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//===- subzero/src/IceAssemblerARM32.h - Assembler for ARM32 ----*- C++ -*-===//
//
// Copyright (c) 2013, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
//
// Modified by the Subzero authors.
//
//===----------------------------------------------------------------------===//
//
// The Subzero Code Generator
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
///
/// \file
/// \brief Declares the Assembler class for ARM32.
///
/// Note: All references to ARM "section" documentation refers to the "ARM
/// Architecture Reference Manual, ARMv7-A and ARMv7-R edition". See:
/// http://infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.ddi0406c
///
//===----------------------------------------------------------------------===//
#ifndef SUBZERO_SRC_ICEASSEMBLERARM32_H
#define SUBZERO_SRC_ICEASSEMBLERARM32_H
#include "IceAssembler.h"
#include "IceConditionCodesARM32.h"
#include "IceDefs.h"
#include "IceFixups.h"
#include "IceInstARM32.h"
#include "IceRegistersARM32.h"
#include "IceTargetLowering.h"
namespace Ice {
namespace ARM32 {
/// Handles encoding of bottom/top 16 bits of an address using movw/movt.
class MoveRelocatableFixup final : public AssemblerFixup {
MoveRelocatableFixup &operator=(const MoveRelocatableFixup &) = delete;
MoveRelocatableFixup(const MoveRelocatableFixup &) = default;
public:
MoveRelocatableFixup() = default;
size_t emit(GlobalContext *Ctx, const Assembler &Asm) const final;
void emitOffset(Assembler *Asm) const;
};
/// Handles encoding of branch and link to global location.
class BlRelocatableFixup final : public AssemblerFixup {
BlRelocatableFixup(const BlRelocatableFixup &) = delete;
BlRelocatableFixup &operator=(const BlRelocatableFixup &) = delete;
public:
BlRelocatableFixup() = default;
size_t emit(GlobalContext *Ctx, const Assembler &Asm) const final;
void emitOffset(Assembler *Asm) const;
};
class AssemblerARM32 : public Assembler {
AssemblerARM32(const AssemblerARM32 &) = delete;
AssemblerARM32 &operator=(const AssemblerARM32 &) = delete;
public:
// Rotation values.
enum RotationValue {
kRotateNone, // Omitted
kRotate8, // ror #8
kRotate16, // ror #16
kRotate24 // ror #24
};
// Encoding of the number of D registers in a list of D registers.
enum DRegListSize {
DRegListSize1 = 7, // 0b0111
DRegListSize2 = 10, // 0b1010
DRegListSIze3 = 6, // 0b0110
DRegListSize4 = 2 // 0b0010
};
class TargetInfo {
TargetInfo(const TargetInfo &) = delete;
TargetInfo &operator=(const TargetInfo &) = delete;
public:
TargetInfo(bool HasFramePointer, RegNumT FrameOrStackReg)
: HasFramePointer(HasFramePointer), FrameOrStackReg(FrameOrStackReg) {}
explicit TargetInfo(const TargetLowering *Target)
: HasFramePointer(Target->hasFramePointer()),
FrameOrStackReg(Target->getFrameOrStackReg()) {}
const bool HasFramePointer;
const RegNumT FrameOrStackReg;
};
explicit AssemblerARM32(bool IsNonsfi, bool use_far_branches = false)
: Assembler(Asm_ARM32), IsNonsfi(IsNonsfi) {
// TODO(kschimpf): Add mode if needed when branches are handled.
