//===-- SelectionDAGBuild.cpp - Selection-DAG building --------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This implements routines for translating from LLVM IR into SelectionDAG IR. // //===----------------------------------------------------------------------===// #define DEBUG_TYPE "isel" #include "SelectionDAGBuild.h" #include "llvm/ADT/BitVector.h" #include "llvm/ADT/SmallSet.h" #include "llvm/Analysis/AliasAnalysis.h" #include "llvm/Constants.h" #include "llvm/CallingConv.h" #include "llvm/DerivedTypes.h" #include "llvm/Function.h" #include "llvm/GlobalVariable.h" #include "llvm/InlineAsm.h" #include "llvm/Instructions.h" #include "llvm/Intrinsics.h" #include "llvm/IntrinsicInst.h" #include "llvm/ParameterAttributes.h" #include "llvm/CodeGen/FastISel.h" #include "llvm/CodeGen/GCStrategy.h" #include "llvm/CodeGen/GCMetadata.h" #include "llvm/CodeGen/MachineFunction.h" #include "llvm/CodeGen/MachineFrameInfo.h" #include "llvm/CodeGen/MachineInstrBuilder.h" #include "llvm/CodeGen/MachineJumpTableInfo.h" #include "llvm/CodeGen/MachineModuleInfo.h" #include "llvm/CodeGen/MachineRegisterInfo.h" #include "llvm/CodeGen/SelectionDAG.h" #include "llvm/Target/TargetRegisterInfo.h" #include "llvm/Target/TargetData.h" #include "llvm/Target/TargetFrameInfo.h" #include "llvm/Target/TargetInstrInfo.h" #include "llvm/Target/TargetLowering.h" #include "llvm/Target/TargetMachine.h" #include "llvm/Target/TargetOptions.h" #include "llvm/Support/Compiler.h" #include "llvm/Support/Debug.h" #include "llvm/Support/MathExtras.h" #include using namespace llvm; /// LimitFloatPrecision - Generate low-precision inline sequences for /// some float libcalls (6, 8 or 12 bits). static unsigned LimitFloatPrecision; static cl::opt LimitFPPrecision("limit-float-precision", cl::desc("Generate low-precision inline sequences " "for some float libcalls"), cl::location(LimitFloatPrecision), cl::init(0)); /// ComputeLinearIndex - Given an LLVM IR aggregate type and a sequence /// insertvalue or extractvalue indices that identify a member, return /// the linearized index of the start of the member. /// static unsigned ComputeLinearIndex(const TargetLowering &TLI, const Type *Ty, const unsigned *Indices, const unsigned *IndicesEnd, unsigned CurIndex = 0) { // Base case: We're done. if (Indices && Indices == IndicesEnd) return CurIndex; // Given a struct type, recursively traverse the elements. if (const StructType *STy = dyn_cast(Ty)) { for (StructType::element_iterator EB = STy->element_begin(), EI = EB, EE = STy->element_end(); EI != EE; ++EI) { if (Indices && *Indices == unsigned(EI - EB)) return ComputeLinearIndex(TLI, *EI, Indices+1, IndicesEnd, CurIndex); CurIndex = ComputeLinearIndex(TLI, *EI, 0, 0, CurIndex); } } // Given an array type, recursively traverse the elements. else if (const ArrayType *ATy = dyn_cast(Ty)) { const Type *EltTy = ATy->getElementType(); for (unsigned i = 0, e = ATy->getNumElements(); i != e; ++i) { if (Indices && *Indices == i) return ComputeLinearIndex(TLI, EltTy, Indices+1, IndicesEnd, CurIndex); CurIndex = ComputeLinearIndex(TLI, EltTy, 0, 0, CurIndex); } } // We haven't found the type we're looking for, so keep searching. return CurIndex + 1; } /// ComputeValueVTs - Given an LLVM IR type, compute a sequence of /// MVTs that represent all the individual underlying /// non-aggregate types that comprise it. /// /// If Offsets is non-null, it points to a vector to be filled in /// with the in-memory offsets of each of the individual values. /// static void ComputeValueVTs(const TargetLowering &TLI, const Type *Ty, SmallVectorImpl &ValueVTs, SmallVectorImpl *Offsets = 0, uint64_t StartingOffset = 0) { // Given a struct type, recursively traverse the elements. if (const StructType *STy = dyn_cast(Ty)) { const StructLayout *SL = TLI.getTargetData()->getStructLayout(STy); for (StructType::element_iterator EB = STy->element_begin(), EI = EB, EE = STy->element_end(); EI != EE; ++EI) ComputeValueVTs(TLI, *EI, ValueVTs, Offsets, StartingOffset + SL->getElementOffset(EI - EB)); return; } // Given an array type, recursively traverse the elements. if (const ArrayType *ATy = dyn_cast(Ty)) { const Type *EltTy = ATy->getElementType(); uint64_t EltSize = TLI.getTargetData()->getABITypeSize(EltTy); for (unsigned i = 0, e = ATy->getNumElements(); i != e; ++i) ComputeValueVTs(TLI, EltTy, ValueVTs, Offsets, StartingOffset + i * EltSize); return; } // Base case: we can get an MVT for this LLVM IR type. ValueVTs.push_back(TLI.getValueType(Ty)); if (Offsets) Offsets->push_back(StartingOffset); } namespace llvm { /// RegsForValue - This struct represents the registers (physical or virtual) /// that a particular set of values is assigned, and the type information about /// the value. The most common situation is to represent one value at a time, /// but struct or array values are handled element-wise as multiple values. /// The splitting of aggregates is performed recursively, so that we never /// have aggregate-typed registers. The values at this point do not necessarily /// have legal types, so each value may require one or more registers of some /// legal type. /// struct VISIBILITY_HIDDEN RegsForValue { /// TLI - The TargetLowering object. /// const TargetLowering *TLI; /// ValueVTs - The value types of the values, which may not be legal, and /// may need be promoted or synthesized from one or more registers. /// SmallVector ValueVTs; /// RegVTs - The value types of the registers. This is the same size as /// ValueVTs and it records, for each value, what the type of the assigned /// register or registers are. (Individual values are never synthesized /// from more than one type of register.) /// /// With virtual registers, the contents of RegVTs is redundant with TLI's /// getRegisterType member function, however when with physical registers /// it is necessary to have a separate record of the types. /// SmallVector RegVTs; /// Regs - This list holds the registers assigned to the values. /// Each legal or promoted value requires one register, and each /// expanded value requires multiple registers. /// SmallVector Regs; RegsForValue() : TLI(0) {} RegsForValue(const TargetLowering &tli, const SmallVector ®s, MVT regvt, MVT valuevt) : TLI(&tli), ValueVTs(1, valuevt), RegVTs(1, regvt), Regs(regs) {} RegsForValue(const TargetLowering &tli, const SmallVector ®s, const SmallVector ®vts, const SmallVector &valuevts) : TLI(&tli), ValueVTs(valuevts), RegVTs(regvts), Regs(regs) {} RegsForValue(const TargetLowering &tli, unsigned Reg, const Type *Ty) : TLI(&tli) { ComputeValueVTs(tli, Ty, ValueVTs); for (unsigned Value = 0, e = ValueVTs.size(); Value != e; ++Value) { MVT ValueVT = ValueVTs[Value]; unsigned NumRegs = TLI->getNumRegisters(ValueVT); MVT RegisterVT = TLI->getRegisterType(ValueVT); for (unsigned i = 0; i != NumRegs; ++i) Regs.push_back(Reg + i); RegVTs.push_back(RegisterVT); Reg += NumRegs; } } /// append - Add the specified values to this one. void append(const RegsForValue &RHS) { TLI = RHS.TLI; ValueVTs.append(RHS.ValueVTs.begin(), RHS.ValueVTs.end()); RegVTs.append(RHS.RegVTs.begin(), RHS.RegVTs.end()); Regs.append(RHS.Regs.begin(), RHS.Regs.end()); } /// getCopyFromRegs - Emit a series of CopyFromReg nodes that copies from /// this value and returns the result as a ValueVTs value. This uses /// Chain/Flag as the input and updates them for the output Chain/Flag. /// If the Flag pointer is NULL, no flag is used. SDValue getCopyFromRegs(SelectionDAG &DAG, SDValue &Chain, SDValue *Flag) const; /// getCopyToRegs - Emit a series of CopyToReg nodes that copies the /// specified value into the registers specified by this object. This uses /// Chain/Flag as the input and updates them for the output Chain/Flag. /// If the Flag pointer is NULL, no flag is used. void getCopyToRegs(SDValue Val, SelectionDAG &DAG, SDValue &Chain, SDValue *Flag) const; /// AddInlineAsmOperands - Add this value to the specified inlineasm node /// operand list. This adds the code marker and includes the number of /// values added into it. void AddInlineAsmOperands(unsigned Code, SelectionDAG &DAG, std::vector &Ops) const; }; } /// isUsedOutsideOfDefiningBlock - Return true if this instruction is used by /// PHI nodes or outside of the basic block that defines it, or used by a /// switch or atomic instruction, which may expand to multiple basic blocks. static bool isUsedOutsideOfDefiningBlock(Instruction *I) { if (isa(I)) return true; BasicBlock *BB = I->getParent(); for (Value::use_iterator UI = I->use_begin(), E = I->use_end(); UI != E; ++UI) if (cast(*UI)->getParent() != BB || isa(*UI) || // FIXME: Remove switchinst special case. isa(*UI)) return true; return false; } /// isOnlyUsedInEntryBlock - If the specified argument is only used in the /// entry block, return true. This includes arguments used by switches, since /// the switch may expand into multiple basic blocks. static bool isOnlyUsedInEntryBlock(Argument *A, bool EnableFastISel) { // With FastISel active, we may be splitting blocks, so force creation // of virtual registers for all non-dead arguments. if (EnableFastISel) return A->use_empty(); BasicBlock *Entry = A->getParent()->begin(); for (Value::use_iterator UI = A->use_begin(), E = A->use_end(); UI != E; ++UI) if (cast(*UI)->getParent() != Entry || isa(*UI)) return false; // Use not in entry block. return true; } FunctionLoweringInfo::FunctionLoweringInfo(TargetLowering &tli) : TLI(tli) { } void FunctionLoweringInfo::set(Function &fn, MachineFunction &mf, bool EnableFastISel) { Fn = &fn; MF = &mf; RegInfo = &MF->getRegInfo(); // Create a vreg for each argument register that is not dead and is used // outside of the entry block for the function. for (Function::arg_iterator AI = Fn->arg_begin(), E = Fn->arg_end(); AI != E; ++AI) if (!isOnlyUsedInEntryBlock(AI, EnableFastISel)) InitializeRegForValue(AI); // Initialize the mapping of values to registers. This is only set up for // instruction values that are used outside of the block that defines // them. Function::iterator BB = Fn->begin(), EB = Fn->end(); for (BasicBlock::iterator I = BB->begin(), E = BB->end(); I != E; ++I) if (AllocaInst *AI = dyn_cast(I)) if (ConstantInt *CUI = dyn_cast(AI->getArraySize())) { const Type *Ty = AI->getAllocatedType(); uint64_t TySize = TLI.getTargetData()->getABITypeSize(Ty); unsigned Align = std::max((unsigned)TLI.getTargetData()->getPrefTypeAlignment(Ty), AI->getAlignment()); TySize *= CUI->getZExtValue(); // Get total allocated size. if (TySize == 0) TySize = 1; // Don't create zero-sized stack objects. StaticAllocaMap[AI] = MF->getFrameInfo()->CreateStackObject(TySize, Align); } for (; BB != EB; ++BB) for (BasicBlock::iterator I = BB->begin(), E = BB->end(); I != E; ++I) if (!I->use_empty() && isUsedOutsideOfDefiningBlock(I)) if (!isa(I) || !StaticAllocaMap.count(cast(I))) InitializeRegForValue(I); // Create an initial MachineBasicBlock for each LLVM BasicBlock in F. This // also creates the initial PHI MachineInstrs, though none of the input // operands are populated. for (BB = Fn->begin(), EB = Fn->end(); BB != EB; ++BB) { MachineBasicBlock *MBB = mf.CreateMachineBasicBlock(BB); MBBMap[BB] = MBB; MF->push_back(MBB); // Create Machine PHI nodes for LLVM PHI nodes, lowering them as // appropriate. PHINode *PN; for (BasicBlock::iterator I = BB->begin();(PN = dyn_cast(I)); ++I){ if (PN->use_empty()) continue; unsigned PHIReg = ValueMap[PN]; assert(PHIReg && "PHI node does not have an assigned virtual register!"); SmallVector ValueVTs; ComputeValueVTs(TLI, PN->getType(), ValueVTs); for (unsigned vti = 0, vte = ValueVTs.size(); vti != vte; ++vti) { MVT VT = ValueVTs[vti]; unsigned NumRegisters = TLI.getNumRegisters(VT); const TargetInstrInfo *TII = MF->getTarget().getInstrInfo(); for (unsigned i = 0; i != NumRegisters; ++i) BuildMI(MBB, TII->get(TargetInstrInfo::PHI), PHIReg+i); PHIReg += NumRegisters; } } } } unsigned FunctionLoweringInfo::MakeReg(MVT VT) { return RegInfo->createVirtualRegister(TLI.getRegClassFor(VT)); } /// CreateRegForValue - Allocate the appropriate number of virtual registers of /// the correctly promoted or expanded types. Assign these registers /// consecutive vreg numbers and return the first assigned number. /// /// In the case that the given value has struct or array type, this function /// will assign registers for each member or element. /// unsigned FunctionLoweringInfo::CreateRegForValue(const Value *V) { SmallVector ValueVTs; ComputeValueVTs(TLI, V->getType(), ValueVTs); unsigned FirstReg = 0; for (unsigned Value = 0, e = ValueVTs.size(); Value != e; ++Value) { MVT ValueVT = ValueVTs[Value]; MVT RegisterVT = TLI.getRegisterType(ValueVT); unsigned NumRegs = TLI.getNumRegisters(ValueVT); for (unsigned i = 0; i != NumRegs; ++i) { unsigned R = MakeReg(RegisterVT); if (!FirstReg) FirstReg = R; } } return FirstReg; } /// getCopyFromParts - Create a value that contains the specified legal parts /// combined into the value they represent. If the parts combine to a type /// larger then ValueVT then AssertOp can be used to specify whether the extra /// bits are known to be zero (ISD::AssertZext) or sign extended from ValueVT /// (ISD::AssertSext). static SDValue getCopyFromParts(SelectionDAG &DAG, const SDValue *Parts, unsigned NumParts, MVT PartVT, MVT ValueVT, ISD::NodeType AssertOp = ISD::DELETED_NODE) { assert(NumParts > 0 && "No parts to assemble!"); TargetLowering &TLI = DAG.getTargetLoweringInfo(); SDValue Val = Parts[0]; if (NumParts > 1) { // Assemble the value from multiple parts. if (!ValueVT.isVector()) { unsigned PartBits = PartVT.getSizeInBits(); unsigned ValueBits = ValueVT.getSizeInBits(); // Assemble the power of 2 part. unsigned RoundParts = NumParts & (NumParts - 1) ? 1 << Log2_32(NumParts) : NumParts; unsigned RoundBits = PartBits * RoundParts; MVT RoundVT = RoundBits == ValueBits ? ValueVT : MVT::getIntegerVT(RoundBits); SDValue Lo, Hi; if (RoundParts > 2) { MVT HalfVT = MVT::getIntegerVT(RoundBits/2); Lo = getCopyFromParts(DAG, Parts, RoundParts/2, PartVT, HalfVT); Hi = getCopyFromParts(DAG, Parts+RoundParts/2, RoundParts/2, PartVT, HalfVT); } else { Lo = Parts[0]; Hi = Parts[1]; } if (TLI.isBigEndian()) std::swap(Lo, Hi); Val = DAG.getNode(ISD::BUILD_PAIR, RoundVT, Lo, Hi); if (RoundParts < NumParts) { // Assemble the trailing non-power-of-2 part. unsigned OddParts = NumParts - RoundParts; MVT OddVT = MVT::getIntegerVT(OddParts * PartBits); Hi = getCopyFromParts(DAG, Parts+RoundParts, OddParts, PartVT, OddVT); // Combine the round and odd parts. Lo = Val; if (TLI.isBigEndian()) std::swap(Lo, Hi); MVT TotalVT = MVT::getIntegerVT(NumParts * PartBits); Hi = DAG.getNode(ISD::ANY_EXTEND, TotalVT, Hi); Hi = DAG.getNode(ISD::SHL, TotalVT, Hi, DAG.getConstant(Lo.getValueType().getSizeInBits(), TLI.getShiftAmountTy())); Lo = DAG.getNode(ISD::ZERO_EXTEND, TotalVT, Lo); Val = DAG.getNode(ISD::OR, TotalVT, Lo, Hi); } } else { // Handle a multi-element vector. MVT IntermediateVT, RegisterVT; unsigned NumIntermediates; unsigned NumRegs = TLI.getVectorTypeBreakdown(ValueVT, IntermediateVT, NumIntermediates, RegisterVT); assert(NumRegs == NumParts && "Part count doesn't match vector breakdown!"); NumParts = NumRegs; // Silence a compiler warning. assert(RegisterVT == PartVT && "Part type doesn't match vector breakdown!"); assert(RegisterVT == Parts[0].getValueType() && "Part type doesn't match part!"); // Assemble the parts into intermediate operands. SmallVector Ops(NumIntermediates); if (NumIntermediates == NumParts) { // If the register was not expanded, truncate or copy the value, // as appropriate. for (unsigned i = 0; i != NumParts; ++i) Ops[i] = getCopyFromParts(DAG, &Parts[i], 1, PartVT, IntermediateVT); } else if (NumParts > 0) { // If the intermediate type was expanded, build the intermediate operands // from the parts. assert(NumParts % NumIntermediates == 0 && "Must expand into a divisible number of parts!"); unsigned Factor = NumParts / NumIntermediates; for (unsigned i = 0; i != NumIntermediates; ++i) Ops[i] = getCopyFromParts(DAG, &Parts[i * Factor], Factor, PartVT, IntermediateVT); } // Build a vector with BUILD_VECTOR or CONCAT_VECTORS from the intermediate // operands. Val = DAG.getNode(IntermediateVT.isVector() ? ISD::CONCAT_VECTORS : ISD::BUILD_VECTOR, ValueVT, &Ops[0], NumIntermediates); } } // There is now one part, held in Val. Correct it to match ValueVT. PartVT = Val.getValueType(); if (PartVT == ValueVT) return Val; if (PartVT.isVector()) { assert(ValueVT.isVector() && "Unknown vector conversion!"); return DAG.getNode(ISD::BIT_CONVERT, ValueVT, Val); } if (ValueVT.isVector()) { assert(ValueVT.getVectorElementType() == PartVT && ValueVT.getVectorNumElements() == 1 && "Only trivial scalar-to-vector conversions should get here!"); return DAG.getNode(ISD::BUILD_VECTOR, ValueVT, Val); } if (PartVT.isInteger() && ValueVT.isInteger()) { if (ValueVT.bitsLT(PartVT)) { // For a truncate, see if we have any information to // indicate whether the truncated bits will always be // zero or sign-extension. if (AssertOp != ISD::DELETED_NODE) Val = DAG.getNode(AssertOp, PartVT, Val, DAG.getValueType(ValueVT)); return DAG.getNode(ISD::TRUNCATE, ValueVT, Val); } else { return DAG.getNode(ISD::ANY_EXTEND, ValueVT, Val); } } if (PartVT.isFloatingPoint() && ValueVT.isFloatingPoint()) { if (ValueVT.bitsLT(Val.getValueType())) // FP_ROUND's are always exact here. return DAG.getNode(ISD::FP_ROUND, ValueVT, Val, DAG.getIntPtrConstant(1)); return DAG.getNode(ISD::FP_EXTEND, ValueVT, Val); } if (PartVT.getSizeInBits() == ValueVT.getSizeInBits()) return DAG.getNode(ISD::BIT_CONVERT, ValueVT, Val); assert(0 && "Unknown mismatch!"); return SDValue(); } /// getCopyToParts - Create a series of nodes that contain the specified value /// split into legal parts. If the parts contain more bits than Val, then, for /// integers, ExtendKind can be used to specify how to generate the extra bits. static void getCopyToParts(SelectionDAG &DAG, SDValue Val, SDValue *Parts, unsigned NumParts, MVT PartVT, ISD::NodeType ExtendKind = ISD::ANY_EXTEND) { TargetLowering &TLI = DAG.getTargetLoweringInfo(); MVT PtrVT = TLI.getPointerTy(); MVT ValueVT = Val.getValueType(); unsigned PartBits = PartVT.getSizeInBits(); assert(TLI.isTypeLegal(PartVT) && "Copying to an illegal type!"); if (!NumParts) return; if (!ValueVT.isVector()) { if (PartVT == ValueVT) { assert(NumParts == 1 && "No-op copy with multiple parts!"); Parts[0] = Val; return; } if (NumParts * PartBits > ValueVT.getSizeInBits()) { // If the parts cover more bits than the value has, promote the value. if (PartVT.isFloatingPoint() && ValueVT.isFloatingPoint()) { assert(NumParts == 1 && "Do not know what to promote to!"); Val = DAG.getNode(ISD::FP_EXTEND, PartVT, Val); } else if (PartVT.isInteger() && ValueVT.isInteger()) { ValueVT = MVT::getIntegerVT(NumParts * PartBits); Val = DAG.getNode(ExtendKind, ValueVT, Val); } else { assert(0 && "Unknown mismatch!"); } } else if (PartBits == ValueVT.getSizeInBits()) { // Different types of the same size. assert(NumParts == 1 && PartVT != ValueVT); Val = DAG.getNode(ISD::BIT_CONVERT, PartVT, Val); } else if (NumParts * PartBits < ValueVT.getSizeInBits()) { // If the parts cover less bits than value has, truncate the value. if (PartVT.isInteger() && ValueVT.isInteger()) { ValueVT = MVT::getIntegerVT(NumParts * PartBits); Val = DAG.getNode(ISD::TRUNCATE, ValueVT, Val); } else { assert(0 && "Unknown mismatch!"); } } // The value may have changed - recompute ValueVT. ValueVT = Val.getValueType(); assert(NumParts * PartBits == ValueVT.getSizeInBits() && "Failed to tile the value with PartVT!"); if (NumParts == 1) { assert(PartVT == ValueVT && "Type conversion failed!"); Parts[0] = Val; return; } // Expand the value into multiple parts. if (NumParts & (NumParts - 1)) { // The number of parts is not a power of 2. Split off and copy the tail. assert(PartVT.isInteger() && ValueVT.isInteger() && "Do not know what to expand to!"); unsigned RoundParts = 1 << Log2_32(NumParts); unsigned RoundBits = RoundParts * PartBits; unsigned OddParts = NumParts - RoundParts; SDValue OddVal = DAG.getNode(ISD::SRL, ValueVT, Val, DAG.getConstant(RoundBits, TLI.getShiftAmountTy())); getCopyToParts(DAG, OddVal, Parts + RoundParts, OddParts, PartVT); if (TLI.isBigEndian()) // The odd parts were reversed by getCopyToParts - unreverse them. std::reverse(Parts + RoundParts, Parts + NumParts); NumParts = RoundParts; ValueVT = MVT::getIntegerVT(NumParts * PartBits); Val = DAG.getNode(ISD::TRUNCATE, ValueVT, Val); } // The number of parts is a power of 2. Repeatedly bisect the value using // EXTRACT_ELEMENT. Parts[0] = DAG.getNode(ISD::BIT_CONVERT, MVT::getIntegerVT(ValueVT.getSizeInBits()), Val); for (unsigned StepSize = NumParts; StepSize > 1; StepSize /= 2) { for (unsigned i = 0; i < NumParts; i += StepSize) { unsigned ThisBits = StepSize * PartBits / 2; MVT ThisVT = MVT::getIntegerVT (ThisBits); SDValue &Part0 = Parts[i]; SDValue &Part1 = Parts[i+StepSize/2]; Part1 = DAG.getNode(ISD::EXTRACT_ELEMENT, ThisVT, Part0, DAG.getConstant(1, PtrVT)); Part0 = DAG.getNode(ISD::EXTRACT_ELEMENT, ThisVT, Part0, DAG.getConstant(0, PtrVT)); if (ThisBits == PartBits && ThisVT != PartVT) { Part0 = DAG.getNode(ISD::BIT_CONVERT, PartVT, Part0); Part1 = DAG.getNode(ISD::BIT_CONVERT, PartVT, Part1); } } } if (TLI.isBigEndian()) std::reverse(Parts, Parts + NumParts); return; } // Vector ValueVT. if (NumParts == 1) { if (PartVT != ValueVT) { if (PartVT.isVector()) { Val = DAG.getNode(ISD::BIT_CONVERT, PartVT, Val); } else { assert(ValueVT.getVectorElementType() == PartVT && ValueVT.getVectorNumElements() == 1 && "Only trivial vector-to-scalar conversions should get here!"); Val = DAG.getNode(ISD::EXTRACT_VECTOR_ELT, PartVT, Val, DAG.getConstant(0, PtrVT)); } } Parts[0] = Val; return; } // Handle a multi-element vector. MVT IntermediateVT, RegisterVT; unsigned NumIntermediates; unsigned NumRegs = DAG.getTargetLoweringInfo() .getVectorTypeBreakdown(ValueVT, IntermediateVT, NumIntermediates, RegisterVT); unsigned NumElements = ValueVT.getVectorNumElements(); assert(NumRegs == NumParts && "Part count doesn't match vector breakdown!"); NumParts = NumRegs; // Silence a compiler warning. assert(RegisterVT == PartVT && "Part type doesn't match vector breakdown!"); // Split the vector into intermediate operands. SmallVector