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swiftshader / SwiftShader / 19e9af23e8a3a9dffbcc93b0ad7b22505a516365 / . / third_party / subzero / src / IceAssemblerX86Base.h
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//===- subzero/src/IceAssemblerX86Base.h - base x86 assembler -*- 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 Defines the AssemblerX86 template class for x86, the base of all X86
/// assemblers.
//
//===----------------------------------------------------------------------===//
#ifndef SUBZERO_SRC_ICEASSEMBLERX86BASE_H
#define SUBZERO_SRC_ICEASSEMBLERX86BASE_H
#include "IceAssembler.h"
#include "IceDefs.h"
#include "IceOperand.h"
#include "IceTypes.h"
#include "IceUtils.h"
namespace Ice {
#ifndef X86NAMESPACE
#error "You must define the X86 Target namespace."
#endif
namespace X86NAMESPACE {
template <typename TraitsType>
class AssemblerX86Base : public ::Ice::Assembler {
AssemblerX86Base(const AssemblerX86Base &) = delete;
AssemblerX86Base &operator=(const AssemblerX86Base &) = delete;
protected:
explicit AssemblerX86Base(
bool EmitAddrSizeOverridePrefix = TraitsType::Is64Bit)
: Assembler(Traits::AsmKind),
EmitAddrSizeOverridePrefix(EmitAddrSizeOverridePrefix) {
assert(Traits::Is64Bit || !EmitAddrSizeOverridePrefix);
}
public:
using Traits = TraitsType;
using Address = typename Traits::Address;
using ByteRegister = typename Traits::ByteRegister;
using BrCond = typename Traits::Cond::BrCond;
using CmppsCond = typename Traits::Cond::CmppsCond;
using GPRRegister = typename Traits::GPRRegister;
using Operand = typename Traits::Operand;
using XmmRegister = typename Traits::XmmRegister;
static constexpr int MAX_NOP_SIZE = 8;
static bool classof(const Assembler *Asm) {
return Asm->getKind() == Traits::AsmKind;
}
class Immediate {
Immediate(const Immediate &) = delete;
Immediate &operator=(const Immediate &) = delete;
public:
explicit Immediate(int32_t value) : value_(value) {}
explicit Immediate(AssemblerFixup *fixup) : fixup_(fixup) {}
int32_t value() const { return value_; }
AssemblerFixup *fixup() const { return fixup_; }
bool is_int8() const {
// We currently only allow 32-bit fixups, and they usually have value = 0,
// so if fixup_ != nullptr, it shouldn't be classified as int8/16.
return fixup_ == nullptr && Utils::IsInt(8, value_);
}
bool is_uint8() const {
return fixup_ == nullptr && Utils::IsUint(8, value_);
}
bool is_uint16() const {
return fixup_ == nullptr && Utils::IsUint(16, value_);
}
private:
const int32_t value_ = 0;
AssemblerFixup *fixup_ = nullptr;
};
/// X86 allows near and far jumps.
class Label final : public Ice::Label {
Label(const Label &) = delete;
Label &operator=(const Label &) = delete;
public:
Label() = default;
~Label() = default;
void finalCheck() const override {
Ice::Label::finalCheck();
assert(!hasNear());
}
/// Returns the position of an earlier branch instruction which assumes that
/// this label is "near", and bumps iterator to the next near position.
intptr_t getNearPosition() {
assert(hasNear());
intptr_t Pos = UnresolvedNearPositions.back();
UnresolvedNearPositions.pop_back();
return Pos;
}
bool hasNear() const { return !UnresolvedNearPositions.empty(); }
bool isUnused() const override {
return Ice::Label::isUnused() && !hasNear();
}
private:
friend class AssemblerX86Base<TraitsType>;
void nearLinkTo(const Assembler &Asm, intptr_t position) {
if (Asm.getPreliminary())
return;
assert(!isBound());
UnresolvedNearPositions.push_back(position);
}
llvm::SmallVector<intptr_t, 20> UnresolvedNearPositions;
};
public:
~AssemblerX86Base() override;
static const bool kNearJump = true;
static const bool kFarJump = false;
void alignFunction() override;
SizeT getBundleAlignLog2Bytes() const override { return 5; }
const char *getAlignDirective() const override { return ".p2align"; }
llvm::ArrayRef<uint8_t> getNonExecBundlePadding() const override {
static const uint8_t Padding[] = {0xF4};
return llvm::ArrayRef<uint8_t>(Padding, 1);
}
void padWithNop(intptr_t Padding) override {
while (Padding > MAX_NOP_SIZE) {
nop(MAX_NOP_SIZE);
Padding -= MAX_NOP_SIZE;
}
if (Padding)
nop(Padding);
}
Ice::Label *getCfgNodeLabel(SizeT NodeNumber) override;
void bindCfgNodeLabel(const CfgNode *Node) override;
Label *getOrCreateCfgNodeLabel(SizeT Number);
Label *getOrCreateLocalLabel(SizeT Number);
void bindLocalLabel(SizeT Number);
bool fixupIsPCRel(FixupKind Kind) const override {
// Currently assuming this is the only PC-rel relocation type used.