(void)use_far_branches;
}
~AssemblerARM32() override {
if (BuildDefs::asserts()) {
for (const Label *Label : CfgNodeLabels) {
Label->finalCheck();
}
for (const Label *Label : LocalLabels) {
Label->finalCheck();
}
}
}
MoveRelocatableFixup *createMoveFixup(bool IsMovW, const Constant *Value);
BlRelocatableFixup *createBlFixup(const ConstantRelocatable *BlTarget);
void alignFunction() override {
const SizeT Align = 1 << getBundleAlignLog2Bytes();
SizeT BytesNeeded = Utils::OffsetToAlignment(Buffer.getPosition(), Align);
constexpr SizeT InstSize = sizeof(IValueT);
assert(BytesNeeded % InstARM32::InstSize == 0);
while (BytesNeeded > 0) {
trap();
BytesNeeded -= InstSize;
}
}
SizeT getBundleAlignLog2Bytes() const override { return 4; }
const char *getAlignDirective() const override { return ".p2alignl"; }
llvm::ArrayRef<uint8_t> getNonExecBundlePadding() const override;
void padWithNop(intptr_t Padding) override;
Ice::Label *getCfgNodeLabel(SizeT NodeNumber) override {
assert(NodeNumber < CfgNodeLabels.size());
return CfgNodeLabels[NodeNumber];
}
Label *getOrCreateCfgNodeLabel(SizeT NodeNumber) {
return getOrCreateLabel(NodeNumber, CfgNodeLabels);
}
Label *getOrCreateLocalLabel(SizeT Number) {
return getOrCreateLabel(Number, LocalLabels);
}
void bindLocalLabel(const InstARM32Label *InstL, SizeT Number) {
if (BuildDefs::dump() && !getFlags().getDisableHybridAssembly()) {
constexpr SizeT InstSize = 0;
emitTextInst(InstL->getLabelName() + ":", InstSize);
}
Label *L = getOrCreateLocalLabel(Number);
if (!getPreliminary())
this->bind(L);
}
bool fixupIsPCRel(FixupKind Kind) const override {
if (Kind == llvm::ELF::R_ARM_MOVW_PREL_NC)
return true;
if (Kind == llvm::ELF::R_ARM_MOVT_PREL)
return true;
return false;
}
/// Accessors to keep track of the number of bytes generated inside
/// InstARM32::emit() methods, when run inside of
/// InstARM32::emitUsingTextFixup().
void resetEmitTextSize() { EmitTextSize = 0; }
void incEmitTextSize(size_t Amount) { EmitTextSize += Amount; }
void decEmitTextSize(size_t Amount) { EmitTextSize -= Amount; }
size_t getEmitTextSize() const { return EmitTextSize; }
void bind(Label *label);
// List of instructions implemented by integrated assembler.
void adc(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
bool SetFlags, CondARM32::Cond Cond);
void add(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
bool SetFlags, CondARM32::Cond Cond);
void and_(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
bool SetFlags, CondARM32::Cond Cond);
void asr(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
bool SetFlags, CondARM32::Cond Cond);
void b(Label *L, CondARM32::Cond Cond);
void bkpt(uint16_t Imm16);
void bic(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
bool SetFlags, CondARM32::Cond Cond);
void bl(const ConstantRelocatable *Target);
void blx(const Operand *Target);
void bx(RegARM32::GPRRegister Rm, CondARM32::Cond Cond = CondARM32::AL);
void clz(const Operand *OpRd, const Operand *OpSrc, CondARM32::Cond Cond);
void cmn(const Operand *OpRn, const Operand *OpSrc1, CondARM32::Cond Cond);
void cmp(const Operand *OpRn, const Operand *OpSrc1, CondARM32::Cond Cond);
void dmb(IValueT Option); // Option is a 4-bit value.
void eor(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
bool SetFlags, CondARM32::Cond Cond);
void ldr(const Operand *OpRt, const Operand *OpAddress, CondARM32::Cond Cond,
const TargetInfo &TInfo);
void ldr(const Operand *OpRt, const Operand *OpAddress, CondARM32::Cond Cond,
const TargetLowering *Lowering) {
const TargetInfo TInfo(Lowering);
ldr(OpRt, OpAddress, Cond, TInfo);
}
void ldrex(const Operand *OpRt, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetInfo &TInfo);
void ldrex(const Operand *OpRt, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetLowering *Lowering) {
const TargetInfo TInfo(Lowering);
ldrex(OpRt, OpAddress, Cond, TInfo);
}
void lsl(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
bool SetFlags, CondARM32::Cond Cond);
void lsr(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
bool SetFlags, CondARM32::Cond Cond);
void mov(const Operand *OpRd, const Operand *OpSrc, CondARM32::Cond Cond);
void movw(const Operand *OpRd, const Operand *OpSrc, CondARM32::Cond Cond);
void movt(const Operand *OpRd, const Operand *OpSrc, CondARM32::Cond Cond);
void mla(const Operand *OpRd, const Operand *OpRn, const Operand *OpRm,
const Operand *OpRa, CondARM32::Cond Cond);
void mls(const Operand *OpRd, const Operand *OpRn, const Operand *OpRm,
const Operand *OpRa, CondARM32::Cond Cond);
void mul(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
bool SetFlags, CondARM32::Cond Cond);
void mvn(const Operand *OpRd, const Operand *OpScc, CondARM32::Cond Cond);
void nop();
void orr(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
bool SetFlags, CondARM32::Cond Cond);
void pop(const Variable *OpRt, CondARM32::Cond Cond);
// Note: Registers is a bitset, where bit n corresponds to register Rn.
