llvm-6502/lib/Target/ARM/ARMCodeEmitter.cpp
Daniel Dunbar ce63ffb52f More migration to raw_ostream, the water has dried up around the iostream hole.
- Some clients which used DOUT have moved to DEBUG. We are deprecating the
   "magic" DOUT behavior which avoided calling printing functions when the
   statement was disabled. In addition to being unnecessary magic, it had the
   downside of leaving code in -Asserts builds, and of hiding potentially
   unnecessary computations.


git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@77019 91177308-0d34-0410-b5e6-96231b3b80d8
2009-07-25 00:23:56 +00:00

1427 lines
46 KiB
C++

//===-- ARM/ARMCodeEmitter.cpp - Convert ARM code to machine code ---------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file contains the pass that transforms the ARM machine instructions into
// relocatable machine code.
//
//===----------------------------------------------------------------------===//
#define DEBUG_TYPE "jit"
#include "ARM.h"
#include "ARMAddressingModes.h"
#include "ARMConstantPoolValue.h"
#include "ARMInstrInfo.h"
#include "ARMRelocations.h"
#include "ARMSubtarget.h"
#include "ARMTargetMachine.h"
#include "llvm/Constants.h"
#include "llvm/DerivedTypes.h"
#include "llvm/Function.h"
#include "llvm/PassManager.h"
#include "llvm/CodeGen/MachineCodeEmitter.h"
#include "llvm/CodeGen/JITCodeEmitter.h"
#include "llvm/CodeGen/ObjectCodeEmitter.h"
#include "llvm/CodeGen/MachineConstantPool.h"
#include "llvm/CodeGen/MachineFunctionPass.h"
#include "llvm/CodeGen/MachineInstr.h"
#include "llvm/CodeGen/MachineJumpTableInfo.h"
#include "llvm/CodeGen/Passes.h"
#include "llvm/ADT/Statistic.h"
#include "llvm/Support/Compiler.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/raw_ostream.h"
#ifndef NDEBUG
#include <iomanip>
#endif
using namespace llvm;
STATISTIC(NumEmitted, "Number of machine instructions emitted");
namespace {
class ARMCodeEmitter {
public:
/// getBinaryCodeForInstr - This function, generated by the
/// CodeEmitterGenerator using TableGen, produces the binary encoding for
/// machine instructions.
unsigned getBinaryCodeForInstr(const MachineInstr &MI);
};
template<class CodeEmitter>
class VISIBILITY_HIDDEN Emitter : public MachineFunctionPass,
public ARMCodeEmitter {
ARMJITInfo *JTI;
const ARMInstrInfo *II;
const TargetData *TD;
TargetMachine &TM;
CodeEmitter &MCE;
const std::vector<MachineConstantPoolEntry> *MCPEs;
const std::vector<MachineJumpTableEntry> *MJTEs;
bool IsPIC;
public:
static char ID;
explicit Emitter(TargetMachine &tm, CodeEmitter &mce)
: MachineFunctionPass(&ID), JTI(0), II(0), TD(0), TM(tm),
MCE(mce), MCPEs(0), MJTEs(0),
IsPIC(TM.getRelocationModel() == Reloc::PIC_) {}
Emitter(TargetMachine &tm, CodeEmitter &mce,
const ARMInstrInfo &ii, const TargetData &td)
: MachineFunctionPass(&ID), JTI(0), II(&ii), TD(&td), TM(tm),
MCE(mce), MCPEs(0), MJTEs(0),
IsPIC(TM.getRelocationModel() == Reloc::PIC_) {}
bool runOnMachineFunction(MachineFunction &MF);
virtual const char *getPassName() const {
return "ARM Machine Code Emitter";
}
void emitInstruction(const MachineInstr &MI);
private:
void emitWordLE(unsigned Binary);
void emitDWordLE(uint64_t Binary);
void emitConstPoolInstruction(const MachineInstr &MI);
void emitMOVi2piecesInstruction(const MachineInstr &MI);
void emitLEApcrelJTInstruction(const MachineInstr &MI);
void emitPseudoMoveInstruction(const MachineInstr &MI);
void addPCLabel(unsigned LabelID);
void emitPseudoInstruction(const MachineInstr &MI);
unsigned getMachineSoRegOpValue(const MachineInstr &MI,
const TargetInstrDesc &TID,
const MachineOperand &MO,
unsigned OpIdx);
unsigned getMachineSoImmOpValue(unsigned SoImm);
unsigned getAddrModeSBit(const MachineInstr &MI,
const TargetInstrDesc &TID) const;
void emitDataProcessingInstruction(const MachineInstr &MI,
unsigned ImplicitRd = 0,
unsigned ImplicitRn = 0);
void emitLoadStoreInstruction(const MachineInstr &MI,
unsigned ImplicitRd = 0,
unsigned ImplicitRn = 0);
void emitMiscLoadStoreInstruction(const MachineInstr &MI,
unsigned ImplicitRn = 0);
void emitLoadStoreMultipleInstruction(const MachineInstr &MI);
void emitMulFrmInstruction(const MachineInstr &MI);
void emitExtendInstruction(const MachineInstr &MI);
void emitMiscArithInstruction(const MachineInstr &MI);
void emitBranchInstruction(const MachineInstr &MI);
void emitInlineJumpTable(unsigned JTIndex);
void emitMiscBranchInstruction(const MachineInstr &MI);
void emitVFPArithInstruction(const MachineInstr &MI);
void emitVFPConversionInstruction(const MachineInstr &MI);
void emitVFPLoadStoreInstruction(const MachineInstr &MI);
void emitVFPLoadStoreMultipleInstruction(const MachineInstr &MI);
void emitMiscInstruction(const MachineInstr &MI);
/// getMachineOpValue - Return binary encoding of operand. If the machine
/// operand requires relocation, record the relocation and return zero.
unsigned getMachineOpValue(const MachineInstr &MI,const MachineOperand &MO);
unsigned getMachineOpValue(const MachineInstr &MI, unsigned OpIdx) {
return getMachineOpValue(MI, MI.getOperand(OpIdx));
}
/// getShiftOp - Return the shift opcode (bit[6:5]) of the immediate value.