Ops(NumIntermediates); for (unsigned i = 0; i != NumIntermediates; ++i) if (IntermediateVT.isVector()) Ops[i] = DAG.getNode(ISD::EXTRACT_SUBVECTOR, IntermediateVT, Val, DAG.getConstant(i * (NumElements / NumIntermediates), PtrVT)); else Ops[i] = DAG.getNode(ISD::EXTRACT_VECTOR_ELT, IntermediateVT, Val, DAG.getConstant(i, PtrVT)); // Split the intermediate operands into legal parts. if (NumParts == NumIntermediates) { // If the register was not expanded, promote or copy the value, // as appropriate. for (unsigned i = 0; i != NumParts; ++i) getCopyToParts(DAG, Ops[i], &Parts[i], 1, PartVT); } else if (NumParts > 0) { // If the intermediate type was expanded, split each the value into // legal parts. assert(NumParts % NumIntermediates == 0 && "Must expand into a divisible number of parts!"); unsigned Factor = NumParts / NumIntermediates; for (unsigned i = 0; i != NumIntermediates; ++i) getCopyToParts(DAG, Ops[i], &Parts[i * Factor], Factor, PartVT); } } void SelectionDAGLowering::init(GCFunctionInfo *gfi, AliasAnalysis &aa) { AA = &aa; GFI = gfi; TD = DAG.getTarget().getTargetData(); } /// clear - Clear out the curret SelectionDAG and the associated /// state and prepare this SelectionDAGLowering object to be used /// for a new block. This doesn't clear out information about /// additional blocks that are needed to complete switch lowering /// or PHI node updating; that information is cleared out as it is /// consumed. void SelectionDAGLowering::clear() { NodeMap.clear(); PendingLoads.clear(); PendingExports.clear(); DAG.clear(); } /// getRoot - Return the current virtual root of the Selection DAG, /// flushing any PendingLoad items. This must be done before emitting /// a store or any other node that may need to be ordered after any /// prior load instructions. /// SDValue SelectionDAGLowering::getRoot() { if (PendingLoads.empty()) return DAG.getRoot(); if (PendingLoads.size() == 1) { SDValue Root = PendingLoads[0]; DAG.setRoot(Root); PendingLoads.clear(); return Root; } // Otherwise, we have to make a token factor node. SDValue Root = DAG.getNode(ISD::TokenFactor, MVT::Other, &PendingLoads[0], PendingLoads.size()); PendingLoads.clear(); DAG.setRoot(Root); return Root; } /// getControlRoot - Similar to getRoot, but instead of flushing all the /// PendingLoad items, flush all the PendingExports items. It is necessary /// to do this before emitting a terminator instruction. /// SDValue SelectionDAGLowering::getControlRoot() { SDValue Root = DAG.getRoot(); if (PendingExports.empty()) return Root; // Turn all of the CopyToReg chains into one factored node. if (Root.getOpcode() != ISD::EntryToken) { unsigned i = 0, e = PendingExports.size(); for (; i != e; ++i) { assert(PendingExports[i].getNode()->getNumOperands() > 1); if (PendingExports[i].getNode()->getOperand(0) == Root) break; // Don't add the root if we already indirectly depend on it. } if (i == e) PendingExports.push_back(Root); } Root = DAG.getNode(ISD::TokenFactor, MVT::Other, &PendingExports[0], PendingExports.size()); PendingExports.clear(); DAG.setRoot(Root); return Root; } void SelectionDAGLowering::visit(Instruction &I) { visit(I.getOpcode(), I); } void SelectionDAGLowering::visit(unsigned Opcode, User &I) { // Note: this doesn't use InstVisitor, because it has to work with // ConstantExpr's in addition to instructions. switch (Opcode) { default: assert(0 && "Unknown instruction type encountered!"); abort(); // Build the switch statement using the Instruction.def file. #define HANDLE_INST(NUM, OPCODE, CLASS) \ case Instruction::OPCODE:return visit##OPCODE((CLASS&)I); #include "llvm/Instruction.def" } } void SelectionDAGLowering::visitAdd(User &I) { if (I.getType()->isFPOrFPVector()) visitBinary(I, ISD::FADD); else visitBinary(I, ISD::ADD); } void SelectionDAGLowering::visitMul(User &I) { if (I.getType()->isFPOrFPVector()) visitBinary(I, ISD::FMUL); else visitBinary(I, ISD::MUL); } SDValue SelectionDAGLowering::getValue(const Value *V) { SDValue &N = NodeMap[V]; if (N.getNode()) return N; if (Constant *C = const_cast(dyn_cast(V))) { MVT VT = TLI.getValueType(V->getType(), true); if (ConstantInt *CI = dyn_cast(C)) return N = DAG.getConstant(CI->getValue(), VT); if (GlobalValue *GV = dyn_cast(C)) return N = DAG.getGlobalAddress(GV, VT); if (isa(C)) return N = DAG.getConstant(0, TLI.getPointerTy()); if (ConstantFP *CFP = dyn_cast(C)) return N = DAG.getConstantFP(CFP->getValueAPF(), VT); if (isa(C) && !isa(V->getType()) && !V->getType()->isAggregateType()) return N = DAG.getNode(ISD::UNDEF, VT); if (ConstantExpr *CE = dyn_cast(C)) { visit(CE->getOpcode(), *CE); SDValue N1 = NodeMap[V]; assert(N1.getNode() && "visit didn't populate the ValueMap!"); return N1; } if (isa(C) || isa(C)) { SmallVector Constants; for (User::const_op_iterator OI = C->op_begin(), OE = C->op_end(); OI != OE; ++OI) { SDNode *Val = getValue(*OI).getNode(); for (unsigned i = 0, e = Val->getNumValues(); i != e; ++i) Constants.push_back(SDValue(Val, i)); } return DAG.getMergeValues(&Constants[0], Constants.size()); } if (isa(C->getType()) || isa(C->getType())) { assert((isa(C) || isa(C)) && "Unknown struct or array constant!"); SmallVector ValueVTs; ComputeValueVTs(TLI, C->getType(), ValueVTs); unsigned NumElts = ValueVTs.size(); if (NumElts == 0) return SDValue(); // empty struct SmallVector Constants(NumElts); for (unsigned i = 0; i != NumElts; ++i) { MVT EltVT = ValueVTs[i]; if (isa(C)) Constants[i] = DAG.getNode(ISD::UNDEF, EltVT); else if (EltVT.isFloatingPoint()) Constants[i] = DAG.getConstantFP(0, EltVT); else Constants[i] = DAG.getConstant(0, EltVT); } return DAG.getMergeValues(&Constants[0], NumElts); } const VectorType *VecTy = cast(V->getType()); unsigned NumElements = VecTy->getNumElements(); // Now that we know the number and type of the elements, get that number of // elements into the Ops array based on what kind of constant it is. SmallVector Ops; if (ConstantVector *CP = dyn_cast(C)) { for (unsigned i = 0; i != NumElements; ++i) Ops.push_back(getValue(CP->getOperand(i))); } else { assert((isa(C) || isa(C)) && "Unknown vector constant!"); MVT EltVT = TLI.getValueType(VecTy->getElementType()); SDValue Op; if (isa(C)) Op = DAG.getNode(ISD::UNDEF, EltVT); else if (EltVT.isFloatingPoint()) Op = DAG.getConstantFP(0, EltVT); else Op = DAG.getConstant(0, EltVT); Ops.assign(NumElements, Op); } // Create a BUILD_VECTOR node. return NodeMap[V] = DAG.getNode(ISD::BUILD_VECTOR, VT, &Ops[0], Ops.size()); } // If this is a static alloca, generate it as the frameindex instead of // computation. if (const AllocaInst *AI = dyn_cast(V)) { DenseMap::iterator SI = FuncInfo.StaticAllocaMap.find(AI); if (SI != FuncInfo.StaticAllocaMap.end()) return DAG.getFrameIndex(SI->second, TLI.getPointerTy()); } unsigned InReg = FuncInfo.ValueMap[V]; assert(InReg && "Value not in map!"); RegsForValue RFV(TLI, InReg, V->getType()); SDValue Chain = DAG.getEntryNode(); return RFV.getCopyFromRegs(DAG, Chain, NULL); } void SelectionDAGLowering::visitRet(ReturnInst &I) { if (I.getNumOperands() == 0) { DAG.setRoot(DAG.getNode(ISD::RET, MVT::Other, getControlRoot())); return; } SmallVector NewValues; NewValues.push_back(getControlRoot()); for (unsigned i = 0, e = I.getNumOperands(); i != e; ++i) { SDValue RetOp = getValue(I.getOperand(i)); SmallVector ValueVTs; ComputeValueVTs(TLI, I.getOperand(i)->getType(), ValueVTs); for (unsigned j = 0, f = ValueVTs.size(); j != f; ++j) { MVT VT = ValueVTs[j]; // FIXME: C calling convention requires the return type to be promoted to // at least 32-bit. But this is not necessary for non-C calling conventions. if (VT.isInteger()) { MVT MinVT = TLI.getRegisterType(MVT::i32); if (VT.bitsLT(MinVT)) VT = MinVT; } unsigned NumParts = TLI.getNumRegisters(VT); MVT PartVT = TLI.getRegisterType(VT); SmallVector Parts(NumParts); ISD::NodeType ExtendKind = ISD::ANY_EXTEND; const Function *F = I.getParent()->getParent(); if (F->paramHasAttr(0, ParamAttr::SExt)) ExtendKind = ISD::SIGN_EXTEND; else if (F->paramHasAttr(0, ParamAttr::ZExt)) ExtendKind = ISD::ZERO_EXTEND; getCopyToParts(DAG, SDValue(RetOp.getNode(), RetOp.getResNo() + j), &Parts[0], NumParts, PartVT, ExtendKind); for (unsigned i = 0; i < NumParts; ++i) { NewValues.push_back(Parts[i]); NewValues.push_back(DAG.getArgFlags(ISD::ArgFlagsTy())); } } } DAG.setRoot(DAG.getNode(ISD::RET, MVT::Other, &NewValues[0], NewValues.size())); } /// ExportFromCurrentBlock - If this condition isn't known to be exported from /// the current basic block, add it to ValueMap now so that we'll get a /// CopyTo/FromReg. void SelectionDAGLowering::ExportFromCurrentBlock(Value *V) { // No need to export constants. if (!isa(V) && !isa(V)) return; // Already exported? if (FuncInfo.isExportedInst(V)) return; unsigned Reg = FuncInfo.InitializeRegForValue(V); CopyValueToVirtualRegister(V, Reg); } bool SelectionDAGLowering::isExportableFromCurrentBlock(Value *V, const BasicBlock *FromBB) { // The operands of the setcc have to be in this block. We don't know // how to export them from some other block. if (Instruction *VI = dyn_cast(V)) { // Can export from current BB. if (VI->getParent() == FromBB) return true; // Is already exported, noop. return FuncInfo.isExportedInst(V); } // If this is an argument, we can export it if the BB is the entry block or // if it is already exported. if (isa(V)) { if (FromBB == &FromBB->getParent()->getEntryBlock()) return true; // Otherwise, can only export this if it is already exported. return FuncInfo.isExportedInst(V); } // Otherwise, constants can always be exported. return true; } static bool InBlock(const Value *V, const BasicBlock *BB) { if (const Instruction *I = dyn_cast(V)) return I->getParent() == BB; return true; } /// FindMergedConditions - If Cond is an expression like void SelectionDAGLowering::FindMergedConditions(Value *Cond, MachineBasicBlock *TBB, MachineBasicBlock *FBB, MachineBasicBlock *CurBB, unsigned Opc) { // If this node is not part of the or/and tree, emit it as a branch. Instruction *BOp = dyn_cast(Cond); if (!BOp || !(isa(BOp) || isa(BOp)) || (unsigned)BOp->getOpcode() != Opc || !BOp->hasOneUse() || BOp->getParent() != CurBB->getBasicBlock() || !InBlock(BOp->getOperand(0), CurBB->getBasicBlock()) || !InBlock(BOp->getOperand(1), CurBB->getBasicBlock())) { const BasicBlock *BB = CurBB->getBasicBlock(); // If the leaf of the tree is a comparison, merge the condition into // the caseblock. if ((isa(Cond) || isa(Cond)) && // The operands of the cmp have to be in this block. We don't know // how to export them from some other block. If this is the first block // of the sequence, no exporting is needed. (CurBB == CurMBB || (isExportableFromCurrentBlock(BOp->getOperand(0), BB) && isExportableFromCurrentBlock(BOp->getOperand(1), BB)))) { BOp = cast(Cond); ISD::CondCode Condition; if (ICmpInst *IC = dyn_cast(Cond)) { switch (IC->getPredicate()) { default: assert(0 && "Unknown icmp predicate opcode!"); case ICmpInst::ICMP_EQ: Condition = ISD::SETEQ; break; case ICmpInst::ICMP_NE: Condition = ISD::SETNE; break; case ICmpInst::ICMP_SLE: Condition = ISD::SETLE; break; case ICmpInst::ICMP_ULE: Condition = ISD::SETULE; break; case ICmpInst::ICMP_SGE: Condition = ISD::SETGE; break; case ICmpInst::ICMP_UGE: Condition = ISD::SETUGE; break; case ICmpInst::ICMP_SLT: Condition = ISD::SETLT; break; case ICmpInst::ICMP_ULT: Condition = ISD::SETULT; break; case ICmpInst::ICMP_SGT: Condition = ISD::SETGT; break; case ICmpInst::ICMP_UGT: Condition = ISD::SETUGT; break; } } else if (FCmpInst *FC = dyn_cast(Cond)) { ISD::CondCode FPC, FOC; switch (FC->getPredicate()) { default: assert(0 && "Unknown fcmp predicate opcode!"); case FCmpInst::FCMP_FALSE: FOC = FPC = ISD::SETFALSE; break; case FCmpInst::FCMP_OEQ: FOC = ISD::SETEQ; FPC = ISD::SETOEQ; break; case FCmpInst::FCMP_OGT: FOC = ISD::SETGT; FPC = ISD::SETOGT; break; case FCmpInst::FCMP_OGE: FOC = ISD::SETGE; FPC = ISD::SETOGE; break; case FCmpInst::FCMP_OLT: FOC = ISD::SETLT; FPC = ISD::SETOLT; break; case FCmpInst::FCMP_OLE: FOC = ISD::SETLE; FPC = ISD::SETOLE; break; case FCmpInst::FCMP_ONE: FOC = ISD::SETNE; FPC = ISD::SETONE; break; case FCmpInst::FCMP_ORD: FOC = FPC = ISD::SETO; break; case FCmpInst::FCMP_UNO: FOC = FPC = ISD::SETUO; break; case FCmpInst::FCMP_UEQ: FOC = ISD::SETEQ; FPC = ISD::SETUEQ; break; case FCmpInst::FCMP_UGT: FOC = ISD::SETGT; FPC = ISD::SETUGT; break; case FCmpInst::FCMP_UGE: FOC = ISD::SETGE; FPC = ISD::SETUGE; break; case FCmpInst::FCMP_ULT: FOC = ISD::SETLT; FPC = ISD::SETULT; break; case FCmpInst::FCMP_ULE: FOC = ISD::SETLE; FPC = ISD::SETULE; break; case FCmpInst::FCMP_UNE: FOC = ISD::SETNE; FPC = ISD::SETUNE; break; case FCmpInst::FCMP_TRUE: FOC = FPC = ISD::SETTRUE; break; } if (FiniteOnlyFPMath()) Condition = FOC; else Condition = FPC; } else { Condition = ISD::SETEQ; // silence warning. assert(0 && "Unknown compare instruction"); } CaseBlock CB(Condition, BOp->getOperand(0), BOp->getOperand(1), NULL, TBB, FBB, CurBB); SwitchCases.push_back(CB); return; } // Create a CaseBlock record representing this branch. CaseBlock CB(ISD::SETEQ, Cond, ConstantInt::getTrue(), NULL, TBB, FBB, CurBB); SwitchCases.push_back(CB); return; } // Create TmpBB after CurBB. MachineFunction::iterator BBI = CurBB; MachineFunction &MF = DAG.getMachineFunction(); MachineBasicBlock *TmpBB = MF.CreateMachineBasicBlock(CurBB->getBasicBlock()); CurBB->getParent()->insert(++BBI, TmpBB); if (Opc == Instruction::Or) { // Codegen X | Y as: // jmp_if_X TBB // jmp TmpBB // TmpBB: // jmp_if_Y TBB // jmp FBB // // Emit the LHS condition. FindMergedConditions(BOp->getOperand(0), TBB, TmpBB, CurBB, Opc); // Emit the RHS condition into TmpBB. FindMergedConditions(BOp->getOperand(1), TBB, FBB, TmpBB, Opc); } else { assert(Opc == Instruction::And && "Unknown merge op!"); // Codegen X & Y as: // jmp_if_X TmpBB // jmp FBB // TmpBB: // jmp_if_Y TBB // jmp FBB // // This requires creation of TmpBB after CurBB. // Emit the LHS condition. FindMergedConditions(BOp->getOperand(0), TmpBB, FBB, CurBB, Opc); // Emit the RHS condition into TmpBB. FindMergedConditions(BOp->getOperand(1), TBB, FBB, TmpBB, Opc); } } /// If the set of cases should be emitted as a series of branches, return true. /// If we should emit this as a bunch of and/or'd together conditions, return /// false. bool SelectionDAGLowering::ShouldEmitAsBranches(const std::vector &Cases){ if (Cases.size() != 2) return true; // If this is two comparisons of the same values or'd or and'd together, they // will get folded into a single comparison, so don't emit two blocks. if ((Cases[0].CmpLHS == Cases[1].CmpLHS && Cases[0].CmpRHS == Cases[1].CmpRHS) || (Cases[0].CmpRHS == Cases[1].CmpLHS && Cases[0].CmpLHS == Cases[1].CmpRHS)) { return false; } return true; } void SelectionDAGLowering::visitBr(BranchInst &I) { // Update machine-CFG edges. MachineBasicBlock *Succ0MBB = FuncInfo.MBBMap[I.getSuccessor(0)]; // Figure out which block is immediately after the current one. MachineBasicBlock *NextBlock = 0; MachineFunction::iterator BBI = CurMBB; if (++BBI != CurMBB->getParent()->end()) NextBlock = BBI; if (I.isUnconditional()) { // Update machine-CFG edges. CurMBB->addSuccessor(Succ0MBB); // If this is not a fall-through branch, emit the branch. if (Succ0MBB != NextBlock) DAG.setRoot(DAG.getNode(ISD::BR, MVT::Other, getControlRoot(), DAG.getBasicBlock(Succ0MBB))); return; } // If this condition is one of the special cases we handle, do special stuff // now. Value *CondVal = I.getCondition(); MachineBasicBlock *Succ1MBB = FuncInfo.MBBMap[I.getSuccessor(1)]; // If this is a series of conditions that are or'd or and'd together, emit // this as a sequence of branches instead of setcc's with and/or operations. // For example, instead of something like: // cmp A, B // C = seteq // cmp D, E // F = setle // or C, F // jnz foo // Emit: // cmp A, B // je foo // cmp D, E // jle foo // if (BinaryOperator *BOp = dyn_cast(CondVal)) { if (BOp->hasOneUse() && (BOp->getOpcode() == Instruction::And || BOp->getOpcode() == Instruction::Or)) { FindMergedConditions(BOp, Succ0MBB, Succ1MBB, CurMBB, BOp->getOpcode()); // If the compares in later blocks need to use values not currently // exported from this block, export them now. This block should always // be the first entry. assert(SwitchCases[0].ThisBB == CurMBB && "Unexpected lowering!"); // Allow some cases to be rejected. if (ShouldEmitAsBranches(SwitchCases)) { for (unsigned i = 1, e = SwitchCases.size(); i != e; ++i) { ExportFromCurrentBlock(SwitchCases[i].CmpLHS); ExportFromCurrentBlock(SwitchCases[i].CmpRHS); } // Emit the branch for this block. visitSwitchCase(SwitchCases[0]); SwitchCases.erase(SwitchCases.begin()); return; } // Okay, we decided not to do this, remove any inserted MBB's and clear // SwitchCases. for (unsigned i = 1, e = SwitchCases.size(); i != e; ++i) CurMBB->getParent()->erase(SwitchCases[i].ThisBB); SwitchCases.clear(); } } // Create a CaseBlock record representing this branch. CaseBlock CB(ISD::SETEQ, CondVal, ConstantInt::getTrue(), NULL, Succ0MBB, Succ1MBB, CurMBB); // Use visitSwitchCase to actually insert the fast branch sequence for this // cond branch. visitSwitchCase(CB); } /// visitSwitchCase - Emits the necessary code to represent a single node in /// the binary search tree resulting from lowering a switch instruction. void SelectionDAGLowering::visitSwitchCase(CaseBlock &CB) { SDValue Cond; SDValue CondLHS = getValue(CB.CmpLHS); // Build the setcc now. if (CB.CmpMHS == NULL) { // Fold "(X == true)" to X and "(X == false)" to !X to // handle common cases produced by branch lowering. if (CB.CmpRHS == ConstantInt::getTrue() && CB.CC == ISD::SETEQ) Cond = CondLHS; else if (CB.CmpRHS == ConstantInt::getFalse() && CB.CC == ISD::SETEQ) { SDValue True = DAG.getConstant(1, CondLHS.getValueType()); Cond = DAG.getNode(ISD::XOR, CondLHS.getValueType(), CondLHS, True); } else Cond = DAG.getSetCC(MVT::i1, CondLHS, getValue(CB.CmpRHS), CB.CC); } else { assert(CB.CC == ISD::SETLE && "Can handle only LE ranges now"); uint64_t Low = cast(CB.CmpLHS)->getSExtValue(); uint64_t High = cast(CB.CmpRHS)->getSExtValue(); SDValue CmpOp = getValue(CB.CmpMHS); MVT VT = CmpOp.getValueType(); if (cast(CB.CmpLHS)->isMinValue(true)) { Cond = DAG.getSetCC(MVT::i1, CmpOp, DAG.getConstant(High, VT), ISD::SETLE); } else { SDValue SUB = DAG.getNode(ISD::SUB, VT, CmpOp, DAG.getConstant(Low, VT)); Cond = DAG.getSetCC(MVT::i1, SUB, DAG.getConstant(High-Low, VT), ISD::SETULE); } } // Update successor info CurMBB->addSuccessor(CB.TrueBB); CurMBB->addSuccessor(CB.FalseBB); // Set NextBlock to be the MBB immediately after the current one, if any. // This is used to avoid emitting unnecessary branches to the next block. MachineBasicBlock *NextBlock = 0; MachineFunction::iterator BBI = CurMBB; if (++BBI != CurMBB->getParent()->end()) NextBlock = BBI; // If the lhs block is the next block, invert the condition so that we can // fall through to the lhs instead of the rhs block. if (CB.TrueBB == NextBlock) { std::swap(CB.TrueBB, CB.FalseBB); SDValue True = DAG.getConstant(1, Cond.getValueType()); Cond = DAG.getNode(ISD::XOR, Cond.getValueType(), Cond, True); } SDValue BrCond = DAG.getNode(ISD::BRCOND, MVT::Other, getControlRoot(), Cond, DAG.getBasicBlock(CB.TrueBB)); // If the branch was constant folded, fix up the CFG. if (BrCond.getOpcode() == ISD::BR) { CurMBB->removeSuccessor(CB.FalseBB); DAG.setRoot(BrCond); } else { // Otherwise, go ahead and insert the false branch. if (BrCond == getControlRoot()) CurMBB->removeSuccessor(CB.TrueBB); if (CB.FalseBB == NextBlock) DAG.setRoot(BrCond); else DAG.setRoot(DAG.getNode(ISD::BR, MVT::Other, BrCond, DAG.getBasicBlock(CB.FalseBB))); } } /// visitJumpTable - Emit JumpTable node in the current MBB void SelectionDAGLowering::visitJumpTable(JumpTable &JT) { // Emit the code for the jump table assert(JT.Reg != -1U && "Should lower JT Header first!"); MVT PTy = TLI.getPointerTy(); SDValue Index = DAG.getCopyFromReg(getControlRoot(), JT.Reg, PTy); SDValue Table = DAG.getJumpTable(JT.JTI, PTy); DAG.setRoot(DAG.getNode(ISD::BR_JT, MVT::Other, Index.getValue(1), Table, Index)); return; } /// visitJumpTableHeader - This function emits necessary code to produce index /// in the JumpTable from switch case. void SelectionDAGLowering::visitJumpTableHeader(JumpTable &JT, JumpTableHeader &JTH) { // Subtract the lowest switch case value from the value being switched on // and conditional branch to default mbb if the result is greater than the // difference between smallest and largest cases. SDValue SwitchOp = getValue(JTH.SValue); MVT VT = SwitchOp.getValueType(); SDValue SUB = DAG.getNode(ISD::SUB, VT, SwitchOp, DAG.getConstant(JTH.First, VT)); // The SDNode we just created, which holds the value being switched on // minus the the smallest case value, needs to be copied to a virtual // register so it can be used as an index into the jump table in a // subsequent basic block. This value may be smaller or larger than the // target's pointer type, and therefore require extension or truncating. if (VT.bitsGT(TLI.getPointerTy())) SwitchOp = DAG.getNode(ISD::TRUNCATE, TLI.getPointerTy(), SUB); else SwitchOp = DAG.getNode(ISD::ZERO_EXTEND, TLI.getPointerTy(), SUB); unsigned JumpTableReg = FuncInfo.MakeReg(TLI.getPointerTy()); SDValue CopyTo = DAG.getCopyToReg(getControlRoot(), JumpTableReg, SwitchOp); JT.Reg = JumpTableReg; // Emit the range check for the jump table, and branch to the default // block for the switch statement if the value being switched on exceeds // the largest case in the switch. SDValue CMP = DAG.getSetCC(TLI.getSetCCResultType(SUB), SUB, DAG.getConstant(JTH.Last-JTH.First,VT), ISD::SETUGT); // Set NextBlock to be the MBB immediately after the current one, if any. // This is used to avoid emitting unnecessary branches to the next block. MachineBasicBlock *NextBlock = 0; MachineFunction::iterator BBI = CurMBB; if (++BBI != CurMBB->getParent()->end()) NextBlock = BBI; SDValue BrCond = DAG.getNode(ISD::BRCOND, MVT::Other, CopyTo, CMP, DAG.getBasicBlock(JT.Default)); if (JT.MBB == NextBlock) DAG.setRoot(BrCond); else DAG.setRoot(DAG.getNode(ISD::BR, MVT::Other, BrCond, DAG.getBasicBlock(JT.MBB))); return; } /// visitBitTestHeader - This function emits necessary code to produce value /// suitable for "bit tests" void SelectionDAGLowering::visitBitTestHeader(BitTestBlock &B) { // Subtract the minimum value SDValue SwitchOp = getValue(B.SValue); MVT VT = SwitchOp.getValueType(); SDValue SUB = DAG.getNode(ISD::SUB, VT, SwitchOp, DAG.getConstant(B.First, VT)); // Check range SDValue RangeCmp = DAG.getSetCC(TLI.getSetCCResultType(SUB), SUB, DAG.getConstant(B.Range, VT), ISD::SETUGT); SDValue ShiftOp; if (VT.bitsGT(TLI.getShiftAmountTy())) ShiftOp = DAG.getNode(ISD::TRUNCATE, TLI.getShiftAmountTy(), SUB); else ShiftOp = DAG.getNode(ISD::ZERO_EXTEND, TLI.getShiftAmountTy(), SUB); // Make desired shift SDValue SwitchVal = DAG.getNode(ISD::SHL, TLI.getPointerTy(), DAG.getConstant(1, TLI.getPointerTy()), ShiftOp); unsigned SwitchReg = FuncInfo.MakeReg(TLI.getPointerTy()); SDValue CopyTo = DAG.getCopyToReg(getControlRoot(), SwitchReg, SwitchVal); B.Reg = SwitchReg; // Set NextBlock to be the MBB immediately after the current one, if any. // This is used to avoid emitting unnecessary branches to the next block. MachineBasicBlock *NextBlock = 0; MachineFunction::iterator BBI = CurMBB; if (++BBI != CurMBB->getParent()->end()) NextBlock = BBI; MachineBasicBlock* MBB = B.Cases[0].ThisBB; CurMBB->addSuccessor(B.Default); CurMBB->addSuccessor(MBB); SDValue BrRange = DAG.getNode(ISD::BRCOND, MVT::Other, CopyTo, RangeCmp, DAG.getBasicBlock(B.Default)); if (MBB == NextBlock) DAG.setRoot(BrRange); else DAG.setRoot(DAG.getNode(ISD::BR, MVT::Other, CopyTo, DAG.getBasicBlock(MBB))); return; } /// visitBitTestCase - this function produces one "bit test" void SelectionDAGLowering::visitBitTestCase(MachineBasicBlock* NextMBB, unsigned Reg, BitTestCase &B) { // Emit bit tests and jumps SDValue SwitchVal = DAG.getCopyFromReg(getControlRoot(), Reg, TLI.getPointerTy()); SDValue AndOp = DAG.getNode(ISD::AND, TLI.getPointerTy(), SwitchVal, DAG.getConstant(B.Mask, TLI.getPointerTy())); SDValue AndCmp = DAG.getSetCC(TLI.getSetCCResultType(AndOp), AndOp, DAG.getConstant(0, TLI.getPointerTy()), ISD::SETNE); CurMBB->addSuccessor(B.TargetBB); CurMBB->addSuccessor(NextMBB); SDValue BrAnd = DAG.getNode(ISD::BRCOND, MVT::Other, getControlRoot(), AndCmp, DAG.getBasicBlock(B.TargetBB)); // Set NextBlock to be the MBB immediately after the current one, if any. // This is used to avoid emitting unnecessary branches to the next block. MachineBasicBlock *NextBlock = 0; MachineFunction::iterator BBI = CurMBB; if (++BBI != CurMBB->getParent()->end()) NextBlock = BBI; if (NextMBB == NextBlock) DAG.setRoot(BrAnd); else DAG.setRoot(DAG.getNode(ISD::BR, MVT::Other, BrAnd, DAG.getBasicBlock(NextMBB))); return; } void SelectionDAGLowering::visitInvoke(InvokeInst &I) { // Retrieve successors. MachineBasicBlock *Return = FuncInfo.MBBMap[I.getSuccessor(0)]; MachineBasicBlock *LandingPad = FuncInfo.MBBMap[I.getSuccessor(1)]; if (isa(I.getCalledValue())) visitInlineAsm(&I); else LowerCallTo(&I, getValue(I.getOperand(0)), false, LandingPad); // If the value of the invoke is used outside of its defining block, make it // available as a virtual register. if (!I.use_empty()) { DenseMap::iterator VMI = FuncInfo.ValueMap.find(&I); if (VMI != FuncInfo.ValueMap.end()) CopyValueToVirtualRegister(&I, VMI->second); } // Update successor info CurMBB->addSuccessor(Return); CurMBB->addSuccessor(LandingPad); // Drop into normal successor. DAG.setRoot(DAG.getNode(ISD::BR, MVT::Other, getControlRoot(), DAG.getBasicBlock(Return))); } void SelectionDAGLowering::visitUnwind(UnwindInst &I) { } /// handleSmallSwitchCaseRange - Emit a series of specific tests (suitable for /// small case ranges). bool SelectionDAGLowering::handleSmallSwitchRange(CaseRec& CR, CaseRecVector& WorkList, Value* SV, MachineBasicBlock* Default) { Case& BackCase = *(CR.Range.second-1); // Size is the number of Cases represented by this range. unsigned Size = CR.Range.second - CR.Range.first; if (Size > 3) return false; // Get the MachineFunction which holds the current MBB. This is used when // inserting any additional MBBs necessary to represent the switch. MachineFunction *CurMF = CurMBB->getParent(); // Figure out which block is immediately after the current one. MachineBasicBlock *NextBlock = 0; MachineFunction::iterator BBI = CR.CaseBB; if (++BBI != CurMBB->getParent()->end()) NextBlock = BBI; // TODO: If any two of the cases has the same destination, and if one value // is the same as the other, but has one bit unset that the other has set, // use bit manipulation to do two compares at once. For example: // "if (X == 6 || X == 4)" -> "if ((X|2) == 6)" // Rearrange the case blocks so that the last one falls through if possible. if (NextBlock && Default != NextBlock && BackCase.BB != NextBlock) { // The last case block won't fall through into 'NextBlock' if we emit the // branches in this order. See if rearranging a case value would help. for (CaseItr I = CR.Range.first, E = CR.Range.second-1; I != E; ++I) { if (I->BB == NextBlock) { std::swap(*I, BackCase); break; } } } // Create a CaseBlock record representing a conditional branch to // the Case's target mbb if the value being switched on SV is equal // to C. MachineBasicBlock *CurBlock = CR.CaseBB; for (CaseItr I = CR.Range.first, E = CR.Range.second; I != E; ++I) { MachineBasicBlock *FallThrough; if (I != E-1) { FallThrough = CurMF->CreateMachineBasicBlock(CurBlock->getBasicBlock()); CurMF->insert(BBI, FallThrough); } else { // If the last case doesn't match, go to the default block. FallThrough = Default; } Value *RHS, *LHS, *MHS; ISD::CondCode CC; if (I->High == I->Low) { // This is just small small case range :) containing exactly 1 case CC = ISD::SETEQ; LHS = SV; RHS = I->High; MHS = NULL; } else { CC = ISD::SETLE; LHS = I->Low; MHS = SV; RHS = I->High; } CaseBlock CB(CC, LHS, RHS, MHS, I->BB, FallThrough, CurBlock); // If emitting the first comparison, just call visitSwitchCase to emit the // code into the current block. Otherwise, push the CaseBlock onto the // vector to be later processed by SDISel, and insert the node's MBB // before the next MBB. if (CurBlock == CurMBB) visitSwitchCase(CB); else SwitchCases.push_back(CB); CurBlock = FallThrough; } return true; } static inline bool areJTsAllowed(const TargetLowering &TLI) { return !DisableJumpTables && (TLI.isOperationLegal(ISD::BR_JT, MVT::Other) || TLI.isOperationLegal(ISD::BRIND, MVT::Other)); } /// handleJTSwitchCase - Emit jumptable for current switch case range bool SelectionDAGLowering::handleJTSwitchCase(CaseRec& CR, CaseRecVector& WorkList, Value* SV, MachineBasicBlock* Default) { Case& FrontCase = *CR.Range.first; Case& BackCase = *(CR.Range.second-1); int64_t First = cast(FrontCase.Low)->getSExtValue(); int64_t Last = cast(BackCase.High)->getSExtValue(); uint64_t TSize = 0; for (CaseItr I = CR.Range.first, E = CR.Range.second; I!=E; ++I) TSize += I->size(); if (!areJTsAllowed(TLI) || TSize <= 3) return false; double Density = (double)TSize / (double)((Last - First) + 1ULL); if (Density < 0.4) return false; DOUT << "Lowering jump table\n" << "First entry: " << First << ". Last entry: " << Last << "\n" << "Size: " << TSize << ". Density: " << Density << "\n\n"; // Get the MachineFunction which holds the current MBB. This is used when // inserting any additional MBBs necessary to represent the switch. MachineFunction *CurMF = CurMBB->getParent(); // Figure out which block is immediately after the current one. MachineBasicBlock *NextBlock = 0; MachineFunction::iterator BBI = CR.CaseBB; if (++BBI != CurMBB->getParent()->end()) NextBlock = BBI; const BasicBlock *LLVMBB = CR.CaseBB->getBasicBlock(); // Create a new basic block to hold the code for loading the address // of the jump table, and jumping to it. Update successor information; // we will either branch to the default case for the switch, or the jump // table. MachineBasicBlock *JumpTableBB = CurMF->CreateMachineBasicBlock(LLVMBB); CurMF->insert(BBI, JumpTableBB); CR.CaseBB->addSuccessor(Default); CR.CaseBB->addSuccessor(JumpTableBB); // Build a vector of destination BBs, corresponding to each target // of the jump table. If the value of the jump table slot corresponds to // a case statement, push the case's BB onto the vector, otherwise, push // the default BB. std::vector DestBBs; int64_t TEI = First; for (CaseItr I = CR.Range.first, E = CR.Range.second; I != E; ++TEI) { int64_t Low = cast(I->Low)->getSExtValue(); int64_t High = cast(I->High)->getSExtValue(); if ((Low <= TEI) && (TEI <= High)) { DestBBs.push_back(I->BB); if (TEI==High) ++I; } else { DestBBs.push_back(Default); } } // Update successor info. Add one edge to each unique successor. BitVector SuccsHandled(CR.CaseBB->getParent()->getNumBlockIDs()); for (std::vector::iterator I = DestBBs.begin(), E = DestBBs.end(); I != E; ++I) { if (!SuccsHandled[(*I)->getNumber()]) { SuccsHandled[(*I)->getNumber()] = true; JumpTableBB->addSuccessor(*I); } } // Create a jump table index for this jump table, or return an existing // one. unsigned JTI = CurMF->getJumpTableInfo()->getJumpTableIndex(DestBBs); // Set the jump table information so that we can codegen it as a second // MachineBasicBlock JumpTable JT(-1U, JTI, JumpTableBB, Default); JumpTableHeader JTH(First, Last, SV, CR.CaseBB, (CR.CaseBB == CurMBB)); if (CR.CaseBB == CurMBB) visitJumpTableHeader(JT, JTH); JTCases.push_back(JumpTableBlock(JTH, JT)); return true; } /// handleBTSplitSwitchCase - emit comparison and split binary search tree into /// 2 subtrees. bool SelectionDAGLowering::handleBTSplitSwitchCase(CaseRec& CR, CaseRecVector& WorkList, Value* SV, MachineBasicBlock* Default) { // Get the MachineFunction which holds the current MBB. This is used when // inserting any additional MBBs necessary to represent the switch. MachineFunction *CurMF = CurMBB->getParent(); // Figure out which block is immediately after the current one. MachineBasicBlock *NextBlock = 0; MachineFunction::iterator BBI = CR.CaseBB; if (++BBI != CurMBB->getParent()->end()) NextBlock = BBI; Case& FrontCase = *CR.Range.first; Case& BackCase = *(CR.Range.second-1); const BasicBlock *LLVMBB = CR.CaseBB->getBasicBlock(); // Size is the number of Cases represented by this range. unsigned Size = CR.Range.second - CR.Range.first; int64_t First = cast(FrontCase.Low)->getSExtValue(); int64_t Last = cast(BackCase.High)->getSExtValue(); double FMetric = 0; CaseItr Pivot = CR.Range.first + Size/2; // Select optimal pivot, maximizing sum density of LHS and RHS. This will // (heuristically) allow us to emit JumpTable's later. uint64_t TSize = 0; for (CaseItr I = CR.Range.first, E = CR.Range.second; I!=E; ++I) TSize += I->size(); uint64_t LSize = FrontCase.size(); uint64_t RSize = TSize-LSize; DOUT << "Selecting best pivot: \n" << "First: " << First << ", Last: " << Last <<"\n" << "LSize: " << LSize << ", RSize: " << RSize << "\n"; for (CaseItr I = CR.Range.first, J=I+1, E = CR.Range.second; J!=E; ++I, ++J) { int64_t LEnd = cast(I->High)->getSExtValue(); int64_t RBegin = cast(J->Low)->getSExtValue(); assert((RBegin-LEnd>=1) && "Invalid case distance"); double LDensity = (double)LSize / (double)((LEnd - First) + 1ULL); double RDensity = (double)RSize / (double)((Last - RBegin) + 1ULL); double Metric = Log2_64(RBegin-LEnd)*(LDensity+RDensity); // Should always split in some non-trivial place DOUT <<"=>Step\n" << "LEnd: " << LEnd << ", RBegin: " << RBegin << "\n" << "LDensity: " << LDensity << ", RDensity: " << RDensity << "\n" << "Metric: " << Metric << "\n"; if (FMetric < Metric) { Pivot = J; FMetric = Metric; DOUT << "Current metric set to: " << FMetric << "\n"; } LSize += J->size(); RSize -= J->size(); } if (areJTsAllowed(TLI)) { // If our case is dense we *really* should handle it earlier! assert((FMetric > 0) && "Should handle dense range earlier!"); } else { Pivot = CR.Range.first + Size/2; } CaseRange LHSR(CR.Range.first, Pivot); CaseRange RHSR(Pivot, CR.Range.second); Constant *C = Pivot->Low; MachineBasicBlock *FalseBB = 0, *TrueBB = 0; // We know that we branch to the LHS if the Value being switched on is // less than the Pivot value, C. We use this to optimize our binary // tree a bit, by recognizing that if SV is greater than or equal to the // LHS's Case Value, and that Case Value is exactly one less than the // Pivot's Value, then we can branch directly to the LHS's Target, // rather than creating a leaf node for it. if ((LHSR.second - LHSR.first) == 1 && LHSR.first->High == CR.GE && cast(C)->getSExtValue() == (cast(CR.GE)->getSExtValue() + 1LL)) { TrueBB = LHSR.first->BB; } else { TrueBB = CurMF->CreateMachineBasicBlock(LLVMBB); CurMF->insert(BBI, TrueBB); WorkList.push_back(CaseRec(TrueBB, C, CR.GE, LHSR)); } // Similar to the optimization above, if the Value being switched on is // known to be less than the Constant CR.LT, and the current Case Value // is CR.LT - 1, then we can branch directly to the target block for // the current Case Value, rather than emitting a RHS leaf node for it. if ((RHSR.second - RHSR.first) == 1 && CR.LT && cast(RHSR.first->Low)->getSExtValue() == (cast(CR.LT)->getSExtValue() - 1LL)) { FalseBB = RHSR.first->BB; } else { FalseBB = CurMF->CreateMachineBasicBlock(LLVMBB); CurMF->insert(BBI, FalseBB); WorkList.push_back(CaseRec(FalseBB,CR.LT,C,RHSR)); } // Create a CaseBlock record representing a conditional branch to // the LHS node if the value being switched on SV is less than C. // Otherwise, branch to LHS. CaseBlock CB(ISD::SETLT, SV, C, NULL, TrueBB, FalseBB, CR.CaseBB); if (CR.CaseBB == CurMBB) visitSwitchCase(CB); else SwitchCases.push_back(CB); return true; } /// handleBitTestsSwitchCase - if current case range has few destination and /// range span less, than machine word bitwidth, encode case range into series /// of masks and emit bit tests with these masks. bool SelectionDAGLowering::handleBitTestsSwitchCase(CaseRec& CR, CaseRecVector& WorkList, Value* SV, MachineBasicBlock* Default){ unsigned IntPtrBits = TLI.getPointerTy().getSizeInBits(); Case& FrontCase = *CR.Range.first; Case& BackCase = *(CR.Range.second-1); // Get the MachineFunction which holds the current MBB. This is used when // inserting any additional MBBs necessary to represent the switch. MachineFunction *CurMF = CurMBB->getParent(); unsigned numCmps = 0; for (CaseItr I = CR.Range.first, E = CR.Range.second; I!=E; ++I) { // Single case counts one, case range - two. if (I->Low == I->High) numCmps +=1; else numCmps +=2; } // Count unique destinations SmallSet Dests; for (CaseItr I = CR.Range.first, E = CR.Range.second; I!=E; ++I) { Dests.insert(I->BB); if (Dests.size() > 3) // Don't bother the code below, if there are too much unique destinations return false; } DOUT << "Total number of unique destinations: " << Dests.size() << "\n" << "Total number of comparisons: " << numCmps << "\n"; // Compute span of values. Constant* minValue = FrontCase.Low; Constant* maxValue = BackCase.High; uint64_t range = cast(maxValue)->getSExtValue() - cast(minValue)->getSExtValue(); DOUT << "Compare range: " << range << "\n" << "Low bound: " << cast(minValue)->getSExtValue() << "\n" << "High bound: " << cast(maxValue)->getSExtValue() << "\n"; if (range>=IntPtrBits || (!(Dests.size() == 1 && numCmps >= 3) && !(Dests.size() == 2 && numCmps >= 5) && !(Dests.size() >= 3 && numCmps >= 6))) return false; DOUT << "Emitting bit tests\n"; int64_t lowBound = 0; // Optimize the case where all the case values fit in a // word without having to subtract minValue. In this case, // we can optimize away the subtraction. if (cast(minValue)->getSExtValue() >= 0 && cast(maxValue)->getSExtValue() < IntPtrBits) { range = cast(maxValue)->getSExtValue(); } else { lowBound = cast(minValue)->getSExtValue(); } CaseBitsVector CasesBits; unsigned i, count = 0; for (CaseItr I = CR.Range.first, E = CR.Range.second; I!=E; ++I) { MachineBasicBlock* Dest = I->BB; for (i = 0; i < count; ++i) if (Dest == CasesBits[i].BB) break; if (i == count) { assert((count < 3) && "Too much destinations to test!"); CasesBits.push_back(CaseBits(0, Dest, 0)); count++; } uint64_t lo = cast(I->Low)->getSExtValue() - lowBound; uint64_t hi = cast(I->High)->getSExtValue() - lowBound; for (uint64_t j = lo; j <= hi; j++) { CasesBits[i].Mask |= 1ULL << j; CasesBits[i].Bits++; } } std::sort(CasesBits.begin(), CasesBits.end(), CaseBitsCmp()); BitTestInfo BTC; // Figure out which block is immediately after the current one. MachineFunction::iterator BBI = CR.CaseBB; ++BBI; const BasicBlock *LLVMBB = CR.CaseBB->getBasicBlock(); DOUT << "Cases:\n"; for (unsigned i = 0, e = CasesBits.size(); i!=e; ++i) { DOUT << "Mask: " << CasesBits[i].Mask << ", Bits: " << CasesBits[i].Bits << ", BB: " << CasesBits[i].BB << "\n"; MachineBasicBlock *CaseBB = CurMF->CreateMachineBasicBlock(LLVMBB); CurMF->insert(BBI, CaseBB); BTC.push_back(BitTestCase(CasesBits[i].Mask, CaseBB, CasesBits[i].BB)); } BitTestBlock BTB(lowBound, range, SV, -1U, (CR.CaseBB == CurMBB), CR.CaseBB, Default, BTC); if (CR.CaseBB == CurMBB) visitBitTestHeader(BTB); BitTestCases.push_back(BTB); return true; } /// Clusterify - Transform simple list of Cases into list of CaseRange's unsigned SelectionDAGLowering::Clusterify(CaseVector& Cases, const SwitchInst& SI) { unsigned numCmps = 0; // Start with "simple" cases for (unsigned i = 1; i < SI.getNumSuccessors(); ++i) { MachineBasicBlock *SMBB = FuncInfo.MBBMap[SI.getSuccessor(i)]; Cases.push_back(Case(SI.getSuccessorValue(i), SI.getSuccessorValue(i), SMBB)); } std::sort(Cases.begin(), Cases.end(), CaseCmp()); // Merge case into clusters if (Cases.size()>=2) // Must recompute end() each iteration because it may be // invalidated by erase if we hold on to it for (CaseItr I=Cases.begin(), J=++(Cases.begin()); J!=Cases.end(); ) { int64_t nextValue = cast(J->Low)->getSExtValue(); int64_t currentValue = cast(I->High)->getSExtValue(); MachineBasicBlock* nextBB = J->BB; MachineBasicBlock* currentBB = I->BB; // If the two neighboring cases go to the same destination, merge them // into a single case. if ((nextValue-currentValue==1) && (currentBB == nextBB)) { I->High = J->High; J = Cases.erase(J); } else { I = J++; } } for (CaseItr I=Cases.begin(), E=Cases.end(); I!=E; ++I, ++numCmps) { if (I->Low != I->High) // A range counts double, since it requires two compares. ++numCmps; } return numCmps; } void SelectionDAGLowering::visitSwitch(SwitchInst &SI) { // Figure out which block is immediately after the current one. MachineBasicBlock *NextBlock = 0; MachineFunction::iterator BBI = CurMBB; MachineBasicBlock *Default = FuncInfo.MBBMap[SI.getDefaultDest()]; // If there is only the default destination, branch to it if it is not the // next basic block. Otherwise, just fall through. if (SI.getNumOperands() == 2) { // Update machine-CFG edges. // If this is not a fall-through branch, emit the branch. CurMBB->addSuccessor(Default); if (Default != NextBlock) DAG.setRoot(DAG.getNode(ISD::BR, MVT::Other, getControlRoot(), DAG.getBasicBlock(Default))); return; } // If there are any non-default case statements, create a vector of Cases // representing each one, and sort the vector so that we can efficiently // create a binary search tree from them. CaseVector Cases; unsigned numCmps = Clusterify(Cases, SI); DOUT << "Clusterify finished. Total clusters: " << Cases.size() << ". Total compares: " << numCmps << "\n"; // Get the Value to be switched on and default basic blocks, which will be // inserted into CaseBlock records, representing basic blocks in the binary // search tree. Value *SV = SI.getOperand(0); // Push the initial CaseRec onto the worklist CaseRecVector WorkList; WorkList.push_back(CaseRec(CurMBB,0,0,CaseRange(Cases.begin(),Cases.end()))); while (!WorkList.empty()) { // Grab a record representing a case range to process off the worklist CaseRec CR = WorkList.back(); WorkList.pop_back(); if (handleBitTestsSwitchCase(CR, WorkList, SV, Default)) continue; // If the range has few cases (two or less) emit a series of specific // tests. if (handleSmallSwitchRange(CR, WorkList, SV, Default)) continue; // If the switch has more than 5 blocks, and at least 40% dense, and the // target supports indirect branches, then emit a jump table rather than // lowering the switch to a binary tree of conditional branches. if (handleJTSwitchCase(CR, WorkList, SV, Default)) continue; // Emit binary tree. We need to pick a pivot, and push left and right ranges // onto the worklist. Leafs are handled via handleSmallSwitchRange() call. handleBTSplitSwitchCase(CR, WorkList, SV, Default); } } void SelectionDAGLowering::visitSub(User &I) { // -0.0 - X --> fneg const Type *Ty = I.getType(); if (isa(Ty)) { if (ConstantVector *CV = dyn_cast(I.getOperand(0))) { const VectorType *DestTy = cast(I.getType()); const Type *ElTy = DestTy->getElementType(); if (ElTy->isFloatingPoint()) { unsigned VL = DestTy->getNumElements(); std::vector NZ(VL, ConstantFP::getNegativeZero(ElTy)); Constant *CNZ = ConstantVector::get(&NZ[0], NZ.size()); if (CV == CNZ) { SDValue Op2 = getValue(I.getOperand(1)); setValue(&I, DAG.getNode(ISD::FNEG, Op2.getValueType(), Op2)); return; } } } } if (Ty->isFloatingPoint()) { if (ConstantFP *CFP = dyn_cast(I.getOperand(0))) if (CFP->isExactlyValue(ConstantFP::getNegativeZero(Ty)->getValueAPF())) { SDValue Op2 = getValue(I.getOperand(1)); setValue(&I, DAG.getNode(ISD::FNEG, Op2.getValueType(), Op2)); return; } } visitBinary(I, Ty->isFPOrFPVector() ? ISD::FSUB : ISD::SUB); } void SelectionDAGLowering::visitBinary(User &I, unsigned OpCode) { SDValue Op1 = getValue(I.getOperand(0)); SDValue Op2 = getValue(I.getOperand(1)); setValue(&I, DAG.getNode(OpCode, Op1.getValueType(), Op1, Op2)); } void SelectionDAGLowering::visitShift(User &I, unsigned Opcode) { SDValue Op1 = getValue(I.getOperand(0)); SDValue Op2 = getValue(I.getOperand(1)); if (!isa(I.getType())) { if (TLI.getShiftAmountTy().bitsLT(Op2.getValueType())) Op2 = DAG.getNode(ISD::TRUNCATE, TLI.getShiftAmountTy(), Op2); else if (TLI.getShiftAmountTy().bitsGT(Op2.getValueType())) Op2 = DAG.getNode(ISD::ANY_EXTEND, TLI.getShiftAmountTy(), Op2); } setValue(&I, DAG.getNode(Opcode, Op1.getValueType(), Op1, Op2)); } void SelectionDAGLowering::visitICmp(User &I) { ICmpInst::Predicate predicate = ICmpInst::BAD_ICMP_PREDICATE; if (ICmpInst *IC = dyn_cast(&I)) predicate = IC->getPredicate(); else if (ConstantExpr *IC = dyn_cast(&I)) predicate = ICmpInst::Predicate(IC->getPredicate()); SDValue Op1 = getValue(I.getOperand(0)); SDValue Op2 = getValue(I.getOperand(1)); ISD::CondCode