//===-- X86FastISel.cpp - X86 FastISel implementation ---------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file defines the X86-specific support for the FastISel class. Much // of the target-specific code is generated by tablegen in the file // X86GenFastISel.inc, which is #included here. // //===----------------------------------------------------------------------===// #include "X86.h" #include "X86InstrBuilder.h" #include "X86RegisterInfo.h" #include "X86Subtarget.h" #include "X86TargetMachine.h" #include "llvm/CallingConv.h" #include "llvm/DerivedTypes.h" #include "llvm/GlobalVariable.h" #include "llvm/Instructions.h" #include "llvm/IntrinsicInst.h" #include "llvm/CodeGen/Analysis.h" #include "llvm/CodeGen/FastISel.h" #include "llvm/CodeGen/FunctionLoweringInfo.h" #include "llvm/CodeGen/MachineConstantPool.h" #include "llvm/CodeGen/MachineFrameInfo.h" #include "llvm/CodeGen/MachineRegisterInfo.h" #include "llvm/Support/CallSite.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/GetElementPtrTypeIterator.h" #include "llvm/Target/TargetOptions.h" using namespace llvm; namespace { class X86FastISel : public FastISel { /// Subtarget - Keep a pointer to the X86Subtarget around so that we can /// make the right decision when generating code for different targets. const X86Subtarget *Subtarget; /// StackPtr - Register used as the stack pointer. /// unsigned StackPtr; /// X86ScalarSSEf32, X86ScalarSSEf64 - Select between SSE or x87 /// floating point ops. /// When SSE is available, use it for f32 operations. /// When SSE2 is available, use it for f64 operations. bool X86ScalarSSEf64; bool X86ScalarSSEf32; public: explicit X86FastISel(FunctionLoweringInfo &funcInfo) : FastISel(funcInfo) { Subtarget = &TM.getSubtarget(); StackPtr = Subtarget->is64Bit() ? X86::RSP : X86::ESP; X86ScalarSSEf64 = Subtarget->hasSSE2(); X86ScalarSSEf32 = Subtarget->hasSSE1(); } virtual bool TargetSelectInstruction(const Instruction *I); /// TryToFoldLoad - The specified machine instr operand is a vreg, and that /// vreg is being provided by the specified load instruction. If possible, /// try to fold the load as an operand to the instruction, returning true if /// possible. virtual bool TryToFoldLoad(MachineInstr *MI, unsigned OpNo, const LoadInst *LI); #include "X86GenFastISel.inc" private: bool X86FastEmitCompare(const Value *LHS, const Value *RHS, EVT VT); bool X86FastEmitLoad(EVT VT, const X86AddressMode &AM, unsigned &RR); bool X86FastEmitStore(EVT VT, const Value *Val, const X86AddressMode &AM); bool X86FastEmitStore(EVT VT, unsigned Val, const X86AddressMode &AM); bool X86FastEmitExtend(ISD::NodeType Opc, EVT DstVT, unsigned Src, EVT SrcVT, unsigned &ResultReg); bool X86SelectAddress(const Value *V, X86AddressMode &AM); bool X86SelectCallAddress(const Value *V, X86AddressMode &AM); bool X86SelectLoad(const Instruction *I); bool X86SelectStore(const Instruction *I); bool X86SelectRet(const Instruction *I); bool X86SelectCmp(const Instruction *I); bool X86SelectZExt(const Instruction *I); bool X86SelectBranch(const Instruction *I); bool X86SelectShift(const Instruction *I); bool X86SelectSelect(const Instruction *I); bool X86SelectTrunc(const Instruction *I); bool X86SelectFPExt(const Instruction *I); bool X86SelectFPTrunc(const Instruction *I); bool X86SelectExtractValue(const Instruction *I); bool X86VisitIntrinsicCall(const IntrinsicInst &I); bool X86SelectCall(const Instruction *I); const X86InstrInfo *getInstrInfo() const { return getTargetMachine()->getInstrInfo(); } const X86TargetMachine *getTargetMachine() const { return static_cast(&TM); } unsigned TargetMaterializeConstant(const Constant *C); unsigned TargetMaterializeAlloca(const AllocaInst *C); /// isScalarFPTypeInSSEReg - Return true if the specified scalar FP type is /// computed in an SSE register, not on the X87 floating point stack. bool isScalarFPTypeInSSEReg(EVT VT) const { return (VT == MVT::f64 && X86ScalarSSEf64) || // f64 is when SSE2 (VT == MVT::f32 && X86ScalarSSEf32); // f32 is when SSE1 } bool isTypeLegal(const Type *Ty, MVT &VT, bool AllowI1 = false); }; } // end anonymous namespace. bool X86FastISel::isTypeLegal(const Type *Ty, MVT &VT, bool AllowI1) { EVT evt = TLI.getValueType(Ty, /*HandleUnknown=*/true); if (evt == MVT::Other || !evt.isSimple()) // Unhandled type. Halt "fast" selection and bail. return false; VT = evt.getSimpleVT(); // For now, require SSE/SSE2 for performing floating-point operations, // since x87 requires additional work. if (VT == MVT::f64 && !X86ScalarSSEf64) return false; if (VT == MVT::f32 && !X86ScalarSSEf32) return false; // Similarly, no f80 support yet. if (VT == MVT::f80) return false; // We only handle legal types. For example, on x86-32 the instruction // selector contains all of the 64-bit instructions from x86-64, // under the assumption that i64 won't be used if the target doesn't // support it. return (AllowI1 && VT == MVT::i1) || TLI.isTypeLegal(VT); } #include "X86GenCallingConv.inc" /// X86FastEmitLoad - Emit a machine instruction to load a value of type VT. /// The address is either pre-computed, i.e. Ptr, or a GlobalAddress, i.e. GV. /// Return true and the result register by reference if it is possible. bool X86FastISel::X86FastEmitLoad(EVT VT, const X86AddressMode &AM, unsigned &ResultReg) { // Get opcode and regclass of the output for the given load instruction. unsigned Opc = 0; const TargetRegisterClass *RC = NULL; switch (VT.getSimpleVT().SimpleTy) { default: return false; case MVT::i1: case MVT::i8: Opc = X86::MOV8rm; RC = X86::GR8RegisterClass; break; case MVT::i16: Opc = X86::MOV16rm; RC = X86::GR16RegisterClass; break; case MVT::i32: Opc = X86::MOV32rm; RC = X86::GR32RegisterClass; break; case MVT::i64: // Must be in x86-64 mode. Opc = X86::MOV64rm; RC = X86::GR64RegisterClass; break; case MVT::f32: if (Subtarget->hasSSE1()) { Opc = X86::MOVSSrm; RC = X86::FR32RegisterClass; } else { Opc = X86::LD_Fp32m; RC = X86::RFP32RegisterClass; } break; case MVT::f64: if (Subtarget->hasSSE2()) { Opc = X86::MOVSDrm; RC = X86::FR64RegisterClass; } else { Opc = X86::LD_Fp64m; RC = X86::RFP64RegisterClass; } break; case MVT::f80: // No f80 support yet. return false; } ResultReg = createResultReg(RC); addFullAddress(BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(Opc), ResultReg), AM); return true; } /// X86FastEmitStore - Emit a machine instruction to store a value Val of /// type VT. The address is either pre-computed, consisted of a base ptr, Ptr /// and a displacement offset, or a GlobalAddress, /// i.e. V. Return true if it is possible. bool X86FastISel::X86FastEmitStore(EVT VT, unsigned Val, const X86AddressMode &AM) { // Get opcode and regclass of the output for the given store instruction. unsigned Opc = 0; switch (VT.getSimpleVT().SimpleTy) { case MVT::f80: // No f80 support yet. default: return false; case MVT::i1: { // Mask out all but lowest bit. unsigned AndResult = createResultReg(X86::GR8RegisterClass); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::AND8ri), AndResult).addReg(Val).addImm(1); Val = AndResult; } // FALLTHROUGH, handling i1 as i8. case MVT::i8: Opc = X86::MOV8mr; break; case MVT::i16: Opc = X86::MOV16mr; break; case MVT::i32: Opc = X86::MOV32mr; break; case MVT::i64: Opc = X86::MOV64mr; break; // Must be in x86-64 mode. case MVT::f32: Opc = Subtarget->hasSSE1() ? X86::MOVSSmr : X86::ST_Fp32m; break; case MVT::f64: Opc = Subtarget->hasSSE2() ? X86::MOVSDmr : X86::ST_Fp64m; break; } addFullAddress(BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(Opc)), AM).addReg(Val); return true; } bool X86FastISel::X86FastEmitStore(EVT VT, const Value *Val, const X86AddressMode &AM) { // Handle 'null' like i32/i64 0. if (isa(Val)) Val = Constant::getNullValue(TD.getIntPtrType(Val->getContext())); // If this is a store of a simple constant, fold the constant into the store. if (const ConstantInt *CI = dyn_cast(Val)) { unsigned Opc = 0; bool Signed = true; switch (VT.getSimpleVT().SimpleTy) { default: break; case MVT::i1: Signed = false; // FALLTHROUGH to handle as i8. case MVT::i8: Opc = X86::MOV8mi; break; case MVT::i16: Opc = X86::MOV16mi; break; case MVT::i32: Opc = X86::MOV32mi; break; case MVT::i64: // Must be a 32-bit sign extended value. if ((int)CI->getSExtValue() == CI->getSExtValue()) Opc = X86::MOV64mi32; break; } if (Opc) { addFullAddress(BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(Opc)), AM) .addImm(Signed ? (uint64_t) CI->getSExtValue() : CI->getZExtValue()); return true; } } unsigned ValReg = getRegForValue(Val); if (ValReg == 0) return false; return X86FastEmitStore(VT, ValReg, AM); } /// X86FastEmitExtend - Emit a machine instruction to extend a value Src of /// type SrcVT to type DstVT using the specified extension opcode Opc (e.g. /// ISD::SIGN_EXTEND). bool X86FastISel::X86FastEmitExtend(ISD::NodeType Opc, EVT DstVT, unsigned Src, EVT SrcVT, unsigned &ResultReg) { unsigned RR = FastEmit_r(SrcVT.getSimpleVT(), DstVT.getSimpleVT(), Opc, Src, /*TODO: Kill=*/false); if (RR != 0) { ResultReg = RR; return true; } else return false; } /// X86SelectAddress - Attempt to fill in an address from the given value. /// bool X86FastISel::X86SelectAddress(const Value *V, X86AddressMode &AM) { const User *U = NULL; unsigned Opcode = Instruction::UserOp1; if (const Instruction *I = dyn_cast(V)) { // Don't walk into other basic blocks; it's possible we haven't // visited them yet, so the instructions may not yet be assigned // virtual registers. if (FuncInfo.StaticAllocaMap.count(static_cast(V)) || FuncInfo.MBBMap[I->getParent()] == FuncInfo.MBB) { Opcode = I->getOpcode(); U = I; } } else if (const ConstantExpr *C = dyn_cast(V)) { Opcode = C->getOpcode(); U = C; } if (const PointerType *Ty = dyn_cast(V->getType())) if (Ty->getAddressSpace() > 255) // Fast instruction selection doesn't support the special // address spaces. return false; switch (Opcode) { default: break; case Instruction::BitCast: // Look past bitcasts. return X86SelectAddress(U->getOperand(0), AM); case Instruction::IntToPtr: // Look past no-op inttoptrs. if (TLI.getValueType(U->getOperand(0)->getType()) == TLI.getPointerTy()) return X86SelectAddress(U->getOperand(0), AM); break; case Instruction::PtrToInt: // Look past no-op ptrtoints. if (TLI.getValueType(U->getType()) == TLI.getPointerTy()) return X86SelectAddress(U->getOperand(0), AM); break; case Instruction::Alloca: { // Do static allocas. const AllocaInst *A = cast(V); DenseMap::iterator SI = FuncInfo.StaticAllocaMap.find(A); if (SI != FuncInfo.StaticAllocaMap.end()) { AM.BaseType = X86AddressMode::FrameIndexBase; AM.Base.FrameIndex = SI->second; return true; } break; } case Instruction::Add: { // Adds of constants are common and easy enough. if (const ConstantInt *CI = dyn_cast(U->getOperand(1))) { uint64_t Disp = (int32_t)AM.Disp + (uint64_t)CI->getSExtValue(); // They have to fit in the 32-bit signed displacement field though. if (isInt<32>(Disp)) { AM.Disp = (uint32_t)Disp; return X86SelectAddress(U->getOperand(0), AM); } } break; } case Instruction::GetElementPtr: { X86AddressMode SavedAM = AM; // Pattern-match simple GEPs. uint64_t Disp = (int32_t)AM.Disp; unsigned IndexReg = AM.IndexReg; unsigned Scale = AM.Scale; gep_type_iterator GTI = gep_type_begin(U); // Iterate through the indices, folding what we can. Constants can be // folded, and one dynamic index can be handled, if the scale is supported. for (User::const_op_iterator i = U->op_begin() + 1, e = U->op_end(); i != e; ++i, ++GTI) { const Value *Op = *i; if (const StructType *STy = dyn_cast(*GTI)) { const StructLayout *SL = TD.getStructLayout(STy); unsigned Idx = cast(Op)->getZExtValue(); Disp += SL->getElementOffset(Idx); } else { uint64_t S = TD.getTypeAllocSize(GTI.getIndexedType()); for (;;) { if (const ConstantInt *CI = dyn_cast(Op)) { // Constant-offset addressing. Disp += CI->getSExtValue() * S; break; } if (isa(Op) && (!isa(Op) || FuncInfo.MBBMap[cast(Op)->getParent()] == FuncInfo.MBB) && isa(cast(Op)->getOperand(1))) { // An add (in the same block) with a constant operand. Fold the // constant. ConstantInt *CI = cast(cast(Op)->getOperand(1)); Disp += CI->getSExtValue() * S; // Iterate on the other operand. Op = cast(Op)->getOperand(0); continue; } if (IndexReg == 0 && (!AM.GV || !Subtarget->isPICStyleRIPRel()) && (S == 1 || S == 2 || S == 4 || S == 8)) { // Scaled-index addressing. Scale = S; IndexReg = getRegForGEPIndex(Op).first; if (IndexReg == 0) return false; break; } // Unsupported. goto unsupported_gep; } } } // Check for displacement overflow. if (!isInt<32>(Disp)) break; // Ok, the GEP indices were covered by constant-offset and scaled-index // addressing. Update the address state and move on to examining the base. AM.IndexReg = IndexReg; AM.Scale = Scale; AM.Disp = (uint32_t)Disp; if (X86SelectAddress(U->getOperand(0), AM)) return true; // If we couldn't merge the sub value into this addr mode, revert back to // our address and just match the value instead of completely failing. AM = SavedAM; break; unsupported_gep: // Ok, the GEP indices weren't all covered. break; } } // Handle constant address. if (const GlobalValue *GV = dyn_cast(V)) { // Can't handle alternate code models yet. if (TM.getCodeModel() != CodeModel::Small) return false; // RIP-relative addresses can't have additional register operands. if (Subtarget->isPICStyleRIPRel() && (AM.Base.Reg != 0 || AM.IndexReg != 0)) return false; // Can't handle TLS yet. if (const GlobalVariable *GVar = dyn_cast(GV)) if (GVar->isThreadLocal()) return false; // Okay, we've committed to selecting this global. Set up the basic address. AM.GV = GV; // Allow the subtarget to classify the global. unsigned char GVFlags = Subtarget->ClassifyGlobalReference(GV, TM); // If this reference is relative to the pic base, set it now. if (isGlobalRelativeToPICBase(GVFlags)) { // FIXME: How do we know Base.Reg is free?? AM.Base.Reg = getInstrInfo()->getGlobalBaseReg(FuncInfo.MF); } // Unless the ABI requires an extra load, return a direct reference to // the global. if (!isGlobalStubReference(GVFlags)) { if (Subtarget->isPICStyleRIPRel()) { // Use rip-relative addressing if we can. Above we verified that the // base and index registers are unused. assert(AM.Base.Reg == 0 && AM.IndexReg == 0); AM.Base.Reg = X86::RIP; } AM.GVOpFlags = GVFlags; return true; } // Ok, we need to do a load from a stub. If we've already loaded from this // stub, reuse the loaded pointer, otherwise emit the load now. DenseMap::iterator I = LocalValueMap.find(V); unsigned LoadReg; if (I != LocalValueMap.end() && I->second != 0) { LoadReg = I->second; } else { // Issue load from stub. unsigned Opc = 0; const TargetRegisterClass *RC = NULL; X86AddressMode StubAM; StubAM.Base.Reg = AM.Base.Reg; StubAM.GV = GV; StubAM.GVOpFlags = GVFlags; // Prepare for inserting code in the local-value area. SavePoint SaveInsertPt = enterLocalValueArea(); if (TLI.getPointerTy() == MVT::i64) { Opc = X86::MOV64rm; RC = X86::GR64RegisterClass; if (Subtarget->isPICStyleRIPRel()) StubAM.Base.Reg = X86::RIP; } else { Opc = X86::MOV32rm; RC = X86::GR32RegisterClass; } LoadReg = createResultReg(RC); MachineInstrBuilder LoadMI = BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(Opc), LoadReg); addFullAddress(LoadMI, StubAM); // Ok, back to normal mode. leaveLocalValueArea(SaveInsertPt); // Prevent loading GV stub multiple times in same MBB. LocalValueMap[V] = LoadReg; } // Now construct the final address. Note that the Disp, Scale, // and Index values may already be set here. AM.Base.Reg = LoadReg; AM.GV = 0; return true; } // If all else fails, try to materialize the value in a register. if (!AM.GV || !Subtarget->isPICStyleRIPRel()) { if (AM.Base.Reg == 0) { AM.Base.Reg = getRegForValue(V); return AM.Base.Reg != 0; } if (AM.IndexReg == 0) { assert(AM.Scale == 1 && "Scale with no index!"); AM.IndexReg = getRegForValue(V); return AM.IndexReg != 0; } } return false; } /// X86SelectCallAddress - Attempt to fill in an address from the given value. /// bool X86FastISel::X86SelectCallAddress(const Value *V, X86AddressMode &AM) { const User *U = NULL; unsigned Opcode = Instruction::UserOp1; if (const Instruction *I = dyn_cast(V)) { Opcode = I->getOpcode(); U = I; } else if (const ConstantExpr *C = dyn_cast(V)) { Opcode = C->getOpcode(); U = C; } switch (Opcode) { default: break; case Instruction::BitCast: // Look past bitcasts. return X86SelectCallAddress(U->getOperand(0), AM); case Instruction::IntToPtr: // Look past no-op inttoptrs. if (TLI.getValueType(U->getOperand(0)->getType()) == TLI.getPointerTy()) return X86SelectCallAddress(U->getOperand(0), AM); break; case Instruction::PtrToInt: // Look past no-op ptrtoints. if (TLI.getValueType(U->getType()) == TLI.getPointerTy()) return X86SelectCallAddress(U->getOperand(0), AM); break; } // Handle constant address. if (const GlobalValue *GV = dyn_cast(V)) { // Can't handle alternate code models yet. if (TM.getCodeModel() != CodeModel::Small) return false; // RIP-relative addresses can't have additional register operands. if (Subtarget->isPICStyleRIPRel() && (AM.Base.Reg != 0 || AM.IndexReg != 0)) return false; // Can't handle DLLImport. if (GV->hasDLLImportLinkage()) return false; // Can't handle TLS. if (const GlobalVariable *GVar = dyn_cast(GV)) if (GVar->isThreadLocal()) return false; // Okay, we've committed to selecting this global. Set up the basic address. AM.GV = GV; // No ABI requires an extra load for anything other than DLLImport, which // we rejected above. Return a direct reference to the global. if (Subtarget->isPICStyleRIPRel()) { // Use rip-relative addressing if we can. Above we verified that the // base and index registers are unused. assert(AM.Base.Reg == 0 && AM.IndexReg == 0); AM.Base.Reg = X86::RIP; } else if (Subtarget->isPICStyleStubPIC()) { AM.GVOpFlags = X86II::MO_PIC_BASE_OFFSET; } else if (Subtarget->isPICStyleGOT()) { AM.GVOpFlags = X86II::MO_GOTOFF; } return true; } // If all else fails, try to materialize the value in a register. if (!AM.GV || !Subtarget->isPICStyleRIPRel()) { if (AM.Base.Reg == 0) { AM.Base.Reg = getRegForValue(V); return AM.Base.Reg != 0; } if (AM.IndexReg == 0) { assert(AM.Scale == 1 && "Scale with no index!"); AM.IndexReg = getRegForValue(V); return AM.IndexReg != 0; } } return false; } /// X86SelectStore - Select and emit code to implement store instructions. bool X86FastISel::X86SelectStore(const Instruction *I) { MVT VT; if (!isTypeLegal(I->getOperand(0)->getType(), VT, /*AllowI1=*/true)) return false; X86AddressMode AM; if (!X86SelectAddress(I->getOperand(1), AM)) return false; return X86FastEmitStore(VT, I->getOperand(0), AM); } /// X86SelectRet - Select and emit code to implement ret instructions. bool X86FastISel::X86SelectRet(const Instruction *I) { const ReturnInst *Ret = cast(I); const Function &F = *I->getParent()->getParent(); if (!FuncInfo.CanLowerReturn) return false; CallingConv::ID CC = F.getCallingConv(); if (CC != CallingConv::C && CC != CallingConv::Fast && CC != CallingConv::X86_FastCall) return false; if (Subtarget->isTargetWin64()) return false; // Don't handle popping bytes on return for now. if (FuncInfo.MF->getInfo() ->getBytesToPopOnReturn() != 0) return 0; // fastcc with -tailcallopt is intended to provide a guaranteed // tail call optimization. Fastisel doesn't know how to do that. if (CC == CallingConv::Fast && GuaranteedTailCallOpt) return false; // Let SDISel handle vararg functions. if (F.isVarArg()) return false; if (Ret->getNumOperands() > 0) { SmallVector Outs; GetReturnInfo(F.getReturnType(), F.getAttributes().getRetAttributes(), Outs, TLI); // Analyze operands of the call, assigning locations to each operand. SmallVector ValLocs; CCState CCInfo(CC, F.isVarArg(), TM, ValLocs, I->getContext()); CCInfo.AnalyzeReturn(Outs, RetCC_X86); const Value *RV = Ret->getOperand(0); unsigned Reg = getRegForValue(RV); if (Reg == 0) return false; // Only handle a single return value for now. if (ValLocs.size() != 1) return false; CCValAssign &VA = ValLocs[0]; // Don't bother handling odd stuff for now. if (VA.getLocInfo() != CCValAssign::Full) return false; // Only handle register returns for now. if (!VA.isRegLoc()) return false; // TODO: For now, don't try to handle cases where getLocInfo() // says Full but the types don't match. if (TLI.getValueType(RV->getType()) != VA.getValVT()) return false; // The calling-convention tables for x87 returns don't tell // the whole story. if (VA.getLocReg() == X86::ST0 || VA.getLocReg() == X86::ST1) return false; // Make the copy. unsigned SrcReg = Reg + VA.getValNo(); unsigned DstReg = VA.getLocReg(); const TargetRegisterClass* SrcRC = MRI.getRegClass(SrcReg); // Avoid a cross-class copy. This is very unlikely. if (!SrcRC->contains(DstReg)) return false; BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(TargetOpcode::COPY), DstReg).addReg(SrcReg); // Mark the register as live out of the function. MRI.addLiveOut(VA.getLocReg()); } // Now emit the RET. BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::RET)); return true; } /// X86SelectLoad - Select and emit code to implement load instructions. /// bool X86FastISel::X86SelectLoad(const Instruction *I) { MVT VT; if (!isTypeLegal(I->getType(), VT, /*AllowI1=*/true)) return false; X86AddressMode AM; if (!X86SelectAddress(I->getOperand(0), AM)) return false; unsigned ResultReg = 0; if (X86FastEmitLoad(VT, AM, ResultReg)) { UpdateValueMap(I, ResultReg); return true; } return false; } static unsigned X86ChooseCmpOpcode(EVT VT, const X86Subtarget *Subtarget) { switch (VT.getSimpleVT().SimpleTy) { default: return 0; case MVT::i8: return X86::CMP8rr; case MVT::i16: return X86::CMP16rr; case MVT::i32: return X86::CMP32rr; case MVT::i64: return X86::CMP64rr; case MVT::f32: return Subtarget->hasSSE1() ? X86::UCOMISSrr : 0; case MVT::f64: return Subtarget->hasSSE2() ? X86::UCOMISDrr : 0; } } /// X86ChooseCmpImmediateOpcode - If we have a comparison with RHS as the RHS /// of the comparison, return an opcode that works for the compare (e.g. /// CMP32ri) otherwise return 0. static unsigned X86ChooseCmpImmediateOpcode(EVT VT, const ConstantInt *RHSC) { switch (VT.getSimpleVT().SimpleTy) { // Otherwise, we can't fold the immediate into this comparison. default: return 0; case MVT::i8: return X86::CMP8ri; case MVT::i16: return X86::CMP16ri; case MVT::i32: return X86::CMP32ri; case MVT::i64: // 64-bit comparisons are only valid if the immediate fits in a 32-bit sext // field. if ((int)RHSC->getSExtValue() == RHSC->getSExtValue()) return X86::CMP64ri32; return 0; } } bool X86FastISel::X86FastEmitCompare(const Value *Op0, const Value *Op1, EVT VT) { unsigned Op0Reg = getRegForValue(Op0); if (Op0Reg == 0) return false; // Handle 'null' like i32/i64 0. if (isa(Op1)) Op1 = Constant::getNullValue(TD.getIntPtrType(Op0->getContext())); // We have two options: compare with register or immediate. If the RHS of // the compare is an immediate that we can fold into this compare, use // CMPri, otherwise use CMPrr. if (const ConstantInt *Op1C = dyn_cast(Op1)) { if (unsigned CompareImmOpc = X86ChooseCmpImmediateOpcode(VT, Op1C)) { BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(CompareImmOpc)) .addReg(Op0Reg) .addImm(Op1C->getSExtValue()); return true; } } unsigned CompareOpc = X86ChooseCmpOpcode(VT, Subtarget); if (CompareOpc == 0) return false; unsigned Op1Reg = getRegForValue(Op1); if (Op1Reg == 0) return false; BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(CompareOpc)) .addReg(Op0Reg) .addReg(Op1Reg); return true; } bool X86FastISel::X86SelectCmp(const Instruction *I) { const CmpInst *CI = cast(I); MVT VT; if (!isTypeLegal(I->getOperand(0)->getType(), VT)) return false; unsigned ResultReg = createResultReg(&X86::GR8RegClass); unsigned SetCCOpc; bool SwapArgs; // false -> compare Op0, Op1. true -> compare Op1, Op0. switch (CI->getPredicate()) { case CmpInst::FCMP_OEQ: { if (!X86FastEmitCompare(CI->getOperand(0), CI->getOperand(1), VT)) return false; unsigned EReg = createResultReg(&X86::GR8RegClass); unsigned NPReg = createResultReg(&X86::GR8RegClass); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::SETEr), EReg); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::SETNPr), NPReg); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::AND8rr), ResultReg).addReg(NPReg).addReg(EReg); UpdateValueMap(I, ResultReg); return true; } case CmpInst::FCMP_UNE: { if (!X86FastEmitCompare(CI->getOperand(0), CI->getOperand(1), VT)) return false; unsigned NEReg = createResultReg(&X86::GR8RegClass); unsigned PReg = createResultReg(&X86::GR8RegClass); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::SETNEr), NEReg); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::SETPr), PReg); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::OR8rr), ResultReg) .addReg(PReg).addReg(NEReg); UpdateValueMap(I, ResultReg); return true; } case CmpInst::FCMP_OGT: SwapArgs = false; SetCCOpc = X86::SETAr; break; case CmpInst::FCMP_OGE: SwapArgs = false; SetCCOpc = X86::SETAEr; break; case CmpInst::FCMP_OLT: SwapArgs = true; SetCCOpc = X86::SETAr; break; case CmpInst::FCMP_OLE: SwapArgs = true; SetCCOpc = X86::SETAEr; break; case CmpInst::FCMP_ONE: SwapArgs = false; SetCCOpc = X86::SETNEr; break; case CmpInst::FCMP_ORD: SwapArgs = false; SetCCOpc = X86::SETNPr; break; case CmpInst::FCMP_UNO: SwapArgs = false; SetCCOpc = X86::SETPr; break; case CmpInst::FCMP_UEQ: SwapArgs = false; SetCCOpc = X86::SETEr; break; case CmpInst::FCMP_UGT: SwapArgs = true; SetCCOpc = X86::SETBr; break; case CmpInst::FCMP_UGE: SwapArgs = true; SetCCOpc = X86::SETBEr; break; case CmpInst::FCMP_ULT: SwapArgs = false; SetCCOpc = X86::SETBr; break; case CmpInst::FCMP_ULE: SwapArgs = false; SetCCOpc = X86::SETBEr; break; case CmpInst::ICMP_EQ: SwapArgs = false; SetCCOpc = X86::SETEr; break; case CmpInst::ICMP_NE: SwapArgs = false; SetCCOpc = X86::SETNEr; break; case CmpInst::ICMP_UGT: SwapArgs = false; SetCCOpc = X86::SETAr; break; case CmpInst::ICMP_UGE: SwapArgs = false; SetCCOpc = X86::SETAEr; break; case CmpInst::ICMP_ULT: SwapArgs = false; SetCCOpc = X86::SETBr; break; case CmpInst::ICMP_ULE: SwapArgs = false; SetCCOpc = X86::SETBEr; break; case CmpInst::ICMP_SGT: SwapArgs = false; SetCCOpc = X86::SETGr; break; case CmpInst::ICMP_SGE: SwapArgs = false; SetCCOpc = X86::SETGEr; break; case CmpInst::ICMP_SLT: SwapArgs = false; SetCCOpc = X86::SETLr; break; case CmpInst::ICMP_SLE: SwapArgs = false; SetCCOpc = X86::SETLEr; break; default: return false; } const Value *Op0 = CI->getOperand(0), *Op1 = CI->getOperand(1); if (SwapArgs) std::swap(Op0, Op1); // Emit a compare of Op0/Op1. if (!X86FastEmitCompare(Op0, Op1, VT)) return false; BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(SetCCOpc), ResultReg); UpdateValueMap(I, ResultReg); return true; } bool X86FastISel::X86SelectZExt(const Instruction *I) { // Handle zero-extension from i1 to i8, which is common. if (I->getType()->isIntegerTy(8) && I->getOperand(0)->getType()->isIntegerTy(1)) { unsigned ResultReg = getRegForValue(I->getOperand(0)); if (ResultReg == 0) return false; // Set the high bits to zero. ResultReg = FastEmitZExtFromI1(MVT::i8, ResultReg, /*TODO: Kill=*/false); if (ResultReg == 0) return false; UpdateValueMap(I, ResultReg); return true; } return false; } bool X86FastISel::X86SelectBranch(const Instruction *I) { // Unconditional branches are selected by tablegen-generated code. // Handle a conditional branch. const BranchInst *BI = cast(I); MachineBasicBlock *TrueMBB = FuncInfo.MBBMap[BI->getSuccessor(0)]; MachineBasicBlock *FalseMBB = FuncInfo.MBBMap[BI->getSuccessor(1)]; // Fold the common case of a conditional branch with a comparison // in the same block (values defined on other blocks may not have // initialized registers). if (const CmpInst *CI = dyn_cast(BI->getCondition())) { if (CI->hasOneUse() && CI->getParent() == I->getParent()) { EVT VT = TLI.getValueType(CI->getOperand(0)->getType()); // Try to take advantage of fallthrough opportunities. CmpInst::Predicate Predicate = CI->getPredicate(); if (FuncInfo.MBB->isLayoutSuccessor(TrueMBB)) { std::swap(TrueMBB, FalseMBB); Predicate = CmpInst::getInversePredicate(Predicate); } bool SwapArgs; // false -> compare Op0, Op1. true -> compare Op1, Op0. unsigned BranchOpc; // Opcode to jump on, e.g. "X86::JA" switch (Predicate) { case CmpInst::FCMP_OEQ: std::swap(TrueMBB, FalseMBB); Predicate = CmpInst::FCMP_UNE; // FALL THROUGH case CmpInst::FCMP_UNE: SwapArgs = false; BranchOpc = X86::JNE_4; break; case CmpInst::FCMP_OGT: SwapArgs = false; BranchOpc = X86::JA_4; break; case CmpInst::FCMP_OGE: SwapArgs = false; BranchOpc = X86::JAE_4; break; case CmpInst::FCMP_OLT: SwapArgs = true; BranchOpc = X86::JA_4; break; case CmpInst::FCMP_OLE: SwapArgs = true; BranchOpc = X86::JAE_4; break; case CmpInst::FCMP_ONE: SwapArgs = false; BranchOpc = X86::JNE_4; break; case CmpInst::FCMP_ORD: SwapArgs = false; BranchOpc = X86::JNP_4; break; case CmpInst::FCMP_UNO: SwapArgs = false; BranchOpc = X86::JP_4; break; case CmpInst::FCMP_UEQ: SwapArgs = false; BranchOpc = X86::JE_4; break; case CmpInst::FCMP_UGT: SwapArgs = true; BranchOpc = X86::JB_4; break; case CmpInst::FCMP_UGE: SwapArgs = true; BranchOpc = X86::JBE_4; break; case CmpInst::FCMP_ULT: SwapArgs = false; BranchOpc = X86::JB_4; break; case CmpInst::FCMP_ULE: SwapArgs = false; BranchOpc = X86::JBE_4; break; case