///
unsigned getShiftOp(unsigned Imm) const ;
/// Routines that handle operands which add machine relocations which are
/// fixed up by the relocation stage.
void emitGlobalAddress(GlobalValue *GV, unsigned Reloc,
bool NeedStub, intptr_t ACPV = 0);
void emitExternalSymbolAddress(const char *ES, unsigned Reloc);
void emitConstPoolAddress(unsigned CPI, unsigned Reloc);
void emitJumpTableAddress(unsigned JTIndex, unsigned Reloc);
void emitMachineBasicBlock(MachineBasicBlock *BB, unsigned Reloc,
intptr_t JTBase = 0);
};
template <class CodeEmitter>
char Emitter<CodeEmitter>::ID = 0;
}
/// createARMCodeEmitterPass - Return a pass that emits the collected ARM code
/// to the specified MCE object.
FunctionPass *llvm::createARMCodeEmitterPass(ARMBaseTargetMachine &TM,
MachineCodeEmitter &MCE) {
return new Emitter<MachineCodeEmitter>(TM, MCE);
}
FunctionPass *llvm::createARMJITCodeEmitterPass(ARMBaseTargetMachine &TM,
JITCodeEmitter &JCE) {
return new Emitter<JITCodeEmitter>(TM, JCE);
}
FunctionPass *llvm::createARMObjectCodeEmitterPass(ARMBaseTargetMachine &TM,
ObjectCodeEmitter &OCE) {
return new Emitter<ObjectCodeEmitter>(TM, OCE);
}
template<class CodeEmitter>
bool Emitter<CodeEmitter>::runOnMachineFunction(MachineFunction &MF) {
assert((MF.getTarget().getRelocationModel() != Reloc::Default ||
MF.getTarget().getRelocationModel() != Reloc::Static) &&
"JIT relocation model must be set to static or default!");
II = ((ARMTargetMachine&)MF.getTarget()).getInstrInfo();
TD = ((ARMTargetMachine&)MF.getTarget()).getTargetData();
JTI = ((ARMTargetMachine&)MF.getTarget()).getJITInfo();
MCPEs = &MF.getConstantPool()->getConstants();
MJTEs = &MF.getJumpTableInfo()->getJumpTables();
IsPIC = TM.getRelocationModel() == Reloc::PIC_;
JTI->Initialize(MF, IsPIC);
do {
DEBUG(errs() << "JITTing function '"
<< MF.getFunction()->getName() << "'\n");
MCE.startFunction(MF);
for (MachineFunction::iterator MBB = MF.begin(), E = MF.end();
MBB != E; ++MBB) {
MCE.StartMachineBasicBlock(MBB);
for (MachineBasicBlock::const_iterator I = MBB->begin(), E = MBB->end();
I != E; ++I)
emitInstruction(*I);
}
} while (MCE.finishFunction(MF));
return false;
}
/// getShiftOp - Return the shift opcode (bit[6:5]) of the immediate value.
///
template<class CodeEmitter>
unsigned Emitter<CodeEmitter>::getShiftOp(unsigned Imm) const {
switch (ARM_AM::getAM2ShiftOpc(Imm)) {
default: llvm_unreachable("Unknown shift opc!");
case ARM_AM::asr: return 2;
case ARM_AM::lsl: return 0;
case ARM_AM::lsr: return 1;
case ARM_AM::ror:
case ARM_AM::rrx: return 3;
}
return 0;
}
/// getMachineOpValue - Return binary encoding of operand. If the machine
/// operand requires relocation, record the relocation and return zero.
template<class CodeEmitter>
unsigned Emitter<CodeEmitter>::getMachineOpValue(const MachineInstr &MI,
const MachineOperand &MO) {
if (MO.isReg())
return ARMRegisterInfo::getRegisterNumbering(MO.getReg());
else if (MO.isImm())
return static_cast<unsigned>(MO.getImm());
else if (MO.isGlobal())
emitGlobalAddress(MO.getGlobal(), ARM::reloc_arm_branch, true);
else if (MO.isSymbol())
emitExternalSymbolAddress(MO.getSymbolName(), ARM::reloc_arm_branch);
else if (MO.isCPI()) {
const TargetInstrDesc &TID = MI.getDesc();
// For VFP load, the immediate offset is multiplied by 4.
unsigned Reloc = ((TID.TSFlags & ARMII::FormMask) == ARMII::VFPLdStFrm)
? ARM::reloc_arm_vfp_cp_entry : ARM::reloc_arm_cp_entry;
emitConstPoolAddress(MO.getIndex(), Reloc);
} else if (MO.isJTI())
emitJumpTableAddress(MO.getIndex(), ARM::reloc_arm_relative);
else if (MO.isMBB())
emitMachineBasicBlock(MO.getMBB(), ARM::reloc_arm_branch);
else {
#ifndef NDEBUG
cerr << MO;
#endif
llvm_unreachable(0);
}
return 0;
}
/// emitGlobalAddress - Emit the specified address to the code stream.
///
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitGlobalAddress(GlobalValue *GV, unsigned Reloc,
bool NeedStub, intptr_t ACPV) {
MCE.addRelocation(MachineRelocation::getGV(MCE.getCurrentPCOffset(), Reloc,
GV, ACPV, NeedStub));
}
/// emitExternalSymbolAddress - Arrange for the address of an external symbol to
/// be emitted to the current location in the function, and allow it to be PC
/// relative.
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitExternalSymbolAddress(const char *ES,
unsigned Reloc) {
MCE.addRelocation(MachineRelocation::getExtSym(MCE.getCurrentPCOffset(),
Reloc, ES));
}
/// emitConstPoolAddress - Arrange for the address of an constant pool
/// to be emitted to the current location in the function, and allow it to be PC
/// relative.
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitConstPoolAddress(unsigned CPI,
unsigned Reloc) {
// Tell JIT emitter we'll resolve the address.
MCE.addRelocation(MachineRelocation::getConstPool(MCE.getCurrentPCOffset(),
Reloc, CPI, 0, true));
}
/// emitJumpTableAddress - Arrange for the address of a jump table to
/// be emitted to the current location in the function, and allow it to be PC
/// relative.
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitJumpTableAddress(unsigned JTIndex,
unsigned Reloc) {
MCE.addRelocation(MachineRelocation::getJumpTable(MCE.getCurrentPCOffset(),
Reloc, JTIndex, 0, true));
}
/// emitMachineBasicBlock - Emit the specified address basic block.