void popList(const IValueT Registers, CondARM32::Cond Cond);
void push(const Operand *OpRt, CondARM32::Cond Cond);
// Note: Registers is a bitset, where bit n corresponds to register Rn.
void pushList(const IValueT Registers, CondARM32::Cond Cond);
void rbit(const Operand *OpRd, const Operand *OpRm, CondARM32::Cond Cond);
void rev(const Operand *OpRd, const Operand *OpRm, CondARM32::Cond Cond);
void rsb(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
bool SetFlags, CondARM32::Cond Cond);
void rsc(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
bool SetFlags, CondARM32::Cond Cond);
void sbc(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
bool SetFlags, CondARM32::Cond Cond);
void sdiv(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
CondARM32::Cond Cond);
void str(const Operand *OpRt, const Operand *OpAddress, CondARM32::Cond Cond,
const TargetInfo &TInfo);
void str(const Operand *OpRt, const Operand *OpAddress, CondARM32::Cond Cond,
const TargetLowering *Lowering) {
const TargetInfo TInfo(Lowering);
str(OpRt, OpAddress, Cond, TInfo);
}
void strex(const Operand *OpRd, const Operand *OpRt, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetInfo &TInfo);
void strex(const Operand *OpRd, const Operand *OpRt, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetLowering *Lowering) {
const TargetInfo TInfo(Lowering);
strex(OpRd, OpRt, OpAddress, Cond, TInfo);
}
void sub(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
bool SetFlags, CondARM32::Cond Cond);
// Implements sxtb/sxth depending on type of OpSrc0.
void sxt(const Operand *OpRd, const Operand *OpSrc0, CondARM32::Cond Cond);
void trap();
void tst(const Operand *OpRn, const Operand *OpSrc1, CondARM32::Cond Cond);
void udiv(const Operand *OpRd, const Operand *OpRn, const Operand *OpSrc1,
CondARM32::Cond Cond);
void umull(const Operand *OpRdLo, const Operand *OpRdHi, const Operand *OpRn,
const Operand *OpRm, CondARM32::Cond Cond);
// Implements uxtb/uxth depending on type of OpSrc0.
void uxt(const Operand *OpRd, const Operand *OpSrc0, CondARM32::Cond Cond);
void vabss(const Operand *OpSd, const Operand *OpSm, CondARM32::Cond Cond);
void vabsd(const Operand *OpDd, const Operand *OpDm, CondARM32::Cond Cond);
void vabsq(const Operand *OpQd, const Operand *OpQm);
void vaddd(const Operand *OpDd, const Operand *OpDn, const Operand *OpDm,
CondARM32::Cond Cond);
void vadds(const Operand *OpSd, const Operand *OpSn, const Operand *OpSm,
CondARM32::Cond Cond);
// Integer vector add.
void vaddqi(Type ElmtTy, const Operand *OpQd, const Operand *OpQm,
const Operand *OpQn);
// Float vector add.
void vaddqf(const Operand *OpQd, const Operand *OpQm, const Operand *OpQn);
void vandq(const Operand *OpQd, const Operand *OpQm, const Operand *OpQn);
void vbslq(const Operand *OpQd, const Operand *OpQm, const Operand *OpQn);
void vceqqi(const Type ElmtTy, const Operand *OpQd, const Operand *OpQm,
const Operand *OpQn);
void vceqqs(const Operand *OpQd, const Operand *OpQm, const Operand *OpQn);
void vcgeqi(const Type ElmtTy, const Operand *OpQd, const Operand *OpQm,
const Operand *OpQn);
void vcugeqi(const Type ElmtTy, const Operand *OpQd, const Operand *OpQm,
const Operand *OpQn);
void vcgeqs(const Operand *OpQd, const Operand *OpQm, const Operand *OpQn);
void vcgtqi(const Type ElmtTy, const Operand *OpQd, const Operand *OpQm,
const Operand *OpQn);
void vcugtqi(const Type ElmtTy, const Operand *OpQd, const Operand *OpQm,
const Operand *OpQn);
void vcgtqs(const Operand *OpQd, const Operand *OpQm, const Operand *OpQn);
void vcmpd(const Operand *OpDd, const Operand *OpDm, CondARM32::Cond cond);
// Second argument of compare is zero (+0.0).
void vcmpdz(const Operand *OpDd, CondARM32::Cond cond);
void vcmps(const Operand *OpSd, const Operand *OpSm, CondARM32::Cond cond);
// Second argument of compare is zero (+0.0).
