src/IceCfgNode.cpp - platform/external/swiftshader - Gitiles

 //===- subzero/src/IceCfgNode.cpp - Basic block (node) implementation -----===//
 //
 //                        The Subzero Code Generator
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file implements the CfgNode class, including the complexities
 // of instruction insertion and in-edge calculation.
 //
 //===----------------------------------------------------------------------===//

 #include "IceCfg.h"
 #include "IceCfgNode.h"
 #include "IceInst.h"
 #include "IceLiveness.h"
 #include "IceOperand.h"
 #include "IceTargetLowering.h"

 namespace Ice {

 CfgNode::CfgNode(Cfg *Func, SizeT LabelNumber, IceString Name)
     : Func(Func), Number(LabelNumber), Name(Name), HasReturn(false) {}

 // Returns the name the node was created with.  If no name was given,
 // it synthesizes a (hopefully) unique name.
 IceString CfgNode::getName() const {
   if (!Name.empty())
     return Name;
   char buf[30];
   snprintf(buf, llvm::array_lengthof(buf), "__%u", getIndex());
   return buf;
 }

 // Adds an instruction to either the Phi list or the regular
 // instruction list.  Validates that all Phis are added before all
 // regular instructions.
 void CfgNode::appendInst(Inst *Inst) {
   if (InstPhi *Phi = llvm::dyn_cast<InstPhi>(Inst)) {
     if (!Insts.empty()) {
       Func->setError("Phi instruction added to the middle of a block");
       return;
     }
     Phis.push_back(Phi);
   } else {
     Insts.push_back(Inst);
   }
   Inst->updateVars(this);
 }

 // Renumbers the non-deleted instructions in the node.  This needs to
 // be done in preparation for live range analysis.  The instruction
 // numbers in a block must be monotonically increasing.  The range of
 // instruction numbers in a block, from lowest to highest, must not
 // overlap with the range of any other block.
 void CfgNode::renumberInstructions() {
   for (PhiList::const_iterator I = Phis.begin(), E = Phis.end(); I != E; ++I) {
     (*I)->renumber(Func);
   }
   InstList::const_iterator I = Insts.begin(), E = Insts.end();
   while (I != E) {
     Inst *Inst = *I++;
     Inst->renumber(Func);
   }
 }

 // When a node is created, the OutEdges are immediately knows, but the
 // InEdges have to be built up incrementally.  After the CFG has been
 // constructed, the computePredecessors() pass finalizes it by
 // creating the InEdges list.
 void CfgNode::computePredecessors() {
   OutEdges = (*Insts.rbegin())->getTerminatorEdges();
   for (NodeList::const_iterator I = OutEdges.begin(), E = OutEdges.end();
        I != E; ++I) {
     CfgNode *Node = *I;
     Node->InEdges.push_back(this);
   }
 }

 // This does part 1 of Phi lowering, by creating a new dest variable
 // for each Phi instruction, replacing the Phi instruction's dest with
 // that variable, and adding an explicit assignment of the old dest to
 // the new dest.  For example,
 //   a=phi(...)
 // changes to
 //   "a_phi=phi(...); a=a_phi".
 //
 // This is in preparation for part 2 which deletes the Phi
 // instructions and appends assignment instructions to predecessor
 // blocks.  Note that this transformation preserves SSA form.
 void CfgNode::placePhiLoads() {
   for (PhiList::iterator I = Phis.begin(), E = Phis.end(); I != E; ++I) {
     Inst *Inst = (*I)->lower(Func, this);
     Insts.insert(Insts.begin(), Inst);
     Inst->updateVars(this);
   }
 }

 // This does part 2 of Phi lowering.  For each Phi instruction at each
 // out-edge, create a corresponding assignment instruction, and add
 // all the assignments near the end of this block.  They need to be
 // added before any branch instruction, and also if the block ends
 // with a compare instruction followed by a branch instruction that we
 // may want to fuse, it's better to insert the new assignments before
 // the compare instruction. The tryOptimizedCmpxchgCmpBr() method
 // assumes this ordering of instructions.
 //
 // Note that this transformation takes the Phi dest variables out of
 // SSA form, as there may be assignments to the dest variable in
 // multiple blocks.
 //
 // TODO: Defer this pass until after register allocation, then split
 // critical edges, add the assignments, and lower them.  This should
 // reduce the amount of shuffling at the end of each block.
 void CfgNode::placePhiStores() {
   // Find the insertion point.  TODO: After branch/compare fusing is
   // implemented, try not to insert Phi stores between the compare and
   // conditional branch instructions, otherwise the branch/compare
   // pattern matching may fail.  However, the branch/compare sequence
   // will have to be broken if the compare result is read (by the
   // assignment) before it is written (by the compare).
   InstList::iterator InsertionPoint = Insts.end();
   // Every block must end in a terminator instruction.
   assert(InsertionPoint != Insts.begin());
   --InsertionPoint;
   // Confirm that InsertionPoint is a terminator instruction.  Calling
   // getTerminatorEdges() on a non-terminator instruction will cause
   // an llvm_unreachable().
   (void)(*InsertionPoint)->getTerminatorEdges();
   // If the current insertion point is at a conditional branch
   // instruction, and the previous instruction is a compare
   // instruction, then we move the insertion point before the compare
   // instruction so as not to interfere with compare/branch fusing.
   if (InstBr *Branch = llvm::dyn_cast<InstBr>(*InsertionPoint)) {
     if (!Branch->isUnconditional()) {
       if (InsertionPoint != Insts.begin()) {
         --InsertionPoint;
         if (!llvm::isa<InstIcmp>(*InsertionPoint) &&
             !llvm::isa<InstFcmp>(*InsertionPoint)) {
           ++InsertionPoint;
         }
       }
     }
   }