Opcode; switch (predicate) { case ICmpInst::ICMP_EQ : Opcode = ISD::SETEQ; break; case ICmpInst::ICMP_NE : Opcode = ISD::SETNE; break; case ICmpInst::ICMP_UGT : Opcode = ISD::SETUGT; break; case ICmpInst::ICMP_UGE : Opcode = ISD::SETUGE; break; case ICmpInst::ICMP_ULT : Opcode = ISD::SETULT; break; case ICmpInst::ICMP_ULE : Opcode = ISD::SETULE; break; case ICmpInst::ICMP_SGT : Opcode = ISD::SETGT; break; case ICmpInst::ICMP_SGE : Opcode = ISD::SETGE; break; case ICmpInst::ICMP_SLT : Opcode = ISD::SETLT; break; case ICmpInst::ICMP_SLE : Opcode = ISD::SETLE; break; default: assert(!"Invalid ICmp predicate value"); Opcode = ISD::SETEQ; break; } setValue(&I, DAG.getSetCC(MVT::i1, Op1, Op2, Opcode)); } void SelectionDAGLowering::visitFCmp(User &I) { FCmpInst::Predicate predicate = FCmpInst::BAD_FCMP_PREDICATE; if (FCmpInst *FC = dyn_cast(&I)) predicate = FC->getPredicate(); else if (ConstantExpr *FC = dyn_cast(&I)) predicate = FCmpInst::Predicate(FC->getPredicate()); SDValue Op1 = getValue(I.getOperand(0)); SDValue Op2 = getValue(I.getOperand(1)); ISD::CondCode Condition, FOC, FPC; switch (predicate) { case FCmpInst::FCMP_FALSE: FOC = FPC = ISD::SETFALSE; break; case FCmpInst::FCMP_OEQ: FOC = ISD::SETEQ; FPC = ISD::SETOEQ; break; case FCmpInst::FCMP_OGT: FOC = ISD::SETGT; FPC = ISD::SETOGT; break; case FCmpInst::FCMP_OGE: FOC = ISD::SETGE; FPC = ISD::SETOGE; break; case FCmpInst::FCMP_OLT: FOC = ISD::SETLT; FPC = ISD::SETOLT; break; case FCmpInst::FCMP_OLE: FOC = ISD::SETLE; FPC = ISD::SETOLE; break; case FCmpInst::FCMP_ONE: FOC = ISD::SETNE; FPC = ISD::SETONE; break; case FCmpInst::FCMP_ORD: FOC = FPC = ISD::SETO; break; case FCmpInst::FCMP_UNO: FOC = FPC = ISD::SETUO; break; case FCmpInst::FCMP_UEQ: FOC = ISD::SETEQ; FPC = ISD::SETUEQ; break; case FCmpInst::FCMP_UGT: FOC = ISD::SETGT; FPC = ISD::SETUGT; break; case FCmpInst::FCMP_UGE: FOC = ISD::SETGE; FPC = ISD::SETUGE; break; case FCmpInst::FCMP_ULT: FOC = ISD::SETLT; FPC = ISD::SETULT; break; case FCmpInst::FCMP_ULE: FOC = ISD::SETLE; FPC = ISD::SETULE; break; case FCmpInst::FCMP_UNE: FOC = ISD::SETNE; FPC = ISD::SETUNE; break; case FCmpInst::FCMP_TRUE: FOC = FPC = ISD::SETTRUE; break; default: assert(!"Invalid FCmp predicate value"); FOC = FPC = ISD::SETFALSE; break; } if (FiniteOnlyFPMath()) Condition = FOC; else Condition = FPC; setValue(&I, DAG.getSetCC(MVT::i1, Op1, Op2, Condition)); } void SelectionDAGLowering::visitVICmp(User &I) { ICmpInst::Predicate predicate = ICmpInst::BAD_ICMP_PREDICATE; if (VICmpInst *IC = dyn_cast(&I)) predicate = IC->getPredicate(); else if (ConstantExpr *IC = dyn_cast(&I)) predicate = ICmpInst::Predicate(IC->getPredicate()); SDValue Op1 = getValue(I.getOperand(0)); SDValue Op2 = getValue(I.getOperand(1)); ISD::CondCode Opcode; switch (predicate) { case ICmpInst::ICMP_EQ : Opcode = ISD::SETEQ; break; case ICmpInst::ICMP_NE : Opcode = ISD::SETNE; break; case ICmpInst::ICMP_UGT : Opcode = ISD::SETUGT; break; case ICmpInst::ICMP_UGE : Opcode = ISD::SETUGE; break; case ICmpInst::ICMP_ULT : Opcode = ISD::SETULT; break; case ICmpInst::ICMP_ULE : Opcode = ISD::SETULE; break; case ICmpInst::ICMP_SGT : Opcode = ISD::SETGT; break; case ICmpInst::ICMP_SGE : Opcode = ISD::SETGE; break; case ICmpInst::ICMP_SLT : Opcode = ISD::SETLT; break; case ICmpInst::ICMP_SLE : Opcode = ISD::SETLE; break; default: assert(!"Invalid ICmp predicate value"); Opcode = ISD::SETEQ; break; } setValue(&I, DAG.getVSetCC(Op1.getValueType(), Op1, Op2, Opcode)); } void SelectionDAGLowering::visitVFCmp(User &I) { FCmpInst::Predicate predicate = FCmpInst::BAD_FCMP_PREDICATE; if (VFCmpInst *FC = dyn_cast(&I)) predicate = FC->getPredicate(); else if (ConstantExpr *FC = dyn_cast(&I)) predicate = FCmpInst::Predicate(FC->getPredicate()); SDValue Op1 = getValue(I.getOperand(0)); SDValue Op2 = getValue(I.getOperand(1)); ISD::CondCode Condition, FOC, FPC; switch (predicate) { case FCmpInst::FCMP_FALSE: FOC = FPC = ISD::SETFALSE; break; case FCmpInst::FCMP_OEQ: FOC = ISD::SETEQ; FPC = ISD::SETOEQ; break; case FCmpInst::FCMP_OGT: FOC = ISD::SETGT; FPC = ISD::SETOGT; break; case FCmpInst::FCMP_OGE: FOC = ISD::SETGE; FPC = ISD::SETOGE; break; case FCmpInst::FCMP_OLT: FOC = ISD::SETLT; FPC = ISD::SETOLT; break; case FCmpInst::FCMP_OLE: FOC = ISD::SETLE; FPC = ISD::SETOLE; break; case FCmpInst::FCMP_ONE: FOC = ISD::SETNE; FPC = ISD::SETONE; break; case FCmpInst::FCMP_ORD: FOC = FPC = ISD::SETO; break; case FCmpInst::FCMP_UNO: FOC = FPC = ISD::SETUO; break; case FCmpInst::FCMP_UEQ: FOC = ISD::SETEQ; FPC = ISD::SETUEQ; break; case FCmpInst::FCMP_UGT: FOC = ISD::SETGT; FPC = ISD::SETUGT; break; case FCmpInst::FCMP_UGE: FOC = ISD::SETGE; FPC = ISD::SETUGE; break; case FCmpInst::FCMP_ULT: FOC = ISD::SETLT; FPC = ISD::SETULT; break; case FCmpInst::FCMP_ULE: FOC = ISD::SETLE; FPC = ISD::SETULE; break; case FCmpInst::FCMP_UNE: FOC = ISD::SETNE; FPC = ISD::SETUNE; break; case FCmpInst::FCMP_TRUE: FOC = FPC = ISD::SETTRUE; break; default: assert(!"Invalid VFCmp predicate value"); FOC = FPC = ISD::SETFALSE; break; } if (FiniteOnlyFPMath()) Condition = FOC; else Condition = FPC; MVT DestVT = TLI.getValueType(I.getType()); setValue(&I, DAG.getVSetCC(DestVT, Op1, Op2, Condition)); } void SelectionDAGLowering::visitSelect(User &I) { SDValue Cond = getValue(I.getOperand(0)); SDValue TrueVal = getValue(I.getOperand(1)); SDValue FalseVal = getValue(I.getOperand(2)); setValue(&I, DAG.getNode(ISD::SELECT, TrueVal.getValueType(), Cond, TrueVal, FalseVal)); } void SelectionDAGLowering::visitTrunc(User &I) { // TruncInst cannot be a no-op cast because sizeof(src) > sizeof(dest). SDValue N = getValue(I.getOperand(0)); MVT DestVT = TLI.getValueType(I.getType()); setValue(&I, DAG.getNode(ISD::TRUNCATE, DestVT, N)); } void SelectionDAGLowering::visitZExt(User &I) { // ZExt cannot be a no-op cast because sizeof(src) < sizeof(dest). // ZExt also can't be a cast to bool for same reason. So, nothing much to do SDValue N = getValue(I.getOperand(0)); MVT DestVT = TLI.getValueType(I.getType()); setValue(&I, DAG.getNode(ISD::ZERO_EXTEND, DestVT, N)); } void SelectionDAGLowering::visitSExt(User &I) { // SExt cannot be a no-op cast because sizeof(src) < sizeof(dest). // SExt also can't be a cast to bool for same reason. So, nothing much to do SDValue N = getValue(I.getOperand(0)); MVT DestVT = TLI.getValueType(I.getType()); setValue(&I, DAG.getNode(ISD::SIGN_EXTEND, DestVT, N)); } void SelectionDAGLowering::visitFPTrunc(User &I) { // FPTrunc is never a no-op cast, no need to check SDValue N = getValue(I.getOperand(0)); MVT DestVT = TLI.getValueType(I.getType()); setValue(&I, DAG.getNode(ISD::FP_ROUND, DestVT, N, DAG.getIntPtrConstant(0))); } void SelectionDAGLowering::visitFPExt(User &I){ // FPTrunc is never a no-op cast, no need to check SDValue N = getValue(I.getOperand(0)); MVT DestVT = TLI.getValueType(I.getType()); setValue(&I, DAG.getNode(ISD::FP_EXTEND, DestVT, N)); } void SelectionDAGLowering::visitFPToUI(User &I) { // FPToUI is never a no-op cast, no need to check SDValue N = getValue(I.getOperand(0)); MVT DestVT = TLI.getValueType(I.getType()); setValue(&I, DAG.getNode(ISD::FP_TO_UINT, DestVT, N)); } void SelectionDAGLowering::visitFPToSI(User &I) { // FPToSI is never a no-op cast, no need to check SDValue N = getValue(I.getOperand(0)); MVT DestVT = TLI.getValueType(I.getType()); setValue(&I, DAG.getNode(ISD::FP_TO_SINT, DestVT, N)); } void SelectionDAGLowering::visitUIToFP(User &I) { // UIToFP is never a no-op cast, no need to check SDValue N = getValue(I.getOperand(0)); MVT DestVT = TLI.getValueType(I.getType()); setValue(&I, DAG.getNode(ISD::UINT_TO_FP, DestVT, N)); } void SelectionDAGLowering::visitSIToFP(User &I){ // UIToFP is never a no-op cast, no need to check SDValue N = getValue(I.getOperand(0)); MVT DestVT = TLI.getValueType(I.getType()); setValue(&I, DAG.getNode(ISD::SINT_TO_FP, DestVT, N)); } void SelectionDAGLowering::visitPtrToInt(User &I) { // What to do depends on the size of the integer and the size of the pointer. // We can either truncate, zero extend, or no-op, accordingly. SDValue N = getValue(I.getOperand(0)); MVT SrcVT = N.getValueType(); MVT DestVT = TLI.getValueType(I.getType()); SDValue Result; if (DestVT.bitsLT(SrcVT)) Result = DAG.getNode(ISD::TRUNCATE, DestVT, N); else // Note: ZERO_EXTEND can handle cases where the sizes are equal too Result = DAG.getNode(ISD::ZERO_EXTEND, DestVT, N); setValue(&I, Result); } void SelectionDAGLowering::visitIntToPtr(User &I) { // What to do depends on the size of the integer and the size of the pointer. // We can either truncate, zero extend, or no-op, accordingly. SDValue N = getValue(I.getOperand(0)); MVT SrcVT = N.getValueType(); MVT DestVT = TLI.getValueType(I.getType()); if (DestVT.bitsLT(SrcVT)) setValue(&I, DAG.getNode(ISD::TRUNCATE, DestVT, N)); else // Note: ZERO_EXTEND can handle cases where the sizes are equal too setValue(&I, DAG.getNode(ISD::ZERO_EXTEND, DestVT, N)); } void SelectionDAGLowering::visitBitCast(User &I) { SDValue N = getValue(I.getOperand(0)); MVT DestVT = TLI.getValueType(I.getType()); // BitCast assures us that source and destination are the same size so this // is either a BIT_CONVERT or a no-op. if (DestVT != N.getValueType()) setValue(&I, DAG.getNode(ISD::BIT_CONVERT, DestVT, N)); // convert types else setValue(&I, N); // noop cast. } void SelectionDAGLowering::visitInsertElement(User &I) { SDValue InVec = getValue(I.getOperand(0)); SDValue InVal = getValue(I.getOperand(1)); SDValue InIdx = DAG.getNode(ISD::ZERO_EXTEND, TLI.getPointerTy(), getValue(I.getOperand(2))); setValue(&I, DAG.getNode(ISD::INSERT_VECTOR_ELT, TLI.getValueType(I.getType()), InVec, InVal, InIdx)); } void SelectionDAGLowering::visitExtractElement(User &I) { SDValue InVec = getValue(I.getOperand(0)); SDValue InIdx = DAG.getNode(ISD::ZERO_EXTEND, TLI.getPointerTy(), getValue(I.getOperand(1))); setValue(&I, DAG.getNode(ISD::EXTRACT_VECTOR_ELT, TLI.getValueType(I.getType()), InVec, InIdx)); } void SelectionDAGLowering::visitShuffleVector(User &I) { SDValue V1 = getValue(I.getOperand(0)); SDValue V2 = getValue(I.getOperand(1)); SDValue Mask = getValue(I.getOperand(2)); setValue(&I, DAG.getNode(ISD::VECTOR_SHUFFLE, TLI.getValueType(I.getType()), V1, V2, Mask)); } void SelectionDAGLowering::visitInsertValue(InsertValueInst &I) { const Value *Op0 = I.getOperand(0); const Value *Op1 = I.getOperand(1); const Type *AggTy = I.getType(); const Type *ValTy = Op1->getType(); bool IntoUndef = isa(Op0); bool FromUndef = isa(Op1); unsigned LinearIndex = ComputeLinearIndex(TLI, AggTy, I.idx_begin(), I.idx_end()); SmallVector AggValueVTs; ComputeValueVTs(TLI, AggTy, AggValueVTs); SmallVector ValValueVTs; ComputeValueVTs(TLI, ValTy, ValValueVTs); unsigned NumAggValues = AggValueVTs.size(); unsigned NumValValues = ValValueVTs.size(); SmallVector Values(NumAggValues); SDValue Agg = getValue(Op0); SDValue Val = getValue(Op1); unsigned i = 0; // Copy the beginning value(s) from the original aggregate. for (; i != LinearIndex; ++i) Values[i] = IntoUndef ? DAG.getNode(ISD::UNDEF, AggValueVTs[i]) : SDValue(Agg.getNode(), Agg.getResNo() + i); // Copy values from the inserted value(s). for (; i != LinearIndex + NumValValues; ++i) Values[i] = FromUndef ? DAG.getNode(ISD::UNDEF, AggValueVTs[i]) : SDValue(Val.getNode(), Val.getResNo() + i - LinearIndex); // Copy remaining value(s) from the original aggregate. for (; i != NumAggValues; ++i) Values[i] = IntoUndef ? DAG.getNode(ISD::UNDEF, AggValueVTs[i]) : SDValue(Agg.getNode(), Agg.getResNo() + i); setValue(&I, DAG.getMergeValues(DAG.getVTList(&AggValueVTs[0], NumAggValues), &Values[0], NumAggValues)); } void SelectionDAGLowering::visitExtractValue(ExtractValueInst &I) { const Value *Op0 = I.getOperand(0); const Type *AggTy = Op0->getType(); const Type *ValTy = I.getType(); bool OutOfUndef = isa(Op0); unsigned LinearIndex = ComputeLinearIndex(TLI, AggTy, I.idx_begin(), I.idx_end()); SmallVector ValValueVTs; ComputeValueVTs(TLI, ValTy, ValValueVTs); unsigned NumValValues = ValValueVTs.size(); SmallVector Values(NumValValues); SDValue Agg = getValue(Op0); // Copy out the selected value(s). for (unsigned i = LinearIndex; i != LinearIndex + NumValValues; ++i) Values[i - LinearIndex] = OutOfUndef ? DAG.getNode(ISD::UNDEF, Agg.getNode()->getValueType(Agg.getResNo() + i)) : SDValue(Agg.getNode(), Agg.getResNo() + i); setValue(&I, DAG.getMergeValues(DAG.getVTList(&ValValueVTs[0], NumValValues), &Values[0], NumValValues)); } void SelectionDAGLowering::visitGetElementPtr(User &I) { SDValue N = getValue(I.getOperand(0)); const Type *Ty = I.getOperand(0)->getType(); for (GetElementPtrInst::op_iterator OI = I.op_begin()+1, E = I.op_end(); OI != E; ++OI) { Value *Idx = *OI; if (const StructType *StTy = dyn_cast(Ty)) { unsigned Field = cast(Idx)->getZExtValue(); if (Field) { // N = N + Offset uint64_t Offset = TD->getStructLayout(StTy)->getElementOffset(Field); N = DAG.getNode(ISD::ADD, N.getValueType(), N, DAG.getIntPtrConstant(Offset)); } Ty = StTy->getElementType(Field); } else { Ty = cast(Ty)->getElementType(); // If this is a constant subscript, handle it quickly. if (ConstantInt *CI = dyn_cast(Idx)) { if (CI->getZExtValue() == 0) continue; uint64_t Offs = TD->getABITypeSize(Ty)*cast(CI)->getSExtValue(); N = DAG.getNode(ISD::ADD, N.getValueType(), N, DAG.getIntPtrConstant(Offs)); continue; } // N = N + Idx * ElementSize; uint64_t ElementSize = TD->getABITypeSize(Ty); SDValue IdxN = getValue(Idx); // If the index is smaller or larger than intptr_t, truncate or extend // it. if (IdxN.getValueType().bitsLT(N.getValueType())) IdxN = DAG.getNode(ISD::SIGN_EXTEND, N.getValueType(), IdxN); else if (IdxN.getValueType().bitsGT(N.getValueType())) IdxN = DAG.getNode(ISD::TRUNCATE, N.getValueType(), IdxN); // If this is a multiply by a power of two, turn it into a shl // immediately. This is a very common case. if (ElementSize != 1) { if (isPowerOf2_64(ElementSize)) { unsigned Amt = Log2_64(ElementSize); IdxN = DAG.getNode(ISD::SHL, N.getValueType(), IdxN, DAG.getConstant(Amt, TLI.getShiftAmountTy())); } else { SDValue Scale = DAG.getIntPtrConstant(ElementSize); IdxN = DAG.getNode(ISD::MUL, N.getValueType(), IdxN, Scale); } } N = DAG.getNode(ISD::ADD, N.getValueType(), N, IdxN); } } setValue(&I, N); } void SelectionDAGLowering::visitAlloca(AllocaInst &I) { // If this is a fixed sized alloca in the entry block of the function, // allocate it statically on the stack. if (FuncInfo.StaticAllocaMap.count(&I)) return; // getValue will auto-populate this. const Type *Ty = I.getAllocatedType(); uint64_t TySize = TLI.getTargetData()->getABITypeSize(Ty); unsigned Align = std::max((unsigned)TLI.getTargetData()->getPrefTypeAlignment(Ty), I.getAlignment()); SDValue AllocSize = getValue(I.getArraySize()); MVT IntPtr = TLI.getPointerTy(); if (IntPtr.bitsLT(AllocSize.getValueType())) AllocSize = DAG.getNode(ISD::TRUNCATE, IntPtr, AllocSize); else if (IntPtr.bitsGT(AllocSize.getValueType())) AllocSize = DAG.getNode(ISD::ZERO_EXTEND, IntPtr, AllocSize); AllocSize = DAG.getNode(ISD::MUL, IntPtr, AllocSize, DAG.getIntPtrConstant(TySize)); // Handle alignment. If the requested alignment is less than or equal to // the stack alignment, ignore it. If the size is greater than or equal to // the stack alignment, we note this in the DYNAMIC_STACKALLOC node. unsigned StackAlign = TLI.getTargetMachine().getFrameInfo()->getStackAlignment(); if (Align <= StackAlign) Align = 0; // Round the size of the allocation up to the stack alignment size // by add SA-1 to the size. AllocSize = DAG.getNode(ISD::ADD, AllocSize.getValueType(), AllocSize, DAG.getIntPtrConstant(StackAlign-1)); // Mask out the low bits for alignment purposes. AllocSize = DAG.getNode(ISD::AND, AllocSize.getValueType(), AllocSize, DAG.getIntPtrConstant(~(uint64_t)(StackAlign-1))); SDValue Ops[] = { getRoot(), AllocSize, DAG.getIntPtrConstant(Align) }; const MVT *VTs = DAG.getNodeValueTypes(AllocSize.getValueType(), MVT::Other); SDValue DSA = DAG.getNode(ISD::DYNAMIC_STACKALLOC, VTs, 2, Ops, 3); setValue(&I, DSA); DAG.setRoot(DSA.getValue(1)); // Inform the Frame Information that we have just allocated a variable-sized // object. CurMBB->getParent()->getFrameInfo()->CreateVariableSizedObject(); } void SelectionDAGLowering::visitLoad(LoadInst &I) { const Value *SV = I.getOperand(0); SDValue Ptr = getValue(SV); const Type *Ty = I.getType(); bool isVolatile = I.isVolatile(); unsigned Alignment = I.getAlignment(); SmallVector ValueVTs; SmallVector Offsets; ComputeValueVTs(TLI, Ty, ValueVTs, &Offsets); unsigned NumValues = ValueVTs.size(); if (NumValues == 0) return; SDValue Root; bool ConstantMemory = false; if (I.isVolatile()) // Serialize volatile loads with other side effects. Root = getRoot(); else if (AA->pointsToConstantMemory(SV)) { // Do not serialize (non-volatile) loads of constant memory with anything. Root = DAG.getEntryNode(); ConstantMemory = true; } else { // Do not serialize non-volatile loads against each other. Root = DAG.getRoot(); } SmallVector Values(NumValues); SmallVector Chains(NumValues); MVT PtrVT = Ptr.getValueType(); for (unsigned i = 0; i != NumValues; ++i) { SDValue L = DAG.getLoad(ValueVTs[i], Root, DAG.getNode(ISD::ADD, PtrVT, Ptr, DAG.getConstant(Offsets[i], PtrVT)), SV, Offsets[i], isVolatile, Alignment); Values[i] = L; Chains[i] = L.getValue(1); } if (!ConstantMemory) { SDValue Chain = DAG.getNode(ISD::TokenFactor, MVT::Other, &Chains[0], NumValues); if (isVolatile) DAG.setRoot(Chain); else PendingLoads.push_back(Chain); } setValue(&I, DAG.getMergeValues(DAG.getVTList(&ValueVTs[0], NumValues), &Values[0], NumValues)); } void SelectionDAGLowering::visitStore(StoreInst &I) { Value *SrcV = I.getOperand(0); Value *PtrV = I.getOperand(1); SmallVector ValueVTs; SmallVector Offsets; ComputeValueVTs(TLI, SrcV->getType(), ValueVTs, &Offsets); unsigned NumValues = ValueVTs.size(); if (NumValues == 0) return; // Get the lowered operands. Note that we do this after // checking if NumResults is zero, because with zero results // the operands won't have values in the map. SDValue Src = getValue(SrcV); SDValue Ptr = getValue(PtrV); SDValue Root = getRoot(); SmallVector Chains(NumValues); MVT PtrVT = Ptr.getValueType(); bool isVolatile = I.isVolatile(); unsigned Alignment = I.getAlignment(); for (unsigned i = 0; i != NumValues; ++i) Chains[i] = DAG.getStore(Root, SDValue(Src.getNode(), Src.getResNo() + i), DAG.getNode(ISD::ADD, PtrVT, Ptr, DAG.getConstant(Offsets[i], PtrVT)), PtrV, Offsets[i], isVolatile, Alignment); DAG.setRoot(DAG.getNode(ISD::TokenFactor, MVT::Other, &Chains[0], NumValues)); } /// visitTargetIntrinsic - Lower a call of a target intrinsic to an INTRINSIC /// node. void SelectionDAGLowering::visitTargetIntrinsic(CallInst &I, unsigned Intrinsic) { bool HasChain = !I.doesNotAccessMemory(); bool OnlyLoad = HasChain && I.onlyReadsMemory(); // Build the operand list. SmallVector Ops; if (HasChain) { // If this intrinsic has side-effects, chainify it. if (OnlyLoad) { // We don't need to serialize loads against other loads. Ops.push_back(DAG.getRoot()); } else { Ops.push_back(getRoot()); } } // Add the intrinsic ID as an integer operand. Ops.push_back(DAG.getConstant(Intrinsic, TLI.getPointerTy())); // Add all operands of the call to the operand list. for (unsigned i = 1, e = I.getNumOperands(); i != e; ++i) { SDValue Op = getValue(I.getOperand(i)); assert(TLI.isTypeLegal(Op.getValueType()) && "Intrinsic uses a non-legal type?"); Ops.push_back(Op); } std::vector VTs; if (I.getType() != Type::VoidTy) { MVT VT = TLI.getValueType(I.getType()); if (VT.isVector()) { const VectorType *DestTy = cast(I.getType()); MVT EltVT = TLI.getValueType(DestTy->getElementType()); VT = MVT::getVectorVT(EltVT, DestTy->getNumElements()); assert(VT != MVT::Other && "Intrinsic uses a non-legal type?"); } assert(TLI.isTypeLegal(VT) && "Intrinsic uses a non-legal type?"); VTs.push_back(VT); } if (HasChain) VTs.push_back(MVT::Other); const MVT *VTList = DAG.getNodeValueTypes(VTs); // Create the node. SDValue Result; if (!HasChain) Result = DAG.getNode(ISD::INTRINSIC_WO_CHAIN, VTList, VTs.size(), &Ops[0], Ops.size()); else if (I.getType() != Type::VoidTy) Result = DAG.getNode(ISD::INTRINSIC_W_CHAIN, VTList, VTs.size(), &Ops[0], Ops.size()); else Result = DAG.getNode(ISD::INTRINSIC_VOID, VTList, VTs.size(), &Ops[0], Ops.size()); if (HasChain) { SDValue Chain = Result.getValue(Result.getNode()->getNumValues()-1); if (OnlyLoad) PendingLoads.push_back(Chain); else DAG.setRoot(Chain); } if (I.getType() != Type::VoidTy) { if (const VectorType *PTy = dyn_cast(I.getType())) { MVT VT = TLI.getValueType(PTy); Result = DAG.getNode(ISD::BIT_CONVERT, VT, Result); } setValue(&I, Result); } } /// ExtractTypeInfo - Returns the type info, possibly bitcast, encoded in V. static GlobalVariable *ExtractTypeInfo(Value *V) { V = V->stripPointerCasts(); GlobalVariable *GV = dyn_cast(V); assert ((GV || isa(V)) && "TypeInfo must be a global variable or NULL"); return GV; } namespace llvm { /// AddCatchInfo - Extract the personality and type infos from an eh.selector /// call, and add them to the specified machine basic block. void AddCatchInfo(CallInst &I, MachineModuleInfo *MMI, MachineBasicBlock *MBB) { // Inform the MachineModuleInfo of the personality for this landing pad. ConstantExpr *CE = cast(I.getOperand(2)); assert(CE->getOpcode() == Instruction::BitCast && isa(CE->getOperand(0)) && "Personality should be a function"); MMI->addPersonality(MBB, cast(CE->getOperand(0))); // Gather all the type infos for this landing pad and pass them along to // MachineModuleInfo. std::vector TyInfo; unsigned N = I.getNumOperands(); for (unsigned i = N - 1; i > 2; --i) { if (ConstantInt *CI = dyn_cast(I.getOperand(i))) { unsigned FilterLength = CI->getZExtValue(); unsigned FirstCatch = i + FilterLength + !FilterLength; assert (FirstCatch <= N && "Invalid filter length"); if (FirstCatch < N) { TyInfo.reserve(N - FirstCatch); for (unsigned j = FirstCatch; j < N; ++j) TyInfo.push_back(ExtractTypeInfo(I.getOperand(j))); MMI->addCatchTypeInfo(MBB, TyInfo); TyInfo.clear(); } if (!FilterLength) { // Cleanup. MMI->addCleanup(MBB); } else { // Filter. TyInfo.reserve(FilterLength - 1); for (unsigned j = i + 1; j < FirstCatch; ++j) TyInfo.push_back(ExtractTypeInfo(I.getOperand(j))); MMI->addFilterTypeInfo(MBB, TyInfo); TyInfo.clear(); } N = i; } } if (N > 