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llvm-mirror/lib/Target/SystemZ/MCTargetDesc/SystemZMCTargetDesc.cpp
Richard Sandiford e46cf32917 [SystemZ] Match operands to fields by name rather than by order 
The SystemZ port currently relies on the order of the instruction operands
matching the order of the instruction field lists.  This isn't desirable
for disassembly, where the two are matched only by name.  E.g. the R1 and R2
fields of an RR instruction should have corresponding R1 and R2 operands.

The main complication is that addresses are compound operands,
and as far as I know there is no mechanism to allow individual
suboperands to be selected by name in "let Inst{...} = ..." assignments.
Luckily it doesn't really matter though.  The SystemZ instruction
encoding groups all address fields together in a predictable order,
so it's just as valid to see the entire compound address operand as
a single field.  That's the approach taken in this patch.

Matching by name in turn means that the operands to COPY SIGN and
CONVERT TO FIXED instructions can be given in natural order.
(It was easier to do this at the same time as the rename,
since otherwise the intermediate step was too confusing.)

No functional change intended.

llvm-svn: 181771
2013-05-14 09:36:44 +00:00

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//===-- SystemZMCTargetDesc.cpp - SystemZ target descriptions -------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "SystemZMCTargetDesc.h"
#include "InstPrinter/SystemZInstPrinter.h"
#include "SystemZMCAsmInfo.h"
#include "llvm/MC/MCCodeGenInfo.h"
#include "llvm/MC/MCInstrInfo.h"
#include "llvm/MC/MCStreamer.h"
#include "llvm/MC/MCSubtargetInfo.h"
#include "llvm/Support/TargetRegistry.h"
#define GET_INSTRINFO_MC_DESC
#include "SystemZGenInstrInfo.inc"
#define GET_SUBTARGETINFO_MC_DESC
#include "SystemZGenSubtargetInfo.inc"
#define GET_REGINFO_MC_DESC
#include "SystemZGenRegisterInfo.inc"
using namespace llvm;
const unsigned SystemZMC::GR32Regs[16] = {
SystemZ::R0W, SystemZ::R1W, SystemZ::R2W, SystemZ::R3W,
SystemZ::R4W, SystemZ::R5W, SystemZ::R6W, SystemZ::R7W,
SystemZ::R8W, SystemZ::R9W, SystemZ::R10W, SystemZ::R11W,
SystemZ::R12W, SystemZ::R13W, SystemZ::R14W, SystemZ::R15W
};
const unsigned SystemZMC::GR64Regs[16] = {
SystemZ::R0D, SystemZ::R1D, SystemZ::R2D, SystemZ::R3D,
SystemZ::R4D, SystemZ::R5D, SystemZ::R6D, SystemZ::R7D,
SystemZ::R8D, SystemZ::R9D, SystemZ::R10D, SystemZ::R11D,
SystemZ::R12D, SystemZ::R13D, SystemZ::R14D, SystemZ::R15D
};
const unsigned SystemZMC::GR128Regs[16] = {
SystemZ::R0Q, 0, SystemZ::R2Q, 0,
SystemZ::R4Q, 0, SystemZ::R6Q, 0,
SystemZ::R8Q, 0, SystemZ::R10Q, 0,
SystemZ::R12Q, 0, SystemZ::R14Q, 0
};
const unsigned SystemZMC::FP32Regs[16] = {
SystemZ::F0S, SystemZ::F1S, SystemZ::F2S, SystemZ::F3S,
SystemZ::F4S, SystemZ::F5S, SystemZ::F6S, SystemZ::F7S,
SystemZ::F8S, SystemZ::F9S, SystemZ::F10S, SystemZ::F11S,
SystemZ::F12S, SystemZ::F13S, SystemZ::F14S, SystemZ::F15S
};
const unsigned SystemZMC::FP64Regs[16] = {
SystemZ::F0D, SystemZ::F1D, SystemZ::F2D, SystemZ::F3D,
SystemZ::F4D, SystemZ::F5D, SystemZ::F6D, SystemZ::F7D,
SystemZ::F8D, SystemZ::F9D, SystemZ::F10D, SystemZ::F11D,
SystemZ::F12D, SystemZ::F13D, SystemZ::F14D, SystemZ::F15D
};
const unsigned SystemZMC::FP128Regs[16] = {
SystemZ::F0Q, SystemZ::F1Q, 0, 0,
SystemZ::F4Q, SystemZ::F5Q, 0, 0,
SystemZ::F8Q, SystemZ::F9Q, 0, 0,
SystemZ::F12Q, SystemZ::F13Q, 0, 0
};
static MCAsmInfo *createSystemZMCAsmInfo(const MCRegisterInfo &MRI,
StringRef TT) {
MCAsmInfo *MAI = new SystemZMCAsmInfo(TT);
MCCFIInstruction Inst =
MCCFIInstruction::createDefCfa(0, MRI.getDwarfRegNum(SystemZ::R15D, true),
SystemZMC::CFAOffsetFromInitialSP);
MAI->addInitialFrameState(Inst);
return MAI;
}
static MCInstrInfo *createSystemZMCInstrInfo() {
MCInstrInfo *X = new MCInstrInfo();