   // Consider every out-edge.
   for (NodeList::const_iterator I1 = OutEdges.begin(), E1 = OutEdges.end();
        I1 != E1; ++I1) {
     CfgNode *Target = *I1;
     // Consider every Phi instruction at the out-edge.
     for (PhiList::const_iterator I2 = Target->Phis.begin(),
                                  E2 = Target->Phis.end();
          I2 != E2; ++I2) {
       Operand *Operand = (*I2)->getOperandForTarget(this);
       assert(Operand);
       Variable *Dest = (*I2)->getDest();
       assert(Dest);
       InstAssign *NewInst = InstAssign::create(Func, Dest, Operand);
       // If Src is a variable, set the Src and Dest variables to
       // prefer each other for register allocation.
       if (Variable *Src = llvm::dyn_cast<Variable>(Operand)) {
         bool AllowOverlap = false;
         Dest->setPreferredRegister(Src, AllowOverlap);
         Src->setPreferredRegister(Dest, AllowOverlap);
       }
       Insts.insert(InsertionPoint, NewInst);
       NewInst->updateVars(this);
     }
   }
 }

 // Deletes the phi instructions after the loads and stores are placed.
 void CfgNode::deletePhis() {
   for (PhiList::iterator I = Phis.begin(), E = Phis.end(); I != E; ++I) {
     (*I)->setDeleted();
   }
 }

 // Does address mode optimization.  Pass each instruction to the
 // TargetLowering object.  If it returns a new instruction
 // (representing the optimized address mode), then insert the new
 // instruction and delete the old.
 void CfgNode::doAddressOpt() {
   TargetLowering *Target = Func->getTarget();
   LoweringContext &Context = Target->getContext();
   Context.init(this);
   while (!Context.atEnd()) {
     Target->doAddressOpt();
   }
 }

 // Drives the target lowering.  Passes the current instruction and the
 // next non-deleted instruction for target lowering.
 void CfgNode::genCode() {
   TargetLowering *Target = Func->getTarget();
   LoweringContext &Context = Target->getContext();
   // Lower only the regular instructions.  Defer the Phi instructions.
   Context.init(this);
   while (!Context.atEnd()) {
     InstList::iterator Orig = Context.getCur();
     if (llvm::isa<InstRet>(*Orig))
       setHasReturn();
     Target->lower();
     // Ensure target lowering actually moved the cursor.
     assert(Context.getCur() != Orig);
   }
 }

 void CfgNode::livenessLightweight() {
   SizeT NumVars = Func->getNumVariables();
   llvm::BitVector Live(NumVars);
   // Process regular instructions in reverse order.
   for (InstList::const_reverse_iterator I = Insts.rbegin(), E = Insts.rend();
        I != E; ++I) {
     if ((*I)->isDeleted())
       continue;
     (*I)->livenessLightweight(Live);
   }
   for (PhiList::const_iterator I = Phis.begin(), E = Phis.end(); I != E; ++I) {
     if ((*I)->isDeleted())
       continue;
     (*I)->livenessLightweight(Live);
   }
 }

 // Performs liveness analysis on the block.  Returns true if the
 // incoming liveness changed from before, false if it stayed the same.
 // (If it changes, the node's predecessors need to be processed
 // again.)
 bool CfgNode::liveness(Liveness *Liveness) {
   SizeT NumVars = Liveness->getNumVarsInNode(this);
   llvm::BitVector Live(NumVars);
   // Mark the beginning and ending of each variable's live range
   // with the sentinel instruction number 0.
   std::vector<InstNumberT> &LiveBegin = Liveness->getLiveBegin(this);
   std::vector<InstNumberT> &LiveEnd = Liveness->getLiveEnd(this);
   InstNumberT Sentinel = Inst::NumberSentinel;
   LiveBegin.assign(NumVars, Sentinel);
   LiveEnd.assign(NumVars, Sentinel);
   // Initialize Live to be the union of all successors' LiveIn.
   for (NodeList::const_iterator I = OutEdges.begin(), E = OutEdges.end();
        I != E; ++I) {
     CfgNode *Succ = *I;
     Live |= Liveness->getLiveIn(Succ);
     // Mark corresponding argument of phis in successor as live.
     for (PhiList::const_iterator I1 = Succ->Phis.begin(), E1 = Succ->Phis.end();
          I1 != E1; ++I1) {
       (*I1)->livenessPhiOperand(Live, this, Liveness);
     }
   }
   Liveness->getLiveOut(this) = Live;