// TODO(jpp): Traits.PcRelTypes.count(Kind) != 0
return Kind == Traits::FK_PcRel;
}
// Operations to emit GPR instructions (and dispatch on operand type).
using TypedEmitGPR = void (AssemblerX86Base::*)(Type, GPRRegister);
using TypedEmitAddr = void (AssemblerX86Base::*)(Type, const Address &);
struct GPREmitterOneOp {
TypedEmitGPR Reg;
TypedEmitAddr Addr;
};
using TypedEmitGPRGPR = void (AssemblerX86Base::*)(Type, GPRRegister,
GPRRegister);
using TypedEmitGPRAddr = void (AssemblerX86Base::*)(Type, GPRRegister,
const Address &);
using TypedEmitGPRImm = void (AssemblerX86Base::*)(Type, GPRRegister,
const Immediate &);
struct GPREmitterRegOp {
TypedEmitGPRGPR GPRGPR;
TypedEmitGPRAddr GPRAddr;
TypedEmitGPRImm GPRImm;
};
struct GPREmitterShiftOp {
// Technically, Addr/GPR and Addr/Imm are also allowed, but */Addr are
// not. In practice, we always normalize the Dest to a Register first.
TypedEmitGPRGPR GPRGPR;
TypedEmitGPRImm GPRImm;
};
using TypedEmitGPRGPRImm = void (AssemblerX86Base::*)(Type, GPRRegister,
GPRRegister,
const Immediate &);
struct GPREmitterShiftD {
// Technically AddrGPR and AddrGPRImm are also allowed, but in practice we
// always normalize Dest to a Register first.
TypedEmitGPRGPR GPRGPR;
TypedEmitGPRGPRImm GPRGPRImm;
};
using TypedEmitAddrGPR = void (AssemblerX86Base::*)(Type, const Address &,
GPRRegister);
using TypedEmitAddrImm = void (AssemblerX86Base::*)(Type, const Address &,
const Immediate &);
struct GPREmitterAddrOp {
TypedEmitAddrGPR AddrGPR;
TypedEmitAddrImm AddrImm;
};
// Operations to emit XMM instructions (and dispatch on operand type).
using TypedEmitXmmXmm = void (AssemblerX86Base::*)(Type, XmmRegister,
XmmRegister);
using TypedEmitXmmAddr = void (AssemblerX86Base::*)(Type, XmmRegister,
const Address &);
struct XmmEmitterRegOp {
TypedEmitXmmXmm XmmXmm;
TypedEmitXmmAddr XmmAddr;
};
using EmitXmmXmm = void (AssemblerX86Base::*)(XmmRegister, XmmRegister);
using EmitXmmAddr = void (AssemblerX86Base::*)(XmmRegister, const Address &);
using EmitAddrXmm = void (AssemblerX86Base::*)(const Address &, XmmRegister);
struct XmmEmitterMovOps {
EmitXmmXmm XmmXmm;
EmitXmmAddr XmmAddr;
EmitAddrXmm AddrXmm;
};
using TypedEmitXmmImm = void (AssemblerX86Base::*)(Type, XmmRegister,
const Immediate &);
struct XmmEmitterShiftOp {
TypedEmitXmmXmm XmmXmm;
TypedEmitXmmAddr XmmAddr;
TypedEmitXmmImm XmmImm;
};
// Cross Xmm/GPR cast instructions.
template <typename DReg_t, typename SReg_t> struct CastEmitterRegOp {
using TypedEmitRegs = void (AssemblerX86Base::*)(Type, DReg_t, Type,
SReg_t);
using TypedEmitAddr = void (AssemblerX86Base::*)(Type, DReg_t, Type,
const Address &);
TypedEmitRegs RegReg;
TypedEmitAddr RegAddr;
};
// Three operand (potentially) cross Xmm/GPR instructions. The last operand
// must be an immediate.