3) { TyInfo.reserve(N - 3); for (unsigned j = 3; j < N; ++j) TyInfo.push_back(ExtractTypeInfo(I.getOperand(j))); MMI->addCatchTypeInfo(MBB, TyInfo); } } } // GetSignificand - Get the significand and build it into a floating-point // number with exponent of 1: // // Op = (Op & 0x007fffff) | 0x3f800000; // // where Op is the hexidecimal representation of floating point value. static SDValue GetSignificand(SelectionDAG &DAG, SDValue Op) { SDValue t1 = DAG.getNode(ISD::AND, MVT::i32, Op, DAG.getConstant(0x007fffff, MVT::i32)); SDValue t2 = DAG.getNode(ISD::OR, MVT::i32, t1, DAG.getConstant(0x3f800000, MVT::i32)); return DAG.getNode(ISD::BIT_CONVERT, MVT::f32, t2); } // GetExponent - Get the exponent: // // (float)(((Op1 & 0x7f800000) >> 23) - 127); // // where Op is the hexidecimal representation of floating point value. static SDValue GetExponent(SelectionDAG &DAG, SDValue Op) { SDValue t1 = DAG.getNode(ISD::AND, MVT::i32, Op, DAG.getConstant(0x7f800000, MVT::i32)); SDValue t2 = DAG.getNode(ISD::SRL, MVT::i32, t1, DAG.getConstant(23, MVT::i32)); SDValue t3 = DAG.getNode(ISD::SUB, MVT::i32, t2, DAG.getConstant(127, MVT::i32)); return DAG.getNode(ISD::UINT_TO_FP, MVT::f32, t3); } /// Inlined utility function to implement binary input atomic intrinsics for /// visitIntrinsicCall: I is a call instruction /// Op is the associated NodeType for I const char * SelectionDAGLowering::implVisitBinaryAtomic(CallInst& I, ISD::NodeType Op) { SDValue Root = getRoot(); SDValue L = DAG.getAtomic(Op, Root, getValue(I.getOperand(1)), getValue(I.getOperand(2)), I.getOperand(1)); setValue(&I, L); DAG.setRoot(L.getValue(1)); return 0; } /// visitExp - Lower an exp intrinsic. Handles the special sequences for /// limited-precision mode. void SelectionDAGLowering::visitExp(CallInst &I) { SDValue result; if (getValue(I.getOperand(1)).getValueType() == MVT::f32 && LimitFloatPrecision > 0 && LimitFloatPrecision <= 18) { SDValue Op = getValue(I.getOperand(1)); // Put the exponent in the right bit position for later addition to the // final result: // // #define LOG2OFe 1.4426950f // IntegerPartOfX = ((int32_t)(X * LOG2OFe)); SDValue t0 = DAG.getNode(ISD::FMUL, MVT::f32, Op, DAG.getConstantFP(APFloat( APInt(32, 0x3fb8aa3b)), MVT::f32)); SDValue IntegerPartOfX = DAG.getNode(ISD::FP_TO_SINT, MVT::i32, t0); // FractionalPartOfX = (X * LOG2OFe) - (float)IntegerPartOfX; SDValue t1 = DAG.getNode(ISD::SINT_TO_FP, MVT::f32, IntegerPartOfX); SDValue X = DAG.getNode(ISD::FSUB, MVT::f32, t0, t1); // IntegerPartOfX <<= 23; IntegerPartOfX = DAG.getNode(ISD::SHL, MVT::i32, IntegerPartOfX, DAG.getConstant(23, MVT::i32)); if (LimitFloatPrecision <= 6) { // For floating-point precision of 6: // // TwoToFractionalPartOfX = // 0.997535578f + // (0.735607626f + 0.252464424f * x) * x; // // error 0.0144103317, which is 6 bits SDValue t2 = DAG.getNode(ISD::FMUL, MVT::f32, X, DAG.getConstantFP(APFloat( APInt(32, 0x3e814304)), MVT::f32)); SDValue t3 = DAG.getNode(ISD::FADD, MVT::f32, t2, DAG.getConstantFP(APFloat( APInt(32, 0x3f3c50c8)), MVT::f32)); SDValue t4 = DAG.getNode(ISD::FMUL, MVT::f32, t3, X); SDValue t5 = DAG.getNode(ISD::FADD, MVT::f32, t4, DAG.getConstantFP(APFloat( APInt(32, 0x3f7f5e7e)), MVT::f32)); SDValue TwoToFracPartOfX = DAG.getNode(ISD::BIT_CONVERT, MVT::i32, t5); // Add the exponent into the result in integer domain. SDValue t6 = DAG.getNode(ISD::ADD, MVT::i32, TwoToFracPartOfX, IntegerPartOfX); result = DAG.getNode(ISD::BIT_CONVERT, MVT::f32, t6); } else if (LimitFloatPrecision > 6 && LimitFloatPrecision <= 12) { // For floating-point precision of 12: // // TwoToFractionalPartOfX = // 0.999892986f + // (0.696457318f + // (0.224338339f + 0.792043434e-1f * x) * x) * x; // // 0.000107046256 error, which is 13 to 14 bits SDValue t2 = DAG.getNode(ISD::FMUL, MVT::f32, X, DAG.getConstantFP(APFloat( APInt(32, 0x3da235e3)), MVT::f32)); SDValue t3 = DAG.getNode(ISD::FADD, MVT::f32, t2, DAG.getConstantFP(APFloat( APInt(32, 0x3e65b8f3)), MVT::f32)); SDValue t4 = DAG.getNode(ISD::FMUL, MVT::f32, t3, X); SDValue t5 = DAG.getNode(ISD::FADD, MVT::f32, t4, DAG.getConstantFP(APFloat( APInt(32, 0x3f324b07)), MVT::f32)); SDValue t6 = DAG.getNode(ISD::FMUL, MVT::f32, t5, X); SDValue t7 = DAG.getNode(ISD::FADD, MVT::f32, t6, DAG.getConstantFP(APFloat( APInt(32, 0x3f7ff8fd)), MVT::f32)); SDValue TwoToFracPartOfX = DAG.getNode(ISD::BIT_CONVERT, MVT::i32, t7); // Add the exponent into the result in integer domain. SDValue t8 = DAG.getNode(ISD::ADD, MVT::i32, TwoToFracPartOfX, IntegerPartOfX); result = DAG.getNode(ISD::BIT_CONVERT, MVT::f32, t8); } else { // LimitFloatPrecision > 12 && LimitFloatPrecision <= 18 // For floating-point precision of 18: // // TwoToFractionalPartOfX = // 0.999999982f + // (0.693148872f + // (0.240227044f + // (0.554906021e-1f + // (0.961591928e-2f + // (0.136028312e-2f + 0.157059148e-3f *x)*x)*x)*x)*x)*x; // // error 2.47208000*10^(-7), which is better than 18 bits SDValue t2 = DAG.getNode(ISD::FMUL, MVT::f32, X, DAG.getConstantFP(APFloat( APInt(32, 0x3924b03e)), MVT::f32)); SDValue t3 = DAG.getNode(ISD::FADD, MVT::f32, t2, DAG.getConstantFP(APFloat( APInt(32, 0x3ab24b87)), MVT::f32)); SDValue t4 = DAG.getNode(ISD::FMUL, MVT::f32, t3, X); SDValue t5 = DAG.getNode(ISD::FADD, MVT::f32, t4, DAG.getConstantFP(APFloat( APInt(32, 0x3c1d8c17)), MVT::f32)); SDValue t6 = DAG.getNode(ISD::FMUL, MVT::f32, t5, X); SDValue t7 = DAG.getNode(ISD::FADD, MVT::f32, t6, DAG.getConstantFP(APFloat( APInt(32, 0x3d634a1d)), MVT::f32)); SDValue t8 = DAG.getNode(ISD::FMUL, MVT::f32, t7, X); SDValue t9 = DAG.getNode(ISD::FADD, MVT::f32, t8, DAG.getConstantFP(APFloat( APInt(32, 0x3e75fe14)), MVT::f32)); SDValue t10 = DAG.getNode(ISD::FMUL, MVT::f32, t9, X); SDValue t11 = DAG.getNode(ISD::FADD, MVT::f32, t10, DAG.getConstantFP(APFloat( APInt(32, 0x3f317234)), MVT::f32)); SDValue t12 = DAG.getNode(ISD::FMUL, MVT::f32, t11, X); SDValue t13 = DAG.getNode(ISD::FADD, MVT::f32, t12, DAG.getConstantFP(APFloat( APInt(32, 0x3f800000)), MVT::f32)); SDValue TwoToFracPartOfX = DAG.getNode(ISD::BIT_CONVERT, MVT::i32, t13); // Add the exponent into the result in integer domain. SDValue t14 = DAG.getNode(ISD::ADD, MVT::i32, TwoToFracPartOfX, IntegerPartOfX); result = DAG.getNode(ISD::BIT_CONVERT, MVT::f32, t14); } } else { // No special expansion. result = DAG.getNode(ISD::FEXP, getValue(I.getOperand(1)).getValueType(), getValue(I.getOperand(1))); } setValue(&I, result); } /// visitLog - Lower a log intrinsic. Handles the special sequences for /// limited-precision mode. void SelectionDAGLowering::visitLog(CallInst &I) { SDValue result; if (getValue(I.getOperand(1)).getValueType() == MVT::f32 && LimitFloatPrecision > 0 && LimitFloatPrecision <= 18) { SDValue Op = getValue(I.getOperand(1)); SDValue Op1 = DAG.getNode(ISD::BIT_CONVERT, MVT::i32, Op); // Scale the exponent by log(2) [0.69314718f]. SDValue Exp = GetExponent(DAG, Op1); SDValue LogOfExponent = DAG.getNode(ISD::FMUL, MVT::f32, Exp, DAG.getConstantFP(APFloat( APInt(32, 0x3f317218)), MVT::f32)); // Get the significand and build it into a floating-point number with // exponent of 1. SDValue X = GetSignificand(DAG, Op1); if (LimitFloatPrecision <= 6) { // For floating-point precision of 6: // // LogofMantissa = // -1.1609546f + // (1.4034025f - 0.23903021f * x) * x; // // error 0.0034276066, which is better than 8 bits SDValue t0 = DAG.getNode(ISD::FMUL, MVT::f32, X, DAG.getConstantFP(APFloat( APInt(32, 0xbe74c456)), MVT::f32)); SDValue t1 = DAG.getNode(ISD::FADD, MVT::f32, t0, DAG.getConstantFP(APFloat( APInt(32, 0x3fb3a2b1)), MVT::f32)); SDValue t2 = DAG.getNode(ISD::FMUL, MVT::f32, t1, X); SDValue LogOfMantissa = DAG.getNode(ISD::FSUB, MVT::f32, t2, DAG.getConstantFP(APFloat( APInt(32, 0x3f949a29)), MVT::f32)); result = DAG.getNode(ISD::FADD, MVT::f32, LogOfExponent, LogOfMantissa); } else if (LimitFloatPrecision > 6 && LimitFloatPrecision <= 12) { // For floating-point precision of 12: // // LogOfMantissa = // -1.7417939f + // (2.8212026f + // (-1.4699568f + // (0.44717955f - 0.56570851e-1f * x) * x) * x) * x; // // error 0.000061011436, which is 14 bits SDValue t0 = DAG.getNode(ISD::FMUL, MVT::f32, X, DAG.getConstantFP(APFloat( APInt(32, 0xbd67b6d6)), MVT::f32)); SDValue t1 = DAG.getNode(ISD::FADD, MVT::f32, t0, DAG.getConstantFP(APFloat( APInt(32, 0x3ee4f4b8)), MVT::f32)); SDValue t2 = DAG.getNode(ISD::FMUL, MVT::f32, t1, X); SDValue t3 = DAG.getNode(ISD::FSUB, MVT::f32, t2, DAG.getConstantFP(APFloat( APInt(32, 0x3fbc278b)), MVT::f32)); SDValue t4 = DAG.getNode(ISD::FMUL, MVT::f32, t3, X); SDValue t5 = DAG.getNode(ISD::FADD, MVT::f32, t4, DAG.getConstantFP(APFloat( APInt(32, 0x40348e95)), MVT::f32)); SDValue t6 = DAG.getNode(ISD::FMUL, MVT::f32, t5, X); SDValue LogOfMantissa = DAG.getNode(ISD::FSUB, MVT::f32, t6, DAG.getConstantFP(APFloat( APInt(32, 0x3fdef31a)), MVT::f32)); result = DAG.getNode(ISD::FADD, MVT::f32, LogOfExponent, LogOfMantissa); } else { // LimitFloatPrecision > 12 && LimitFloatPrecision <= 18 // For floating-point precision of 18: // // LogOfMantissa = // -2.1072184f + // (4.2372794f + // (-3.7029485f + // (2.2781945f + // (-0.87823314f + // (0.19073739f - 0.17809712e-1f * x) * x) * x) * x) * x)*x; // // error 0.0000023660568, which is better than 18 bits SDValue t0 = DAG.getNode(ISD::FMUL, MVT::f32, X, DAG.getConstantFP(APFloat( APInt(32, 0xbc91e5ac)), MVT::f32)); SDValue t1 = DAG.getNode(ISD::FADD, MVT::f32, t0, DAG.getConstantFP(APFloat( APInt(32, 0x3e4350aa)), MVT::f32)); SDValue t2 = DAG.getNode(ISD::FMUL, MVT::f32, t1, X); SDValue t3 = DAG.getNode(ISD::FSUB, MVT::f32, t2, DAG.getConstantFP(APFloat( APInt(32, 0x3f60d3e3)), MVT::f32)); SDValue t4 = DAG.getNode(ISD::FMUL, MVT::f32, t3, X); SDValue t5 = DAG.getNode(ISD::FADD, MVT::f32, t4, DAG.getConstantFP(APFloat( APInt(32, 0x4011cdf0)), MVT::f32)); SDValue t6 = DAG.getNode(ISD::FMUL, MVT::f32, t5, X); SDValue t7 = DAG.getNode(ISD::FSUB, MVT::f32, t6, DAG.getConstantFP(APFloat( APInt(32, 0x406cfd1c)), MVT::f32)); SDValue t8 = DAG.getNode(ISD::FMUL, MVT::f32, t7, X); SDValue t9 = DAG.getNode(ISD::FADD, MVT::f32, t8, DAG.getConstantFP(APFloat( APInt(32, 0x408797cb)), MVT::f32)); SDValue t10 = DAG.getNode(ISD::FMUL, MVT::f32, t9, X); SDValue LogOfMantissa = DAG.getNode(ISD::FSUB, MVT::f32, t10, DAG.getConstantFP(APFloat( APInt(32, 0x4006dcab)), MVT::f32)); result = DAG.getNode(ISD::FADD, MVT::f32, LogOfExponent, LogOfMantissa); } } else { // No special expansion. result = DAG.getNode(ISD::FLOG, getValue(I.getOperand(1)).getValueType(), getValue(I.getOperand(1))); } setValue(&I, result); } /// visitLog2 - Lower a log2 intrinsic. Handles the special sequences for /// limited-precision mode. void SelectionDAGLowering::visitLog2(CallInst &I) { SDValue result; if (getValue(I.getOperand(1)).getValueType() == MVT::f32 && LimitFloatPrecision > 0 && LimitFloatPrecision <= 18) { SDValue Op = getValue(I.getOperand(1)); SDValue Op1 = DAG.getNode(ISD::BIT_CONVERT, MVT::i32, Op); // Get the exponent. SDValue LogOfExponent = GetExponent(DAG, Op1); // Get the significand and build it into a floating-point number with // exponent of 1. SDValue X = GetSignificand(DAG, Op1); // Different possible minimax approximations of significand in // floating-point for various degrees of accuracy over [1,2]. if (LimitFloatPrecision <= 6) { // For floating-point precision of 6: // // Log2ofMantissa = -1.6749035f + (2.0246817f - .34484768f * x) * x; // // error 0.0049451742, which is more than 7 bits SDValue t0 = DAG.getNode(ISD::FMUL, MVT::f32, X, DAG.getConstantFP(APFloat( APInt(32, 0xbeb08fe0)), MVT::f32)); SDValue t1 = DAG.getNode(ISD::FADD, MVT::f32, t0, DAG.getConstantFP(APFloat( APInt(32, 0x40019463)), MVT::f32)); SDValue t2 = DAG.getNode(ISD::FMUL, MVT::f32, t1, X); SDValue Log2ofMantissa = DAG.getNode(ISD::FSUB, MVT::f32, t2, DAG.getConstantFP(APFloat( APInt(32, 0x3fd6633d)), MVT::f32)); result = DAG.getNode(ISD::FADD, MVT::f32, LogOfExponent, Log2ofMantissa); } else if (LimitFloatPrecision > 6 && LimitFloatPrecision <= 12) { // For floating-point precision of 12: // // Log2ofMantissa = // -2.51285454f + // (4.07009056f + // (-2.12067489f + // (.645142248f - 0.816157886e-1f * x) * x) * x) * x; // // error 0.0000876136000, which is better than 13 bits SDValue t0 = DAG.getNode(ISD::FMUL, MVT::f32, X, DAG.getConstantFP(APFloat( APInt(32, 0xbda7262e)), MVT::f32)); SDValue t1 = DAG.getNode(ISD::FADD, MVT::f32, t0, DAG.getConstantFP(APFloat( APInt(32, 0x3f25280b)), MVT::f32)); SDValue t2 = DAG.getNode(ISD::FMUL, MVT::f32, t1, X); SDValue t3 = DAG.getNode(ISD::FSUB, MVT::f32, t2, DAG.getConstantFP(APFloat( APInt(32, 0x4007b923)), MVT::f32)); SDValue t4 = DAG.getNode(ISD::FMUL, MVT::f32, t3, X); SDValue t5 = DAG.getNode(ISD::FADD, MVT::f32, t4, DAG.getConstantFP(APFloat( APInt(32, 0x40823e2f)), MVT::f32)); SDValue t6 = DAG.getNode(ISD::FMUL, MVT::f32, t5, X); SDValue Log2ofMantissa = DAG.getNode(ISD::FSUB, MVT::f32, t6, DAG.getConstantFP(APFloat( APInt(32, 0x4020d29c)), MVT::f32)); result = DAG.getNode(ISD::FADD, MVT::f32, LogOfExponent, Log2ofMantissa); } else { // LimitFloatPrecision > 12 && LimitFloatPrecision <= 18 // For floating-point precision of 18: // // Log2ofMantissa = // -3.0400495f + // (6.1129976f + // (-5.3420409f + // (3.2865683f + // (-1.2669343f + // (0.27515199f - // 0.25691327e-1f * x) * x) * x) * x) * x) * x; // // error 0.0000018516, which is better than 18 bits SDValue t0 = DAG.getNode(ISD::FMUL, MVT::f32, X, DAG.getConstantFP(APFloat( APInt(32, 0xbcd2769e)), MVT::f32)); SDValue t1 = DAG.getNode(ISD::FADD, MVT::f32, t0, DAG.getConstantFP(APFloat( APInt(32, 0x3e8ce0b9)), MVT::f32)); SDValue t2 = DAG.getNode(ISD::FMUL, MVT::f32, t1, X); SDValue t3 = DAG.getNode(ISD::FSUB, MVT::f32, t2, DAG.getConstantFP(APFloat( APInt(32, 0x3fa22ae7)), MVT::f32)); SDValue t4 = DAG.getNode(ISD::FMUL, MVT::f32, t3, X); SDValue t5 = DAG.getNode(ISD::FADD, MVT::f32, t4, DAG.getConstantFP(APFloat( APInt(32, 0x40525723)), MVT::f32)); SDValue t6 = DAG.getNode(ISD::FMUL, MVT::f32, t5, X); SDValue t7 = DAG.getNode(ISD::FSUB, MVT::f32, t6, DAG.getConstantFP(APFloat( APInt(32, 0x40aaf200)), MVT::f32)); SDValue t8 = DAG.getNode(ISD::FMUL, MVT::f32, t7, X); SDValue t9 = DAG.getNode(ISD::FADD, MVT::f32, t8, DAG.getConstantFP(APFloat( APInt(32, 0x40c39dad)), MVT::f32)); SDValue t10 = DAG.getNode(ISD::FMUL, MVT::f32, t9, X); SDValue Log2ofMantissa = DAG.getNode(ISD::FSUB, MVT::f32, t10, DAG.getConstantFP(APFloat( APInt(32, 0x4042902c)), MVT::f32)); result = DAG.getNode(ISD::FADD, MVT::f32, LogOfExponent, Log2ofMantissa); } } else { // No special expansion. result = DAG.getNode(ISD::FLOG2, getValue(I.getOperand(1)).getValueType(), getValue(I.getOperand(1))); } setValue(&I, result); } /// visitLog10 - Lower a log10 intrinsic. Handles the special sequences for /// limited-precision mode. void SelectionDAGLowering::visitLog10(CallInst &I) { SDValue result; if (getValue(I.getOperand(1)).getValueType() == MVT::f32 && LimitFloatPrecision > 0 && LimitFloatPrecision <= 18) { SDValue Op = getValue(I.getOperand(1)); SDValue Op1 = DAG.getNode(ISD::BIT_CONVERT, MVT::i32, Op); // Scale the exponent by log10(2) [0.30102999f]. SDValue Exp = GetExponent(DAG, Op1); SDValue LogOfExponent = DAG.getNode(ISD::FMUL, MVT::f32, Exp, DAG.getConstantFP(APFloat( APInt(32, 0x3e9a209a)), MVT::f32)); // Get the significand and build it into a floating-point number with // exponent of 1. SDValue X = GetSignificand(DAG, Op1); if (LimitFloatPrecision <= 6) { // For floating-point precision of 6: // // Log10ofMantissa = // -0.50419619f + // (0.60948995f - 0.10380950f * x) * x; // // error 0.0014886165, which is 6 bits SDValue t0 = DAG.getNode(ISD::FMUL, MVT::f32, X, DAG.getConstantFP(APFloat( APInt(32, 0xbdd49a13)), MVT::f32)); SDValue t1 = DAG.getNode(ISD::FADD, MVT::f32, t0, DAG.getConstantFP(APFloat( APInt(32, 0x3f1c0789)), MVT::f32)); SDValue t2 = DAG.getNode(ISD::FMUL, MVT::f32, t1, X); SDValue Log10ofMantissa = DAG.getNode(ISD::FSUB, MVT::f32, t2, DAG.getConstantFP(APFloat( APInt(32, 0x3f011300)), MVT::f32)); result = DAG.getNode(ISD::FADD, MVT::f32, LogOfExponent, Log10ofMantissa); } else if (LimitFloatPrecision > 6 && LimitFloatPrecision <= 12) { // For floating-point precision of 12: // // Log10ofMantissa = // -0.64831180f + // (0.91751397f + // (-0.31664806f + 0.47637168e-1f * x) * x) * x; // // error 0.00019228036, which is better than 12 bits SDValue t0 = DAG.getNode(ISD::FMUL, MVT::f32, X, DAG.getConstantFP(APFloat( APInt(32, 0x3d431f31)), MVT::f32)); SDValue t1 = DAG.getNode(ISD::FSUB, MVT::f32, t0, DAG.getConstantFP(APFloat( APInt(32, 0x3ea21fb2)), MVT::f32)); SDValue t2 = DAG.getNode(ISD::FMUL, MVT::f32, t1, X); SDValue t3 = DAG.getNode(ISD::FADD, MVT::f32, t2, DAG.getConstantFP(APFloat( APInt(32, 0x3f6ae232)), MVT::f32)); SDValue t4 = DAG.getNode(ISD::FMUL, MVT::f32, t3, X); SDValue Log10ofMantissa = DAG.getNode(ISD::FSUB, MVT::f32, t4, DAG.getConstantFP(APFloat( APInt(32, 0x3f25f7c3)), MVT::f32)); result = DAG.getNode(ISD::FADD, MVT::f32, LogOfExponent, Log10ofMantissa); } else { // LimitFloatPrecision > 12 && LimitFloatPrecision <= 18 // For floating-point precision of 18: // // Log10ofMantissa = // -0.84299375f + // (1.5327582f + // (-1.0688956f + // (0.49102474f + // (-0.12539807f + 0.13508273e-1f * x) * x) * x) * x) * x; // // error 0.0000037995730, which is better than 18 bits SDValue t0 = DAG.getNode(ISD::FMUL, MVT::f32, X, DAG.getConstantFP(APFloat( APInt(32, 0x3c5d51ce)), MVT::f32)); SDValue t1 = DAG.getNode(ISD::FSUB, MVT::f32, t0, DAG.getConstantFP(APFloat( APInt(32, 0x3e00685a)), MVT::f32)); SDValue t2 = DAG.getNode(ISD::FMUL, MVT::f32, t1, X); SDValue t3 = DAG.getNode(ISD::FADD, MVT::f32, t2, DAG.getConstantFP(APFloat( APInt(32, 0x3efb6798)), MVT::f32)); SDValue t4 = DAG.getNode(ISD::FMUL, MVT::f32, t3, X); SDValue t5 = DAG.getNode(ISD::FSUB, MVT::f32, t4, DAG.getConstantFP(APFloat( APInt(32, 0x3f88d192)), MVT::f32)); SDValue t6 = DAG.getNode(ISD::FMUL, MVT::f32, t5, X); SDValue t7 = DAG.getNode(ISD::FADD, MVT::f32, t6, DAG.getConstantFP(APFloat( APInt(32, 0x3fc4316c)), MVT::f32)); SDValue t8 = DAG.getNode(ISD::FMUL, MVT::f32, t7, X); SDValue Log10ofMantissa = DAG.getNode(ISD::FSUB, MVT::f32, t8, DAG.getConstantFP(APFloat( APInt(32, 0x3f57ce70)), MVT::f32)); result = DAG.getNode(ISD::FADD, MVT::f32, LogOfExponent, Log10ofMantissa); } } else { // No special expansion. result = DAG.getNode(ISD::FLOG10, getValue(I.getOperand(1)).getValueType(), getValue(I.getOperand(1))); } setValue(&I, result); } /// visitExp2 - Lower an exp2 intrinsic. Handles the special sequences for /// limited-precision mode. void SelectionDAGLowering::visitExp2(CallInst &I) { SDValue result; if (getValue(I.getOperand(1)).getValueType() == MVT::f32 && LimitFloatPrecision > 0 && LimitFloatPrecision <= 18) { SDValue Op = getValue(I.getOperand(1)); SDValue IntegerPartOfX = DAG.getNode(ISD::FP_TO_SINT, MVT::i32, Op); // FractionalPartOfX = x - (float)IntegerPartOfX; SDValue t1 = DAG.getNode(ISD::SINT_TO_FP, MVT::f32, IntegerPartOfX); SDValue X = DAG.getNode(ISD::FSUB, MVT::f32, Op, t1); // IntegerPartOfX <<= 23; IntegerPartOfX = DAG.getNode(ISD::SHL, MVT::i32, IntegerPartOfX, DAG.getConstant(23, MVT::i32)); if (LimitFloatPrecision <= 6) { // For floating-point precision of 6: // // TwoToFractionalPartOfX = // 0.997535578f + // (0.735607626f + 0.252464424f * x) * x; // // error 0.0144103317, which is 6 bits SDValue t2 = DAG.getNode(ISD::FMUL, MVT::f32, X, DAG.getConstantFP(APFloat( APInt(32, 0x3e814304)), MVT::f32)); SDValue t3 = DAG.getNode(ISD::FADD, MVT::f32, t2, DAG.getConstantFP(APFloat( APInt(32, 0x3f3c50c8)), MVT::f32)); SDValue t4 = DAG.getNode(ISD::FMUL, MVT::f32, t3, X); SDValue t5 = DAG.getNode(ISD::FADD, MVT::f32, t4, DAG.getConstantFP(APFloat( APInt(32, 0x3f7f5e7e)), MVT::f32)); SDValue t6 = DAG.getNode(ISD::BIT_CONVERT, MVT::i32, t5); SDValue TwoToFractionalPartOfX = DAG.getNode(ISD::ADD, MVT::i32, t6, IntegerPartOfX); result = DAG.getNode(ISD::BIT_CONVERT, MVT::f32, TwoToFractionalPartOfX); } else if (LimitFloatPrecision > 6 && LimitFloatPrecision <= 12) { // For floating-point precision of 12: // // TwoToFractionalPartOfX = // 0.999892986f + // (0.696457318f + // (0.224338339f + 0.792043434e-1f * x) * x) * x; // // error 0.000107046256, which is 13 to 14 bits SDValue t2 = DAG.getNode(ISD::FMUL, MVT::f32, X, DAG.getConstantFP(APFloat( APInt(32, 0x3da235e3)), MVT::f32)); SDValue t3 = DAG.getNode(ISD::FADD, MVT::f32, t2, DAG.getConstantFP(APFloat( APInt(32, 0x3e65b8f3)), MVT::f32)); SDValue t4 = DAG.getNode(ISD::FMUL, MVT::f32, t3, X); SDValue t5 = DAG.getNode(ISD::FADD, MVT::f32, t4, DAG.getConstantFP(APFloat( APInt(32, 0x3f324b07)), MVT::f32)); SDValue t6 = DAG.getNode(ISD::FMUL, MVT::f32, t5, X); SDValue t7 = DAG.getNode(ISD::FADD, MVT::f32, t6, DAG.getConstantFP(APFloat( APInt(32, 0x3f7ff8fd)), MVT::f32)); SDValue t8 = DAG.getNode(ISD::BIT_CONVERT, MVT::i32, t7); SDValue TwoToFractionalPartOfX = DAG.getNode(ISD::ADD, MVT::i32, t8, IntegerPartOfX); result = DAG.getNode(ISD::BIT_CONVERT, MVT::f32, TwoToFractionalPartOfX); } else { // LimitFloatPrecision > 12 && LimitFloatPrecision <= 18 // For floating-point precision of 18: // // TwoToFractionalPartOfX = // 0.999999982f + // (0.693148872f + // (0.240227044f + // (0.554906021e-1f + // (0.961591928e-2f + // (0.136028312e-2f + 0.157059148e-3f *x)*x)*x)*x)*x)*x; // error 2.47208000*10^(-7), which is better than 18 bits SDValue t2 = DAG.getNode(ISD::FMUL, MVT::f32, X, DAG.getConstantFP(APFloat( APInt(32, 0x3924b03e)), MVT::f32)); SDValue t3 = DAG.getNode(ISD::FADD, MVT::f32, t2, DAG.getConstantFP(APFloat( APInt(32, 0x3ab24b87)), MVT::f32)); SDValue t4 = DAG.getNode(ISD::FMUL, MVT::f32, t3, X); SDValue t5 = DAG.getNode(ISD::FADD, MVT::f32, t4, DAG.getConstantFP(APFloat( APInt(32, 0x3c1d8c17)), MVT::f32)); SDValue t6 = DAG.getNode(ISD::FMUL, MVT::f32, t5, X); SDValue t7 = DAG.getNode(ISD::FADD, MVT::f32, t6, DAG.getConstantFP(APFloat( APInt(32, 0x3d634a1d)), MVT::f32)); SDValue t8 = DAG.getNode(ISD::FMUL, MVT::f32, t7, X); SDValue t9 = DAG.getNode(ISD::FADD, MVT::f32, t8, DAG.getConstantFP(APFloat( APInt(32, 0x3e75fe14)), MVT::f32)); SDValue t10 = DAG.getNode(ISD::FMUL, MVT::f32, t9, X); SDValue t11 = DAG.getNode(ISD::FADD, MVT::f32, t10, DAG.getConstantFP(APFloat( APInt(32, 0x3f317234)), MVT::f32)); SDValue t12 = DAG.getNode(ISD::FMUL, MVT::f32, t11, X); SDValue t13 = DAG.getNode(ISD::FADD, MVT::f32, t12, DAG.getConstantFP(APFloat( APInt(32, 0x3f800000)), MVT::f32)); SDValue t14 = DAG.getNode(ISD::BIT_CONVERT, MVT::i32, t13); SDValue TwoToFractionalPartOfX = DAG.getNode(ISD::ADD, MVT::i32, t14, IntegerPartOfX); result = DAG.getNode(ISD::BIT_CONVERT, MVT::f32, TwoToFractionalPartOfX); } } else { // No special expansion. result = DAG.getNode(ISD::FEXP2, getValue(I.getOperand(1)).getValueType(), getValue(I.getOperand(1))); } setValue(&I, result); } /// visitIntrinsicCall - Lower the call to the specified intrinsic function. If /// we want to emit this as a call to a named external function, return the name /// otherwise lower it and return null. const char * SelectionDAGLowering::visitIntrinsicCall(CallInst &I, unsigned Intrinsic) { switch (Intrinsic) { default: // By default, turn this into a target intrinsic node. visitTargetIntrinsic(I, Intrinsic); return 0; case Intrinsic::vastart: visitVAStart(I); return 0; case Intrinsic::vaend: visitVAEnd(I); return 0; case Intrinsic::vacopy: visitVACopy(I); return 0; case Intrinsic::returnaddress: setValue(&I, DAG.getNode(ISD::RETURNADDR, TLI.getPointerTy(), getValue(I.getOperand(1)))); return 0; case Intrinsic::frameaddress: setValue(&I, DAG.getNode(ISD::FRAMEADDR, TLI.getPointerTy(), getValue(I.getOperand(1)))); return 0; case Intrinsic::setjmp: return "_setjmp"+!TLI.usesUnderscoreSetJmp(); break; case Intrinsic::longjmp: return "_longjmp"+!TLI.usesUnderscoreLongJmp(); break; case Intrinsic::memcpy_i32: case Intrinsic::memcpy_i64: { SDValue Op1 = getValue(I.getOperand(1)); SDValue Op2 = getValue(I.getOperand(2)); SDValue Op3 = getValue(I.getOperand(3)); unsigned Align = cast(I.getOperand(4))->getZExtValue(); DAG.setRoot(DAG.getMemcpy(getRoot(), Op1, Op2, Op3, Align, false, I.getOperand(1), 0, I.getOperand(2), 0)); return 0; } case Intrinsic::memset_i32: case Intrinsic::memset_i64: { SDValue Op1 = getValue(I.getOperand(1)); SDValue Op2 = getValue(I.getOperand(2)); SDValue Op3 = getValue(I.getOperand(3)); unsigned Align = cast(I.getOperand(4))->getZExtValue(); DAG.setRoot(DAG.getMemset(getRoot(), Op1, Op2, Op3, Align, I.getOperand(1), 0)); return 0; } case Intrinsic::memmove_i32: case Intrinsic::memmove_i64: { SDValue Op1 = getValue(I.getOperand(1)); SDValue Op2 = getValue(I.getOperand(2)); SDValue Op3 = getValue(I.getOperand(3)); unsigned Align = cast(I.getOperand(4))->getZExtValue(); // If the source and destination are known to not be aliases, we can // lower memmove as memcpy. uint64_t Size = -1ULL; if (ConstantSDNode *C = dyn_cast(Op3)) Size = C->getValue(); if (AA->alias(I.getOperand(1), Size, I.getOperand(2), Size) == AliasAnalysis::NoAlias) { DAG.setRoot(DAG.getMemcpy(getRoot(), Op1, Op2, Op3, Align, false, I.getOperand(1), 0, I.getOperand(2), 0)); return 0; } DAG.setRoot(DAG.getMemmove(getRoot(), Op1, Op2, Op3, Align, I.getOperand(1), 0, I.getOperand(2), 0)); return 0; } case Intrinsic::dbg_stoppoint: { MachineModuleInfo *MMI = DAG.getMachineModuleInfo(); DbgStopPointInst &SPI = cast(I); if (MMI && SPI.getContext() && MMI->Verify(SPI.getContext())) { DebugInfoDesc *DD = MMI->getDescFor(SPI.getContext()); assert(DD && "Not a debug information descriptor"); DAG.setRoot(DAG.getDbgStopPoint(getRoot(), SPI.getLine(), SPI.getColumn(), cast(DD))); } return 0; } case Intrinsic::dbg_region_start: { MachineModuleInfo *MMI = DAG.getMachineModuleInfo(); DbgRegionStartInst &RSI = cast(I); if (MMI && RSI.getContext() && MMI->Verify(RSI.getContext())) { unsigned LabelID = MMI->RecordRegionStart(RSI.getContext()); DAG.setRoot(DAG.getLabel(ISD::DBG_LABEL, getRoot(), LabelID)); } return 0; } case Intrinsic::dbg_region_end: { MachineModuleInfo *MMI = DAG.getMachineModuleInfo(); DbgRegionEndInst &REI = cast(I); if (MMI && REI.getContext() && MMI->Verify(REI.getContext())) { unsigned LabelID = MMI->RecordRegionEnd(REI.getContext()); DAG.setRoot(DAG.getLabel(ISD::DBG_LABEL, getRoot(), LabelID)); } return 0; } case Intrinsic::dbg_func_start: { MachineModuleInfo *MMI = DAG.getMachineModuleInfo(); if (!MMI) return 0; DbgFuncStartInst &FSI = cast(I); Value *SP = FSI.getSubprogram(); if (SP && MMI->Verify(SP)) { // llvm.dbg.func.start implicitly defines a dbg_stoppoint which is // what (most?) gdb expects. DebugInfoDesc *DD = MMI->getDescFor(SP); assert(DD && "Not a debug information descriptor"); SubprogramDesc *Subprogram = cast(DD); const CompileUnitDesc *CompileUnit = Subprogram->getFile(); unsigned SrcFile = MMI->RecordSource(CompileUnit); // Record the source line but does create a label. It will be emitted // at asm emission time. MMI->RecordSourceLine(Subprogram->getLine(), 0, SrcFile); } return 0; } case Intrinsic::dbg_declare: { MachineModuleInfo *MMI = DAG.getMachineModuleInfo(); DbgDeclareInst &DI = cast(I); Value *Variable = DI.getVariable(); if (MMI && Variable && MMI->Verify(Variable)) DAG.setRoot(DAG.getNode(ISD::DECLARE, MVT::Other, getRoot(), getValue(DI.getAddress()), getValue(Variable))); return 0; } case Intrinsic::eh_exception: { if (!CurMBB->isLandingPad()) { // FIXME: Mark exception register as live in. Hack for PR1508. unsigned Reg = TLI.getExceptionAddressRegister(); if (Reg) CurMBB->addLiveIn(Reg); } // Insert the EXCEPTIONADDR instruction. SDVTList VTs = DAG.getVTList(TLI.getPointerTy(), MVT::Other); SDValue Ops[1]; Ops[0] = DAG.getRoot(); SDValue Op = DAG.getNode(ISD::EXCEPTIONADDR, VTs, Ops, 1); setValue(&I, Op); DAG.setRoot(Op.getValue(1)); return 0; } case Intrinsic::eh_selector_i32: case Intrinsic::eh_selector_i64: { MachineModuleInfo *MMI = DAG.getMachineModuleInfo(); MVT VT = (Intrinsic == Intrinsic::eh_selector_i32 ? MVT::i32 : MVT::i64); if (MMI) { if (CurMBB->isLandingPad()) AddCatchInfo(I, MMI, CurMBB); else { #ifndef NDEBUG FuncInfo.CatchInfoLost.insert(&I); #endif // FIXME: Mark exception selector register as live in. Hack for PR1508. unsigned Reg = TLI.getExceptionSelectorRegister(); if (Reg) CurMBB->addLiveIn(Reg); } // Insert the EHSELECTION instruction. SDVTList VTs = DAG.getVTList(VT, MVT::Other); SDValue Ops[2]; Ops[0] = getValue(I.getOperand(1)); Ops[1] = getRoot(); SDValue Op = DAG.getNode(ISD::EHSELECTION, VTs, Ops, 2); setValue(&I, Op); DAG.setRoot(Op.getValue(1)); } else { setValue(&I, DAG.getConstant(0, VT)); } return 0; } case Intrinsic::eh_typeid_for_i32: case Intrinsic::eh_typeid_for_i64: { MachineModuleInfo *MMI = DAG.getMachineModuleInfo(); MVT VT = (Intrinsic == Intrinsic::eh_typeid_for_i32 ? MVT::i32 : MVT::i64); if (MMI) { // Find the type id for the given typeinfo. GlobalVariable *GV = ExtractTypeInfo(I.getOperand(1)); unsigned TypeID = MMI->getTypeIDFor(GV); setValue(&I, DAG.getConstant(TypeID, VT)); } else { // Return something different to eh_selector. setValue(&I, DAG.getConstant(1, VT)); } return 0; } case Intrinsic::eh_return_i32: case Intrinsic::eh_return_i64: if (MachineModuleInfo *MMI = DAG.getMachineModuleInfo()) { MMI->setCallsEHReturn(true); DAG.setRoot(DAG.getNode(ISD::EH_RETURN, MVT::Other, getControlRoot(), getValue(I.getOperand(1)), getValue(I.getOperand(2)))); } else { setValue(&I, DAG.getConstant(0, TLI.getPointerTy())); } return 0; case Intrinsic::eh_unwind_init: if (MachineModuleInfo *MMI = DAG.getMachineModuleInfo()) { MMI->setCallsUnwindInit(true); } return 0; case Intrinsic::eh_dwarf_cfa: { MVT VT = getValue(I.getOperand(1)).getValueType(); SDValue CfaArg; if (VT.bitsGT(TLI.getPointerTy())) CfaArg = DAG.getNode(ISD::TRUNCATE, TLI.getPointerTy(), getValue(I.getOperand(1))); else CfaArg = DAG.getNode(ISD::SIGN_EXTEND, TLI.getPointerTy(), getValue(I.getOperand(1))); SDValue Offset = DAG.getNode(ISD::ADD, TLI.getPointerTy(), DAG.getNode(ISD::FRAME_TO_ARGS_OFFSET, TLI.getPointerTy()), CfaArg); setValue(&I, DAG.getNode(ISD::ADD, TLI.getPointerTy(), DAG.getNode(ISD::FRAMEADDR, TLI.getPointerTy(), DAG.getConstant(0, TLI.getPointerTy())), Offset)); return 0; } case Intrinsic::sqrt: setValue(&I, DAG.getNode(ISD::FSQRT, getValue(I.getOperand(1)).getValueType(), getValue(I.getOperand(1)))); return 0; case Intrinsic::powi: setValue(&I, DAG.getNode(ISD::FPOWI, getValue(I.getOperand(1)).getValueType(), getValue(I.getOperand(1)), getValue(I.getOperand(2)))); return 0; case Intrinsic::sin: setValue(&I, DAG.getNode(ISD::FSIN, getValue(I.getOperand(1)).getValueType(), getValue(I.getOperand(1)))); return 0; case Intrinsic::cos: setValue(&I, DAG.getNode(ISD::FCOS, getValue(I.getOperand(1)).getValueType(), getValue(I.getOperand(1)))); return 0; case Intrinsic::log: visitLog(I); return 0; case Intrinsic::log2: visitLog2(I); return 0; case Intrinsic::log10: visitLog10(I); return 0; case Intrinsic::exp: visitExp(I); return 0; case Intrinsic::exp2: visitExp2(I); return 0; case Intrinsic::pow: setValue(&I, DAG.getNode(ISD::FPOW, getValue(I.getOperand(1)).getValueType(), getValue(I.getOperand(1)), getValue(I.getOperand(2)))); return 0; case Intrinsic::pcmarker: { SDValue Tmp = getValue(I.getOperand(1)); DAG.setRoot(DAG.getNode(ISD::PCMARKER, MVT::Other, getRoot(), Tmp)); return 0; } case Intrinsic::readcyclecounter: { SDValue Op = getRoot(); SDValue Tmp = DAG.getNode(ISD::READCYCLECOUNTER, DAG.getNodeValueTypes(MVT::i64, MVT::Other), 2, &Op, 1); setValue(&I, Tmp); DAG.setRoot(Tmp.getValue(1)); return 0; } case Intrinsic::part_select: { // Currently not implemented: just abort assert(0 && "part_select intrinsic not implemented"); abort(); } case Intrinsic::part_set: { // Currently not implemented: just abort assert(0 && "part_set intrinsic not implemented"); abort(); } case Intrinsic::bswap: setValue(&I, DAG.getNode(ISD::BSWAP, getValue(I.getOperand(1)).getValueType(), getValue(I.getOperand(1)))); return 0; case Intrinsic::cttz: { SDValue Arg = getValue(I.getOperand(1)); MVT Ty = Arg.getValueType(); SDValue result = DAG.getNode(ISD::CTTZ, Ty, Arg); setValue(&I, result); return 0; } case Intrinsic::ctlz: { SDValue Arg = getValue(I.getOperand(1)); MVT Ty = Arg.getValueType(); SDValue result = DAG.getNode(ISD::CTLZ, Ty, Arg); setValue(&I, result); return 0; } case Intrinsic::ctpop: { SDValue Arg = getValue(I.getOperand(1)); MVT Ty = Arg.getValueType(); SDValue result = DAG.getNode(ISD::CTPOP, Ty, Arg); setValue(&I, result); return 0; } case Intrinsic::stacksave: { SDValue Op = getRoot(); SDValue Tmp = DAG.getNode(ISD::STACKSAVE, DAG.getNodeValueTypes(TLI.getPointerTy(), MVT::Other), 2, &Op, 1); setValue(&I, Tmp); DAG.setRoot(Tmp.getValue(1)); return 0; } case Intrinsic::stackrestore: { SDValue Tmp = getValue(I.getOperand(1)); DAG.setRoot(DAG.getNode(ISD::STACKRESTORE, MVT::Other, getRoot(), Tmp)); return 0; } case Intrinsic::var_annotation: // Discard annotate attributes return 0; case Intrinsic::init_trampoline: { const Function *F = cast(I.getOperand(2)->stripPointerCasts()); SDValue Ops[6]; Ops[0] = getRoot(); Ops[1] = getValue(I.getOperand(1)); Ops[2] = getValue(I.getOperand(2)); Ops[3] = getValue(I.getOperand(3)); Ops[4] = DAG.getSrcValue(I.getOperand(1)); Ops[5] = DAG.getSrcValue(F); SDValue Tmp = DAG.getNode(ISD::TRAMPOLINE, DAG.getNodeValueTypes(TLI.getPointerTy(), MVT::Other), 2, Ops, 6); setValue(&I, Tmp); DAG.setRoot(Tmp.getValue(1)); return 0; } case Intrinsic::gcroot: if (GFI) { Value *Alloca = I.getOperand(1); Constant *TypeMap = cast(I.getOperand(2)); FrameIndexSDNode *FI = cast(getValue(Alloca).getNode()); GFI->addStackRoot(FI->getIndex(), TypeMap); } return 0; case Intrinsic::gcread: case Intrinsic::gcwrite: assert(0 && "GC failed to lower gcread/gcwrite intrinsics!"); return 0; case Intrinsic::flt_rounds: { setValue(&I, DAG.getNode(ISD::FLT_ROUNDS_, MVT::i32)); return 0; } case Intrinsic::trap: { DAG.setRoot(DAG.getNode(ISD::TRAP, MVT::Other, getRoot())); return 0; } case Intrinsic::prefetch: { SDValue Ops[4]; Ops[0] = getRoot(); Ops[1] = getValue(I.getOperand(1)); Ops[2] = getValue(I.getOperand(2)); Ops[3] = getValue(I.getOperand(3)); DAG.setRoot(DAG.getNode(ISD::PREFETCH, MVT::Other, &Ops[0], 4)); return 0; } case Intrinsic::memory_barrier: { SDValue Ops[6]; Ops[0] = getRoot(); for (int x = 1; x < 6; ++x) Ops[x] = getValue(I.getOperand(x)); DAG.setRoot(DAG.getNode(ISD::MEMBARRIER, MVT::Other, &Ops[0], 6)); return 0; } case Intrinsic::atomic_cmp_swap: { SDValue Root = getRoot(); SDValue L; switch (getValue(I.getOperand(2)).getValueType().getSimpleVT()) { case MVT::i8: L = DAG.getAtomic(ISD::ATOMIC_CMP_SWAP_8, Root, getValue(I.getOperand(1)), getValue(I.getOperand(2)), getValue(I.getOperand(3)), I.getOperand(1)); break; case MVT::i16: L = DAG.getAtomic(ISD::ATOMIC_CMP_SWAP_16, Root, getValue(I.getOperand(1)), getValue(I.getOperand(2)), getValue(I.getOperand(3)), I.getOperand(1)); break; case MVT::i32: L = DAG.getAtomic(ISD::ATOMIC_CMP_SWAP_32, Root, getValue(I.getOperand(1)), getValue(I.getOperand(2)), getValue(I.getOperand(3)), I.getOperand(1)); break; case MVT::i64: L = DAG.getAtomic(ISD::ATOMIC_CMP_SWAP_64, Root, getValue(I.getOperand(1)), getValue(I.getOperand(2)), getValue(I.getOperand(3)), I.getOperand(1)); break; default: assert(0 && "Invalid atomic type"); abort(); } setValue(&I, L); DAG.setRoot(L.getValue(1)); return 0; } case Intrinsic::atomic_load_add: switch (getValue(I.getOperand(2)).getValueType().getSimpleVT()) { case MVT::i8: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_ADD_8); case MVT::i16: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_ADD_16); case MVT::i32: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_ADD_32); case MVT::i64: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_ADD_64); default: assert(0 && "Invalid atomic type"); abort(); } case Intrinsic::atomic_load_sub: switch (getValue(I.getOperand(2)).getValueType().getSimpleVT()) { case MVT::i8: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_SUB_8); case MVT::i16: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_SUB_16); case MVT::i32: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_SUB_32); case MVT::i64: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_SUB_64); default: assert(0 && "Invalid atomic type"); abort(); } case Intrinsic::atomic_load_or: switch (getValue(I.getOperand(2)).getValueType().getSimpleVT()) { case MVT::i8: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_OR_8); case MVT::i16: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_OR_16); case MVT::i32: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_OR_32); case MVT::i64: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_OR_64); default: assert(0 && "Invalid atomic type"); abort(); } case Intrinsic::atomic_load_xor: switch (getValue(I.getOperand(2)).getValueType().getSimpleVT()) { case MVT::i8: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_XOR_8); case MVT::i16: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_XOR_16); case MVT::i32: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_XOR_32); case MVT::i64: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_XOR_64); default: assert(0 && "Invalid atomic type"); abort(); } case Intrinsic::atomic_load_and: switch (getValue(I.getOperand(2)).getValueType().getSimpleVT()) { case MVT::i8: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_AND_8); case MVT::i16: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_AND_16); case MVT::i32: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_AND_32); case MVT::i64: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_AND_64); default: assert(0 && "Invalid atomic type"); abort(); } case Intrinsic::atomic_load_nand: switch (getValue(I.getOperand(2)).getValueType().getSimpleVT()) { case MVT::i8: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_NAND_8); case MVT::i16: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_NAND_16); case MVT::i32: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_NAND_32); case MVT::i64: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_NAND_64); default: assert(0 && "Invalid atomic type"); abort(); } case Intrinsic::atomic_load_max: switch (getValue(I.getOperand(2)).getValueType().getSimpleVT()) { case MVT::i8: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_MAX_8); case MVT::i16: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_MAX_16); case MVT::i32: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_MAX_32); case MVT::i64: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_MAX_64); default: assert(0 && "Invalid atomic type"); abort(); } case Intrinsic::atomic_load_min: switch (getValue(I.getOperand(2)).getValueType().getSimpleVT()) { case MVT::i8: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_MIN_8); case MVT::i16: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_MIN_16); case MVT::i32: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_MIN_32); case MVT::i64: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_MIN_64); default: assert(0 && "Invalid atomic type"); abort(); } case Intrinsic::atomic_load_umin: switch (getValue(I.getOperand(2)).getValueType().getSimpleVT()) { case MVT::i8: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_UMIN_8); case MVT::i16: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_UMIN_16); case MVT::i32: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_UMIN_32); case MVT::i64: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_UMIN_64); default: assert(0 && "Invalid atomic type"); abort(); } case Intrinsic::atomic_load_umax: switch (getValue(I.getOperand(2)).getValueType().getSimpleVT()) { case MVT::i8: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_UMAX_8); case MVT::i16: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_UMAX_16); case MVT::i32: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_UMAX_32); case MVT::i64: return implVisitBinaryAtomic(I, ISD::ATOMIC_LOAD_UMAX_64); default: assert(0 && "Invalid atomic type"); abort(); } case Intrinsic::atomic_swap: switch (getValue(I.getOperand(2)).getValueType().getSimpleVT()) { case MVT::i8: return implVisitBinaryAtomic(I, ISD::ATOMIC_SWAP_8); case MVT::i16: return implVisitBinaryAtomic(I, ISD::ATOMIC_SWAP_16); case MVT::i32: return implVisitBinaryAtomic(I, ISD::ATOMIC_SWAP_32); case MVT::i64: return implVisitBinaryAtomic(I, ISD::ATOMIC_SWAP_64); default: assert(0 && "Invalid atomic type"); abort(); } } } void SelectionDAGLowering::LowerCallTo(CallSite CS, SDValue Callee, bool IsTailCall, MachineBasicBlock *LandingPad) { const PointerType *PT = cast(CS.getCalledValue()->getType()); const FunctionType *FTy = cast(PT->getElementType()); MachineModuleInfo *MMI = DAG.getMachineModuleInfo(); unsigned BeginLabel = 0, EndLabel = 0; TargetLowering::ArgListTy Args; TargetLowering::ArgListEntry Entry; Args.reserve(CS.arg_size()); for (CallSite::arg_iterator i = CS.arg_begin(), e = CS.arg_end(); i != e; ++i) { SDValue ArgNode = getValue(*i); Entry.Node = ArgNode; Entry.Ty = (*i)->getType(); unsigned attrInd = i - CS.arg_begin() + 1; Entry.isSExt = CS.paramHasAttr(attrInd, ParamAttr::SExt); Entry.isZExt = CS.paramHasAttr(attrInd, ParamAttr::ZExt); Entry.isInReg = CS.paramHasAttr(attrInd, ParamAttr::InReg); Entry.isSRet = CS.paramHasAttr(attrInd, ParamAttr::StructRet); Entry.isNest = CS.paramHasAttr(attrInd, ParamAttr::Nest); Entry.isByVal = CS.paramHasAttr(attrInd, ParamAttr::ByVal); Entry.Alignment = CS.getParamAlignment(attrInd); Args.push_back(Entry); } if (LandingPad && MMI) { // Insert a label before the invoke call to mark the try range. This can be // used to detect deletion of the invoke via the MachineModuleInfo. BeginLabel = MMI->NextLabelID(); // Both PendingLoads and PendingExports must be flushed here; // this call might not return. (void)getRoot(); DAG.setRoot(DAG.getLabel(ISD::EH_LABEL, getControlRoot(), BeginLabel)); } std::pair Result = TLI.LowerCallTo(getRoot(), CS.getType(), CS.paramHasAttr(0, ParamAttr::SExt), CS.paramHasAttr(0, ParamAttr::ZExt), FTy->isVarArg(), CS.getCallingConv(), IsTailCall, Callee, Args, DAG); if (CS.getType() != Type::VoidTy) setValue(CS.getInstruction(), Result.first); DAG.setRoot(Result.second); if (LandingPad && MMI) { // Insert a label at the end of the invoke call to mark the try range. This // can be used to detect deletion of the invoke via the MachineModuleInfo. EndLabel = MMI->NextLabelID(); DAG.setRoot(DAG.getLabel(ISD::EH_LABEL, getRoot(), EndLabel)); // Inform MachineModuleInfo of range. MMI->addInvoke(LandingPad, BeginLabel, EndLabel); } } void SelectionDAGLowering::visitCall(CallInst &I) { const char *RenameFn = 0; if (Function *F = I.getCalledFunction()) { if (F->isDeclaration()) { if (unsigned IID = F->getIntrinsicID()) { RenameFn = visitIntrinsicCall(I, IID); if (!RenameFn) return; } } // Check for well-known libc/libm calls. If the function is internal, it // can't be a library call. unsigned NameLen = F->getNameLen(); if (!F->hasInternalLinkage() && NameLen) { const char *NameStr = F->getNameStart(); if (NameStr[0] == 'c' && ((NameLen == 8 && !strcmp(NameStr, "copysign")) || (NameLen == 9 && !strcmp(NameStr, "copysignf")))) { if (I.getNumOperands() == 3 && // Basic sanity checks. I.getOperand(1)->getType()->isFloatingPoint() && I.getType() == I.getOperand(1)->getType() && I.getType() == I.getOperand(2)->getType()) { SDValue LHS = getValue(I.getOperand(1)); SDValue RHS = getValue(I.getOperand(2)); setValue(&I, DAG.getNode(ISD::FCOPYSIGN, LHS.getValueType(), LHS, RHS)); return; } } else if (NameStr[0] == 'f' && ((NameLen == 4 && !strcmp(NameStr, "fabs")) || (NameLen == 5 && !strcmp(NameStr, "fabsf")) || (NameLen == 5 && !strcmp(NameStr, "fabsl")))) { if (I.getNumOperands() == 2 && // Basic sanity checks. I.getOperand(1)->getType()->isFloatingPoint() && I.getType() == I.getOperand(1)->getType()) { SDValue Tmp = getValue(I.getOperand(1)); setValue(&I, DAG.getNode(ISD::FABS, Tmp.getValueType(), Tmp)); return; } } else if (NameStr[0] == 's' && ((NameLen == 3 && !strcmp(NameStr, "sin")) || (NameLen == 4 && !strcmp(NameStr, "sinf")) || (NameLen == 4 && !strcmp(NameStr, "sinl")))) { if (I.getNumOperands() == 2 && // Basic sanity checks. I.getOperand(1)->getType()->isFloatingPoint() && I.getType() == I.getOperand(1)->getType()) { SDValue Tmp = getValue(I.getOperand(1)); setValue(&I, DAG.getNode(ISD::FSIN, Tmp.getValueType(), Tmp)); return; } } else if (NameStr[0] == 'c' && ((NameLen == 3 && !strcmp(NameStr, "cos")) || (NameLen == 4 && !strcmp(NameStr, "cosf")) || (NameLen == 4 && !strcmp(NameStr, "cosl")))) { if (I.getNumOperands() == 2 && // Basic sanity checks. I.getOperand(1)->getType()->isFloatingPoint() && I.getType() == I.getOperand(1)->getType()) { SDValue Tmp = getValue(I.getOperand(1)); setValue(&I, DAG.getNode(ISD::FCOS, Tmp.getValueType(), Tmp)); return; } } } } else if (isa(I.getOperand(0))) { visitInlineAsm(&I); return; } SDValue Callee; if (!RenameFn) Callee = getValue(I.getOperand(0)); else Callee = DAG.getExternalSymbol(RenameFn, TLI.getPointerTy()); LowerCallTo(&I, Callee, I.isTailCall()); } /// getCopyFromRegs - Emit a series of CopyFromReg nodes that copies from /// this value and returns the result as a ValueVT value. This uses /// Chain/Flag as the input and updates them for the output Chain/Flag. /// If the Flag pointer is NULL, no flag is used. SDValue RegsForValue::getCopyFromRegs(SelectionDAG &DAG, SDValue &Chain, SDValue *Flag) const { // Assemble the legal parts into the final values. SmallVector Values(ValueVTs.size()); SmallVector Parts; for (unsigned Value = 0, Part = 0, e = ValueVTs.size(); Value != e; ++Value) { // Copy the legal parts from the registers. MVT ValueVT = ValueVTs[Value]; unsigned NumRegs = TLI->getNumRegisters(ValueVT); MVT RegisterVT = RegVTs[Value]; Parts.resize(NumRegs); for (unsigned i = 0; i != NumRegs; ++i) { SDValue P; if (Flag == 0) P = DAG.getCopyFromReg(Chain, Regs[Part+i], RegisterVT); else { P = DAG.getCopyFromReg(Chain, Regs[Part+i], RegisterVT, *Flag); *Flag = P.getValue(2); } Chain = P.getValue(1); // If the source register was virtual and if we know something about it, // add an assert node. if (TargetRegisterInfo::isVirtualRegister(Regs[Part+i]) && RegisterVT.isInteger() && !RegisterVT.isVector()) { unsigned SlotNo = Regs[Part+i]-TargetRegisterInfo::FirstVirtualRegister; FunctionLoweringInfo &FLI = DAG.getFunctionLoweringInfo(); if (FLI.LiveOutRegInfo.size() > SlotNo) { FunctionLoweringInfo::LiveOutInfo &LOI = FLI.LiveOutRegInfo[SlotNo]; unsigned RegSize = RegisterVT.getSizeInBits(); unsigned NumSignBits = LOI.NumSignBits; unsigned NumZeroBits = LOI.KnownZero.countLeadingOnes(); // FIXME: We capture more information than the dag can represent. For // now, just use the tightest assertzext/assertsext possible. bool isSExt = true; MVT FromVT(MVT::Other); if (NumSignBits == RegSize) isSExt = true, FromVT = MVT::i1; // ASSERT SEXT 1 else if (NumZeroBits >= RegSize-1) isSExt = false, FromVT = MVT::i1; // ASSERT ZEXT 1 else if (NumSignBits > RegSize-8) isSExt = true, FromVT = MVT::i8; // ASSERT SEXT 8 else if (NumZeroBits >= RegSize-9) isSExt = false, FromVT = MVT::i8; // ASSERT ZEXT 8 else if (NumSignBits > RegSize-16) isSExt = true, FromVT = MVT::i16; // ASSERT SEXT 16 else if (NumZeroBits >= RegSize-17) isSExt = false, FromVT = MVT::i16; // ASSERT ZEXT 16 else if (NumSignBits > RegSize-32) isSExt = true, FromVT = MVT::i32; // ASSERT SEXT 32 else if (NumZeroBits >= RegSize-33) isSExt = false, FromVT = MVT::i32; // ASSERT ZEXT 32 if (FromVT != MVT::Other) { P = DAG.getNode(isSExt ? ISD::AssertSext : ISD::AssertZext, RegisterVT, P, DAG.getValueType(FromVT)); } } } Parts[i] = P; } Values[Value] = getCopyFromParts(DAG, Parts.begin(), NumRegs, RegisterVT, ValueVT); Part += NumRegs; Parts.clear(); } return DAG.getMergeValues(DAG.getVTList(&ValueVTs[0], ValueVTs.size()), &Values[0], ValueVTs.size()); } /// getCopyToRegs - Emit a series of CopyToReg nodes that copies the /// specified value into the registers specified by this object. This uses /// Chain/Flag as the input and updates them for the output Chain/Flag. /// If the Flag pointer is NULL, no flag is used. void RegsForValue::getCopyToRegs(SDValue Val, SelectionDAG &DAG, SDValue &Chain, SDValue *Flag) const { // Get the list of the values's legal parts. unsigned NumRegs = Regs.size(); SmallVector Parts(NumRegs); for (unsigned Value = 0, Part = 0, e = ValueVTs.size(); Value != e; ++Value) { MVT ValueVT = ValueVTs[Value]; unsigned NumParts = TLI->getNumRegisters(ValueVT); MVT RegisterVT = RegVTs[Value]; getCopyToParts(DAG, Val.getValue(Val.getResNo() + Value), &Parts[Part], NumParts, RegisterVT); Part += NumParts; } // Copy the parts into the registers. SmallVector Chains(NumRegs); for (unsigned i = 0; i != NumRegs; ++i) { SDValue Part; if (Flag == 0) Part = DAG.getCopyToReg(Chain, Regs[i], Parts[i]); else { Part = DAG.getCopyToReg(Chain, Regs[i], Parts[i], *Flag); *Flag = Part.getValue(1); } Chains[i] = Part.getValue(0); } if (NumRegs == 1 || Flag) // If NumRegs > 1 && Flag is used then the use of the last CopyToReg is // flagged to it. That is the CopyToReg nodes and the user are considered // a single scheduling unit. If we create a TokenFactor and return it as // chain, then the TokenFactor is both a predecessor (operand) of the // user as well as a successor (the TF operands are flagged to the user). // c1, f1 = CopyToReg // c2, f2 = CopyToReg // c3 = TokenFactor c1, c2 // ... // = op c3, ..., f2 Chain = Chains[NumRegs-1]; else Chain = DAG.getNode(ISD::TokenFactor, MVT::Other, &Chains[0], NumRegs); } /// AddInlineAsmOperands - Add this value to the specified inlineasm node /// operand list. This adds the code marker and includes the number of /// values added into it. void RegsForValue::AddInlineAsmOperands(unsigned Code, SelectionDAG &DAG, std::vector &Ops) const { MVT IntPtrTy = DAG.getTargetLoweringInfo().getPointerTy(); Ops.push_back(DAG.getTargetConstant(Code | (Regs.size() << 3), IntPtrTy)); for (unsigned Value = 0, Reg = 0, e = ValueVTs.size(); Value != e; ++Value) { unsigned NumRegs = TLI->getNumRegisters(ValueVTs[Value]); MVT RegisterVT = RegVTs[Value]; for (unsigned i = 0; i != NumRegs; ++i) Ops.push_back(DAG.getRegister(Regs[Reg++], RegisterVT)); } } /// isAllocatableRegister - If the specified register is safe to allocate, /// i.e. it isn't a stack pointer or some other special register, return the /// register class for the register. Otherwise, return null. static const TargetRegisterClass * isAllocatableRegister(unsigned Reg, MachineFunction &MF, const TargetLowering &TLI, const TargetRegisterInfo *TRI) { MVT FoundVT = MVT::Other; const TargetRegisterClass *FoundRC = 0; for (TargetRegisterInfo::regclass_iterator RCI = TRI->regclass_begin(), E = TRI->regclass_end(); RCI != E; ++RCI) { MVT ThisVT = MVT::Other; const TargetRegisterClass *RC = *RCI; // If none of the the value types for this register class are valid, we // can't use it. For example, 64-bit reg classes on 32-bit targets. for (TargetRegisterClass::vt_iterator I = RC->vt_begin(), E = RC->vt_end(); I != E; ++I) { if (TLI.isTypeLegal(*I)) { // If we have already found this register in a different register class, // choose the one with the largest VT specified. For example, on // PowerPC, we favor f64 register classes over f32. if (FoundVT == MVT::Other || FoundVT.bitsLT(*I)) { ThisVT = *I; break; } } } if (ThisVT == MVT::Other) continue; // NOTE: This isn't ideal. In particular, this might allocate the // frame pointer in functions that need it (due to them not being taken // out of allocation, because a variable sized allocation hasn't been seen // yet). This is a slight code pessimization, but should still work. for (TargetRegisterClass::iterator I = RC->allocation_order_begin(MF), E = RC->allocation_order_end(MF); I != E; ++I) if (*I == Reg) { // We found a matching register class. Keep looking at others in case // we find one with larger registers that this physreg is also in. FoundRC = RC; FoundVT = ThisVT; break; } } return FoundRC; } namespace llvm { /// AsmOperandInfo - This contains information for each constraint that we are /// lowering. struct VISIBILITY_HIDDEN SDISelAsmOperandInfo : public TargetLowering::AsmOperandInfo { /// CallOperand - If this is the result output operand or a clobber /// this is null, otherwise it is the incoming operand to the CallInst. /// This gets modified as the asm is processed. SDValue CallOperand; /// AssignedRegs - If this is a register or register class operand, this /// contains the set of register corresponding to the operand. RegsForValue AssignedRegs; explicit SDISelAsmOperandInfo(const InlineAsm::ConstraintInfo &info) : TargetLowering::AsmOperandInfo(info), CallOperand(0,0) { } /// MarkAllocatedRegs - Once AssignedRegs is set, mark the assigned registers /// busy in OutputRegs/InputRegs. void MarkAllocatedRegs(bool isOutReg, bool isInReg, std::set &OutputRegs, std::set &InputRegs, const TargetRegisterInfo &TRI) const { if (isOutReg) { for (unsigned i = 0, e = AssignedRegs.Regs.size(); i != e; ++i) MarkRegAndAliases(AssignedRegs.Regs[i], OutputRegs, TRI); } if (isInReg) { for (unsigned i = 0, e = AssignedRegs.Regs.size(); i != e; ++i) MarkRegAndAliases(AssignedRegs.Regs[i], InputRegs, TRI); } } private: /// MarkRegAndAliases - Mark the specified register and all aliases in the /// specified set. static void MarkRegAndAliases(unsigned Reg, std::set &Regs, const TargetRegisterInfo &TRI) { assert(TargetRegisterInfo::isPhysicalRegister(Reg) && "Isn't a physreg"); Regs.insert(Reg); if (const unsigned *Aliases = TRI.getAliasSet(Reg)) for (; *Aliases; ++Aliases) Regs.insert(*Aliases); } }; } // end llvm namespace. /// GetRegistersForValue - Assign registers (virtual or physical) for the /// specified operand. We prefer to assign virtual registers, to allow the /// register allocator handle the assignment process. However, if the asm uses /// features that we can't model on machineinstrs, we have SDISel do the /// allocation. This produces generally horrible, but correct, code. /// /// OpInfo describes the operand. /// HasEarlyClobber is true if there are any early clobber constraints (=&r) /// or any explicitly clobbered registers. /// Input and OutputRegs are the set of already allocated physical registers. /// void SelectionDAGLowering:: GetRegistersForValue(SDISelAsmOperandInfo &OpInfo, bool HasEarlyClobber, std::set &OutputRegs, std::set &InputRegs) { // Compute whether this value requires an input register, an output register, // or both. bool isOutReg = false; bool isInReg = false; switch (OpInfo.Type) { case InlineAsm::isOutput: isOutReg = true; // If this is an early-clobber output, or if there is an input // constraint that matches this, we need to reserve the input register // so no other inputs allocate to it. isInReg = OpInfo.isEarlyClobber || OpInfo.hasMatchingInput; break; case InlineAsm::isInput: isInReg = true; isOutReg = false; break; case InlineAsm::isClobber: isOutReg = true; isInReg = true; break; } MachineFunction &MF = DAG.getMachineFunction(); SmallVector Regs; // If this is a constraint for a single physreg, or a constraint for a // register class, find it. std::pair PhysReg = TLI.getRegForInlineAsmConstraint(OpInfo.ConstraintCode, OpInfo.ConstraintVT); unsigned NumRegs = 1; if (OpInfo.ConstraintVT != MVT::Other) NumRegs = TLI.getNumRegisters(OpInfo.ConstraintVT); MVT RegVT; MVT ValueVT = OpInfo.ConstraintVT; // If this is a constraint for a specific physical register, like {r17}, // assign it now. if (PhysReg.first) { if (OpInfo.ConstraintVT == MVT::Other) ValueVT = *PhysReg.second->vt_begin(); // Get the actual register value type. This is important, because the user // may have asked for (e.g.) the AX register in i32 type. We need to // remember that AX is actually i16 to get the right extension. RegVT = *PhysReg.second->vt_begin(); // This is a explicit reference to a physical register. Regs.push_back(PhysReg.first); // If this is an expanded reference, add the rest of the regs to Regs. if (NumRegs != 1) { TargetRegisterClass::iterator I = PhysReg.second->begin(); for (; *I != PhysReg.first; ++I) assert(I != PhysReg.second->end() && "Didn't find reg!"); // Already added the first reg. --NumRegs; ++I; for (; NumRegs; --NumRegs, ++I) { assert(I != PhysReg.second->end() && "Ran out of registers to allocate!"); Regs.push_back(*I); } } OpInfo.AssignedRegs = RegsForValue(TLI, Regs, RegVT, ValueVT); const TargetRegisterInfo *TRI = DAG.getTarget().getRegisterInfo(); OpInfo.MarkAllocatedRegs(isOutReg, isInReg, OutputRegs, InputRegs, *TRI); return; } // Otherwise, if this was a reference to an LLVM register class, create vregs // for this reference. std::vector RegClassRegs; const TargetRegisterClass *RC = PhysReg.second; if (RC) { // If this is an early clobber or tied register, our regalloc doesn't know // how to maintain the constraint. If it isn't, go ahead and create vreg // and let the regalloc do the right thing. if (!OpInfo.hasMatchingInput && !OpInfo.isEarlyClobber && // If there is some other early clobber and this is an input register, // then we are forced to pre-allocate the input reg so it doesn't // conflict with the earlyclobber. !(OpInfo.Type == InlineAsm::isInput && HasEarlyClobber)) { RegVT = *PhysReg.second->vt_begin(); if (OpInfo.ConstraintVT == MVT::Other) ValueVT = RegVT; // Create the appropriate number of virtual registers. MachineRegisterInfo &RegInfo = MF.getRegInfo(); for (; NumRegs; --NumRegs) Regs.push_back(RegInfo.createVirtualRegister(PhysReg.second)); OpInfo.AssignedRegs = RegsForValue(TLI, Regs, RegVT, ValueVT); return; } // Otherwise, we can't allocate it. Let the code below figure out how to // maintain these constraints. RegClassRegs.assign(PhysReg.second->begin(), PhysReg.second->end()); } else { // This is a reference to a register class that doesn't directly correspond // to an LLVM register class. Allocate NumRegs consecutive, available, // registers from the class. RegClassRegs = TLI.getRegClassForInlineAsmConstraint(OpInfo.ConstraintCode, OpInfo.ConstraintVT); } const TargetRegisterInfo *TRI = DAG.getTarget().getRegisterInfo(); unsigned NumAllocated = 0; for (unsigned i = 0, e = RegClassRegs.size(); i != e; ++i) { unsigned Reg = RegClassRegs[i]; // See if this register is available. if ((isOutReg && OutputRegs.count(Reg)) || // Already used. (isInReg && InputRegs.count(Reg))) { // Already used. // Make sure we find consecutive registers. NumAllocated = 0; continue; } // Check to see if this register is allocatable (i.e. don't give out the // stack pointer). if (RC == 0) { RC = isAllocatableRegister(Reg, MF, TLI, TRI); if (!RC) { // Couldn't allocate this register. // Reset NumAllocated to make sure we return consecutive registers. NumAllocated = 0; continue; } } // Okay, this register is good, we can use it. ++NumAllocated; // If we allocated enough consecutive registers, succeed. if (NumAllocated == NumRegs) { unsigned RegStart = (i-NumAllocated)+1; unsigned RegEnd = i+1; // Mark all of the allocated registers used. for (unsigned i = RegStart; i != RegEnd; ++i) Regs.push_back(RegClassRegs[i]); OpInfo.AssignedRegs = RegsForValue(TLI, Regs, *RC->vt_begin(), OpInfo.ConstraintVT); OpInfo.MarkAllocatedRegs(isOutReg, isInReg, OutputRegs, InputRegs, *TRI); return; } } // Otherwise, we couldn't allocate enough registers for this. } /// visitInlineAsm - Handle a call to an InlineAsm object. /// void SelectionDAGLowering::visitInlineAsm(CallSite CS) { InlineAsm *IA = cast(CS.getCalledValue()); /// ConstraintOperands - Information about all of the constraints. std::vector ConstraintOperands; SDValue Chain = getRoot(); SDValue Flag; std::set OutputRegs, InputRegs; // Do a prepass over the constraints, canonicalizing them, and building up the // ConstraintOperands list. std::vector ConstraintInfos = IA->ParseConstraints(); // SawEarlyClobber - Keep track of whether we saw an earlyclobber output // constraint. If so, we can't let the register allocator allocate any input // registers, because it will not know to avoid the earlyclobbered output reg. bool SawEarlyClobber = false; unsigned ArgNo = 0; // ArgNo - The argument of the CallInst. unsigned ResNo = 0; // ResNo - The result number of the next output. for (unsigned i = 0, e = ConstraintInfos.size(); i != e; ++i) { ConstraintOperands.push_back(SDISelAsmOperandInfo(ConstraintInfos[i])); SDISelAsmOperandInfo &OpInfo = ConstraintOperands.back(); MVT OpVT = MVT::Other; // Compute the value type for each operand. switch (OpInfo.Type) { case InlineAsm::isOutput: // Indirect outputs just consume an argument. if (OpInfo.isIndirect) { OpInfo.CallOperandVal = CS.getArgument(ArgNo++); break; } // The return value of the call is this value. As such, there is no // corresponding argument. assert(CS.getType() != Type::VoidTy && "Bad inline asm!"); if (const StructType *STy = dyn_cast(CS.getType())) { OpVT = TLI.getValueType(STy->getElementType(ResNo)); } else { assert(ResNo == 0 && "Asm only has one result!"); OpVT = TLI.getValueType(CS.getType()); } ++ResNo; break; case InlineAsm::isInput: OpInfo.CallOperandVal = CS.getArgument(ArgNo++); break; case InlineAsm::isClobber: // Nothing to do. break; } // If this is an input or an indirect output, process the call argument. // BasicBlocks are labels, currently appearing only in asm's. if (OpInfo.CallOperandVal) { if (BasicBlock *BB = dyn_cast(OpInfo.CallOperandVal)) OpInfo.CallOperand = DAG.getBasicBlock(FuncInfo.MBBMap[BB]); else { OpInfo.CallOperand = getValue(OpInfo.CallOperandVal); const Type *OpTy = OpInfo.CallOperandVal->getType(); // If this is an indirect operand, the operand is a pointer to the // accessed type. if (OpInfo.isIndirect) OpTy = cast(OpTy)->getElementType(); // If OpTy is not a single value, it may be a struct/union that we // can tile with integers. if (!OpTy->isSingleValueType() && OpTy->isSized()) { unsigned BitSize = TD->getTypeSizeInBits(OpTy); switch (BitSize) { default: break; case 1: case 8: case 16: case 32: case 64: OpTy = IntegerType::get(BitSize); break; } } OpVT = TLI.getValueType(OpTy, true); } } OpInfo.ConstraintVT = OpVT; // Compute the constraint code and ConstraintType to use. TLI.ComputeConstraintToUse(OpInfo, OpInfo.CallOperand, &DAG); // Keep track of whether we see an earlyclobber. SawEarlyClobber |= OpInfo.isEarlyClobber; // If we see a clobber of a register, it is an early clobber. if (!SawEarlyClobber && OpInfo.Type == InlineAsm::isClobber && OpInfo.ConstraintType == TargetLowering::C_Register) { // Note that we want to ignore things that we don't track here, like // dirflag, fpsr, flags, etc. std::pair PhysReg = TLI.getRegForInlineAsmConstraint(OpInfo.ConstraintCode, OpInfo.ConstraintVT); if (PhysReg.first || PhysReg.second) { // This is a register we know of. SawEarlyClobber = true; } } // If this is a memory input, and if the operand is not indirect, do what we // need to to provide an address for the memory input. if (OpInfo.ConstraintType == TargetLowering::C_Memory && !OpInfo.isIndirect) { assert(OpInfo.Type == InlineAsm::isInput && "Can only indirectify direct input operands!"); // Memory operands really want the address of the value. If we don't have // an indirect input, put it in the constpool if we can, otherwise spill // it to a stack slot. // If the operand is a float, integer, or vector constant, spill to a // constant pool entry to get its address. Value *OpVal = OpInfo.CallOperandVal; if (isa(OpVal) || isa(OpVal) || isa(OpVal)) { OpInfo.CallOperand = DAG.getConstantPool(cast(OpVal), TLI.getPointerTy()); } else { // Otherwise, create a stack slot and emit a store to it before the // asm. const Type *Ty = OpVal->getType(); uint64_t TySize = TLI.getTargetData()->getABITypeSize(Ty); unsigned Align = TLI.getTargetData()->getPrefTypeAlignment(Ty); MachineFunction &MF = DAG.getMachineFunction(); int SSFI = MF.getFrameInfo()->CreateStackObject(TySize, Align); SDValue StackSlot = DAG.getFrameIndex(SSFI, TLI.getPointerTy()); Chain = DAG.getStore(Chain, OpInfo.CallOperand, StackSlot, NULL, 0); OpInfo.CallOperand = StackSlot; } // There is no longer a Value* corresponding to this operand. OpInfo.CallOperandVal = 0; // It is now an indirect operand. OpInfo.isIndirect = true; } // If this constraint is for a specific register, allocate it before // anything else. if (OpInfo.ConstraintType == TargetLowering::C_Register) GetRegistersForValue(OpInfo, SawEarlyClobber, OutputRegs, InputRegs); } ConstraintInfos.clear(); // Second pass - Loop over all of the operands, assigning virtual or physregs // to registerclass operands. for (unsigned i = 0, e = ConstraintOperands.size(); i != e; ++i) { SDISelAsmOperandInfo &OpInfo = ConstraintOperands[i]; // C_Register operands have already been allocated, Other/Memory don't need // to be. if (OpInfo.ConstraintType == TargetLowering::C_RegisterClass) GetRegistersForValue(OpInfo, SawEarlyClobber, OutputRegs, InputRegs); } // AsmNodeOperands - The operands for the ISD::INLINEASM node. std::vector AsmNodeOperands; AsmNodeOperands.push_back(SDValue()); // reserve space for input chain AsmNodeOperands.push_back( DAG.getTargetExternalSymbol(IA->getAsmString().c_str(), MVT::Other)); // Loop over all of the inputs, copying the operand values into the // appropriate registers and processing the output regs. RegsForValue RetValRegs; // IndirectStoresToEmit - The set of stores to emit after the inline asm node. std::vector > IndirectStoresToEmit; for (unsigned i = 0, e = ConstraintOperands.size(); i != e; ++i) { SDISelAsmOperandInfo &OpInfo = ConstraintOperands[i]; switch (OpInfo.Type) { case InlineAsm::isOutput: { if (OpInfo.ConstraintType != TargetLowering::C_RegisterClass && OpInfo.ConstraintType != TargetLowering::C_Register) { // Memory output, or 'other' output (e.g. 'X' constraint). assert(OpInfo.isIndirect && "Memory output must be indirect operand"); // Add information to the INLINEASM node to know about this output. unsigned ResOpType = 4/*MEM*/ | (1 << 3); AsmNodeOperands.push_back(DAG.getTargetConstant(ResOpType, TLI.getPointerTy())); AsmNodeOperands.push_back(OpInfo.CallOperand); break; } // Otherwise, this is a register or register class output. // Copy the output from the appropriate register. Find a register that // we can use. if (OpInfo.AssignedRegs.Regs.empty()) { cerr << "Couldn't allocate output reg for constraint '" << OpInfo.ConstraintCode << "'!