PI == PE) return 0; BlockT *Pred = *PI; ++PI; if (PI != PE) return 0; return Pred; } void doBlock(BlockT *BB, BlockT *LoopHead, SmallPtrSet<BlockT *, 8> &BlocksInLoop) { DEBUG(dbgs() << "doBlock(" << getBlockName(BB) << ")\n"); setBlockFreq(BB, 0); if (BB == LoopHead) { setBlockFreq(BB, EntryFreq); return; } if(BlockT *Pred = getSingleBlockPred(BB)) { if (BlocksInLoop.count(Pred)) setBlockFreq(BB, getEdgeFreq(Pred, BB)); // TODO: else? irreducible, ignore it for now. return; } bool isInLoop = false; bool isLoopHead = false; for (typename GT::ChildIteratorType PI = GraphTraits< Inverse<BlockT *> >::child_begin(BB), PE = GraphTraits< Inverse<BlockT *> >::child_end(BB); PI != PE; ++PI) { BlockT *Pred = *PI; if (isReachable(Pred) && isBackedge(Pred, BB)) { isLoopHead = true; } else if (BlocksInLoop.count(Pred)) { incBlockFreq(BB, getEdgeFreq(Pred, BB)); isInLoop = true; } // TODO: else? irreducible. } if (!isInLoop) return; if (!isLoopHead) return; assert(EntryFreq >= CycleProb[BB]); uint32_t CProb = CycleProb[BB]; uint32_t Numerator = EntryFreq - CProb ? EntryFreq - CProb : 1; divBlockFreq(BB, BranchProbability(Numerator, EntryFreq)); } /// doLoop - Propagate block frequency down throught the loop. void doLoop(BlockT *Head, BlockT *Tail) { DEBUG(dbgs() << "doLoop(" << getBlockName(Head) << ", " << getBlockName(Tail) << ")\n"); SmallPtrSet<BlockT *, 8> BlocksInLoop; for (rpot_iterator I = rpot_at(Head), E = rpot_at(Tail); ; ++I) { BlockT *BB = *I; doBlock(BB, Head, BlocksInLoop); BlocksInLoop.insert(BB); if (I == E) break; } // Compute loop's cyclic probability using backedges probabilities. for (typename GT::ChildIteratorType PI = GraphTraits< Inverse<BlockT *> >::child_begin(Head), PE = GraphTraits< Inverse<BlockT *> >::child_end(Head); PI != PE; ++PI) { BlockT *Pred = *PI; assert(Pred); if (isReachable(Pred) && isBackedge(Pred, Head)) { uint64_t N = getEdgeFreq(Pred, Head).getFrequency(); uint64_t D = getBlockFreq(Head).getFrequency(); assert(N <= EntryFreq && "Backedge frequency must be <= EntryFreq!"); uint64_t Res = (N * EntryFreq) / D; assert(Res <= UINT32_MAX); CycleProb[Head] += (uint32_t) Res; DEBUG(dbgs() << " CycleProb[" << getBlockName(Head) << "] += " << Res << " --> " << CycleProb[Head] << "\n"); } } } friend class BlockFrequencyInfo; friend class MachineBlockFrequencyInfo; BlockFrequencyImpl() : EntryFreq(BlockFrequency::getEntryFrequency()) { } void doFunction(FunctionT *fn, BlockProbInfoT *bpi) { Fn = fn; BPI = bpi; // Clear everything. RPO.clear(); POT.clear(); CycleProb.clear(); Freqs.clear(); BlockT *EntryBlock = fn->begin(); copy(po_begin(EntryBlock), po_end(EntryBlock), back_inserter(POT)); unsigned RPOidx = 0; for (rpot_iterator I = rpot_begin(), E = rpot_end(); I != E; ++I) { BlockT *BB = *I; RPO[BB] = ++RPOidx; DEBUG(dbgs() << "RPO[" << getBlockName(BB) << "] = " << RPO[BB] << "\n"); } // Travel over all blocks in postorder. for (pot_iterator I = pot_begin(), E = pot_end(); I != E; ++I) { BlockT *BB = *I; BlockT *LastTail = 0; DEBUG(dbgs() << "POT: " << getBlockName(BB) << "\n"); for (typename GT::ChildIteratorType PI = GraphTraits< Inverse<BlockT *> >::child_begin(BB), PE = GraphTraits< Inverse<BlockT *> >::child_end(BB); PI != PE; ++PI) { BlockT *Pred = *PI; if (isReachable(Pred) && isBackedge(Pred, BB) && (!LastTail || RPO[Pred] > RPO[LastTail])) LastTail = Pred; } if (LastTail) doLoop(BB, LastTail); } // At the end assume the whole function as a loop, and travel over it once // again. doLoop(*(rpot_begin()), *(pot_begin())); } public: /// getBlockFreq - Return block frequency. Return 0 if we don't have it. BlockFrequency getBlockFreq(const BlockT *BB) const { typename DenseMap<const BlockT *, BlockFrequency>::const_iterator I = Freqs.find(BB); if (I != Freqs.end()) return I->second; return 0; } void print(raw_ostream &OS) const { OS << "\n\n---- Block Freqs ----\n"; for (typename FunctionT::iterator I = Fn->begin(), E = Fn->end(); I != E;) { BlockT *BB = I++; OS << " " << getBlockName(BB) << " = " << getBlockFreq(BB) << "\n"; for (typename GraphTraits<BlockT *>::ChildIteratorType SI = GraphTraits<BlockT *>::child_begin(BB), SE = GraphTraits<BlockT *>::child_end(BB); SI != SE; ++SI) { BlockT *Succ = *SI; OS << " " << getBlockName(BB) << " -> " << getBlockName(Succ) << " = " << getEdgeFreq(BB, Succ) << "\n"; } } } void dump() const { print(dbgs()); } }; } #endif