CmpInst::ICMP_EQ: SwapArgs = false; BranchOpc = X86::JE_4; break; case CmpInst::ICMP_NE: SwapArgs = false; BranchOpc = X86::JNE_4; break; case CmpInst::ICMP_UGT: SwapArgs = false; BranchOpc = X86::JA_4; break; case CmpInst::ICMP_UGE: SwapArgs = false; BranchOpc = X86::JAE_4; break; case CmpInst::ICMP_ULT: SwapArgs = false; BranchOpc = X86::JB_4; break; case CmpInst::ICMP_ULE: SwapArgs = false; BranchOpc = X86::JBE_4; break; case CmpInst::ICMP_SGT: SwapArgs = false; BranchOpc = X86::JG_4; break; case CmpInst::ICMP_SGE: SwapArgs = false; BranchOpc = X86::JGE_4; break; case CmpInst::ICMP_SLT: SwapArgs = false; BranchOpc = X86::JL_4; break; case CmpInst::ICMP_SLE: SwapArgs = false; BranchOpc = X86::JLE_4; break; default: return false; } const Value *Op0 = CI->getOperand(0), *Op1 = CI->getOperand(1); if (SwapArgs) std::swap(Op0, Op1); // Emit a compare of the LHS and RHS, setting the flags. if (!X86FastEmitCompare(Op0, Op1, VT)) return false; BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(BranchOpc)) .addMBB(TrueMBB); if (Predicate == CmpInst::FCMP_UNE) { // X86 requires a second branch to handle UNE (and OEQ, // which is mapped to UNE above). BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::JP_4)) .addMBB(TrueMBB); } FastEmitBranch(FalseMBB, DL); FuncInfo.MBB->addSuccessor(TrueMBB); return true; } } else if (ExtractValueInst *EI = dyn_cast(BI->getCondition())) { // Check to see if the branch instruction is from an "arithmetic with // overflow" intrinsic. The main way these intrinsics are used is: // // %t = call { i32, i1 } @llvm.sadd.with.overflow.i32(i32 %v1, i32 %v2) // %sum = extractvalue { i32, i1 } %t, 0 // %obit = extractvalue { i32, i1 } %t, 1 // br i1 %obit, label %overflow, label %normal // // The %sum and %obit are converted in an ADD and a SETO/SETB before // reaching the branch. Therefore, we search backwards through the MBB // looking for the SETO/SETB instruction. If an instruction modifies the // EFLAGS register before we reach the SETO/SETB instruction, then we can't // convert the branch into a JO/JB instruction. if (const IntrinsicInst *CI = dyn_cast(EI->getAggregateOperand())){ if (CI->getIntrinsicID() == Intrinsic::sadd_with_overflow || CI->getIntrinsicID() == Intrinsic::uadd_with_overflow) { const MachineInstr *SetMI = 0; unsigned Reg = getRegForValue(EI); for (MachineBasicBlock::const_reverse_iterator RI = FuncInfo.MBB->rbegin(), RE = FuncInfo.MBB->rend(); RI != RE; ++RI) { const MachineInstr &MI = *RI; if (MI.definesRegister(Reg)) { if (MI.isCopy()) { Reg = MI.getOperand(1).getReg(); continue; } SetMI = &MI; break; } const TargetInstrDesc &TID = MI.getDesc(); if (TID.hasImplicitDefOfPhysReg(X86::EFLAGS) || MI.hasUnmodeledSideEffects()) break; } if (SetMI) { unsigned OpCode = SetMI->getOpcode(); if (OpCode == X86::SETOr || OpCode == X86::SETBr) { BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(OpCode == X86::SETOr ? X86::JO_4 : X86::JB_4)) .addMBB(TrueMBB); FastEmitBranch(FalseMBB, DL); FuncInfo.MBB->addSuccessor(TrueMBB); return true; } } } } } // Otherwise do a clumsy setcc and re-test it. unsigned OpReg = getRegForValue(BI->getCondition()); if (OpReg == 0) return false; BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::TEST8rr)) .addReg(OpReg).addReg(OpReg); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::JNE_4)) .addMBB(TrueMBB); FastEmitBranch(FalseMBB, DL); FuncInfo.MBB->addSuccessor(TrueMBB); return true; } bool X86FastISel::X86SelectShift(const Instruction *I) { unsigned CReg = 0, OpReg = 0, OpImm = 0; const TargetRegisterClass *RC = NULL; if (I->getType()->isIntegerTy(8)) { CReg = X86::CL; RC = &X86::GR8RegClass; switch (I->getOpcode()) { case Instruction::LShr: OpReg = X86::SHR8rCL; OpImm = X86::SHR8ri; break; case Instruction::AShr: OpReg = X86::SAR8rCL; OpImm = X86::SAR8ri; break; case Instruction::Shl: OpReg = X86::SHL8rCL; OpImm = X86::SHL8ri; break; default: return false; } } else if (I->getType()->isIntegerTy(16)) { CReg = X86::CX; RC = &X86::GR16RegClass; switch (I->getOpcode()) { case Instruction::LShr: OpReg = X86::SHR16rCL; OpImm = X86::SHR16ri; break; case Instruction::AShr: OpReg = X86::SAR16rCL; OpImm = X86::SAR16ri; break; case Instruction::Shl: OpReg = X86::SHL16rCL; OpImm = X86::SHL16ri; break; default: return false; } } else if (I->getType()->isIntegerTy(32)) { CReg = X86::ECX; RC = &X86::GR32RegClass; switch (I->getOpcode()) { case Instruction::LShr: OpReg = X86::SHR32rCL; OpImm = X86::SHR32ri; break; case Instruction::AShr: OpReg = X86::SAR32rCL; OpImm = X86::SAR32ri; break; case Instruction::Shl: OpReg = X86::SHL32rCL; OpImm = X86::SHL32ri; break; default: return false; } } else if (I->getType()->isIntegerTy(64)) { CReg = X86::RCX; RC = &X86::GR64RegClass; switch (I->getOpcode()) { case Instruction::LShr: OpReg = X86::SHR64rCL; OpImm = X86::SHR64ri; break; case Instruction::AShr: OpReg = X86::SAR64rCL; OpImm = X86::SAR64ri; break; case Instruction::Shl: OpReg = X86::SHL64rCL; OpImm = X86::SHL64ri; break; default: return false; } } else { return false; } MVT VT; if (!isTypeLegal(I->getType(), VT)) return false; unsigned Op0Reg = getRegForValue(I->getOperand(0)); if (Op0Reg == 0) return false; // Fold immediate in shl(x,3). if (const ConstantInt *CI = dyn_cast(I->getOperand(1))) { unsigned ResultReg = createResultReg(RC); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(OpImm), ResultReg).addReg(Op0Reg).addImm(CI->getZExtValue() & 0xff); UpdateValueMap(I, ResultReg); return true; } unsigned Op1Reg = getRegForValue(I->getOperand(1)); if (Op1Reg == 0) return false; BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(TargetOpcode::COPY), CReg).addReg(Op1Reg); // The shift instruction uses X86::CL. If we defined a super-register // of X86::CL, emit a subreg KILL to precisely describe what we're doing here. if (CReg != X86::CL) BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(TargetOpcode::KILL), X86::CL) .addReg(CReg, RegState::Kill); unsigned ResultReg = createResultReg(RC); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(OpReg), ResultReg) .addReg(Op0Reg); UpdateValueMap(I, ResultReg); return true; } bool X86FastISel::X86SelectSelect(const Instruction *I) { MVT VT; if (!isTypeLegal(I->getType(), VT)) return false; // We only use cmov here, if we don't have a cmov instruction bail. if (!Subtarget->hasCMov()) return false; unsigned Opc = 0; const TargetRegisterClass *RC = NULL; if (VT == MVT::i16) { Opc = X86::CMOVE16rr; RC = &X86::GR16RegClass; } else if (VT == MVT::i32) { Opc = X86::CMOVE32rr; RC = &X86::GR32RegClass; } else if (VT == MVT::i64) { Opc = X86::CMOVE64rr; RC = &X86::GR64RegClass; } else { return false; } unsigned Op0Reg = getRegForValue(I->getOperand(0)); if (Op0Reg == 0) return false; unsigned Op1Reg = getRegForValue(I->getOperand(1)); if (Op1Reg == 0) return false; unsigned Op2Reg = getRegForValue(I->getOperand(2)); if (Op2Reg == 0) return false; BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::TEST8rr)) .addReg(Op0Reg).addReg(Op0Reg); unsigned ResultReg = createResultReg(RC); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(Opc), ResultReg) .addReg(Op1Reg).addReg(Op2Reg); UpdateValueMap(I, ResultReg); return true; } bool X86FastISel::X86SelectFPExt(const Instruction *I) { // fpext from float to double. if (Subtarget->hasSSE2() && I->getType()->isDoubleTy()) { const Value *V = I->getOperand(0); if (V->getType()->isFloatTy()) { unsigned OpReg = getRegForValue(V); if (OpReg == 0) return false; unsigned ResultReg = createResultReg(X86::FR64RegisterClass); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::CVTSS2SDrr), ResultReg) .addReg(OpReg); UpdateValueMap(I, ResultReg); return true; } } return false; } bool X86FastISel::X86SelectFPTrunc(const Instruction *I) { if (Subtarget->hasSSE2()) { if (I->getType()->isFloatTy()) { const Value *V = I->getOperand(0); if (V->getType()->isDoubleTy()) { unsigned OpReg = getRegForValue(V); if (OpReg == 0) return false; unsigned ResultReg = createResultReg(X86::FR32RegisterClass); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::CVTSD2SSrr), ResultReg) .addReg(OpReg); UpdateValueMap(I, ResultReg); return true; } } } return false; } bool X86FastISel::X86SelectTrunc(const Instruction *I) { if (Subtarget->is64Bit()) // All other cases should be handled by the tblgen generated code. return false; EVT SrcVT = TLI.getValueType(I->getOperand(0)->getType()); EVT DstVT = TLI.getValueType(I->getType()); // This code only handles truncation to byte right now. if (DstVT != MVT::i8 && DstVT != MVT::i1) // All other cases should be handled by the tblgen generated code. return false; if (SrcVT != MVT::i16 && SrcVT != MVT::i32) // All other cases should be handled by the tblgen generated code. return false; unsigned InputReg = getRegForValue(I->getOperand(0)); if (!InputReg) // Unhandled operand. Halt "fast" selection and bail. return false; // First issue a copy to GR16_ABCD or GR32_ABCD. const TargetRegisterClass *CopyRC = (SrcVT == MVT::i16) ? X86::GR16_ABCDRegisterClass : X86::GR32_ABCDRegisterClass; unsigned CopyReg = createResultReg(CopyRC); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(TargetOpcode::COPY), CopyReg).addReg(InputReg); // Then issue an extract_subreg. unsigned ResultReg = FastEmitInst_extractsubreg(MVT::i8, CopyReg, /*Kill=*/true, X86::sub_8bit); if (!ResultReg) return false; UpdateValueMap(I, ResultReg); return true; } bool X86FastISel::X86SelectExtractValue(const Instruction *I) { const ExtractValueInst *EI = cast(I); const Value *Agg = EI->getAggregateOperand(); if (const IntrinsicInst *CI = dyn_cast(Agg)) { switch (CI->getIntrinsicID()) { default: break; case Intrinsic::sadd_with_overflow: case Intrinsic::uadd_with_overflow: { // Cheat a little. We know that the registers for "add" and "seto" are // allocated sequentially. However, we only keep track of the register // for "add" in the value map. Use extractvalue's index to get the // correct register for "seto". unsigned OpReg = getRegForValue(Agg); if (OpReg == 0) return false; UpdateValueMap(I, OpReg + *EI->idx_begin()); return true; } } } return false; } bool X86FastISel::X86VisitIntrinsicCall(const IntrinsicInst &I) { // FIXME: Handle more intrinsics. switch (I.getIntrinsicID()) { default: return false; case Intrinsic::stackprotector: { // Emit code inline code to store the stack guard onto the stack. EVT PtrTy = TLI.getPointerTy(); const Value *Op1 = I.getArgOperand(0); // The guard's value. const AllocaInst *Slot = cast(I.getArgOperand(1)); // Grab the frame index. X86AddressMode AM; if (!X86SelectAddress(Slot, AM)) return false; if (!X86FastEmitStore(PtrTy, Op1, AM)) return false; return true; } case Intrinsic::objectsize: { ConstantInt *CI = dyn_cast(I.getArgOperand(1)); const Type *Ty = I.getCalledFunction()->getReturnType(); assert(CI && "Non-constant type in Intrinsic::objectsize?"); MVT VT; if (!isTypeLegal(Ty, VT)) return false; unsigned OpC = 0; if (VT == MVT::i32) OpC = X86::MOV32ri; else if (VT == MVT::i64) OpC = X86::MOV64ri; else return false; unsigned ResultReg = createResultReg(TLI.getRegClassFor(VT)); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(OpC), ResultReg). addImm(CI->isZero() ? -1ULL : 0); UpdateValueMap(&I, ResultReg); return true; } case Intrinsic::dbg_declare: { const DbgDeclareInst *DI = cast(&I); X86AddressMode AM; assert(DI->getAddress() && "Null address should be checked earlier!"); if (!X86SelectAddress(DI->getAddress(), AM)) return false; const TargetInstrDesc &II = TII.get(TargetOpcode::DBG_VALUE); // FIXME may need to add RegState::Debug to any registers produced, // although ESP/EBP should be the only ones at the moment. addFullAddress(BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, II), AM). addImm(0).addMetadata(DI->getVariable()); return true; } case Intrinsic::trap: { BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::TRAP)); return true; } case Intrinsic::sadd_with_overflow: case Intrinsic::uadd_with_overflow: { // Replace "add with overflow" intrinsics with an "add" instruction followed // by a seto/setc instruction. Later on, when the "extractvalue" // instructions are encountered, we use the fact that two registers were // created sequentially to get the correct registers for the "sum" and the // "overflow bit". const Function *Callee = I.getCalledFunction(); const Type *RetTy = cast(Callee->getReturnType())->getTypeAtIndex(unsigned(0)); MVT VT; if (!isTypeLegal(RetTy, VT)) return false; const Value *Op1 = I.getArgOperand(0); const Value *Op2 = I.getArgOperand(1); unsigned Reg1 = getRegForValue(Op1); unsigned Reg2 = getRegForValue(Op2); if (Reg1 == 0 || Reg2 == 0) // FIXME: Handle values *not* in registers. return false; unsigned OpC = 0; if (VT == MVT::i32) OpC = X86::ADD32rr; else if (VT == MVT::i64) OpC = X86::ADD64rr; else return false; unsigned ResultReg = createResultReg(TLI.getRegClassFor(VT)); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(OpC), ResultReg) .addReg(Reg1).addReg(Reg2); unsigned DestReg1 = UpdateValueMap(&I, ResultReg); // If the add with overflow is an intra-block value then we just want to // create temporaries for it like normal. If it is a cross-block value then // UpdateValueMap will return the cross-block register used. Since we // *really* want the value to be live in the register pair known by // UpdateValueMap, we have to use DestReg1+1 as the destination register in // the cross block case. In the non-cross-block case, we should just make // another register for the value. if (DestReg1 != ResultReg) ResultReg = DestReg1+1; else ResultReg = createResultReg(TLI.getRegClassFor(MVT::i8)); unsigned Opc = X86::SETBr; if (I.getIntrinsicID() == Intrinsic::sadd_with_overflow) Opc = X86::SETOr; BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(Opc), ResultReg); return true; } } } bool X86FastISel::X86SelectCall(const Instruction *I) { const CallInst *CI = cast(I); const Value *Callee = CI->getCalledValue(); // Can't handle inline asm yet. if (isa(Callee)) return false; // Handle intrinsic calls. if (const IntrinsicInst *II = dyn_cast(CI)) return X86VisitIntrinsicCall(*II); // Handle only C and fastcc calling conventions for now. ImmutableCallSite CS(CI); CallingConv::ID CC = CS.getCallingConv(); if (CC != CallingConv::C && CC != CallingConv::Fast && CC != CallingConv::X86_FastCall) return false; // fastcc with -tailcallopt is intended to provide a guaranteed // tail call optimization. Fastisel doesn't know how to do that. if (CC == CallingConv::Fast && GuaranteedTailCallOpt) return false; // Let SDISel handle vararg functions. const PointerType *PT = cast(CS.getCalledValue()->getType()); const FunctionType *FTy = cast(PT->getElementType()); if (FTy->isVarArg()) return false; // Fast-isel doesn't know about callee-pop yet. if (Subtarget->IsCalleePop(FTy->isVarArg(), CC)) return false; // Handle *simple* calls for now. const Type *RetTy = CS.getType(); MVT RetVT; if (RetTy->isVoidTy()) RetVT = MVT::isVoid; else if (!isTypeLegal(RetTy, RetVT, true)) return false; // Materialize callee address in a register. FIXME: GV address can be // handled with a CALLpcrel32 instead. X86AddressMode CalleeAM; if (!X86SelectCallAddress(Callee, CalleeAM)) return false; unsigned CalleeOp = 0; const GlobalValue *GV = 0; if (CalleeAM.GV != 0) { GV = CalleeAM.GV; } else if (CalleeAM.Base.Reg != 0) { CalleeOp = CalleeAM.Base.Reg; } else return false; // Allow calls which produce i1 results. bool AndToI1 = false; if (RetVT == MVT::i1) { RetVT = MVT::i8; AndToI1 = true; } // Deal with call operands first. SmallVector ArgVals; SmallVector Args; SmallVector ArgVTs; SmallVector ArgFlags; Args.reserve(CS.arg_size()); ArgVals.reserve(CS.arg_size()); ArgVTs.reserve(CS.arg_size()); ArgFlags.reserve(CS.arg_size()); for (ImmutableCallSite::arg_iterator i = CS.arg_begin(), e = CS.arg_end(); i != e; ++i) { unsigned Arg = getRegForValue(*i); if (Arg == 0) return false; ISD::ArgFlagsTy Flags; unsigned AttrInd = i - CS.arg_begin() + 1; if (CS.paramHasAttr(AttrInd, Attribute::SExt)) Flags.setSExt(); if (CS.paramHasAttr(AttrInd, Attribute::ZExt)) Flags.setZExt(); // FIXME: Only handle *easy* calls for now. if (CS.paramHasAttr(AttrInd, Attribute::InReg) || CS.paramHasAttr(AttrInd, Attribute::StructRet) || CS.paramHasAttr(AttrInd, Attribute::Nest) || CS.paramHasAttr(AttrInd, Attribute::ByVal)) return false; const Type *ArgTy = (*i)->getType(); MVT ArgVT; if (!isTypeLegal(ArgTy, ArgVT)) return false; unsigned OriginalAlignment = TD.getABITypeAlignment(ArgTy); Flags.setOrigAlign(OriginalAlignment); Args.push_back(Arg); ArgVals.push_back(*i); ArgVTs.push_back(ArgVT); ArgFlags.push_back(Flags); } // Analyze operands of the call, assigning locations to each operand. SmallVector ArgLocs; CCState CCInfo(CC, false, TM, ArgLocs, I->getParent()->getContext()); // Allocate shadow area for Win64 if (Subtarget->isTargetWin64()) { CCInfo.AllocateStack(32, 8); } CCInfo.AnalyzeCallOperands(ArgVTs, ArgFlags, CC_X86); // Get a count of how many bytes are to be pushed on the stack. unsigned NumBytes = CCInfo.getNextStackOffset(); // Issue CALLSEQ_START unsigned AdjStackDown = TM.getRegisterInfo()->getCallFrameSetupOpcode(); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(AdjStackDown)) .addImm(NumBytes); // Process argument: walk the register/memloc assignments, inserting // copies / loads. SmallVector RegArgs; for (unsigned i = 0, e = ArgLocs.size(); i != e; ++i) { CCValAssign &VA = ArgLocs[i]; unsigned Arg = Args[VA.getValNo()]; EVT ArgVT = ArgVTs[VA.getValNo()]; // Promote the value if needed. switch (VA.getLocInfo()) { default: llvm_unreachable("Unknown loc info!"); case CCValAssign::Full: break; case CCValAssign::SExt: { bool Emitted = X86FastEmitExtend(ISD::SIGN_EXTEND, VA.getLocVT(), Arg, ArgVT, Arg); assert(Emitted && "Failed to emit a sext!"); (void)Emitted; ArgVT = VA.getLocVT(); break; } case CCValAssign::ZExt: { bool Emitted = X86FastEmitExtend(ISD::ZERO_EXTEND, VA.getLocVT(), Arg, ArgVT, Arg); assert(Emitted && "Failed to emit a zext!"); (void)Emitted; ArgVT = VA.getLocVT(); break; } case CCValAssign::AExt: { // We don't handle MMX parameters yet. if (VA.getLocVT().isVector() && VA.getLocVT().getSizeInBits() == 128) return false; bool Emitted = X86FastEmitExtend(ISD::ANY_EXTEND, VA.getLocVT(), Arg, ArgVT, Arg); if (!Emitted) Emitted = X86FastEmitExtend(ISD::ZERO_EXTEND, VA.getLocVT(), Arg, ArgVT, Arg); if (!Emitted) Emitted = X86FastEmitExtend(ISD::SIGN_EXTEND, VA.getLocVT(), Arg, ArgVT, Arg); assert(Emitted && "Failed to emit a aext!"); (void)Emitted; ArgVT = VA.getLocVT(); break; } case CCValAssign::BCvt: { unsigned BC = FastEmit_r(ArgVT.getSimpleVT(), VA.getLocVT(), ISD::BITCAST, Arg, /*TODO: Kill=*/false); assert(BC != 0 && "Failed to emit a bitcast!"); Arg = BC; ArgVT = VA.getLocVT(); break; } } if (VA.isRegLoc()) { BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(TargetOpcode::COPY), VA.getLocReg()).addReg(Arg); RegArgs.push_back(VA.getLocReg()); } else { unsigned LocMemOffset = VA.getLocMemOffset(); X86AddressMode AM; AM.Base.Reg = StackPtr; AM.Disp = LocMemOffset; const Value *ArgVal = ArgVals[VA.getValNo()]; // If this is a really simple value, emit this with the Value* version of // X86FastEmitStore. If it isn't simple, we don't want to do this, as it // can cause us to reevaluate the argument. if (isa(ArgVal) || isa(ArgVal)) X86FastEmitStore(ArgVT, ArgVal, AM); else X86FastEmitStore(ArgVT, Arg, AM); } } // ELF / PIC requires GOT in the EBX register before function calls via PLT // GOT pointer. if (Subtarget->isPICStyleGOT()) { unsigned Base = getInstrInfo()->getGlobalBaseReg(FuncInfo.MF); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(TargetOpcode::COPY), X86::EBX).addReg(Base); } // Issue the call. MachineInstrBuilder MIB; if (CalleeOp) { // Register-indirect call. unsigned CallOpc; if (Subtarget->isTargetWin64()) CallOpc = X86::WINCALL64r; else if (Subtarget->is64Bit()) CallOpc = X86::CALL64r; else CallOpc = X86::CALL32r; MIB = BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(CallOpc)) .addReg(CalleeOp); } else { // Direct call. assert(GV && "Not a direct call"); unsigned CallOpc; if (Subtarget->isTargetWin64()) CallOpc = X86::WINCALL64pcrel32; else if (Subtarget->is64Bit()) CallOpc = X86::CALL64pcrel32; else CallOpc = X86::CALLpcrel32; // See if we need any target-specific flags on the GV operand. unsigned char OpFlags = 0; // On ELF targets, in both X86-64 and X86-32 mode, direct calls to // external symbols most go through the PLT in PIC mode. If the symbol // has hidden or protected visibility, or if it is static or local, then // we don't need to use the PLT - we can directly call it. if (Subtarget->isTargetELF() && TM.getRelocationModel() == Reloc::PIC_ && GV->hasDefaultVisibility() && !GV->hasLocalLinkage()) { OpFlags = X86II::MO_PLT; } else if (Subtarget->isPICStyleStubAny() && (GV->isDeclaration() || GV->isWeakForLinker()) && Subtarget->getDarwinVers() < 9) { // PC-relative references to external symbols should go through $stub, // unless we're building with the leopard linker or later, which // automatically synthesizes these stubs. OpFlags = X86II::MO_DARWIN_STUB; } MIB = BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(CallOpc)) .addGlobalAddress(GV, 0, OpFlags); } // Add an implicit use GOT pointer in EBX. if (Subtarget->isPICStyleGOT()) MIB.addReg(X86::EBX); // Add implicit physical register uses to the call. for (unsigned i = 0, e = RegArgs.size(); i != e; ++i) MIB.addReg(RegArgs[i]); // Issue CALLSEQ_END unsigned AdjStackUp = TM.getRegisterInfo()->getCallFrameDestroyOpcode(); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(AdjStackUp)) .addImm(NumBytes).addImm(0); // Now handle call return value (if any). SmallVector UsedRegs; if (RetVT != MVT::isVoid) { SmallVector RVLocs; CCState CCInfo(CC, false, TM, RVLocs, I->getParent()->getContext()); CCInfo.AnalyzeCallResult(RetVT, RetCC_X86); // Copy all of the result registers out of their specified physreg. assert(RVLocs.size() == 1 && "Can't handle multi-value calls!"); EVT CopyVT = RVLocs[0].getValVT(); TargetRegisterClass* DstRC = TLI.getRegClassFor(CopyVT); // If this is a call to a function that returns an fp value on the x87 fp // stack, but where we prefer to use the value in xmm registers, copy it // out as F80 and use a truncate to move it from fp stack reg to xmm reg. if ((RVLocs[0].getLocReg() == X86::ST0 || RVLocs[0].getLocReg() == X86::ST1) && isScalarFPTypeInSSEReg(RVLocs[0].getValVT())) { CopyVT = MVT::f80; DstRC = X86::RFP80RegisterClass; } unsigned ResultReg = createResultReg(DstRC); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(TargetOpcode::COPY), ResultReg).addReg(RVLocs[0].getLocReg()); UsedRegs.push_back(RVLocs[0].getLocReg()); if (CopyVT != RVLocs[0].getValVT()) { // Round the F80 the right size, which also moves to the appropriate xmm // register. This is accomplished by storing the F80 value in memory and // then loading it back. Ewww... EVT ResVT = RVLocs[0].getValVT(); unsigned Opc = ResVT == MVT::f32 ? X86::ST_Fp80m32 : X86::ST_Fp80m64; unsigned MemSize = ResVT.getSizeInBits()/8; int FI = MFI.CreateStackObject(MemSize, MemSize, false); addFrameReference(BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(Opc)), FI) .addReg(ResultReg); DstRC = ResVT == MVT::f32 ? X86::FR32RegisterClass : X86::FR64RegisterClass; Opc = ResVT == MVT::f32 ? X86::MOVSSrm : X86::MOVSDrm; ResultReg = createResultReg(DstRC); addFrameReference(BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(Opc), ResultReg), FI); } if (AndToI1) { // Mask out all but lowest bit for some call which produces an i1. unsigned AndResult = createResultReg(X86::GR8RegisterClass); BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(X86::AND8ri), AndResult).addReg(ResultReg).addImm(1); ResultReg = AndResult; } UpdateValueMap(I, ResultReg); } // Set all unused physreg defs as dead. static_cast(MIB)->setPhysRegsDeadExcept(UsedRegs, TRI); return true; } bool X86FastISel::TargetSelectInstruction(const Instruction *I) { switch (I->getOpcode()) { default: break; case Instruction::Load: return X86SelectLoad(I); case Instruction::Store: return X86SelectStore(I); case Instruction::Ret: return X86SelectRet(I); case Instruction::ICmp: case Instruction::FCmp: return X86SelectCmp(I); case Instruction::ZExt: return X86SelectZExt(I); case Instruction::Br: return X86SelectBranch(I); case Instruction::Call: return X86SelectCall(I); case Instruction::LShr: case Instruction::AShr: case Instruction::Shl: return X86SelectShift(I); case Instruction::Select: return X86SelectSelect(I); case Instruction::Trunc: return X86SelectTrunc(I); case Instruction::FPExt: return X86SelectFPExt(I); case Instruction::FPTrunc: return X86SelectFPTrunc(I); case Instruction::ExtractValue: return X86SelectExtractValue(I); case Instruction::IntToPtr: // Deliberate fall-through. case Instruction::PtrToInt: { EVT SrcVT = TLI.getValueType(I->getOperand(0)->getType()); EVT DstVT = TLI.getValueType(I->getType()); if (DstVT.bitsGT(SrcVT)) return X86SelectZExt(I); if (DstVT.bitsLT(SrcVT)) return X86SelectTrunc(I); unsigned Reg = getRegForValue(I->getOperand(0)); if (Reg == 0) return false; UpdateValueMap(I, Reg); return true; } } return false; } unsigned X86FastISel::TargetMaterializeConstant(const Constant *C) { MVT VT; if (!isTypeLegal(C->getType(), VT)) return false; // Get opcode and regclass of the output for the given load instruction. unsigned Opc = 0; const TargetRegisterClass *RC = NULL; switch (VT.SimpleTy) { default: return false; case MVT::i8: Opc = X86::MOV8rm; RC = X86::GR8RegisterClass; break; case MVT::i16: Opc = X86::MOV16rm; RC = X86::GR16RegisterClass; break; case MVT::i32: Opc = X86::MOV32rm; RC = X86::GR32RegisterClass; break; case MVT::i64: // Must be in x86-64 mode. Opc = X86::MOV64rm; RC = X86::GR64RegisterClass; break; case MVT::f32: if (Subtarget->hasSSE1()) { Opc = X86::MOVSSrm; RC = X86::FR32RegisterClass; } else { Opc = X86::LD_Fp32m; RC = X86::RFP32RegisterClass; } break; case MVT::f64: if (Subtarget->hasSSE2()) { Opc = X86::MOVSDrm; RC = X86::FR64RegisterClass; } else { Opc = X86::LD_Fp64m; RC = X86::RFP64RegisterClass; } break; case MVT::f80: // No f80 support yet. return false; } // Materialize addresses with LEA instructions. if (isa(C)) { X86AddressMode AM; if (X86SelectAddress(C, AM)) { if (TLI.getPointerTy() == MVT::i32) Opc = X86::LEA32r; else Opc = X86::LEA64r; unsigned ResultReg = createResultReg(RC); addFullAddress(BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(Opc), ResultReg), AM); return ResultReg; } return 0; } // MachineConstantPool wants an explicit alignment. unsigned Align = TD.getPrefTypeAlignment(C->getType()); if (Align == 0) { // Alignment of vector types. FIXME! Align = TD.getTypeAllocSize(C->getType()); } // x86-32 PIC requires a PIC base register for constant pools. unsigned PICBase = 0; unsigned char OpFlag = 0; if (Subtarget->isPICStyleStubPIC()) { // Not dynamic-no-pic OpFlag = X86II::MO_PIC_BASE_OFFSET; PICBase = getInstrInfo()->getGlobalBaseReg(FuncInfo.MF); } else if (Subtarget->isPICStyleGOT()) { OpFlag = X86II::MO_GOTOFF; PICBase = getInstrInfo()->getGlobalBaseReg(FuncInfo.MF); } else if (Subtarget->isPICStyleRIPRel() && TM.getCodeModel() == CodeModel::Small) { PICBase = X86::RIP; } // Create the load from the constant pool. unsigned MCPOffset = MCP.getConstantPoolIndex(C, Align); unsigned ResultReg = createResultReg(RC); addConstantPoolReference(BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(Opc), ResultReg), MCPOffset, PICBase, OpFlag); return ResultReg; } unsigned X86FastISel::TargetMaterializeAlloca(const AllocaInst *C) { // Fail on dynamic allocas. At this point, getRegForValue has already // checked its CSE maps, so if we're here trying to handle a dynamic // alloca, we're not going to succeed. X86SelectAddress has a // check for dynamic allocas, because it's called directly from // various places, but TargetMaterializeAlloca also needs a check // in order to avoid recursion between getRegForValue, // X86SelectAddrss, and TargetMaterializeAlloca. if (!FuncInfo.StaticAllocaMap.count(C)) return 0; X86AddressMode AM; if (!X86SelectAddress(C, AM)) return 0; unsigned Opc = Subtarget->is64Bit() ? X86::LEA64r : X86::LEA32r; TargetRegisterClass* RC = TLI.getRegClassFor(TLI.getPointerTy()); unsigned ResultReg = createResultReg(RC); addFullAddress(BuildMI(*FuncInfo.MBB, FuncInfo.InsertPt, DL, TII.get(Opc), ResultReg), AM); return ResultReg; } /// TryToFoldLoad - The specified machine instr operand is a vreg, and that /// vreg is being provided by the specified load instruction. If possible, /// try to fold the load as an operand to the instruction, returning true if /// possible. bool X86FastISel::TryToFoldLoad(MachineInstr *MI, unsigned OpNo, const LoadInst *LI) { X86AddressMode AM; if (!X86SelectAddress(LI->getOperand(0), AM)) return false; X86InstrInfo &XII = (X86InstrInfo&)TII; unsigned Size = TD.getTypeAllocSize(LI->getType()); unsigned Alignment = LI->getAlignment(); SmallVector AddrOps; AM.getFullAddress(AddrOps); MachineInstr *Result = XII.foldMemoryOperandImpl(*FuncInfo.MF, MI, OpNo, AddrOps, Size, Alignment); if (Result == 0) return false; FuncInfo.MBB->insert(FuncInfo.InsertPt, Result); MI->eraseFromParent(); return true; } namespace llvm { llvm::FastISel *X86::createFastISel(FunctionLoweringInfo &funcInfo) { return new X86FastISel(funcInfo); } }