void vcmpsz(const Operand *OpSd, CondARM32::Cond cond);
void vcvtds(const Operand *OpDd, const Operand *OpSm, CondARM32::Cond Cond);
// vcvt<c>.S32.F32
void vcvtis(const Operand *OpSd, const Operand *OpSm, CondARM32::Cond Cond);
// vcvt<c>.S32.F64
void vcvtid(const Operand *OpSd, const Operand *OpDm, CondARM32::Cond Cond);
// vcvt<c>.F64.S32
void vcvtdi(const Operand *OpDd, const Operand *OpSm, CondARM32::Cond Cond);
// vcvt<c>.F64.U32
void vcvtdu(const Operand *OpDd, const Operand *OpSm, CondARM32::Cond Cond);
void vcvtsd(const Operand *OpSd, const Operand *OpDm, CondARM32::Cond Cond);
// vcvt<c>.F32.S32
void vcvtsi(const Operand *OpSd, const Operand *OpSm, CondARM32::Cond Cond);
// vcvt<c>.F32.U32
void vcvtsu(const Operand *OpSd, const Operand *OpSm, CondARM32::Cond Cond);
// vcvt<c>.U32.F64
void vcvtud(const Operand *OpSd, const Operand *OpDm, CondARM32::Cond Cond);
// vcvt<c>.u32.f32
void vcvtus(const Operand *OpSd, const Operand *OpSm, CondARM32::Cond Cond);
void vcvtqsi(const Operand *OpQd, const Operand *OpQm);
void vcvtqsu(const Operand *OpQd, const Operand *OpQm);
void vcvtqis(const Operand *OpQd, const Operand *OpQm);
void vcvtqus(const Operand *OpQd, const Operand *OpQm);
void vdivd(const Operand *OpDd, const Operand *OpDn, const Operand *OpDm,
CondARM32::Cond Cond);
void vdivs(const Operand *OpSd, const Operand *OpSn, const Operand *OpSm,
CondARM32::Cond Cond);
void veord(const Operand *OpDd, const Operand *OpDn, const Operand *OpDm);
void veorq(const Operand *OpQd, const Operand *OpQn, const Operand *OpQm);
void vldrd(const Operand *OpDd, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetInfo &TInfo);
void vldrd(const Operand *OpDd, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetLowering *Lowering) {
const TargetInfo TInfo(Lowering);
vldrd(OpDd, OpAddress, Cond, TInfo);
}
void vldrs(const Operand *OpSd, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetInfo &TInfo);
void vldrs(const Operand *OpSd, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetLowering *Lowering) {
const TargetInfo TInfo(Lowering);
vldrs(OpSd, OpAddress, Cond, TInfo);
}
// ElmtSize = #bits in vector element.
void vld1qr(size_t ElmtSize, const Operand *OpQd, const Operand *OpRn,
const TargetInfo &TInfo);
void vld1qr(size_t ElmtSize, const Operand *OpQd, const Operand *OpRn,
const TargetLowering *Lowering) {
const TargetInfo TInfo(Lowering);
vld1qr(ElmtSize, OpQd, OpRn, TInfo);
}
// Qn[i] = Imm for all i in vector. Returns true iff Imm can be defined as an
// Imm8 using AdvSIMDExpandImm().
bool vmovqc(const Operand *OpQd, const ConstantInteger32 *Imm);
// Dn = FpImm
void vmovd(const Operand *OpDn, const OperandARM32FlexFpImm *OpFpImm,
CondARM32::Cond Cond);
// Dd = Dm
void vmovdd(const Operand *OpDd, const Variable *OpDm, CondARM32::Cond Cond);
// Dm = Rt:Rt2
void vmovdrr(const Operand *OpDm, const Operand *OpRt, const Operand *OpRt2,
CondARM32::Cond Cond);
// Qd[Index] = Rt
void vmovqir(const Operand *OpQd, uint32_t Index, const Operand *OpRt,
CondARM32::Cond Cond);
// Qd[Index] = Sm
void vmovqis(const Operand *OpQd, uint32_t Indx, const Operand *OpSm,
CondARM32::Cond Cond);
// Rt = Qm[Index]
void vmovrqi(const Operand *OpRt, const Operand *OpQd, uint32_t Index,
CondARM32::Cond Cond);
// Rt:Rt2 = Dm
void vmovrrd(const Operand *OpRt, const Operand *OpRt2, const Operand *OpDm,
CondARM32::Cond Cond);
// Rt = Sn
void vmovrs(const Operand *OpRt, const Operand *OpSn, CondARM32::Cond Cond);
// Sn = FpImm
void vmovs(const Operand *OpSn, const OperandARM32FlexFpImm *OpFpImm,
CondARM32::Cond Cond);
// Sd = Sm
void vmovss(const Operand *OpSd, const Variable *OpSm, CondARM32::Cond Cond);
// Sd = Qm[Index]
void vmovsqi(const Operand *OpSd, const Operand *OpQm, uint32_t Index,
CondARM32::Cond Cond);
// Sn = Rt
void vmovsr(const Operand *OpSn, const Operand *OpRt, CondARM32::Cond Cond);
void vmlad(const Operand *OpDd, const Operand *OpDn, const Operand *OpDm,
CondARM32::Cond Cond);
void vmlas(const Operand *OpSd, const Operand *OpSn, const Operand *OpSm,
CondARM32::Cond Cond);
void vmlsd(const Operand *OpDd, const Operand *OpDn, const Operand *OpDm,
CondARM32::Cond Cond);
void vmlss(const Operand *OpSd, const Operand *OpSn, const Operand *OpSm,
CondARM32::Cond Cond);
// Uses APSR_nzcv as register
void vmrsAPSR_nzcv(CondARM32::Cond Cond);
void vmuld(const Operand *OpDd, const Operand *OpDn, const Operand *OpDm,
CondARM32::Cond Cond);
// Integer vector multiply.