\n"; exit(1); } // If this is an indirect operand, store through the pointer after the // asm. if (OpInfo.isIndirect) { IndirectStoresToEmit.push_back(std::make_pair(OpInfo.AssignedRegs, OpInfo.CallOperandVal)); } else { // This is the result value of the call. assert(CS.getType() != Type::VoidTy && "Bad inline asm!"); // Concatenate this output onto the outputs list. RetValRegs.append(OpInfo.AssignedRegs); } // Add information to the INLINEASM node to know that this register is // set. OpInfo.AssignedRegs.AddInlineAsmOperands(2 /*REGDEF*/, DAG, AsmNodeOperands); break; } case InlineAsm::isInput: { SDValue InOperandVal = OpInfo.CallOperand; if (isdigit(OpInfo.ConstraintCode[0])) { // Matching constraint? // If this is required to match an output register we have already set, // just use its register. unsigned OperandNo = atoi(OpInfo.ConstraintCode.c_str()); // Scan until we find the definition we already emitted of this operand. // When we find it, create a RegsForValue operand. unsigned CurOp = 2; // The first operand. for (; OperandNo; --OperandNo) { // Advance to the next operand. unsigned NumOps = cast(AsmNodeOperands[CurOp])->getValue(); assert(((NumOps & 7) == 2 /*REGDEF*/ || (NumOps & 7) == 4 /*MEM*/) && "Skipped past definitions?"); CurOp += (NumOps>>3)+1; } unsigned NumOps = cast(AsmNodeOperands[CurOp])->getValue(); if ((NumOps & 7) == 2 /*REGDEF*/) { // Add NumOps>>3 registers to MatchedRegs. RegsForValue MatchedRegs; MatchedRegs.TLI = &TLI; MatchedRegs.ValueVTs.push_back(InOperandVal.getValueType()); MatchedRegs.RegVTs.push_back(AsmNodeOperands[CurOp+1].getValueType()); for (unsigned i = 0, e = NumOps>>3; i != e; ++i) { unsigned Reg = cast(AsmNodeOperands[++CurOp])->getReg(); MatchedRegs.Regs.push_back(Reg); } // Use the produced MatchedRegs object to MatchedRegs.getCopyToRegs(InOperandVal, DAG, Chain, &Flag); MatchedRegs.AddInlineAsmOperands(1 /*REGUSE*/, DAG, AsmNodeOperands); break; } else { assert((NumOps & 7) == 4/*MEM*/ && "Unknown matching constraint!"); assert((NumOps >> 3) == 1 && "Unexpected number of operands"); // Add information to the INLINEASM node to know about this input. unsigned ResOpType = 4/*MEM*/ | (1 << 3); AsmNodeOperands.push_back(DAG.getTargetConstant(ResOpType, TLI.getPointerTy())); AsmNodeOperands.push_back(AsmNodeOperands[CurOp+1]); break; } } if (OpInfo.ConstraintType == TargetLowering::C_Other) { assert(!OpInfo.isIndirect && "Don't know how to handle indirect other inputs yet!"); std::vector Ops; TLI.LowerAsmOperandForConstraint(InOperandVal, OpInfo.ConstraintCode[0], Ops, DAG); if (Ops.empty()) { cerr << "Invalid operand for inline asm constraint '" << OpInfo.ConstraintCode << "'!\n"; exit(1); } // Add information to the INLINEASM node to know about this input. unsigned ResOpType = 3 /*IMM*/ | (Ops.size() << 3); AsmNodeOperands.push_back(DAG.getTargetConstant(ResOpType, TLI.getPointerTy())); AsmNodeOperands.insert(AsmNodeOperands.end(), Ops.begin(), Ops.end()); break; } else if (OpInfo.ConstraintType == TargetLowering::C_Memory) { assert(OpInfo.isIndirect && "Operand must be indirect to be a mem!"); assert(InOperandVal.getValueType() == TLI.getPointerTy() && "Memory operands expect pointer values"); // Add information to the INLINEASM node to know about this input. unsigned ResOpType = 4/*MEM*/ | (1 << 3); AsmNodeOperands.push_back(DAG.getTargetConstant(ResOpType, TLI.getPointerTy())); AsmNodeOperands.push_back(InOperandVal); break; } assert((OpInfo.ConstraintType == TargetLowering::C_RegisterClass || OpInfo.ConstraintType == TargetLowering::C_Register) && "Unknown constraint type!"); assert(!OpInfo.isIndirect && "Don't know how to handle indirect register inputs yet!"); // Copy the input into the appropriate registers. assert(!OpInfo.AssignedRegs.Regs.empty() && "Couldn't allocate input reg!"); OpInfo.AssignedRegs.getCopyToRegs(InOperandVal, DAG, Chain, &Flag); OpInfo.AssignedRegs.AddInlineAsmOperands(1/*REGUSE*/, DAG, AsmNodeOperands); break; } case InlineAsm::isClobber: { // Add the clobbered value to the operand list, so that the register // allocator is aware that the physreg got clobbered. if (!OpInfo.AssignedRegs.Regs.empty()) OpInfo.AssignedRegs.AddInlineAsmOperands(2/*REGDEF*/, DAG, AsmNodeOperands); break; } } } // Finish up input operands. AsmNodeOperands[0] = Chain; if (Flag.getNode()) AsmNodeOperands.push_back(Flag); Chain = DAG.getNode(ISD::INLINEASM, DAG.getNodeValueTypes(MVT::Other, MVT::Flag), 2, &AsmNodeOperands[0], AsmNodeOperands.size()); Flag = Chain.getValue(1); // If this asm returns a register value, copy the result from that register // and set it as the value of the call. if (!RetValRegs.Regs.empty()) { SDValue Val = RetValRegs.getCopyFromRegs(DAG, Chain, &Flag); // If any of the results of the inline asm is a vector, it may have the // wrong width/num elts. This can happen for register classes that can // contain multiple different value types. The preg or vreg allocated may // not have the same VT as was expected. Convert it to the right type with // bit_convert. if (const StructType *ResSTy = dyn_cast(CS.getType())) { for (unsigned i = 0, e = ResSTy->getNumElements(); i != e; ++i) { if (Val.getNode()->getValueType(i).isVector()) Val = DAG.getNode(ISD::BIT_CONVERT, TLI.getValueType(ResSTy->getElementType(i)), Val); } } else { if (Val.getValueType().isVector()) Val = DAG.getNode(ISD::BIT_CONVERT, TLI.getValueType(CS.getType()), Val); } setValue(CS.getInstruction(), Val); } std::vector > StoresToEmit; // Process indirect outputs, first output all of the flagged copies out of // physregs. for (unsigned i = 0, e = IndirectStoresToEmit.size(); i != e; ++i) { RegsForValue &OutRegs = IndirectStoresToEmit[i].first; Value *Ptr = IndirectStoresToEmit[i].second; SDValue OutVal = OutRegs.getCopyFromRegs(DAG, Chain, &Flag); StoresToEmit.push_back(std::make_pair(OutVal, Ptr)); } // Emit the non-flagged stores from the physregs. SmallVector OutChains; for (unsigned i = 0, e = StoresToEmit.size(); i != e; ++i) OutChains.push_back(DAG.getStore(Chain, StoresToEmit[i].first, getValue(StoresToEmit[i].second), StoresToEmit[i].second, 0)); if (!OutChains.empty()) Chain = DAG.getNode(ISD::TokenFactor, MVT::Other, &OutChains[0], OutChains.size()); DAG.setRoot(Chain); } void SelectionDAGLowering::visitMalloc(MallocInst &I) { SDValue Src = getValue(I.getOperand(0)); MVT IntPtr = TLI.getPointerTy(); if (IntPtr.bitsLT(Src.getValueType())) Src = DAG.getNode(ISD::TRUNCATE, IntPtr, Src); else if (IntPtr.bitsGT(Src.getValueType())) Src = DAG.getNode(ISD::ZERO_EXTEND, IntPtr, Src); // Scale the source by the type size. uint64_t ElementSize = TD->getABITypeSize(I.getType()->getElementType()); Src = DAG.getNode(ISD::MUL, Src.getValueType(), Src, DAG.getIntPtrConstant(ElementSize)); TargetLowering::ArgListTy Args; TargetLowering::ArgListEntry Entry; Entry.Node = Src; Entry.Ty = TLI.getTargetData()->getIntPtrType(); Args.push_back(Entry); std::pair Result = TLI.LowerCallTo(getRoot(), I.getType(), false, false, false, CallingConv::C, true, DAG.getExternalSymbol("malloc", IntPtr), Args, DAG); setValue(&I, Result.first); // Pointers always fit in registers DAG.setRoot(Result.second); } void SelectionDAGLowering::visitFree(FreeInst &I) { TargetLowering::ArgListTy Args; TargetLowering::ArgListEntry Entry; Entry.Node = getValue(I.getOperand(0)); Entry.Ty = TLI.getTargetData()->getIntPtrType(); Args.push_back(Entry); MVT IntPtr = TLI.getPointerTy(); std::pair Result = TLI.LowerCallTo(getRoot(), Type::VoidTy, false, false, false, CallingConv::C, true, DAG.getExternalSymbol("free", IntPtr), Args, DAG); DAG.setRoot(Result.second); } void SelectionDAGLowering::visitVAStart(CallInst &I) { DAG.setRoot(DAG.getNode(ISD::VASTART, MVT::Other, getRoot(), getValue(I.getOperand(1)), DAG.getSrcValue(I.getOperand(1)))); } void SelectionDAGLowering::visitVAArg(VAArgInst &I) { SDValue V = DAG.getVAArg(TLI.getValueType(I.getType()), getRoot(), getValue(I.getOperand(0)), DAG.getSrcValue(I.getOperand(0))); setValue(&I, V); DAG.setRoot(V.getValue(1)); } void SelectionDAGLowering::visitVAEnd(CallInst &I) { DAG.setRoot(DAG.getNode(ISD::VAEND, MVT::Other, getRoot(), getValue(I.getOperand(1)), DAG.getSrcValue(I.getOperand(1)))); } void SelectionDAGLowering::visitVACopy(CallInst &I) { DAG.setRoot(DAG.getNode(ISD::VACOPY, MVT::Other, getRoot(), getValue(I.getOperand(1)), getValue(I.getOperand(2)), DAG.getSrcValue(I.getOperand(1)), DAG.getSrcValue(I.getOperand(2)))); } /// TargetLowering::LowerArguments - This is the default LowerArguments /// implementation, which just inserts a FORMAL_ARGUMENTS node. FIXME: When all /// targets are migrated to using FORMAL_ARGUMENTS, this hook should be /// integrated into SDISel. void TargetLowering::LowerArguments(Function &F, SelectionDAG &DAG, SmallVectorImpl &ArgValues) { // Add CC# and isVararg as operands to the FORMAL_ARGUMENTS node. SmallVector Ops; Ops.push_back(DAG.getRoot()); Ops.push_back(DAG.getConstant(F.getCallingConv(), getPointerTy())); Ops.push_back(DAG.getConstant(F.isVarArg(), getPointerTy())); // Add one result value for each formal argument. SmallVector RetVals; unsigned j = 1; for (Function::arg_iterator I = F.arg_begin(), E = F.arg_end(); I != E; ++I, ++j) { SmallVector ValueVTs; ComputeValueVTs(*this, I->getType(), ValueVTs); for (unsigned Value = 0, NumValues = ValueVTs.size(); Value != NumValues; ++Value) { MVT VT = ValueVTs[Value]; const Type *ArgTy = VT.getTypeForMVT(); ISD::ArgFlagsTy Flags; unsigned OriginalAlignment = getTargetData()->getABITypeAlignment(ArgTy); if (F.paramHasAttr(j, ParamAttr::ZExt)) Flags.setZExt(); if (F.paramHasAttr(j, ParamAttr::SExt)) Flags.setSExt(); if (F.paramHasAttr(j, ParamAttr::InReg)) Flags.setInReg(); if (F.paramHasAttr(j, ParamAttr::StructRet)) Flags.setSRet(); if (F.paramHasAttr(j, ParamAttr::ByVal)) { Flags.setByVal(); const PointerType *Ty = cast(I->getType()); const Type *ElementTy = Ty->getElementType(); unsigned FrameAlign = getByValTypeAlignment(ElementTy); unsigned FrameSize = getTargetData()->getABITypeSize(ElementTy); // For ByVal, alignment should be passed from FE. BE will guess if // this info is not there but there are cases it cannot get right. if (F.getParamAlignment(j)) FrameAlign = F.getParamAlignment(j); Flags.setByValAlign(FrameAlign); Flags.setByValSize(FrameSize); } if (F.paramHasAttr(j, ParamAttr::Nest)) Flags.setNest(); Flags.setOrigAlign(OriginalAlignment); MVT RegisterVT = getRegisterType(VT); unsigned NumRegs = getNumRegisters(VT); for (unsigned i = 0; i != NumRegs; ++i) { RetVals.push_back(RegisterVT); ISD::ArgFlagsTy MyFlags = Flags; if (NumRegs > 1 && i == 0) MyFlags.setSplit(); // if it isn't first piece, alignment must be 1 else if (i > 0) MyFlags.setOrigAlign(1); Ops.push_back(DAG.getArgFlags(MyFlags)); } } } RetVals.push_back(MVT::Other); // Create the node. SDNode *Result = DAG.getNode(ISD::FORMAL_ARGUMENTS, DAG.getVTList(&RetVals[0], RetVals.size()), &Ops[0], Ops.size()).getNode(); // Prelower FORMAL_ARGUMENTS. This isn't required for functionality, but // allows exposing the loads that may be part of the argument access to the // first DAGCombiner pass. SDValue TmpRes = LowerOperation(SDValue(Result, 0), DAG); // The number of results should match up, except that the lowered one may have // an extra flag result. assert((Result->getNumValues() == TmpRes.getNode()->getNumValues() || (Result->getNumValues()+1 == TmpRes.getNode()->getNumValues() && TmpRes.getValue(Result->getNumValues()).getValueType() == MVT::Flag)) && "Lowering produced unexpected number of results!"); // The FORMAL_ARGUMENTS node itself is likely no longer needed. if (Result != TmpRes.getNode() && Result->use_empty()) { HandleSDNode Dummy(DAG.getRoot()); DAG.RemoveDeadNode(Result); } Result = TmpRes.getNode(); unsigned NumArgRegs = Result->getNumValues() - 1; DAG.setRoot(SDValue(Result, NumArgRegs)); // Set up the return result vector. unsigned i = 0; unsigned Idx = 1; for (Function::arg_iterator I = F.arg_begin(), E = F.arg_end(); I != E; ++I, ++Idx) { SmallVector ValueVTs; ComputeValueVTs(*this, I->getType(), ValueVTs); for (unsigned Value = 0, NumValues = ValueVTs.size(); Value != NumValues; ++Value) { MVT VT = ValueVTs[Value]; MVT PartVT = getRegisterType(VT); unsigned NumParts = getNumRegisters(VT); SmallVector Parts(NumParts); for (unsigned j = 0; j != NumParts; ++j) Parts[j] = SDValue(Result, i++); ISD::NodeType AssertOp = ISD::DELETED_NODE; if (F.paramHasAttr(Idx, ParamAttr::SExt)) AssertOp = ISD::AssertSext; else if (F.paramHasAttr(Idx, ParamAttr::ZExt)) AssertOp = ISD::AssertZext; ArgValues.push_back(getCopyFromParts(DAG, &Parts[0], NumParts, PartVT, VT, AssertOp)); } } assert(i == NumArgRegs && "Argument register count mismatch!"); } /// TargetLowering::LowerCallTo - This is the default LowerCallTo /// implementation, which just inserts an ISD::CALL node, which is later custom /// lowered by the target to something concrete. FIXME: When all targets are /// migrated to using ISD::CALL, this hook should be integrated into SDISel. std::pair TargetLowering::LowerCallTo(SDValue Chain, const Type *RetTy, bool RetSExt, bool RetZExt, bool isVarArg, unsigned CallingConv, bool isTailCall, SDValue Callee, ArgListTy &Args, SelectionDAG &DAG) { SmallVector Ops; Ops.push_back(Chain); // Op#0 - Chain Ops.push_back(DAG.getConstant(CallingConv, getPointerTy())); // Op#1 - CC Ops.push_back(DAG.getConstant(isVarArg, getPointerTy())); // Op#2 - VarArg Ops.push_back(DAG.getConstant(isTailCall, getPointerTy())); // Op#3 - Tail Ops.push_back(Callee); // Handle all of the outgoing arguments. for (unsigned i = 0, e = Args.size(); i != e; ++i) { SmallVector ValueVTs; ComputeValueVTs(*this, Args[i].Ty, ValueVTs); for (unsigned Value = 0, NumValues = ValueVTs.size(); Value != NumValues; ++Value) { MVT VT = ValueVTs[Value]; const Type *ArgTy = VT.getTypeForMVT(); SDValue Op = SDValue(Args[i].Node.getNode(), Args[i].Node.getResNo() + Value); ISD::ArgFlagsTy Flags; unsigned OriginalAlignment = getTargetData()->getABITypeAlignment(ArgTy); if (Args[i].isZExt) Flags.setZExt(); if (Args[i].isSExt) Flags.setSExt(); if (Args[i].isInReg) Flags.setInReg(); if (Args[i].isSRet) Flags.setSRet(); if (Args[i].isByVal) { Flags.setByVal(); const PointerType *Ty = cast(Args[i].Ty); const Type *ElementTy = Ty->getElementType(); unsigned FrameAlign = getByValTypeAlignment(ElementTy); unsigned FrameSize = getTargetData()->getABITypeSize(ElementTy); // For ByVal, alignment should come from FE. BE will guess if this // info is not there but there are cases it cannot get right. if (Args[i].Alignment) FrameAlign = Args[i].Alignment; Flags.setByValAlign(FrameAlign); Flags.setByValSize(FrameSize); } if (Args[i].isNest) Flags.setNest(); Flags.setOrigAlign(OriginalAlignment); MVT PartVT = getRegisterType(VT); unsigned NumParts = getNumRegisters(VT); SmallVector Parts(NumParts); ISD::NodeType ExtendKind = ISD::ANY_EXTEND; if (Args[i].isSExt) ExtendKind = ISD::SIGN_EXTEND; else if (Args[i].isZExt) ExtendKind = ISD::ZERO_EXTEND; getCopyToParts(DAG, Op, &Parts[0], NumParts, PartVT, ExtendKind); for (unsigned i = 0; i != NumParts; ++i) { // if it isn't first piece, alignment must be 1 ISD::ArgFlagsTy MyFlags = Flags; if (NumParts > 1 && i == 0) MyFlags.setSplit(); else if (i != 0) MyFlags.setOrigAlign(1); Ops.push_back(Parts[i]); Ops.push_back(DAG.getArgFlags(MyFlags)); } } } // Figure out the result value types. We start by making a list of // the potentially illegal return value types. SmallVector LoweredRetTys; SmallVector RetTys; ComputeValueVTs(*this, RetTy, RetTys); // Then we translate that to a list of legal types. for (unsigned I = 0, E = RetTys.size(); I != E; ++I) { MVT VT = RetTys[I]; MVT RegisterVT = getRegisterType(VT); unsigned NumRegs = getNumRegisters(VT); for (unsigned i = 0; i != NumRegs; ++i) LoweredRetTys.push_back(RegisterVT); } LoweredRetTys.push_back(MVT::Other); // Always has a chain. // Create the CALL node. SDValue Res = DAG.getNode(ISD::CALL, DAG.getVTList(&LoweredRetTys[0], LoweredRetTys.size()), &Ops[0], Ops.size()); Chain = Res.getValue(LoweredRetTys.size() - 1); // Gather up the call result into a single value. if (RetTy != Type::VoidTy) { ISD::NodeType AssertOp = ISD::DELETED_NODE; if (RetSExt) AssertOp = ISD::AssertSext; else if (RetZExt) AssertOp = ISD::AssertZext; SmallVector ReturnValues; unsigned RegNo = 0; for (unsigned I = 0, E = RetTys.size(); I != E; ++I) { MVT VT = RetTys[I]; MVT RegisterVT = getRegisterType(VT); unsigned NumRegs = getNumRegisters(VT); unsigned RegNoEnd = NumRegs + RegNo; SmallVector Results; for (; RegNo != RegNoEnd; ++RegNo) Results.push_back(Res.getValue(RegNo)); SDValue ReturnValue = getCopyFromParts(DAG, &Results[0], NumRegs, RegisterVT, VT, AssertOp); ReturnValues.push_back(ReturnValue); } Res = DAG.getMergeValues(DAG.getVTList(&RetTys[0], RetTys.size()), &ReturnValues[0], ReturnValues.size()); } return std::make_pair(Res, Chain); } SDValue TargetLowering::LowerOperation(SDValue Op, SelectionDAG &DAG) { assert(0 && "LowerOperation not implemented for this target!"); abort(); return SDValue(); } void SelectionDAGLowering::CopyValueToVirtualRegister(Value *V, unsigned Reg) { SDValue Op = getValue(V); assert((Op.getOpcode() != ISD::CopyFromReg || cast(Op.getOperand(1))->getReg() != Reg) && "Copy from a reg to the same reg!"); assert(!TargetRegisterInfo::isPhysicalRegister(Reg) && "Is a physreg"); RegsForValue RFV(TLI, Reg, V->getType()); SDValue Chain = DAG.getEntryNode(); RFV.getCopyToRegs(Op, DAG, Chain, 0); PendingExports.push_back(Chain); } #include "llvm/CodeGen/SelectionDAGISel.h" void SelectionDAGISel:: LowerArguments(BasicBlock *LLVMBB) { // If this is the entry block, emit arguments. Function &F = *LLVMBB->getParent(); SDValue OldRoot = SDL->DAG.getRoot(); SmallVector Args; TLI.LowerArguments(F, SDL->DAG, Args); unsigned a = 0; for (Function::arg_iterator AI = F.arg_begin(), E = F.arg_end(); AI != E; ++AI) { SmallVector ValueVTs; ComputeValueVTs(TLI, AI->getType(), ValueVTs); unsigned NumValues = ValueVTs.size(); if (!AI->use_empty()) { SDL->setValue(AI, SDL->DAG.getMergeValues(&Args[a], NumValues)); // If this argument is live outside of the entry block, insert a copy from // whereever we got it to the vreg that other BB's will reference it as. DenseMap::iterator VMI=FuncInfo->ValueMap.find(AI); if (VMI != FuncInfo->ValueMap.end()) { SDL->CopyValueToVirtualRegister(AI, VMI->second); } } a += NumValues; } // Finally, if the target has anything special to do, allow it to do so. // FIXME: this should insert code into the DAG! EmitFunctionEntryCode(F, SDL->DAG.getMachineFunction()); } /// Handle PHI nodes in successor blocks. Emit code into the SelectionDAG to /// ensure constants are generated when needed. Remember the virtual registers /// that need to be added to the Machine PHI nodes as input. We cannot just /// directly add them, because expansion might result in multiple MBB's for one /// BB. As such, the start of the BB might correspond to a different MBB than /// the end. /// void SelectionDAGISel::HandlePHINodesInSuccessorBlocks(BasicBlock *LLVMBB) { TerminatorInst *TI = LLVMBB->getTerminator(); SmallPtrSet SuccsHandled; // Check successor nodes' PHI nodes that expect a constant to be available // from this block. for (unsigned succ = 0, e = TI->getNumSuccessors(); succ != e; ++succ) { BasicBlock *SuccBB = TI->getSuccessor(succ); if (!isa(SuccBB->begin())) continue; MachineBasicBlock *SuccMBB = FuncInfo->MBBMap[SuccBB]; // If this terminator has multiple identical successors (common for // switches), only handle each succ once. if (!SuccsHandled.insert(SuccMBB)) continue; MachineBasicBlock::iterator MBBI = SuccMBB->begin(); PHINode *PN; // At this point we know that there is a 1-1 correspondence between LLVM PHI // nodes and Machine PHI nodes, but the incoming operands have not been // emitted yet. for (BasicBlock::iterator I = SuccBB->begin(); (PN = dyn_cast(I)); ++I) { // Ignore dead phi's. if (PN->use_empty()) continue; unsigned Reg; Value *PHIOp = PN->getIncomingValueForBlock(LLVMBB); if (Constant *C = dyn_cast(PHIOp)) { unsigned &RegOut = SDL->ConstantsOut[C]; if (RegOut == 0) { RegOut = FuncInfo->CreateRegForValue(C); SDL->CopyValueToVirtualRegister(C, RegOut); } Reg = RegOut; } else { Reg = FuncInfo->ValueMap[PHIOp]; if (Reg == 0) { assert(isa(PHIOp) && FuncInfo->StaticAllocaMap.count(cast(PHIOp)) && "Didn't codegen value into a register!??"); Reg = FuncInfo->CreateRegForValue(PHIOp); SDL->CopyValueToVirtualRegister(PHIOp, Reg); } } // Remember that this register needs to added to the machine PHI node as // the input for this MBB. SmallVector ValueVTs; ComputeValueVTs(TLI, PN->getType(), ValueVTs); for (unsigned vti = 0, vte = ValueVTs.size(); vti != vte; ++vti) { MVT VT = ValueVTs[vti]; unsigned NumRegisters = TLI.getNumRegisters(VT); for (unsigned i = 0, e = NumRegisters; i != e; ++i) SDL->PHINodesToUpdate.push_back(std::make_pair(MBBI++, Reg+i)); Reg += NumRegisters; } } } SDL->ConstantsOut.clear(); } /// This is the Fast-ISel version of HandlePHINodesInSuccessorBlocks. It only /// supports legal types, and it emits MachineInstrs directly instead of /// creating SelectionDAG nodes. /// bool SelectionDAGISel::HandlePHINodesInSuccessorBlocksFast(BasicBlock *LLVMBB, FastISel *F) { TerminatorInst *TI = LLVMBB->getTerminator(); SmallPtrSet SuccsHandled; unsigned OrigNumPHINodesToUpdate = SDL->PHINodesToUpdate.size(); // Check successor nodes' PHI nodes that expect a constant to be available // from this block. for (unsigned succ = 0, e = TI->getNumSuccessors(); succ != e; ++succ) { BasicBlock *SuccBB = TI->getSuccessor(succ); if (!isa(SuccBB->begin())) continue; MachineBasicBlock *SuccMBB = FuncInfo->MBBMap[SuccBB]; // If this terminator has multiple identical successors (common for // switches), only handle each succ once. if (!SuccsHandled.insert(SuccMBB)) continue; MachineBasicBlock::iterator MBBI = SuccMBB->begin(); PHINode *PN; // At this point we know that there is a 1-1 correspondence between LLVM PHI // nodes and Machine PHI nodes, but the incoming operands have not been // emitted yet. for (BasicBlock::iterator I = SuccBB->begin(); (PN = dyn_cast(I)); ++I) { // Ignore dead phi's. if (PN->use_empty()) continue; // Only handle legal types. Two interesting things to note here. First, // by bailing out early, we may leave behind some dead instructions, // since SelectionDAG's HandlePHINodesInSuccessorBlocks will insert its // own moves. Second, this check is necessary becuase FastISel doesn't // use CreateRegForValue to create registers, so it always creates // exactly one register for each non-void instruction. MVT VT = TLI.getValueType(PN->getType(), /*AllowUnknown=*/true); if (VT == MVT::Other || !TLI.isTypeLegal(VT)) { SDL->PHINodesToUpdate.resize(OrigNumPHINodesToUpdate); return false; } Value *PHIOp = PN->getIncomingValueForBlock(LLVMBB); unsigned Reg = F->getRegForValue(PHIOp); if (Reg == 0) { SDL->PHINodesToUpdate.resize(OrigNumPHINodesToUpdate); return false; } SDL->PHINodesToUpdate.push_back(std::make_pair(MBBI++, Reg)); } } return true; }