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitMachineBasicBlock(MachineBasicBlock *BB,
unsigned Reloc, intptr_t JTBase) {
MCE.addRelocation(MachineRelocation::getBB(MCE.getCurrentPCOffset(),
Reloc, BB, JTBase));
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitWordLE(unsigned Binary) {
#ifndef NDEBUG
DOUT << " 0x" << std::hex << std::setw(8) << std::setfill('0')
<< Binary << std::dec << "\n";
#endif
MCE.emitWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitDWordLE(uint64_t Binary) {
#ifndef NDEBUG
DOUT << " 0x" << std::hex << std::setw(8) << std::setfill('0')
<< (unsigned)Binary << std::dec << "\n";
DOUT << " 0x" << std::hex << std::setw(8) << std::setfill('0')
<< (unsigned)(Binary >> 32) << std::dec << "\n";
#endif
MCE.emitDWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitInstruction(const MachineInstr &MI) {
DOUT << "JIT: " << (void*)MCE.getCurrentPCValue() << ":\t" << MI;
MCE.processDebugLoc(MI.getDebugLoc());
NumEmitted++; // Keep track of the # of mi's emitted
switch (MI.getDesc().TSFlags & ARMII::FormMask) {
default: {
llvm_unreachable("Unhandled instruction encoding format!");
break;
}
case ARMII::Pseudo:
emitPseudoInstruction(MI);
break;
case ARMII::DPFrm:
case ARMII::DPSoRegFrm:
emitDataProcessingInstruction(MI);
break;
case ARMII::LdFrm:
case ARMII::StFrm:
emitLoadStoreInstruction(MI);
break;
case ARMII::LdMiscFrm:
case ARMII::StMiscFrm:
emitMiscLoadStoreInstruction(MI);
break;
case ARMII::LdStMulFrm:
emitLoadStoreMultipleInstruction(MI);
break;
case ARMII::MulFrm:
emitMulFrmInstruction(MI);
break;
case ARMII::ExtFrm:
emitExtendInstruction(MI);
break;
case ARMII::ArithMiscFrm:
emitMiscArithInstruction(MI);
break;
case ARMII::BrFrm:
emitBranchInstruction(MI);
break;
case ARMII::BrMiscFrm:
emitMiscBranchInstruction(MI);
break;
// VFP instructions.
case ARMII::VFPUnaryFrm:
case ARMII::VFPBinaryFrm:
emitVFPArithInstruction(MI);
break;
case ARMII::VFPConv1Frm:
case ARMII::VFPConv2Frm:
case ARMII::VFPConv3Frm:
case ARMII::VFPConv4Frm:
case ARMII::VFPConv5Frm:
emitVFPConversionInstruction(MI);
break;
case ARMII::VFPLdStFrm:
emitVFPLoadStoreInstruction(MI);
break;
case ARMII::VFPLdStMulFrm:
emitVFPLoadStoreMultipleInstruction(MI);
break;
case ARMII::VFPMiscFrm:
emitMiscInstruction(MI);
break;
}
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitConstPoolInstruction(const MachineInstr &MI) {
unsigned CPI = MI.getOperand(0).getImm(); // CP instruction index.
unsigned CPIndex = MI.getOperand(1).getIndex(); // Actual cp entry index.
const MachineConstantPoolEntry &MCPE = (*MCPEs)[CPIndex];
// Remember the CONSTPOOL_ENTRY address for later relocation.
JTI->addConstantPoolEntryAddr(CPI, MCE.getCurrentPCValue());
// Emit constpool island entry. In most cases, the actual values will be
// resolved and relocated after code emission.
if (MCPE.isMachineConstantPoolEntry()) {
ARMConstantPoolValue *ACPV =
static_cast<ARMConstantPoolValue*>(MCPE.Val.MachineCPVal);
DOUT << " ** ARM constant pool #" << CPI << " @ "
<< (void*)MCE.getCurrentPCValue() << " " << *ACPV << '\n';
GlobalValue *GV = ACPV->getGV();
if (GV) {
assert(!ACPV->isStub() && "Don't know how to deal this yet!");
if (ACPV->isNonLazyPointer())
MCE.addRelocation(MachineRelocation::getIndirectSymbol(
MCE.getCurrentPCOffset(), ARM::reloc_arm_machine_cp_entry, GV,
(intptr_t)ACPV, false));
else
emitGlobalAddress(GV, ARM::reloc_arm_machine_cp_entry,
ACPV->isStub() || isa<Function>(GV), (intptr_t)ACPV);
} else {
assert(!ACPV->isNonLazyPointer() && "Don't know how to deal this yet!");
emitExternalSymbolAddress(ACPV->getSymbol(), ARM::reloc_arm_absolute);
}
emitWordLE(0);
} else {
Constant *CV = MCPE.Val.ConstVal;
DEBUG({
errs() << " ** Constant pool #" << CPI << " @ "
<< (void*)MCE.getCurrentPCValue() << " ";
if (const Function *F = dyn_cast<Function>(CV))
errs() << F->getName();
else
errs() << *CV;
errs() << '\n';
});
if (GlobalValue *GV = dyn_cast<GlobalValue>(CV)) {
emitGlobalAddress(GV, ARM::reloc_arm_absolute, isa<Function>(GV));
emitWordLE(0);
} else if (const ConstantInt *CI = dyn_cast<ConstantInt>(CV)) {
uint32_t Val = *(uint32_t*)CI->getValue().getRawData();
emitWordLE(Val);
} else if (const ConstantFP *CFP = dyn_cast<ConstantFP>(CV)) {
if (CFP->getType() == Type::FloatTy)
emitWordLE(CFP->getValueAPF().bitcastToAPInt().getZExtValue());
else if (CFP->getType() == Type::DoubleTy)
emitDWordLE(CFP->getValueAPF().bitcastToAPInt().getZExtValue());
else {
llvm_unreachable("Unable to handle this constantpool entry!");
}
} else {
llvm_unreachable("Unable to handle this constantpool entry!");
}
}
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitMOVi2piecesInstruction(const MachineInstr &MI) {
const MachineOperand &MO0 = MI.getOperand(0);
const MachineOperand &MO1 = MI.getOperand(1);
assert(MO1.isImm() && ARM_AM::getSOImmVal(MO1.isImm()) != -1 &&
"Not a valid so_imm value!");
unsigned V1 = ARM_AM::getSOImmTwoPartFirst(MO1.getImm());
unsigned V2 = ARM_AM::getSOImmTwoPartSecond(MO1.getImm());
// Emit the 'mov' instruction.
unsigned Binary = 0xd << 21; // mov: Insts{24-21} = 0b1101
// Set the conditional execution predicate.
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
// Encode Rd.