   // Process regular instructions in reverse order.
   for (InstList::const_reverse_iterator I = Insts.rbegin(), E = Insts.rend();
        I != E; ++I) {
     if ((*I)->isDeleted())
       continue;
     (*I)->liveness((*I)->getNumber(), Live, Liveness, this);
   }
   // Process phis in forward order so that we can override the
   // instruction number to be that of the earliest phi instruction in
   // the block.
   InstNumberT FirstPhiNumber = Inst::NumberSentinel;
   for (PhiList::const_iterator I = Phis.begin(), E = Phis.end(); I != E; ++I) {
     if ((*I)->isDeleted())
       continue;
     if (FirstPhiNumber == Inst::NumberSentinel)
       FirstPhiNumber = (*I)->getNumber();
     (*I)->liveness(FirstPhiNumber, Live, Liveness, this);
   }

   // When using the sparse representation, after traversing the
   // instructions in the block, the Live bitvector should only contain
   // set bits for global variables upon block entry.  We validate this
   // by shrinking the Live vector and then testing it against the
   // pre-shrunk version.  (The shrinking is required, but the
   // validation is not.)
   llvm::BitVector LiveOrig = Live;
   Live.resize(Liveness->getNumGlobalVars());
   // Non-global arguments in the entry node are allowed to be live on
   // entry.
   bool IsEntry = (Func->getEntryNode() == this);
   if (!(IsEntry || Live == LiveOrig)) {
     // This is a fatal liveness consistency error.  Print some
     // diagnostics and abort.
     Ostream &Str = Func->getContext()->getStrDump();
     Func->setCurrentNode(NULL);
     Str << "LiveOrig-Live =";
     for (SizeT i = Live.size(); i < LiveOrig.size(); ++i) {
       if (LiveOrig.test(i)) {
         Str << " ";
         Liveness->getVariable(i, this)->dump(Func);
       }
     }
     Str << "\n";
     llvm_unreachable("Fatal inconsistency in liveness analysis");
   }

   bool Changed = false;
   llvm::BitVector &LiveIn = Liveness->getLiveIn(this);
   // Add in current LiveIn
   Live |= LiveIn;
   // Check result, set LiveIn=Live
   Changed = (Live != LiveIn);
   if (Changed)
     LiveIn = Live;
   return Changed;
 }

 // Now that basic liveness is complete, remove dead instructions that
 // were tentatively marked as dead, and compute actual live ranges.
 // It is assumed that within a single basic block, a live range begins
 // at most once and ends at most once.  This is certainly true for
 // pure SSA form.  It is also true once phis are lowered, since each
 // assignment to the phi-based temporary is in a different basic
 // block, and there is a single read that ends the live in the basic
 // block that contained the actual phi instruction.
 void CfgNode::livenessPostprocess(LivenessMode Mode, Liveness *Liveness) {
   InstNumberT FirstInstNum = Inst::NumberSentinel;
   InstNumberT LastInstNum = Inst::NumberSentinel;
   // Process phis in any order.  Process only Dest operands.
   for (PhiList::const_iterator I = Phis.begin(), E = Phis.end(); I != E; ++I) {
     InstPhi *Inst = *I;
     Inst->deleteIfDead();
     if (Inst->isDeleted())
       continue;
     if (FirstInstNum == Inst::NumberSentinel)
       FirstInstNum = Inst->getNumber();
     assert(Inst->getNumber() > LastInstNum);
     LastInstNum = Inst->getNumber();
   }
   // Process instructions
   for (InstList::const_iterator I = Insts.begin(), E = Insts.end(); I != E;
        ++I) {
     Inst *Inst = *I;
     Inst->deleteIfDead();
     if (Inst->isDeleted())
       continue;
     if (FirstInstNum == Inst::NumberSentinel)
       FirstInstNum = Inst->getNumber();
     assert(Inst->getNumber() > LastInstNum);
     LastInstNum = Inst->getNumber();
     // Create fake live ranges for a Kill instruction, but only if the
     // linked instruction is still alive.
     if (Mode == Liveness_Intervals) {
       if (InstFakeKill *Kill = llvm::dyn_cast<InstFakeKill>(Inst)) {
         if (!Kill->getLinked()->isDeleted()) {
           SizeT NumSrcs = Inst->getSrcSize();
           for (SizeT i = 0; i < NumSrcs; ++i) {
             Variable *Var = llvm::cast<Variable>(Inst->getSrc(i));
             InstNumberT InstNumber = Inst->getNumber();
             Liveness->addLiveRange(Var, InstNumber, InstNumber, 1);
           }
         }
       }
     }
   }
   if (Mode != Liveness_Intervals)
     return;