InitSystemZMCInstrInfo(X);
return X;
}
static MCRegisterInfo *createSystemZMCRegisterInfo(StringRef TT) {
MCRegisterInfo *X = new MCRegisterInfo();
InitSystemZMCRegisterInfo(X, SystemZ::R14D);
return X;
}
static MCSubtargetInfo *createSystemZMCSubtargetInfo(StringRef TT,
StringRef CPU,
StringRef FS) {
MCSubtargetInfo *X = new MCSubtargetInfo();
InitSystemZMCSubtargetInfo(X, TT, CPU, FS);
return X;
}
static MCCodeGenInfo *createSystemZMCCodeGenInfo(StringRef TT, Reloc::Model RM,
CodeModel::Model CM,
CodeGenOpt::Level OL) {
MCCodeGenInfo *X = new MCCodeGenInfo();
// Static code is suitable for use in a dynamic executable; there is no
// separate DynamicNoPIC model.
if (RM == Reloc::Default || RM == Reloc::DynamicNoPIC)
RM = Reloc::Static;
// For SystemZ we define the models as follows:
//
// Small: BRASL can call any function and will use a stub if necessary.
// Locally-binding symbols will always be in range of LARL.
//
// Medium: BRASL can call any function and will use a stub if necessary.
// GOT slots and locally-defined text will always be in range
// of LARL, but other symbols might not be.
//
// Large: Equivalent to Medium for now.
//
// Kernel: Equivalent to Medium for now.
//
// This means that any PIC module smaller than 4GB meets the
// requirements of Small, so Small seems like the best default there.
//
// All symbols bind locally in a non-PIC module, so the choice is less
// obvious. There are two cases:
//
// - When creating an executable, PLTs and copy relocations allow
// us to treat external symbols as part of the executable.
// Any executable smaller than 4GB meets the requirements of Small,
// so that seems like the best default.
//
// - When creating JIT code, stubs will be in range of BRASL if the
// image is less than 4GB in size. GOT entries will likewise be
// in range of LARL. However, the JIT environment has no equivalent
// of copy relocs, so locally-binding data symbols might not be in
// the range of LARL. We need the Medium model in that case.
if (CM == CodeModel::Default)
CM = CodeModel::Small;
else if (CM == CodeModel::JITDefault)
CM = RM == Reloc::PIC_ ? CodeModel::Small : CodeModel::Medium;
X->InitMCCodeGenInfo(RM, CM, OL);
return X;
}
static MCInstPrinter *createSystemZMCInstPrinter(const Target &T,
unsigned SyntaxVariant,
const MCAsmInfo &MAI,
const MCInstrInfo &MII,
const MCRegisterInfo &MRI,
const MCSubtargetInfo &STI) {
return new SystemZInstPrinter(MAI, MII, MRI);
}
static MCStreamer *createSystemZMCObjectStreamer(const Target &T, StringRef TT,
MCContext &Ctx,
MCAsmBackend &MAB,
raw_ostream &OS,
MCCodeEmitter *Emitter,
bool RelaxAll,
bool NoExecStack) {
return createELFStreamer(Ctx, MAB, OS, Emitter, RelaxAll, NoExecStack);
}
extern "C" void LLVMInitializeSystemZTargetMC() {
// Register the MCAsmInfo.
TargetRegistry::RegisterMCAsmInfo(TheSystemZTarget,
createSystemZMCAsmInfo);
// Register the MCCodeGenInfo.
TargetRegistry::RegisterMCCodeGenInfo(TheSystemZTarget,
createSystemZMCCodeGenInfo);
// Register the MCCodeEmitter.
TargetRegistry::RegisterMCCodeEmitter(TheSystemZTarget,
createSystemZMCCodeEmitter);
// Register the MCInstrInfo.
TargetRegistry::RegisterMCInstrInfo(TheSystemZTarget,
createSystemZMCInstrInfo);
// Register the MCRegisterInfo.
TargetRegistry::RegisterMCRegInfo(TheSystemZTarget,
createSystemZMCRegisterInfo);
// Register the MCSubtargetInfo.
TargetRegistry::RegisterMCSubtargetInfo(TheSystemZTarget,
createSystemZMCSubtargetInfo);
// Register the MCAsmBackend.
TargetRegistry::RegisterMCAsmBackend(TheSystemZTarget,
createSystemZMCAsmBackend);
// Register the MCInstPrinter.
TargetRegistry::RegisterMCInstPrinter(TheSystemZTarget,
createSystemZMCInstPrinter);
// Register the MCObjectStreamer;
TargetRegistry::RegisterMCObjectStreamer(TheSystemZTarget,
createSystemZMCObjectStreamer);
}
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