Binary |= getMachineOpValue(MI, MO0) << ARMII::RegRdShift;
// Encode so_imm.
// Set bit I(25) to identify this is the immediate form of <shifter_op>
Binary |= 1 << ARMII::I_BitShift;
Binary |= getMachineSoImmOpValue(V1);
emitWordLE(Binary);
// Now the 'orr' instruction.
Binary = 0xc << 21; // orr: Insts{24-21} = 0b1100
// Set the conditional execution predicate.
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
// Encode Rd.
Binary |= getMachineOpValue(MI, MO0) << ARMII::RegRdShift;
// Encode Rn.
Binary |= getMachineOpValue(MI, MO0) << ARMII::RegRnShift;
// Encode so_imm.
// Set bit I(25) to identify this is the immediate form of <shifter_op>
Binary |= 1 << ARMII::I_BitShift;
Binary |= getMachineSoImmOpValue(V2);
emitWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitLEApcrelJTInstruction(const MachineInstr &MI) {
// It's basically add r, pc, (LJTI - $+8)
const TargetInstrDesc &TID = MI.getDesc();
// Emit the 'add' instruction.
unsigned Binary = 0x4 << 21; // add: Insts{24-31} = 0b0100
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
// Encode S bit if MI modifies CPSR.
Binary |= getAddrModeSBit(MI, TID);
// Encode Rd.
Binary |= getMachineOpValue(MI, 0) << ARMII::RegRdShift;
// Encode Rn which is PC.
Binary |= ARMRegisterInfo::getRegisterNumbering(ARM::PC) << ARMII::RegRnShift;
// Encode the displacement.
Binary |= 1 << ARMII::I_BitShift;
emitJumpTableAddress(MI.getOperand(1).getIndex(), ARM::reloc_arm_jt_base);
emitWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitPseudoMoveInstruction(const MachineInstr &MI) {
unsigned Opcode = MI.getDesc().Opcode;
// Part of binary is determined by TableGn.
unsigned Binary = getBinaryCodeForInstr(MI);
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
// Encode S bit if MI modifies CPSR.
if (Opcode == ARM::MOVsrl_flag || Opcode == ARM::MOVsra_flag)
Binary |= 1 << ARMII::S_BitShift;
// Encode register def if there is one.
Binary |= getMachineOpValue(MI, 0) << ARMII::RegRdShift;
// Encode the shift operation.
switch (Opcode) {
default: break;
case ARM::MOVrx:
// rrx
Binary |= 0x6 << 4;
break;
case ARM::MOVsrl_flag:
// lsr #1
Binary |= (0x2 << 4) | (1 << 7);
break;
case ARM::MOVsra_flag:
// asr #1
Binary |= (0x4 << 4) | (1 << 7);
break;
}
// Encode register Rm.
Binary |= getMachineOpValue(MI, 1);
emitWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::addPCLabel(unsigned LabelID) {
DOUT << " ** LPC" << LabelID << " @ "
<< (void*)MCE.getCurrentPCValue() << '\n';
JTI->addPCLabelAddr(LabelID, MCE.getCurrentPCValue());
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitPseudoInstruction(const MachineInstr &MI) {
unsigned Opcode = MI.getDesc().Opcode;
switch (Opcode) {
default:
llvm_unreachable("ARMCodeEmitter::emitPseudoInstruction");//FIXME:
case TargetInstrInfo::INLINEASM: {
// We allow inline assembler nodes with empty bodies - they can
// implicitly define registers, which is ok for JIT.
if (MI.getOperand(0).getSymbolName()[0]) {
llvm_report_error("JIT does not support inline asm!");
}
break;
}
case TargetInstrInfo::DBG_LABEL:
case TargetInstrInfo::EH_LABEL:
MCE.emitLabel(MI.getOperand(0).getImm());
break;
case TargetInstrInfo::IMPLICIT_DEF:
case TargetInstrInfo::DECLARE:
case ARM::DWARF_LOC:
// Do nothing.
break;
case ARM::CONSTPOOL_ENTRY:
emitConstPoolInstruction(MI);
break;
case ARM::PICADD: {
// Remember of the address of the PC label for relocation later.
addPCLabel(MI.getOperand(2).getImm());
// PICADD is just an add instruction that implicitly read pc.
emitDataProcessingInstruction(MI, 0, ARM::PC);
break;
}
case ARM::PICLDR:
case ARM::PICLDRB:
case ARM::PICSTR:
case ARM::PICSTRB: {
// Remember of the address of the PC label for relocation later.
addPCLabel(MI.getOperand(2).getImm());
// These are just load / store instructions that implicitly read pc.
emitLoadStoreInstruction(MI, 0, ARM::PC);
break;
}
case ARM::PICLDRH:
case ARM::PICLDRSH:
case ARM::PICLDRSB:
case ARM::PICSTRH: {
// Remember of the address of the PC label for relocation later.
addPCLabel(MI.getOperand(2).getImm());
// These are just load / store instructions that implicitly read pc.
emitMiscLoadStoreInstruction(MI, ARM::PC);
break;
}
case ARM::MOVi2pieces:
// Two instructions to materialize a constant.
emitMOVi2piecesInstruction(MI);
break;
case ARM::LEApcrelJT:
// Materialize jumptable address.
emitLEApcrelJTInstruction(MI);
break;
case ARM::MOVrx:
case ARM::MOVsrl_flag:
case ARM::MOVsra_flag:
emitPseudoMoveInstruction(MI);
break;
}
}
template<class CodeEmitter>
unsigned Emitter<CodeEmitter>::getMachineSoRegOpValue(
const MachineInstr &MI,
const TargetInstrDesc &TID,
const MachineOperand &MO,
unsigned OpIdx) {
unsigned Binary = getMachineOpValue(MI, MO);
const MachineOperand &MO1 = MI.getOperand(OpIdx + 1);
const MachineOperand &MO2 = MI.getOperand(OpIdx + 2);
ARM_AM::ShiftOpc SOpc = ARM_AM::getSORegShOp(MO2.getImm());
// Encode the shift opcode.
unsigned SBits = 0;
unsigned Rs = MO1.getReg();
if (Rs) {
// Set shift operand (bit[7:4]).