   SizeT NumVars = Liveness->getNumVarsInNode(this);
   SizeT NumGlobals = Liveness->getNumGlobalVars();
   llvm::BitVector &LiveIn = Liveness->getLiveIn(this);
   llvm::BitVector &LiveOut = Liveness->getLiveOut(this);
   std::vector<InstNumberT> &LiveBegin = Liveness->getLiveBegin(this);
   std::vector<InstNumberT> &LiveEnd = Liveness->getLiveEnd(this);
   for (SizeT i = 0; i < NumVars; ++i) {
     // Deal with the case where the variable is both live-in and
     // live-out, but LiveEnd comes before LiveBegin.  In this case, we
     // need to add two segments to the live range because there is a
     // hole in the middle.  This would typically happen as a result of
     // phi lowering in the presence of loopback edges.
     bool IsGlobal = (i < NumGlobals);
     if (IsGlobal && LiveIn[i] && LiveOut[i] && LiveBegin[i] > LiveEnd[i]) {
       Variable *Var = Liveness->getVariable(i, this);
       Liveness->addLiveRange(Var, FirstInstNum, LiveEnd[i], 1);
       Liveness->addLiveRange(Var, LiveBegin[i], LastInstNum + 1, 1);
       continue;
     }
     InstNumberT Begin = (IsGlobal && LiveIn[i]) ? FirstInstNum : LiveBegin[i];
     InstNumberT End = (IsGlobal && LiveOut[i]) ? LastInstNum + 1 : LiveEnd[i];
     if (Begin == Inst::NumberSentinel && End == Inst::NumberSentinel)
       continue;
     if (Begin <= FirstInstNum)
       Begin = FirstInstNum;
     if (End == Inst::NumberSentinel)
       End = LastInstNum + 1;
     Variable *Var = Liveness->getVariable(i, this);
     Liveness->addLiveRange(Var, Begin, End, 1);
   }
 }

 // ======================== Dump routines ======================== //

 void CfgNode::emit(Cfg *Func) const {
   Func->setCurrentNode(this);
   Ostream &Str = Func->getContext()->getStrEmit();
   if (Func->getEntryNode() == this) {
     Str << Func->getContext()->mangleName(Func->getFunctionName()) << ":\n";
   }
   Str << getAsmName() << ":\n";
   for (PhiList::const_iterator I = Phis.begin(), E = Phis.end(); I != E; ++I) {
     InstPhi *Inst = *I;
     if (Inst->isDeleted())
       continue;
     // Emitting a Phi instruction should cause an error.
     Inst->emit(Func);
   }
   for (InstList::const_iterator I = Insts.begin(), E = Insts.end(); I != E;
        ++I) {
     Inst *Inst = *I;
     if (Inst->isDeleted())
       continue;
     // Here we detect redundant assignments like "mov eax, eax" and
     // suppress them.
     if (Inst->isRedundantAssign())
       continue;
     (*I)->emit(Func);
   }
 }

 void CfgNode::dump(Cfg *Func) const {
   Func->setCurrentNode(this);
   Ostream &Str = Func->getContext()->getStrDump();
   Liveness *Liveness = Func->getLiveness();
   if (Func->getContext()->isVerbose(IceV_Instructions)) {
     Str << getName() << ":\n";
   }
   // Dump list of predecessor nodes.
   if (Func->getContext()->isVerbose(IceV_Preds) && !InEdges.empty()) {
     Str << "    // preds = ";
     for (NodeList::const_iterator I = InEdges.begin(), E = InEdges.end();
          I != E; ++I) {
       if (I != InEdges.begin())
         Str << ", ";
       Str << "%" << (*I)->getName();
     }
     Str << "\n";
   }
   // Dump the live-in variables.
   llvm::BitVector LiveIn;
   if (Liveness)
     LiveIn = Liveness->getLiveIn(this);
   if (Func->getContext()->isVerbose(IceV_Liveness) && !LiveIn.empty()) {
     Str << "    // LiveIn:";
     for (SizeT i = 0; i < LiveIn.size(); ++i) {
       if (LiveIn[i]) {
         Str << " %" << Liveness->getVariable(i, this)->getName();
       }
     }
     Str << "\n";
   }
   // Dump each instruction.
   if (Func->getContext()->isVerbose(IceV_Instructions)) {
     for (PhiList::const_iterator I = Phis.begin(), E = Phis.end(); I != E;
          ++I) {
       const Inst *Inst = *I;
       Inst->dumpDecorated(Func);
     }
     InstList::const_iterator I = Insts.begin(), E = Insts.end();
     while (I != E) {
       Inst *Inst = *I++;
       Inst->dumpDecorated(Func);
     }
   }
   // Dump the live-out variables.
   llvm::BitVector LiveOut;
   if (Liveness)
     LiveOut = Liveness->getLiveOut(this);
   if (Func->getContext()->isVerbose(IceV_Liveness) && !LiveOut.empty()) {
     Str << "    // LiveOut:";
     for (SizeT i = 0; i < LiveOut.size(); ++i) {
       if (LiveOut[i]) {
         Str << " %" << Liveness->getVariable(i, this)->getName();
       }
     }
     Str << "\n";
   }
   // Dump list of successor nodes.
   if (Func->getContext()->isVerbose(IceV_Succs)) {
     Str << "    // succs = ";
     for (NodeList::const_iterator I = OutEdges.begin(), E = OutEdges.end();
          I != E; ++I) {
       if (I != OutEdges.begin())
         Str << ", ";
       Str << "%" << (*I)->getName();
     }
     Str << "\n";
   }
 }