template <typename DReg_t, typename SReg_t> struct ThreeOpImmEmitter {
using TypedEmitRegRegImm = void (AssemblerX86Base::*)(Type, DReg_t, SReg_t,
const Immediate &);
using TypedEmitRegAddrImm = void (AssemblerX86Base::*)(Type, DReg_t,
const Address &,
const Immediate &);
TypedEmitRegRegImm RegRegImm;
TypedEmitRegAddrImm RegAddrImm;
};
/*
* Emit Machine Instructions.
*/
void call(GPRRegister reg);
void call(const Address &address);
void call(const ConstantRelocatable *label); // not testable.
void call(const Immediate &abs_address);
static const intptr_t kCallExternalLabelSize = 5;
void pushl(GPRRegister reg);
void pushl(const Immediate &Imm);
void pushl(const ConstantRelocatable *Label);
void popl(GPRRegister reg);
void popl(const Address &address);
template <typename T = Traits,
typename = typename std::enable_if<T::HasPusha>::type>
void pushal();
template <typename T = Traits,
typename = typename std::enable_if<T::HasPopa>::type>
void popal();
void setcc(BrCond condition, ByteRegister dst);
void setcc(BrCond condition, const Address &address);
void mov(Type Ty, GPRRegister dst, const Immediate &src);
void mov(Type Ty, GPRRegister dst, GPRRegister src);
void mov(Type Ty, GPRRegister dst, const Address &src);
void mov(Type Ty, const Address &dst, GPRRegister src);
void mov(Type Ty, const Address &dst, const Immediate &imm);
template <typename T = Traits>
typename std::enable_if<T::Is64Bit, void>::type movabs(const GPRRegister Dst,
uint64_t Imm64);
template <typename T = Traits>
typename std::enable_if<!T::Is64Bit, void>::type movabs(const GPRRegister,
uint64_t) {
llvm::report_fatal_error("movabs is only supported in 64-bit x86 targets.");
}
void movzx(Type Ty, GPRRegister dst, GPRRegister src);
void movzx(Type Ty, GPRRegister dst, const Address &src);
void movsx(Type Ty, GPRRegister dst, GPRRegister src);
void movsx(Type Ty, GPRRegister dst, const Address &src);
void lea(Type Ty, GPRRegister dst, const Address &src);
void cmov(Type Ty, BrCond cond, GPRRegister dst, GPRRegister src);
void cmov(Type Ty, BrCond cond, GPRRegister dst, const Address &src);
void rep_movsb();
void movss(Type Ty, XmmRegister dst, const Address &src);
void movss(Type Ty, const Address &dst, XmmRegister src);
void movss(Type Ty, XmmRegister dst, XmmRegister src);
void movd(Type SrcTy, XmmRegister dst, GPRRegister src);
void movd(Type SrcTy, XmmRegister dst, const Address &src);
void movd(Type DestTy, GPRRegister dst, XmmRegister src);
void movd(Type DestTy, const Address &dst, XmmRegister src);
void movq(XmmRegister dst, XmmRegister src);
void movq(const Address &dst, XmmRegister src);
void movq(XmmRegister dst, const Address &src);
void addss(Type Ty, XmmRegister dst, XmmRegister src);
void addss(Type Ty, XmmRegister dst, const Address &src);
void subss(Type Ty, XmmRegister dst, XmmRegister src);
void subss(Type Ty, XmmRegister dst, const Address &src);
void mulss(Type Ty, XmmRegister dst, XmmRegister src);
void mulss(Type Ty, XmmRegister dst, const Address &src);
void divss(Type Ty, XmmRegister dst, XmmRegister src);
void divss(Type Ty, XmmRegister dst, const Address &src);
void movaps(XmmRegister dst, XmmRegister src);
void movups(XmmRegister dst, XmmRegister src);
void movups(XmmRegister dst, const Address &src);
void movups(const Address &dst, XmmRegister src);
void padd(Type Ty, XmmRegister dst, XmmRegister src);
void padd(Type Ty, XmmRegister dst, const Address &src);
void padds(Type Ty, XmmRegister dst, XmmRegister src);