// LSL - 0001
// LSR - 0011
// ASR - 0101
// ROR - 0111
// RRX - 0110 and bit[11:8] clear.
switch (SOpc) {
default: llvm_unreachable("Unknown shift opc!");
case ARM_AM::lsl: SBits = 0x1; break;
case ARM_AM::lsr: SBits = 0x3; break;
case ARM_AM::asr: SBits = 0x5; break;
case ARM_AM::ror: SBits = 0x7; break;
case ARM_AM::rrx: SBits = 0x6; break;
}
} else {
// Set shift operand (bit[6:4]).
// LSL - 000
// LSR - 010
// ASR - 100
// ROR - 110
switch (SOpc) {
default: llvm_unreachable("Unknown shift opc!");
case ARM_AM::lsl: SBits = 0x0; break;
case ARM_AM::lsr: SBits = 0x2; break;
case ARM_AM::asr: SBits = 0x4; break;
case ARM_AM::ror: SBits = 0x6; break;
}
}
Binary |= SBits << 4;
if (SOpc == ARM_AM::rrx)
return Binary;
// Encode the shift operation Rs or shift_imm (except rrx).
if (Rs) {
// Encode Rs bit[11:8].
assert(ARM_AM::getSORegOffset(MO2.getImm()) == 0);
return Binary |
(ARMRegisterInfo::getRegisterNumbering(Rs) << ARMII::RegRsShift);
}
// Encode shift_imm bit[11:7].
return Binary | ARM_AM::getSORegOffset(MO2.getImm()) << 7;
}
template<class CodeEmitter>
unsigned Emitter<CodeEmitter>::getMachineSoImmOpValue(unsigned SoImm) {
int SoImmVal = ARM_AM::getSOImmVal(SoImm);
assert(SoImmVal != -1 && "Not a valid so_imm value!");
// Encode rotate_imm.
unsigned Binary = (ARM_AM::getSOImmValRot((unsigned)SoImmVal) >> 1)
<< ARMII::SoRotImmShift;
// Encode immed_8.
Binary |= ARM_AM::getSOImmValImm((unsigned)SoImmVal);
return Binary;
}
template<class CodeEmitter>
unsigned Emitter<CodeEmitter>::getAddrModeSBit(const MachineInstr &MI,
const TargetInstrDesc &TID) const {
for (unsigned i = MI.getNumOperands(), e = TID.getNumOperands(); i != e; --i){
const MachineOperand &MO = MI.getOperand(i-1);
if (MO.isReg() && MO.isDef() && MO.getReg() == ARM::CPSR)
return 1 << ARMII::S_BitShift;
}
return 0;
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitDataProcessingInstruction(
const MachineInstr &MI,
unsigned ImplicitRd,
unsigned ImplicitRn) {
const TargetInstrDesc &TID = MI.getDesc();
if (TID.Opcode == ARM::BFC) {
llvm_report_error("ERROR: ARMv6t2 JIT is not yet supported.");
}
// Part of binary is determined by TableGn.
unsigned Binary = getBinaryCodeForInstr(MI);
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
// Encode S bit if MI modifies CPSR.
Binary |= getAddrModeSBit(MI, TID);
// Encode register def if there is one.
unsigned NumDefs = TID.getNumDefs();
unsigned OpIdx = 0;
if (NumDefs)
Binary |= getMachineOpValue(MI, OpIdx++) << ARMII::RegRdShift;
else if (ImplicitRd)
// Special handling for implicit use (e.g. PC).
Binary |= (ARMRegisterInfo::getRegisterNumbering(ImplicitRd)
<< ARMII::RegRdShift);
// If this is a two-address operand, skip it. e.g. MOVCCr operand 1.
if (TID.getOperandConstraint(OpIdx, TOI::TIED_TO) != -1)
++OpIdx;
// Encode first non-shifter register operand if there is one.
bool isUnary = TID.TSFlags & ARMII::UnaryDP;
if (!isUnary) {
if (ImplicitRn)
// Special handling for implicit use (e.g. PC).
Binary |= (ARMRegisterInfo::getRegisterNumbering(ImplicitRn)
<< ARMII::RegRnShift);
else {
Binary |= getMachineOpValue(MI, OpIdx) << ARMII::RegRnShift;
++OpIdx;
}
}
// Encode shifter operand.
const MachineOperand &MO = MI.getOperand(OpIdx);
if ((TID.TSFlags & ARMII::FormMask) == ARMII::DPSoRegFrm) {
// Encode SoReg.
emitWordLE(Binary | getMachineSoRegOpValue(MI, TID, MO, OpIdx));
return;
}
if (MO.isReg()) {
// Encode register Rm.
emitWordLE(Binary | ARMRegisterInfo::getRegisterNumbering(MO.getReg()));
return;
}
// Encode so_imm.
Binary |= getMachineSoImmOpValue((unsigned)MO.getImm());
emitWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitLoadStoreInstruction(
const MachineInstr &MI,
unsigned ImplicitRd,
unsigned ImplicitRn) {
const TargetInstrDesc &TID = MI.getDesc();
unsigned Form = TID.TSFlags & ARMII::FormMask;
bool IsPrePost = (TID.TSFlags & ARMII::IndexModeMask) != 0;
// Part of binary is determined by TableGn.
unsigned Binary = getBinaryCodeForInstr(MI);
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
unsigned OpIdx = 0;
// Operand 0 of a pre- and post-indexed store is the address base
// writeback. Skip it.
bool Skipped = false;
if (IsPrePost && Form == ARMII::StFrm) {
++OpIdx;
Skipped = true;
}
// Set first operand
if (ImplicitRd)
// Special handling for implicit use (e.g. PC).
Binary |= (ARMRegisterInfo::getRegisterNumbering(ImplicitRd)
<< ARMII::RegRdShift);
else
Binary |= getMachineOpValue(MI, OpIdx++) << ARMII::RegRdShift;
// Set second operand
if (ImplicitRn)
// Special handling for implicit use (e.g. PC).
Binary |= (ARMRegisterInfo::getRegisterNumbering(ImplicitRn)
<< ARMII::RegRnShift);
else
Binary |= getMachineOpValue(MI, OpIdx++) << ARMII::RegRnShift;
// If this is a two-address operand, skip it. e.g. LDR_PRE.
if (!Skipped && TID.getOperandConstraint(OpIdx, TOI::TIED_TO) != -1)
++OpIdx;
const MachineOperand &MO2 = MI.getOperand(OpIdx);
unsigned AM2Opc = (ImplicitRn == ARM::PC)
? 0 : MI.getOperand(OpIdx+1).getImm();
// Set bit U(23) according to sign of immed value (positive or negative).