 } // end of namespace Ice
	//===- subzero/src/IceCfgNode.cpp - Basic block (node) implementation -----===//
	//
	// The Subzero Code Generator
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file implements the CfgNode class, including the complexities
	// of instruction insertion and in-edge calculation.
	//
	//===----------------------------------------------------------------------===//

	#include "IceCfg.h"
	#include "IceCfgNode.h"
	#include "IceInst.h"
	#include "IceLiveness.h"
	#include "IceOperand.h"
	#include "IceTargetLowering.h"

	namespace Ice {

	CfgNode::CfgNode(Cfg *Func, SizeT LabelNumber, IceString Name)
	: Func(Func), Number(LabelNumber), Name(Name), HasReturn(false) {}

	// Returns the name the node was created with. If no name was given,
	// it synthesizes a (hopefully) unique name.
	IceString CfgNode::getName() const {
	if (!Name.empty())
	return Name;
	char buf[30];
	snprintf(buf, llvm::array_lengthof(buf), "__%u", getIndex());
	return buf;
	}

	// Adds an instruction to either the Phi list or the regular
	// instruction list. Validates that all Phis are added before all
	// regular instructions.
	void CfgNode::appendInst(Inst *Inst) {
	if (InstPhi *Phi = llvm::dyn_cast<InstPhi>(Inst)) {
	if (!Insts.empty()) {
	Func->setError("Phi instruction added to the middle of a block");
	return;
	}
	Phis.push_back(Phi);
	} else {
	Insts.push_back(Inst);
	}
	Inst->updateVars(this);
	}

	// Renumbers the non-deleted instructions in the node. This needs to
	// be done in preparation for live range analysis. The instruction
	// numbers in a block must be monotonically increasing. The range of
	// instruction numbers in a block, from lowest to highest, must not
	// overlap with the range of any other block.
	void CfgNode::renumberInstructions() {
	for (PhiList::const_iterator I = Phis.begin(), E = Phis.end(); I != E; ++I) {
	(*I)->renumber(Func);
	}
	InstList::const_iterator I = Insts.begin(), E = Insts.end();
	while (I != E) {
	Inst Inst = I++;
	Inst->renumber(Func);
	}
	}

	// When a node is created, the OutEdges are immediately knows, but the
	// InEdges have to be built up incrementally. After the CFG has been
	// constructed, the computePredecessors() pass finalizes it by
	// creating the InEdges list.
	void CfgNode::computePredecessors() {
	OutEdges = (*Insts.rbegin())->getTerminatorEdges();
	for (NodeList::const_iterator I = OutEdges.begin(), E = OutEdges.end();
	I != E; ++I) {
	CfgNode Node = I;
	Node->InEdges.push_back(this);
	}
	}

	// This does part 1 of Phi lowering, by creating a new dest variable
	// for each Phi instruction, replacing the Phi instruction's dest with
	// that variable, and adding an explicit assignment of the old dest to
	// the new dest. For example,
	// a=phi(...)
	// changes to
	// "a_phi=phi(...); a=a_phi".
	//
	// This is in preparation for part 2 which deletes the Phi
	// instructions and appends assignment instructions to predecessor
	// blocks. Note that this transformation preserves SSA form.
	void CfgNode::placePhiLoads() {
	for (PhiList::iterator I = Phis.begin(), E = Phis.end(); I != E; ++I) {
	Inst Inst = (I)->lower(Func, this);
	Insts.insert(Insts.begin(), Inst);
	Inst->updateVars(this);
	}
	}

	// This does part 2 of Phi lowering. For each Phi instruction at each
	// out-edge, create a corresponding assignment instruction, and add
	// all the assignments near the end of this block. They need to be
	// added before any branch instruction, and also if the block ends
	// with a compare instruction followed by a branch instruction that we
	// may want to fuse, it's better to insert the new assignments before
	// the compare instruction. The tryOptimizedCmpxchgCmpBr() method
	// assumes this ordering of instructions.
	//
	// Note that this transformation takes the Phi dest variables out of
	// SSA form, as there may be assignments to the dest variable in
	// multiple blocks.
	//
	// TODO: Defer this pass until after register allocation, then split
	// critical edges, add the assignments, and lower them. This should
	// reduce the amount of shuffling at the end of each block.
	void CfgNode::placePhiStores() {
	// Find the insertion point. TODO: After branch/compare fusing is
	// implemented, try not to insert Phi stores between the compare and
	// conditional branch instructions, otherwise the branch/compare
	// pattern matching may fail. However, the branch/compare sequence
	// will have to be broken if the compare result is read (by the
	// assignment) before it is written (by the compare).
	InstList::iterator InsertionPoint = Insts.end();
	// Every block must end in a terminator instruction.
	assert(InsertionPoint != Insts.begin());
	--InsertionPoint;
	// Confirm that InsertionPoint is a terminator instruction. Calling
	// getTerminatorEdges() on a non-terminator instruction will cause
	// an llvm_unreachable().
	(void)(*InsertionPoint)->getTerminatorEdges();
	// If the current insertion point is at a conditional branch
	// instruction, and the previous instruction is a compare
	// instruction, then we move the insertion point before the compare
	// instruction so as not to interfere with compare/branch fusing.
	if (InstBr Branch = llvm::dyn_cast<InstBr>(InsertionPoint)) {
	if (!Branch->isUnconditional()) {
	if (InsertionPoint != Insts.begin()) {
	--InsertionPoint;
	if (!llvm::isa<InstIcmp>(*InsertionPoint) &&
	!llvm::isa<InstFcmp>(*InsertionPoint)) {
	++InsertionPoint;
	}
	}
	}
	}