void padds(Type Ty, XmmRegister dst, const Address &src);
void paddus(Type Ty, XmmRegister dst, XmmRegister src);
void paddus(Type Ty, XmmRegister dst, const Address &src);
void pand(Type Ty, XmmRegister dst, XmmRegister src);
void pand(Type Ty, XmmRegister dst, const Address &src);
void pandn(Type Ty, XmmRegister dst, XmmRegister src);
void pandn(Type Ty, XmmRegister dst, const Address &src);
void pmull(Type Ty, XmmRegister dst, XmmRegister src);
void pmull(Type Ty, XmmRegister dst, const Address &src);
void pmulhw(Type Ty, XmmRegister dst, XmmRegister src);
void pmulhw(Type Ty, XmmRegister dst, const Address &src);
void pmulhuw(Type Ty, XmmRegister dst, XmmRegister src);
void pmulhuw(Type Ty, XmmRegister dst, const Address &src);
void pmaddwd(Type Ty, XmmRegister dst, XmmRegister src);
void pmaddwd(Type Ty, XmmRegister dst, const Address &src);
void pmuludq(Type Ty, XmmRegister dst, XmmRegister src);
void pmuludq(Type Ty, XmmRegister dst, const Address &src);
void por(Type Ty, XmmRegister dst, XmmRegister src);
void por(Type Ty, XmmRegister dst, const Address &src);
void psub(Type Ty, XmmRegister dst, XmmRegister src);
void psub(Type Ty, XmmRegister dst, const Address &src);
void psubs(Type Ty, XmmRegister dst, XmmRegister src);
void psubs(Type Ty, XmmRegister dst, const Address &src);
void psubus(Type Ty, XmmRegister dst, XmmRegister src);
void psubus(Type Ty, XmmRegister dst, const Address &src);
void pxor(Type Ty, XmmRegister dst, XmmRegister src);
void pxor(Type Ty, XmmRegister dst, const Address &src);
void psll(Type Ty, XmmRegister dst, XmmRegister src);
void psll(Type Ty, XmmRegister dst, const Address &src);
void psll(Type Ty, XmmRegister dst, const Immediate &src);
void psra(Type Ty, XmmRegister dst, XmmRegister src);
void psra(Type Ty, XmmRegister dst, const Address &src);
void psra(Type Ty, XmmRegister dst, const Immediate &src);
void psrl(Type Ty, XmmRegister dst, XmmRegister src);
void psrl(Type Ty, XmmRegister dst, const Address &src);
void psrl(Type Ty, XmmRegister dst, const Immediate &src);
void addps(Type Ty, XmmRegister dst, XmmRegister src);
void addps(Type Ty, XmmRegister dst, const Address &src);
void subps(Type Ty, XmmRegister dst, XmmRegister src);
void subps(Type Ty, XmmRegister dst, const Address &src);
void divps(Type Ty, XmmRegister dst, XmmRegister src);
void divps(Type Ty, XmmRegister dst, const Address &src);
void mulps(Type Ty, XmmRegister dst, XmmRegister src);
void mulps(Type Ty, XmmRegister dst, const Address &src);
void minps(Type Ty, XmmRegister dst, const Address &src);
void minps(Type Ty, XmmRegister dst, XmmRegister src);
void minss(Type Ty, XmmRegister dst, const Address &src);
void minss(Type Ty, XmmRegister dst, XmmRegister src);
void maxps(Type Ty, XmmRegister dst, const Address &src);
void maxps(Type Ty, XmmRegister dst, XmmRegister src);
void maxss(Type Ty, XmmRegister dst, const Address &src);
void maxss(Type Ty, XmmRegister dst, XmmRegister src);
void andnps(Type Ty, XmmRegister dst, const Address &src);
void andnps(Type Ty, XmmRegister dst, XmmRegister src);
void andps(Type Ty, XmmRegister dst, const Address &src);
void andps(Type Ty, XmmRegister dst, XmmRegister src);
void orps(Type Ty, XmmRegister dst, const Address &src);
void orps(Type Ty, XmmRegister dst, XmmRegister src);
void blendvps(Type Ty, XmmRegister dst, XmmRegister src);
void blendvps(Type Ty, XmmRegister dst, const Address &src);
void pblendvb(Type Ty, XmmRegister dst, XmmRegister src);