void vmulqi(Type ElmtTy, const Operand *OpQd, const Operand *OpQn,
const Operand *OpQm);
// Float vector multiply.
void vmulqf(const Operand *OpQd, const Operand *OpQn, const Operand *OpQm);
void vmuls(const Operand *OpSd, const Operand *OpSn, const Operand *OpSm,
CondARM32::Cond Cond);
void vmvnq(const Operand *OpQd, const Operand *OpQm);
void vnegqs(const Operand *OpQd, const Operand *OpQm);
void vnegqs(Type ElmtTy, const Operand *OpQd, const Operand *OpQm);
void vorrq(const Operand *OpQd, const Operand *OpQm, const Operand *OpQn);
void vpop(const Variable *OpBaseReg, SizeT NumConsecRegs,
CondARM32::Cond Cond);
void vpush(const Variable *OpBaseReg, SizeT NumConsecRegs,
CondARM32::Cond Cond);
void vshlqi(Type ElmtTy, const Operand *OpQd, const Operand *OpQm,
const Operand *OpQn);
void vshlqu(Type ElmtTy, const Operand *OpQd, const Operand *OpQm,
const Operand *OpQn);
void vshlqc(Type ElmtTy, const Operand *OpQd, const Operand *OpQm,
const ConstantInteger32 *OpQn);
void vshrqic(Type ElmtTy, const Operand *OpQd, const Operand *OpQm,
const ConstantInteger32 *OpQn);
void vshrquc(Type ElmtTy, const Operand *OpQd, const Operand *OpQm,
const ConstantInteger32 *OpQn);
void vsqrtd(const Operand *OpDd, const Operand *OpDm, CondARM32::Cond Cond);
void vsqrts(const Operand *OpSd, const Operand *OpSm, CondARM32::Cond Cond);
void vstrd(const Operand *OpDd, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetInfo &TInfo);
void vstrd(const Operand *OpDd, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetLowering *Lowering) {
const TargetInfo TInfo(Lowering);
vstrd(OpDd, OpAddress, Cond, TInfo);
}
void vstrs(const Operand *OpSd, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetInfo &TInfo);
void vstrs(const Operand *OpSd, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetLowering *Lowering) {
const TargetInfo TInfo(Lowering);
vstrs(OpSd, OpAddress, Cond, TInfo);
}
// ElmtSize = #bits in vector element.
void vst1qr(size_t ElmtSize, const Operand *OpQd, const Operand *OpAddress,
const TargetInfo &TInfo);
void vst1qr(size_t ElmtSize, const Operand *OpQd, const Operand *OpRn,
const TargetLowering *Lowering) {
const TargetInfo TInfo(Lowering);
vst1qr(ElmtSize, OpQd, OpRn, TInfo);
}
void vsubd(const Operand *OpDd, const Operand *OpDn, const Operand *OpDm,
CondARM32::Cond Cond);
// Integer vector subtract.
void vsubqi(Type ElmtTy, const Operand *OpQd, const Operand *OpQm,
const Operand *OpQn);
// Float vector subtract
void vsubqf(const Operand *OpQd, const Operand *OpQm, const Operand *OpQn);
void vsubs(const Operand *OpSd, const Operand *OpSn, const Operand *OpSm,
CondARM32::Cond Cond);
static bool classof(const Assembler *Asm) {
return Asm->getKind() == Asm_ARM32;
}
void emitTextInst(const std::string &Text, SizeT InstSize);
private:
ENABLE_MAKE_UNIQUE;
const bool IsNonsfi;
// A vector of pool-allocated x86 labels for CFG nodes.
using LabelVector = std::vector<Label *>;
LabelVector CfgNodeLabels;
// A vector of pool-allocated x86 labels for Local labels.