Binary |= ((ARM_AM::getAM2Op(AM2Opc) == ARM_AM::add ? 1 : 0) <<
ARMII::U_BitShift);
if (!MO2.getReg()) { // is immediate
if (ARM_AM::getAM2Offset(AM2Opc))
// Set the value of offset_12 field
Binary |= ARM_AM::getAM2Offset(AM2Opc);
emitWordLE(Binary);
return;
}
// Set bit I(25), because this is not in immediate enconding.
Binary |= 1 << ARMII::I_BitShift;
assert(TargetRegisterInfo::isPhysicalRegister(MO2.getReg()));
// Set bit[3:0] to the corresponding Rm register
Binary |= ARMRegisterInfo::getRegisterNumbering(MO2.getReg());
// If this instr is in scaled register offset/index instruction, set
// shift_immed(bit[11:7]) and shift(bit[6:5]) fields.
if (unsigned ShImm = ARM_AM::getAM2Offset(AM2Opc)) {
Binary |= getShiftOp(AM2Opc) << ARMII::ShiftImmShift; // shift
Binary |= ShImm << ARMII::ShiftShift; // shift_immed
}
emitWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitMiscLoadStoreInstruction(const MachineInstr &MI,
unsigned ImplicitRn) {
const TargetInstrDesc &TID = MI.getDesc();
unsigned Form = TID.TSFlags & ARMII::FormMask;
bool IsPrePost = (TID.TSFlags & ARMII::IndexModeMask) != 0;
// Part of binary is determined by TableGn.
unsigned Binary = getBinaryCodeForInstr(MI);
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
unsigned OpIdx = 0;
// Operand 0 of a pre- and post-indexed store is the address base
// writeback. Skip it.
bool Skipped = false;
if (IsPrePost && Form == ARMII::StMiscFrm) {
++OpIdx;
Skipped = true;
}
// Set first operand
Binary |= getMachineOpValue(MI, OpIdx++) << ARMII::RegRdShift;
// Skip LDRD and STRD's second operand.
if (TID.Opcode == ARM::LDRD || TID.Opcode == ARM::STRD)
++OpIdx;
// Set second operand
if (ImplicitRn)
// Special handling for implicit use (e.g. PC).
Binary |= (ARMRegisterInfo::getRegisterNumbering(ImplicitRn)
<< ARMII::RegRnShift);
else
Binary |= getMachineOpValue(MI, OpIdx++) << ARMII::RegRnShift;
// If this is a two-address operand, skip it. e.g. LDRH_POST.
if (!Skipped && TID.getOperandConstraint(OpIdx, TOI::TIED_TO) != -1)
++OpIdx;
const MachineOperand &MO2 = MI.getOperand(OpIdx);
unsigned AM3Opc = (ImplicitRn == ARM::PC)
? 0 : MI.getOperand(OpIdx+1).getImm();
// Set bit U(23) according to sign of immed value (positive or negative)
Binary |= ((ARM_AM::getAM3Op(AM3Opc) == ARM_AM::add ? 1 : 0) <<
ARMII::U_BitShift);
// If this instr is in register offset/index encoding, set bit[3:0]
// to the corresponding Rm register.
if (MO2.getReg()) {
Binary |= ARMRegisterInfo::getRegisterNumbering(MO2.getReg());
emitWordLE(Binary);
return;
}
// This instr is in immediate offset/index encoding, set bit 22 to 1.
Binary |= 1 << ARMII::AM3_I_BitShift;
if (unsigned ImmOffs = ARM_AM::getAM3Offset(AM3Opc)) {
// Set operands
Binary |= (ImmOffs >> 4) << ARMII::ImmHiShift; // immedH
Binary |= (ImmOffs & 0xF); // immedL
}
emitWordLE(Binary);
}
static unsigned getAddrModeUPBits(unsigned Mode) {
unsigned Binary = 0;
// Set addressing mode by modifying bits U(23) and P(24)
// IA - Increment after - bit U = 1 and bit P = 0
// IB - Increment before - bit U = 1 and bit P = 1
// DA - Decrement after - bit U = 0 and bit P = 0
// DB - Decrement before - bit U = 0 and bit P = 1
switch (Mode) {
default: llvm_unreachable("Unknown addressing sub-mode!");
case ARM_AM::da: break;
case ARM_AM::db: Binary |= 0x1 << ARMII::P_BitShift; break;
case ARM_AM::ia: Binary |= 0x1 << ARMII::U_BitShift; break;
case ARM_AM::ib: Binary |= 0x3 << ARMII::U_BitShift; break;
}
return Binary;
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitLoadStoreMultipleInstruction(
const MachineInstr &MI) {
// Part of binary is determined by TableGn.
unsigned Binary = getBinaryCodeForInstr(MI);
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
// Set base address operand
Binary |= getMachineOpValue(MI, 0) << ARMII::RegRnShift;
// Set addressing mode by modifying bits U(23) and P(24)
const MachineOperand &MO = MI.getOperand(1);
Binary |= getAddrModeUPBits(ARM_AM::getAM4SubMode(MO.getImm()));
// Set bit W(21)
if (ARM_AM::getAM4WBFlag(MO.getImm()))
Binary |= 0x1 << ARMII::W_BitShift;
// Set registers
for (unsigned i = 4, e = MI.getNumOperands(); i != e; ++i) {
const MachineOperand &MO = MI.getOperand(i);
if (!MO.isReg() || MO.isImplicit())
break;
unsigned RegNum = ARMRegisterInfo::getRegisterNumbering(MO.getReg());
assert(TargetRegisterInfo::isPhysicalRegister(MO.getReg()) &&
RegNum < 16);
Binary |= 0x1 << RegNum;
}
emitWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitMulFrmInstruction(const MachineInstr &MI) {
const TargetInstrDesc &TID = MI.getDesc();
// Part of binary is determined by TableGn.
unsigned Binary = getBinaryCodeForInstr(MI);
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
// Encode S bit if MI modifies CPSR.