	// Consider every out-edge.
	for (NodeList::const_iterator I1 = OutEdges.begin(), E1 = OutEdges.end();
	I1 != E1; ++I1) {
	CfgNode Target = I1;
	// Consider every Phi instruction at the out-edge.
	for (PhiList::const_iterator I2 = Target->Phis.begin(),
	E2 = Target->Phis.end();
	I2 != E2; ++I2) {
	Operand Operand = (I2)->getOperandForTarget(this);
	assert(Operand);
	Variable Dest = (I2)->getDest();
	assert(Dest);
	InstAssign *NewInst = InstAssign::create(Func, Dest, Operand);
	// If Src is a variable, set the Src and Dest variables to
	// prefer each other for register allocation.
	if (Variable *Src = llvm::dyn_cast<Variable>(Operand)) {
	bool AllowOverlap = false;
	Dest->setPreferredRegister(Src, AllowOverlap);
	Src->setPreferredRegister(Dest, AllowOverlap);
	}
	Insts.insert(InsertionPoint, NewInst);
	NewInst->updateVars(this);
	}
	}
	}

	// Deletes the phi instructions after the loads and stores are placed.
	void CfgNode::deletePhis() {
	for (PhiList::iterator I = Phis.begin(), E = Phis.end(); I != E; ++I) {
	(*I)->setDeleted();
	}
	}

	// Does address mode optimization. Pass each instruction to the
	// TargetLowering object. If it returns a new instruction
	// (representing the optimized address mode), then insert the new
	// instruction and delete the old.
	void CfgNode::doAddressOpt() {
	TargetLowering *Target = Func->getTarget();
	LoweringContext &Context = Target->getContext();
	Context.init(this);
	while (!Context.atEnd()) {
	Target->doAddressOpt();
	}
	}

	// Drives the target lowering. Passes the current instruction and the
	// next non-deleted instruction for target lowering.
	void CfgNode::genCode() {
	TargetLowering *Target = Func->getTarget();
	LoweringContext &Context = Target->getContext();
	// Lower only the regular instructions. Defer the Phi instructions.
	Context.init(this);
	while (!Context.atEnd()) {
	InstList::iterator Orig = Context.getCur();
	if (llvm::isa<InstRet>(*Orig))
	setHasReturn();
	Target->lower();
	// Ensure target lowering actually moved the cursor.
	assert(Context.getCur() != Orig);
	}
	}

	void CfgNode::livenessLightweight() {
	SizeT NumVars = Func->getNumVariables();
	llvm::BitVector Live(NumVars);
	// Process regular instructions in reverse order.
	for (InstList::const_reverse_iterator I = Insts.rbegin(), E = Insts.rend();
	I != E; ++I) {
	if ((*I)->isDeleted())
	continue;
	(*I)->livenessLightweight(Live);
	}
	for (PhiList::const_iterator I = Phis.begin(), E = Phis.end(); I != E; ++I) {
	if ((*I)->isDeleted())
	continue;
	(*I)->livenessLightweight(Live);
	}
	}

	// Performs liveness analysis on the block. Returns true if the
	// incoming liveness changed from before, false if it stayed the same.
	// (If it changes, the node's predecessors need to be processed
	// again.)
	bool CfgNode::liveness(Liveness *Liveness) {
	SizeT NumVars = Liveness->getNumVarsInNode(this);
	llvm::BitVector Live(NumVars);
	// Mark the beginning and ending of each variable's live range
	// with the sentinel instruction number 0.
	std::vector<InstNumberT> &LiveBegin = Liveness->getLiveBegin(this);
	std::vector<InstNumberT> &LiveEnd = Liveness->getLiveEnd(this);
	InstNumberT Sentinel = Inst::NumberSentinel;
	LiveBegin.assign(NumVars, Sentinel);
	LiveEnd.assign(NumVars, Sentinel);
	// Initialize Live to be the union of all successors' LiveIn.
	for (NodeList::const_iterator I = OutEdges.begin(), E = OutEdges.end();
	I != E; ++I) {
	CfgNode Succ = I;
	Live \|= Liveness->getLiveIn(Succ);
	// Mark corresponding argument of phis in successor as live.
	for (PhiList::const_iterator I1 = Succ->Phis.begin(), E1 = Succ->Phis.end();
	I1 != E1; ++I1) {
	(*I1)->livenessPhiOperand(Live, this, Liveness);
	}
	}
	Liveness->getLiveOut(this) = Live;

