//===- PgmDependenceGraph.cpp - Enumerate PDG for a function ----*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file was developed by the LLVM research group and is distributed under // the University of Illinois Open Source License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // The Program Dependence Graph (PDG) for a single function represents all // data and control dependences for the function. This file provides an // iterator to enumerate all these dependences. In particular, it enumerates: // // -- Data dependences on memory locations, computed using the // MemoryDepAnalysis pass; // -- Data dependences on SSA registers, directly from Def-Use edges of Values; // -- Control dependences, computed using postdominance frontiers // (NOT YET IMPLEMENTED). // // Note that this file does not create an explicit dependence graph -- // it only provides an iterator to traverse the PDG conceptually. // The MemoryDepAnalysis does build an explicit graph, which is used internally // here. That graph could be augmented with the other dependences above if // desired, but for most uses there will be little need to do that. // //===----------------------------------------------------------------------===// #include "PgmDependenceGraph.h" #include "llvm/Analysis/PostDominators.h" #include "llvm/Function.h" #include namespace llvm { //---------------------------------------------------------------------------- // class DepIterState //---------------------------------------------------------------------------- const DepIterState::IterStateFlags DepIterState::NoFlag = 0x0; const DepIterState::IterStateFlags DepIterState::MemDone = 0x1; const DepIterState::IterStateFlags DepIterState::SSADone = 0x2; const DepIterState::IterStateFlags DepIterState::AllDone = 0x4; const DepIterState::IterStateFlags DepIterState::FirstTimeFlag= 0x8; // Find the first memory dependence for the current Mem In/Out iterators. // Find the first memory dependence for the current Mem In/Out iterators. // Sets dep to that dependence and returns true if one is found. // bool DepIterState::SetFirstMemoryDep() { if (! (depFlags & MemoryDeps)) return false; bool doIncomingDeps = dep.getDepType() & IncomingFlag; if (( doIncomingDeps && memDepIter == memDepGraph->inDepEnd( *depNode)) || (!doIncomingDeps && memDepIter == memDepGraph->outDepEnd(*depNode))) { iterFlags |= MemDone; return false; } dep = *memDepIter; // simple copy from dependence in memory DepGraph return true; } // Find the first valid data dependence for the current SSA In/Out iterators. // A valid data dependence is one that is to/from an Instruction. // E.g., an SSA edge from a formal parameter is not a valid dependence. // Sets dep to that dependence and returns true if a valid one is found. // Returns false and leaves dep unchanged otherwise. // bool DepIterState::SetFirstSSADep() { if (! (depFlags & SSADeps)) return false; bool doIncomingDeps = dep.getDepType() & IncomingFlag; Instruction* firstTarget = NULL; // Increment the In or Out iterator till it runs out or we find a valid dep if (doIncomingDeps) for (Instruction::op_iterator E = depNode->getInstr().op_end(); ssaInEdgeIter != E && (firstTarget = dyn_cast(ssaInEdgeIter))== NULL; ) ++ssaInEdgeIter; else for (Value::use_iterator E = depNode->getInstr().use_end(); ssaOutEdgeIter != E && (firstTarget = dyn_cast(*ssaOutEdgeIter)) == NULL; ) ++ssaOutEdgeIter; // If the iterator ran out before we found a valid dep, there isn't one. if (!firstTarget) { iterFlags |= SSADone; return false; } // Create a simple dependence object to represent this SSA dependence. dep = Dependence(memDepGraph->getNode(*firstTarget, /*create*/ true), TrueDependence, doIncomingDeps); return true; } DepIterState::DepIterState(DependenceGraph* _memDepGraph, Instruction& I, bool incomingDeps, PDGIteratorFlags whichDeps) : memDepGraph(_memDepGraph), depFlags(whichDeps), iterFlags(NoFlag) { depNode = memDepGraph->getNode(I, /*create*/ true); if (incomingDeps) { if (whichDeps & MemoryDeps) memDepIter= memDepGraph->inDepBegin(*depNode); if (whichDeps & SSADeps) ssaInEdgeIter = I.op_begin(); /* Initialize control dependence iterator here. */ } else { if (whichDeps & MemoryDeps) memDepIter=memDepGraph->outDepBegin(*depNode); if (whichDeps & SSADeps) ssaOutEdgeIter = I.use_begin(); /* Initialize control dependence iterator here. */ } // Set the dependence to the first of a memory dep or an SSA dep // and set the done flag if either is found. Otherwise, set the // init flag to indicate that the iterators have just been initialized. // if (!SetFirstMemoryDep() && !SetFirstSSADep()) iterFlags |= AllDone; else iterFlags |= FirstTimeFlag; } // Helper function for ++ operator that bumps iterator by 1 (to next // dependence) and resets the dep field to represent the new dependence. // void DepIterState::Next() { // firstMemDone and firstSsaDone are used to indicate when the memory or // SSA iterators just ran out, or when this is the very first increment. // In either case, the next iterator (if any) should not be incremented. // bool firstMemDone = iterFlags & FirstTimeFlag; bool firstSsaDone = iterFlags & FirstTimeFlag; bool doIncomingDeps = dep.getDepType() & IncomingFlag; if (depFlags & MemoryDeps && ! (iterFlags & MemDone)) { iterFlags &= ~FirstTimeFlag; // clear "firstTime" flag ++memDepIter; if (SetFirstMemoryDep()) return; firstMemDone = true; // flags that we _just_ rolled over } if (depFlags & SSADeps && ! (iterFlags & SSADone)) { // Don't increment the SSA iterator if we either just rolled over from // the memory dep iterator, or if the SSA iterator is already done. iterFlags &= ~FirstTimeFlag; // clear "firstTime" flag if (! firstMemDone) if (doIncomingDeps) ++ssaInEdgeIter; else ++ssaOutEdgeIter; if (SetFirstSSADep()) return; firstSsaDone = true; // flags if we just rolled over } if ((depFlags & ControlDeps) != 0) { assert(0 && "Cannot handle control deps"); // iterFlags &= ~FirstTimeFlag; // clear "firstTime" flag } // This iterator is now complete. iterFlags |= AllDone; } //---------------------------------------------------------------------------- // class PgmDependenceGraph //---------------------------------------------------------------------------- // MakeIterator -- Create and initialize an iterator as specified. // PDGIterator PgmDependenceGraph::MakeIterator(Instruction& I, bool incomingDeps, PDGIteratorFlags whichDeps) { assert(memDepGraph && "Function not initialized!"); return PDGIterator(new DepIterState(memDepGraph, I, incomingDeps, whichDeps)); } void PgmDependenceGraph::printOutgoingSSADeps(Instruction& I, std::ostream &O) { iterator SI = this->outDepBegin(I, SSADeps); iterator SE = this->outDepEnd(I, SSADeps); if (SI == SE) return; O << "\n Outgoing SSA dependences:\n"; for ( ; SI != SE; ++SI) { O << "\t"; SI->print(O); O << " to instruction:"; O << SI->getSink()->getInstr(); } } void PgmDependenceGraph::print(std::ostream &O, const Module*) const { MemoryDepAnalysis& graphSet = getAnalysis(); // TEMPORARY LOOP for (hash_map::iterator I = graphSet.funcMap.begin(), E = graphSet.funcMap.end(); I != E; ++I) { Function* func = I->first; DependenceGraph* depGraph = I->second; const_cast(this)->runOnFunction(*func); O << "DEPENDENCE GRAPH FOR FUNCTION " << func->getName() << ":\n"; for (Function::iterator BB=func->begin(), FE=func->end(); BB != FE; ++BB) for (BasicBlock::iterator II=BB->begin(), IE=BB->end(); II !=IE; ++II) { DepGraphNode* dgNode = depGraph->getNode(*II, /*create*/ true); dgNode->print(O); const_cast(this)->printOutgoingSSADeps(*II, O); } } // END TEMPORARY LOOP } void PgmDependenceGraph::dump() const { this->print(std::cerr); } static RegisterAnalysis Z("pgmdep", "Enumerate Program Dependence Graph (data and control)"); } // End llvm namespace