Binary |= getAddrModeSBit(MI, TID);
// 32x32->64bit operations have two destination registers. The number
// of register definitions will tell us if that's what we're dealing with.
unsigned OpIdx = 0;
if (TID.getNumDefs() == 2)
Binary |= getMachineOpValue (MI, OpIdx++) << ARMII::RegRdLoShift;
// Encode Rd
Binary |= getMachineOpValue(MI, OpIdx++) << ARMII::RegRdHiShift;
// Encode Rm
Binary |= getMachineOpValue(MI, OpIdx++);
// Encode Rs
Binary |= getMachineOpValue(MI, OpIdx++) << ARMII::RegRsShift;
// Many multiple instructions (e.g. MLA) have three src operands. Encode
// it as Rn (for multiply, that's in the same offset as RdLo.
if (TID.getNumOperands() > OpIdx &&
!TID.OpInfo[OpIdx].isPredicate() &&
!TID.OpInfo[OpIdx].isOptionalDef())
Binary |= getMachineOpValue(MI, OpIdx) << ARMII::RegRdLoShift;
emitWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitExtendInstruction(const MachineInstr &MI) {
const TargetInstrDesc &TID = MI.getDesc();
// Part of binary is determined by TableGn.
unsigned Binary = getBinaryCodeForInstr(MI);
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
unsigned OpIdx = 0;
// Encode Rd
Binary |= getMachineOpValue(MI, OpIdx++) << ARMII::RegRdShift;
const MachineOperand &MO1 = MI.getOperand(OpIdx++);
const MachineOperand &MO2 = MI.getOperand(OpIdx);
if (MO2.isReg()) {
// Two register operand form.
// Encode Rn.
Binary |= getMachineOpValue(MI, MO1) << ARMII::RegRnShift;
// Encode Rm.
Binary |= getMachineOpValue(MI, MO2);
++OpIdx;
} else {
Binary |= getMachineOpValue(MI, MO1);
}
// Encode rot imm (0, 8, 16, or 24) if it has a rotate immediate operand.
if (MI.getOperand(OpIdx).isImm() &&
!TID.OpInfo[OpIdx].isPredicate() &&
!TID.OpInfo[OpIdx].isOptionalDef())
Binary |= (getMachineOpValue(MI, OpIdx) / 8) << ARMII::ExtRotImmShift;
emitWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitMiscArithInstruction(const MachineInstr &MI) {
const TargetInstrDesc &TID = MI.getDesc();
// Part of binary is determined by TableGn.
unsigned Binary = getBinaryCodeForInstr(MI);
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
unsigned OpIdx = 0;
// Encode Rd
Binary |= getMachineOpValue(MI, OpIdx++) << ARMII::RegRdShift;
const MachineOperand &MO = MI.getOperand(OpIdx++);
if (OpIdx == TID.getNumOperands() ||
TID.OpInfo[OpIdx].isPredicate() ||
TID.OpInfo[OpIdx].isOptionalDef()) {
// Encode Rm and it's done.
Binary |= getMachineOpValue(MI, MO);
emitWordLE(Binary);
return;
}
// Encode Rn.
Binary |= getMachineOpValue(MI, MO) << ARMII::RegRnShift;
// Encode Rm.
Binary |= getMachineOpValue(MI, OpIdx++);
// Encode shift_imm.
unsigned ShiftAmt = MI.getOperand(OpIdx).getImm();
assert(ShiftAmt < 32 && "shift_imm range is 0 to 31!");
Binary |= ShiftAmt << ARMII::ShiftShift;
emitWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitBranchInstruction(const MachineInstr &MI) {
const TargetInstrDesc &TID = MI.getDesc();
if (TID.Opcode == ARM::TPsoft) {
llvm_unreachable("ARM::TPsoft FIXME"); // FIXME
}
// Part of binary is determined by TableGn.
unsigned Binary = getBinaryCodeForInstr(MI);
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
// Set signed_immed_24 field
Binary |= getMachineOpValue(MI, 0);
emitWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitInlineJumpTable(unsigned JTIndex) {
// Remember the base address of the inline jump table.
uintptr_t JTBase = MCE.getCurrentPCValue();
JTI->addJumpTableBaseAddr(JTIndex, JTBase);
DOUT << " ** Jump Table #" << JTIndex << " @ " << (void*)JTBase << '\n';
// Now emit the jump table entries.
const std::vector<MachineBasicBlock*> &MBBs = (*MJTEs)[JTIndex].MBBs;
for (unsigned i = 0, e = MBBs.size(); i != e; ++i) {
if (IsPIC)
// DestBB address - JT base.
emitMachineBasicBlock(MBBs[i], ARM::reloc_arm_pic_jt, JTBase);
else
// Absolute DestBB address.
emitMachineBasicBlock(MBBs[i], ARM::reloc_arm_absolute);
emitWordLE(0);
}
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitMiscBranchInstruction(const MachineInstr &MI) {
const TargetInstrDesc &TID = MI.getDesc();
// Handle jump tables.
if (TID.Opcode == ARM::BR_JTr || TID.Opcode == ARM::BR_JTadd) {
// First emit a ldr pc, [] instruction.
emitDataProcessingInstruction(MI, ARM::PC);
// Then emit the inline jump table.
unsigned JTIndex =
(TID.Opcode == ARM::BR_JTr)
? MI.getOperand(1).getIndex() : MI.getOperand(2).getIndex();
emitInlineJumpTable(JTIndex);
return;
} else if (TID.Opcode == ARM::BR_JTm) {
// First emit a ldr pc, [] instruction.
emitLoadStoreInstruction(MI, ARM::PC);
// Then emit the inline jump table.
emitInlineJumpTable(MI.getOperand(3).getIndex());
return;
}
// Part of binary is determined by TableGn.
unsigned Binary = getBinaryCodeForInstr(MI);
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
if (TID.Opcode == ARM::BX_RET)
// The return register is LR.