	// Process regular instructions in reverse order.
	for (InstList::const_reverse_iterator I = Insts.rbegin(), E = Insts.rend();
	I != E; ++I) {
	if ((*I)->isDeleted())
	continue;
	(I)->liveness((I)->getNumber(), Live, Liveness, this);
	}
	// Process phis in forward order so that we can override the
	// instruction number to be that of the earliest phi instruction in
	// the block.
	InstNumberT FirstPhiNumber = Inst::NumberSentinel;
	for (PhiList::const_iterator I = Phis.begin(), E = Phis.end(); I != E; ++I) {
	if ((*I)->isDeleted())
	continue;
	if (FirstPhiNumber == Inst::NumberSentinel)
	FirstPhiNumber = (*I)->getNumber();
	(*I)->liveness(FirstPhiNumber, Live, Liveness, this);
	}

	// When using the sparse representation, after traversing the
	// instructions in the block, the Live bitvector should only contain
	// set bits for global variables upon block entry. We validate this
	// by shrinking the Live vector and then testing it against the
	// pre-shrunk version. (The shrinking is required, but the
	// validation is not.)
	llvm::BitVector LiveOrig = Live;
	Live.resize(Liveness->getNumGlobalVars());
	// Non-global arguments in the entry node are allowed to be live on
	// entry.
	bool IsEntry = (Func->getEntryNode() == this);
	if (!(IsEntry \|\| Live == LiveOrig)) {
	// This is a fatal liveness consistency error. Print some
	// diagnostics and abort.
	Ostream &Str = Func->getContext()->getStrDump();
	Func->setCurrentNode(NULL);
	Str << "LiveOrig-Live =";
	for (SizeT i = Live.size(); i < LiveOrig.size(); ++i) {
	if (LiveOrig.test(i)) {
	Str << " ";
	Liveness->getVariable(i, this)->dump(Func);
	}
	}
	Str << "\n";
	llvm_unreachable("Fatal inconsistency in liveness analysis");
	}

	bool Changed = false;
	llvm::BitVector &LiveIn = Liveness->getLiveIn(this);
	// Add in current LiveIn
	Live \|= LiveIn;
	// Check result, set LiveIn=Live
	Changed = (Live != LiveIn);
	if (Changed)
	LiveIn = Live;
	return Changed;
	}

	// Now that basic liveness is complete, remove dead instructions that
	// were tentatively marked as dead, and compute actual live ranges.
	// It is assumed that within a single basic block, a live range begins
	// at most once and ends at most once. This is certainly true for
	// pure SSA form. It is also true once phis are lowered, since each
	// assignment to the phi-based temporary is in a different basic
	// block, and there is a single read that ends the live in the basic
	// block that contained the actual phi instruction.
	void CfgNode::livenessPostprocess(LivenessMode Mode, Liveness *Liveness) {
	InstNumberT FirstInstNum = Inst::NumberSentinel;
	InstNumberT LastInstNum = Inst::NumberSentinel;
	// Process phis in any order. Process only Dest operands.
	for (PhiList::const_iterator I = Phis.begin(), E = Phis.end(); I != E; ++I) {
	InstPhi Inst = I;
	Inst->deleteIfDead();
	if (Inst->isDeleted())
	continue;
	if (FirstInstNum == Inst::NumberSentinel)
	FirstInstNum = Inst->getNumber();
	assert(Inst->getNumber() > LastInstNum);
	LastInstNum = Inst->getNumber();
	}
	// Process instructions
	for (InstList::const_iterator I = Insts.begin(), E = Insts.end(); I != E;
	++I) {
	Inst Inst = I;
	Inst->deleteIfDead();
	if (Inst->isDeleted())
	continue;
	if (FirstInstNum == Inst::NumberSentinel)
	FirstInstNum = Inst->getNumber();
	assert(Inst->getNumber() > LastInstNum);
	LastInstNum = Inst->getNumber();
	// Create fake live ranges for a Kill instruction, but only if the
	// linked instruction is still alive.
	if (Mode == Liveness_Intervals) {
	if (InstFakeKill *Kill = llvm::dyn_cast<InstFakeKill>(Inst)) {
	if (!Kill->getLinked()->isDeleted()) {
	SizeT NumSrcs = Inst->getSrcSize();
	for (SizeT i = 0; i < NumSrcs; ++i) {
	Variable *Var = llvm::cast<Variable>(Inst->getSrc(i));
	InstNumberT InstNumber = Inst->getNumber();
	Liveness->addLiveRange(Var, InstNumber, InstNumber, 1);
	}
	}
	}
	}
	}
	if (Mode != Liveness_Intervals)
	return;