LabelVector LocalLabels;
// Number of bytes emitted by InstARM32::emit() methods, when run inside
// InstARM32::emitUsingTextFixup().
size_t EmitTextSize = 0;
// Load/store multiple addressing mode.
enum BlockAddressMode {
// bit encoding P U W
DA = (0 | 0 | 0) << 21, // decrement after
IA = (0 | 4 | 0) << 21, // increment after
DB = (8 | 0 | 0) << 21, // decrement before
IB = (8 | 4 | 0) << 21, // increment before
DA_W = (0 | 0 | 1) << 21, // decrement after with writeback to base
IA_W = (0 | 4 | 1) << 21, // increment after with writeback to base
DB_W = (8 | 0 | 1) << 21, // decrement before with writeback to base
IB_W = (8 | 4 | 1) << 21 // increment before with writeback to base
};
Label *getOrCreateLabel(SizeT Number, LabelVector &Labels);
void bindCfgNodeLabel(const CfgNode *Node) override;
// SIMD encoding for the vector ElmtTy.
static IValueT encodeElmtType(Type ElmtTy);
void emitInst(IValueT Value) {
AssemblerBuffer::EnsureCapacity _(&Buffer);
Buffer.emit<IValueT>(Value);
}
// List of possible checks to apply when calling emitType01() (below).
enum EmitChecks { NoChecks, RdIsPcAndSetFlags };
// Pattern cccctttoooosnnnnddddiiiiiiiiiiii where cccc=Cond, ttt=InstType,
// s=SetFlags, oooo=Opcode, nnnn=Rn, dddd=Rd, iiiiiiiiiiii=imm12 (See ARM
// section A5.2.3).
void emitType01(CondARM32::Cond Cond, IValueT InstType, IValueT Opcode,
bool SetFlags, IValueT Rn, IValueT Rd, IValueT imm12,
EmitChecks RuleChecks, const char *InstName);
// Converts appropriate representation on a data operation, and then calls
// emitType01 above.
void emitType01(CondARM32::Cond Cond, IValueT Opcode, const Operand *OpRd,
const Operand *OpRn, const Operand *OpSrc1, bool SetFlags,
EmitChecks RuleChecks, const char *InstName);
// Same as above, but the value for Rd and Rn have already been converted
// into instruction values.
void emitType01(CondARM32::Cond Cond, IValueT Opcode, IValueT OpRd,
IValueT OpRn, const Operand *OpSrc1, bool SetFlags,
EmitChecks RuleChecks, const char *InstName);
void emitType05(CondARM32::Cond Cond, int32_t Offset, bool Link);
// Emit ccccoooaabalnnnnttttaaaaaaaaaaaa where cccc=Cond,
// ooo=InstType, l=isLoad, b=isByte, and
// aaa0a0aaaa0000aaaaaaaaaaaa=Address. Note that Address is assumed to be
// defined by decodeAddress() in IceAssemblerARM32.cpp.
void emitMemOp(CondARM32::Cond Cond, IValueT InstType, bool IsLoad,
bool IsByte, IValueT Rt, IValueT Address);
// Emit ccccxxxxxxxxxxxxddddxxxxxxxxmmmm where cccc=Cond,
// xxxxxxxxxxxx0000xxxxxxxx0000=Opcode, dddd=Rd, and mmmm=Rm.
void emitRdRm(CondARM32::Cond Cond, IValueT Opcode, const Operand *OpRd,
const Operand *OpRm, const char *InstName);
// Emit ldr/ldrb/str/strb instruction with given address.
void emitMemOp(CondARM32::Cond Cond, bool IsLoad, bool IsByte, IValueT Rt,
const Operand *OpAddress, const TargetInfo &TInfo,
const char *InstName);
// Emit ldrh/ldrd/strh/strd instruction with given address using encoding 3.
void emitMemOpEnc3(CondARM32::Cond Cond, IValueT Opcode, IValueT Rt,
const Operand *OpAddress, const TargetInfo &TInfo,
const char *InstName);
// Emit cccc00011xxlnnnndddd11111001tttt where cccc=Cond, xx encodes type
// size, l=IsLoad, nnnn=Rn (as defined by OpAddress), and tttt=Rt.