Binary |= ARMRegisterInfo::getRegisterNumbering(ARM::LR);
else
// otherwise, set the return register
Binary |= getMachineOpValue(MI, 0);
emitWordLE(Binary);
}
static unsigned encodeVFPRd(const MachineInstr &MI, unsigned OpIdx) {
unsigned RegD = MI.getOperand(OpIdx).getReg();
unsigned Binary = 0;
bool isSPVFP = false;
RegD = ARMRegisterInfo::getRegisterNumbering(RegD, &isSPVFP);
if (!isSPVFP)
Binary |= RegD << ARMII::RegRdShift;
else {
Binary |= ((RegD & 0x1E) >> 1) << ARMII::RegRdShift;
Binary |= (RegD & 0x01) << ARMII::D_BitShift;
}
return Binary;
}
static unsigned encodeVFPRn(const MachineInstr &MI, unsigned OpIdx) {
unsigned RegN = MI.getOperand(OpIdx).getReg();
unsigned Binary = 0;
bool isSPVFP = false;
RegN = ARMRegisterInfo::getRegisterNumbering(RegN, &isSPVFP);
if (!isSPVFP)
Binary |= RegN << ARMII::RegRnShift;
else {
Binary |= ((RegN & 0x1E) >> 1) << ARMII::RegRnShift;
Binary |= (RegN & 0x01) << ARMII::N_BitShift;
}
return Binary;
}
static unsigned encodeVFPRm(const MachineInstr &MI, unsigned OpIdx) {
unsigned RegM = MI.getOperand(OpIdx).getReg();
unsigned Binary = 0;
bool isSPVFP = false;
RegM = ARMRegisterInfo::getRegisterNumbering(RegM, &isSPVFP);
if (!isSPVFP)
Binary |= RegM;
else {
Binary |= ((RegM & 0x1E) >> 1);
Binary |= (RegM & 0x01) << ARMII::M_BitShift;
}
return Binary;
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitVFPArithInstruction(const MachineInstr &MI) {
const TargetInstrDesc &TID = MI.getDesc();
// Part of binary is determined by TableGn.
unsigned Binary = getBinaryCodeForInstr(MI);
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
unsigned OpIdx = 0;
assert((Binary & ARMII::D_BitShift) == 0 &&
(Binary & ARMII::N_BitShift) == 0 &&
(Binary & ARMII::M_BitShift) == 0 && "VFP encoding bug!");
// Encode Dd / Sd.
Binary |= encodeVFPRd(MI, OpIdx++);
// If this is a two-address operand, skip it, e.g. FMACD.
if (TID.getOperandConstraint(OpIdx, TOI::TIED_TO) != -1)
++OpIdx;
// Encode Dn / Sn.
if ((TID.TSFlags & ARMII::FormMask) == ARMII::VFPBinaryFrm)
Binary |= encodeVFPRn(MI, OpIdx++);
if (OpIdx == TID.getNumOperands() ||
TID.OpInfo[OpIdx].isPredicate() ||
TID.OpInfo[OpIdx].isOptionalDef()) {
// FCMPEZD etc. has only one operand.
emitWordLE(Binary);
return;
}
// Encode Dm / Sm.
Binary |= encodeVFPRm(MI, OpIdx);
emitWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitVFPConversionInstruction(
const MachineInstr &MI) {
const TargetInstrDesc &TID = MI.getDesc();
unsigned Form = TID.TSFlags & ARMII::FormMask;
// Part of binary is determined by TableGn.
unsigned Binary = getBinaryCodeForInstr(MI);
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
switch (Form) {
default: break;
case ARMII::VFPConv1Frm:
case ARMII::VFPConv2Frm:
case ARMII::VFPConv3Frm:
// Encode Dd / Sd.
Binary |= encodeVFPRd(MI, 0);
break;
case ARMII::VFPConv4Frm:
// Encode Dn / Sn.
Binary |= encodeVFPRn(MI, 0);
break;
case ARMII::VFPConv5Frm:
// Encode Dm / Sm.
Binary |= encodeVFPRm(MI, 0);
break;
}
switch (Form) {
default: break;
case ARMII::VFPConv1Frm:
// Encode Dm / Sm.
Binary |= encodeVFPRm(MI, 1);
break;
case ARMII::VFPConv2Frm:
case ARMII::VFPConv3Frm:
// Encode Dn / Sn.
Binary |= encodeVFPRn(MI, 1);
break;
case ARMII::VFPConv4Frm:
case ARMII::VFPConv5Frm:
// Encode Dd / Sd.
Binary |= encodeVFPRd(MI, 1);
break;
}
if (Form == ARMII::VFPConv5Frm)
// Encode Dn / Sn.
Binary |= encodeVFPRn(MI, 2);
else if (Form == ARMII::VFPConv3Frm)
// Encode Dm / Sm.
Binary |= encodeVFPRm(MI, 2);
emitWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitVFPLoadStoreInstruction(const MachineInstr &MI) {
// Part of binary is determined by TableGn.
unsigned Binary = getBinaryCodeForInstr(MI);
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
unsigned OpIdx = 0;
// Encode Dd / Sd.
Binary |= encodeVFPRd(MI, OpIdx++);
// Encode address base.
const MachineOperand &Base = MI.getOperand(OpIdx++);
Binary |= getMachineOpValue(MI, Base) << ARMII::RegRnShift;
// If there is a non-zero immediate offset, encode it.
if (Base.isReg()) {
const MachineOperand &Offset = MI.getOperand(OpIdx);
if (unsigned ImmOffs = ARM_AM::getAM5Offset(Offset.getImm())) {
if (ARM_AM::getAM5Op(Offset.getImm()) == ARM_AM::add)
Binary |= 1 << ARMII::U_BitShift;
Binary |= ImmOffs;
emitWordLE(Binary);
return;
}
}
// If immediate offset is omitted, default to +0.
Binary |= 1 << ARMII::U_BitShift;
emitWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitVFPLoadStoreMultipleInstruction(
const MachineInstr &MI) {
// Part of binary is determined by TableGn.
unsigned Binary = getBinaryCodeForInstr(MI);
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
// Set base address operand
Binary |= getMachineOpValue(MI, 0) << ARMII::RegRnShift;
// Set addressing mode by modifying bits U(23) and P(24)
const MachineOperand &MO = MI.getOperand(1);
Binary |= getAddrModeUPBits(ARM_AM::getAM5SubMode(MO.getImm()));
// Set bit W(21)
if (ARM_AM::getAM5WBFlag(MO.getImm()))
Binary |= 0x1 << ARMII::W_BitShift;
// First register is encoded in Dd.
Binary |= encodeVFPRd(MI, 4);
// Number of registers are encoded in offset field.
unsigned NumRegs = 1;
for (unsigned i = 5, e = MI.getNumOperands(); i != e; ++i) {
const MachineOperand &MO = MI.getOperand(i);
if (!MO.isReg() || MO.isImplicit())
break;
++NumRegs;
}
Binary |= NumRegs * 2;
emitWordLE(Binary);
}
template<class CodeEmitter>
void Emitter<CodeEmitter>::emitMiscInstruction(const MachineInstr &MI) {
// Part of binary is determined by TableGn.
unsigned Binary = getBinaryCodeForInstr(MI);
// Set the conditional execution predicate
Binary |= II->getPredicate(&MI) << ARMII::CondShift;
emitWordLE(Binary);
}
#include "ARMGenCodeEmitter.inc"