	SizeT NumVars = Liveness->getNumVarsInNode(this);
	SizeT NumGlobals = Liveness->getNumGlobalVars();
	llvm::BitVector &LiveIn = Liveness->getLiveIn(this);
	llvm::BitVector &LiveOut = Liveness->getLiveOut(this);
	std::vector<InstNumberT> &LiveBegin = Liveness->getLiveBegin(this);
	std::vector<InstNumberT> &LiveEnd = Liveness->getLiveEnd(this);
	for (SizeT i = 0; i < NumVars; ++i) {
	// Deal with the case where the variable is both live-in and
	// live-out, but LiveEnd comes before LiveBegin. In this case, we
	// need to add two segments to the live range because there is a
	// hole in the middle. This would typically happen as a result of
	// phi lowering in the presence of loopback edges.
	bool IsGlobal = (i < NumGlobals);
	if (IsGlobal && LiveIn[i] && LiveOut[i] && LiveBegin[i] > LiveEnd[i]) {
	Variable *Var = Liveness->getVariable(i, this);
	Liveness->addLiveRange(Var, FirstInstNum, LiveEnd[i], 1);
	Liveness->addLiveRange(Var, LiveBegin[i], LastInstNum + 1, 1);
	continue;
	}
	InstNumberT Begin = (IsGlobal && LiveIn[i]) ? FirstInstNum : LiveBegin[i];
	InstNumberT End = (IsGlobal && LiveOut[i]) ? LastInstNum + 1 : LiveEnd[i];
	if (Begin == Inst::NumberSentinel && End == Inst::NumberSentinel)
	continue;
	if (Begin <= FirstInstNum)
	Begin = FirstInstNum;
	if (End == Inst::NumberSentinel)
	End = LastInstNum + 1;
	Variable *Var = Liveness->getVariable(i, this);
	Liveness->addLiveRange(Var, Begin, End, 1);
	}
	}

	// ======================== Dump routines ======================== //

	void CfgNode::emit(Cfg *Func) const {
	Func->setCurrentNode(this);
	Ostream &Str = Func->getContext()->getStrEmit();
	if (Func->getEntryNode() == this) {
	Str << Func->getContext()->mangleName(Func->getFunctionName()) << ":\n";
	}
	Str << getAsmName() << ":\n";
	for (PhiList::const_iterator I = Phis.begin(), E = Phis.end(); I != E; ++I) {
	InstPhi Inst = I;
	if (Inst->isDeleted())
	continue;
	// Emitting a Phi instruction should cause an error.
	Inst->emit(Func);
	}
	for (InstList::const_iterator I = Insts.begin(), E = Insts.end(); I != E;
	++I) {
	Inst Inst = I;
	if (Inst->isDeleted())
	continue;
	// Here we detect redundant assignments like "mov eax, eax" and
	// suppress them.
	if (Inst->isRedundantAssign())
	continue;
	(*I)->emit(Func);
	}
	}

	void CfgNode::dump(Cfg *Func) const {
	Func->setCurrentNode(this);
	Ostream &Str = Func->getContext()->getStrDump();
	Liveness *Liveness = Func->getLiveness();
	if (Func->getContext()->isVerbose(IceV_Instructions)) {
	Str << getName() << ":\n";
	}
	// Dump list of predecessor nodes.
	if (Func->getContext()->isVerbose(IceV_Preds) && !InEdges.empty()) {
	Str << " // preds = ";
	for (NodeList::const_iterator I = InEdges.begin(), E = InEdges.end();
	I != E; ++I) {
	if (I != InEdges.begin())
	Str << ", ";
	Str << "%" << (*I)->getName();
	}
	Str << "\n";
	}
	// Dump the live-in variables.
	llvm::BitVector LiveIn;
	if (Liveness)
	LiveIn = Liveness->getLiveIn(this);
	if (Func->getContext()->isVerbose(IceV_Liveness) && !LiveIn.empty()) {
	Str << " // LiveIn:";
	for (SizeT i = 0; i < LiveIn.size(); ++i) {
	if (LiveIn[i]) {
	Str << " %" << Liveness->getVariable(i, this)->getName();
	}
	}
	Str << "\n";
	}
	// Dump each instruction.
	if (Func->getContext()->isVerbose(IceV_Instructions)) {
	for (PhiList::const_iterator I = Phis.begin(), E = Phis.end(); I != E;
	++I) {
	const Inst Inst = I;
	Inst->dumpDecorated(Func);
	}
	InstList::const_iterator I = Insts.begin(), E = Insts.end();
	while (I != E) {
	Inst Inst = I++;
	Inst->dumpDecorated(Func);
	}
	}
	// Dump the live-out variables.
	llvm::BitVector LiveOut;
	if (Liveness)
	LiveOut = Liveness->getLiveOut(this);
	if (Func->getContext()->isVerbose(IceV_Liveness) && !LiveOut.empty()) {
	Str << " // LiveOut:";
	for (SizeT i = 0; i < LiveOut.size(); ++i) {
	if (LiveOut[i]) {
	Str << " %" << Liveness->getVariable(i, this)->getName();
	}
	}
	Str << "\n";
	}
	// Dump list of successor nodes.
	if (Func->getContext()->isVerbose(IceV_Succs)) {
	Str << " // succs = ";
	for (NodeList::const_iterator I = OutEdges.begin(), E = OutEdges.end();
	I != E; ++I) {
	if (I != OutEdges.begin())
	Str << ", ";
	Str << "%" << (*I)->getName();
	}
	Str << "\n";
	}
	}

	} // end of namespace Ice