void emitMemExOp(CondARM32::Cond, Type Ty, bool IsLoad, const Operand *OpRd,
IValueT Rt, const Operand *OpAddress,
const TargetInfo &TInfo, const char *InstName);
// Pattern cccc100aaaalnnnnrrrrrrrrrrrrrrrr where cccc=Cond,
// aaaa<<21=AddressMode, l=IsLoad, nnnn=BaseReg, and
// rrrrrrrrrrrrrrrr is bitset of Registers.
void emitMultiMemOp(CondARM32::Cond Cond, BlockAddressMode AddressMode,
bool IsLoad, IValueT BaseReg, IValueT Registers);
// Pattern ccccxxxxxDxxxxxxddddxxxxiiiiiiii where cccc=Cond, ddddD=BaseReg,
// iiiiiiii=NumConsecRegs, and xxxxx0xxxxxx0000xxxx00000000=Opcode.
void emitVStackOp(CondARM32::Cond Cond, IValueT Opcode,
const Variable *OpBaseReg, SizeT NumConsecRegs);
// Pattern cccc111xxDxxxxxxdddd101xxxMxmmmm where cccc=Cond, ddddD=Sd,
// Mmmmm=Dm, and xx0xxxxxxdddd000xxx0x0000=Opcode.
void emitVFPsd(CondARM32::Cond Cond, IValueT Opcode, IValueT Sd, IValueT Dm);
// Pattern cccc111xxDxxxxxxdddd101xxxMxmmmm where cccc=Cond, Ddddd=Dd,
// mmmmM=Sm, and xx0xxxxxxdddd000xxx0x0000=Opcode.
void emitVFPds(CondARM32::Cond Cond, IValueT Opcode, IValueT Dd, IValueT Sm);
// Pattern 111100000D00nnnnddddttttssaammmm | Opcode where Ddddd=Dd, nnnn=Rn,
// mmmmm=Rm, tttt=NumDRegs, ElmtSize in {8, 16, 32, 64) and defines ss, and
// aa=Align.
void emitVMem1Op(IValueT Opcode, IValueT Dd, IValueT Rn, IValueT Rm,
DRegListSize NumDRegs, size_t ElmtSize, IValueT Align,
const char *InstName);
// Pattern cccc011100x1dddd1111mmmm0001nnn where cccc=Cond,
// x=Opcode, dddd=Rd, nnnn=Rn, mmmm=Rm.
void emitDivOp(CondARM32::Cond Cond, IValueT Opcode, IValueT Rd, IValueT Rn,
IValueT Rm);
// cccc1110iiiennnntttt1011Njj10000 where cccc=Cond, tttt=Rt, Ndddd=2*Qn=Dn,
// iii=Opcode1, jj=Opcode2, Opcode1Opcode2 encodes Index and the
// corresponding element size of the vector element, and e=IsExtract.
void emitInsertExtractInt(CondARM32::Cond Cond, const Operand *OpQn,
uint32_t Index, const Operand *OpRt, bool IsExtract,
const char *InstName);
// cccc11101D110000dddd101001M0mmmm where cccc=Cond, ddddD=Sd, and mmmmM=Sm.
// Assigns Sd the value of Sm.
void emitMoveSS(CondARM32::Cond Cond, IValueT Sd, IValueT Sm);
// Pattern ccccxxxxxxxfnnnnddddssss1001mmmm where cccc=Cond, dddd=Rd, nnnn=Rn,
// mmmm=Rm, ssss=Rs, f=SetFlags and xxxxxxx=Opcode.
void emitMulOp(CondARM32::Cond Cond, IValueT Opcode, IValueT Rd, IValueT Rn,
IValueT Rm, IValueT Rs, bool SetFlags);
// Pattern cccc0001101s0000ddddxxxxxtt0mmmm where cccc=Cond, s=SetFlags,
// dddd=Rd, mmmm=Rm, tt=Shift, and xxxxx is defined by OpSrc1. OpSrc1 defines
// either xxxxx=Imm5, or xxxxx=ssss0 where ssss=Rs.
void emitShift(const CondARM32::Cond Cond,
const OperandARM32::ShiftKind Shift, const Operand *OpRd,
const Operand *OpRm, const Operand *OpSrc1,
const bool SetFlags, const char *InstName);
// Implements various forms of signed/unsigned extend value, using pattern
// ccccxxxxxxxxnnnnddddrr000111mmmm where cccc=Cond, xxxxxxxx<<20=Opcode,
// nnnn=Rn, dddd=Rd, rr=Rotation, and mmmm=Rm.
void emitSignExtend(CondARM32::Cond, IValueT Opcode, const Operand *OpRd,
const Operand *OpSrc0, const char *InstName);
// Implements various forms of vector (SIMD) operations. Implements pattern
// 111100100D00nnnndddn00F0NQM0mmmm where Dddd=Dd, Nnnn=Dn, Mmmm=Dm,
// Q=UseQRegs, F=IsFloatTy, and Opcode is unioned into the pattern.
void emitSIMDBase(IValueT Opcode, IValueT Dd, IValueT Dn, IValueT Dm,
bool UseQRegs, bool IsFloatTy);
// Same as emitSIMDBase above, except ElmtShift=20 and ElmtSize is computed
// from ElmtTy.
void emitSIMD(IValueT Opcode, Type ElmtTy, IValueT Dd, IValueT Dn, IValueT Dm,
bool UseQRegs);
// Implements various integer forms of vector (SIMD) operations using Q
// registers. Implements pattern 111100100D00nnn0ddd000F0N1M0mmm0 where
// Dddd=Qd, Nnnn=Qn, Mmmm=Qm, F=IsFloatTy, and Opcode is unioned into the
// pattern.
void emitSIMDqqqBase(IValueT Opcode, const Operand *OpQd, const Operand *OpQn,
const Operand *OpQm, bool IsFloatTy,
const char *OpcodeName);
// Same as emitSIMD above, except ElmtShift=20 and ElmtSize is computed from
// ElmtTy.
void emitSIMDqqq(IValueT Opcode, Type ElmtTy, const Operand *OpQd,
const Operand *OpQn, const Operand *OpQm,
const char *OpcodeName);
// Implements various forms of vector (SIMD) shifts using Q registers.
// Implements pattern 111100101Diiiiiidddd010101M1mmmm where Dddd=Qd, Mmmm=Qm,
// iiiiii=Imm6, and Opcode is unioned into the pattern.
void emitSIMDShiftqqc(IValueT Opcode, const Operand *OpQd,
const Operand *OpQm, const IValueT Imm6,
const char *OpcodeName);
// Implements various forms of vector (SIMD) casts between (signed and
// unsigned) integer and floating point types (f32). Implements pattern
// 111100111D11ss11dddd011ooQM0mmmm where Dddd=Qd, Mmmm=Qm, 10=ss, op=00, 1=Q,
// and Opcode is unioned into the pattern.
void emitSIMDCvtqq(IValueT Opcode, const Operand *OpQd, const Operand *OpQm,
const char *CvtName);
// Pattern cccctttxxxxnnnn0000iiiiiiiiiiii where cccc=Cond, nnnn=Rn,
// ttt=Instruction type (derived from OpSrc1), iiiiiiiiiiii is derived from
// OpSrc1, and xxxx=Opcode.
void emitCompareOp(CondARM32::Cond Cond, IValueT Opcode, const Operand *OpRn,
const Operand *OpSrc1, const char *CmpName);
void emitBranch(Label *L, CondARM32::Cond, bool Link);
// Returns the offset encoded in the branch instruction Inst.
static IOffsetT decodeBranchOffset(IValueT Inst);
// Implements movw/movt, generating pattern ccccxxxxxxxsiiiiddddiiiiiiiiiiii
// where cccc=Cond, xxxxxxx<<21=Opcode, dddd=Rd, s=SetFlags, and
// iiiiiiiiiiiiiiii=Imm16.
void emitMovwt(CondARM32::Cond Cond, bool IsMovw, const Operand *OpRd,
const Operand *OpSrc, const char *MovName);
// Emit VFP instruction with 3 D registers.
void emitVFPddd(CondARM32::Cond Cond, IValueT Opcode, const Operand *OpDd,
const Operand *OpDn, const Operand *OpDm,
const char *InstName);
void emitVFPddd(CondARM32::Cond Cond, IValueT Opcode, IValueT Dd, IValueT Dn,
IValueT Dm);
// Emit VFP instruction with 3 S registers.
void emitVFPsss(CondARM32::Cond Cond, IValueT Opcode, IValueT Sd, IValueT Sn,
IValueT Sm);
void emitVFPsss(CondARM32::Cond Cond, IValueT Opcode, const Operand *OpSd,
const Operand *OpSn, const Operand *OpSm,
const char *InstName);
};
} // end of namespace ARM32
} // end of namespace Ice
#endif // SUBZERO_SRC_ICEASSEMBLERARM32_H