void pblendvb(Type Ty, XmmRegister dst, const Address &src);
void cmpps(Type Ty, XmmRegister dst, XmmRegister src, CmppsCond CmpCondition);
void cmpps(Type Ty, XmmRegister dst, const Address &src,
CmppsCond CmpCondition);
void sqrtps(XmmRegister dst);
void rsqrtps(XmmRegister dst);
void reciprocalps(XmmRegister dst);
void movhlps(XmmRegister dst, XmmRegister src);
void movlhps(XmmRegister dst, XmmRegister src);
void unpcklps(XmmRegister dst, XmmRegister src);
void unpckhps(XmmRegister dst, XmmRegister src);
void unpcklpd(XmmRegister dst, XmmRegister src);
void unpckhpd(XmmRegister dst, XmmRegister src);
void set1ps(XmmRegister dst, GPRRegister tmp, const Immediate &imm);
void sqrtpd(XmmRegister dst);
void pshufb(Type Ty, XmmRegister dst, XmmRegister src);
void pshufb(Type Ty, XmmRegister dst, const Address &src);
void pshufd(Type Ty, XmmRegister dst, XmmRegister src, const Immediate &mask);
void pshufd(Type Ty, XmmRegister dst, const Address &src,
const Immediate &mask);
void punpckl(Type Ty, XmmRegister Dst, XmmRegister Src);
void punpckl(Type Ty, XmmRegister Dst, const Address &Src);
void punpckh(Type Ty, XmmRegister Dst, XmmRegister Src);
void punpckh(Type Ty, XmmRegister Dst, const Address &Src);
void packss(Type Ty, XmmRegister Dst, XmmRegister Src);
void packss(Type Ty, XmmRegister Dst, const Address &Src);
void packus(Type Ty, XmmRegister Dst, XmmRegister Src);
void packus(Type Ty, XmmRegister Dst, const Address &Src);
void shufps(Type Ty, XmmRegister dst, XmmRegister src, const Immediate &mask);
void shufps(Type Ty, XmmRegister dst, const Address &src,
const Immediate &mask);
void cvtdq2ps(Type, XmmRegister dst, XmmRegister src);
void cvtdq2ps(Type, XmmRegister dst, const Address &src);
void cvttps2dq(Type, XmmRegister dst, XmmRegister src);
void cvttps2dq(Type, XmmRegister dst, const Address &src);
void cvtps2dq(Type, XmmRegister dst, XmmRegister src);
void cvtps2dq(Type, XmmRegister dst, const Address &src);
void cvtsi2ss(Type DestTy, XmmRegister dst, Type SrcTy, GPRRegister src);
void cvtsi2ss(Type DestTy, XmmRegister dst, Type SrcTy, const Address &src);
void cvtfloat2float(Type SrcTy, XmmRegister dst, XmmRegister src);
void cvtfloat2float(Type SrcTy, XmmRegister dst, const Address &src);
void cvttss2si(Type DestTy, GPRRegister dst, Type SrcTy, XmmRegister src);
void cvttss2si(Type DestTy, GPRRegister dst, Type SrcTy, const Address &src);
void cvtss2si(Type DestTy, GPRRegister dst, Type SrcTy, XmmRegister src);
void cvtss2si(Type DestTy, GPRRegister dst, Type SrcTy, const Address &src);
void ucomiss(Type Ty, XmmRegister a, XmmRegister b);
void ucomiss(Type Ty, XmmRegister a, const Address &b);
void movmsk(Type Ty, GPRRegister dst, XmmRegister src);
void sqrt(Type Ty, XmmRegister dst, const Address &src);
void sqrt(Type Ty, XmmRegister dst, XmmRegister src);
void xorps(Type Ty, XmmRegister dst, const Address &src);
void xorps(Type Ty, XmmRegister dst, XmmRegister src);
void insertps(Type Ty, XmmRegister dst, XmmRegister src,
const Immediate &imm);
void insertps(Type Ty, XmmRegister dst, const Address &src,
const Immediate &imm);
void pinsr(Type Ty, XmmRegister dst, GPRRegister src, const Immediate &imm);
void pinsr(Type Ty, XmmRegister dst, const Address &src,
const Immediate &imm);
void pextr(Type Ty, GPRRegister dst, XmmRegister src, const Immediate &imm);
void pmovsxdq(XmmRegister dst, XmmRegister src);
void pcmpeq(Type Ty, XmmRegister dst, XmmRegister src);
void pcmpeq(Type Ty, XmmRegister dst, const Address &src);
void pcmpgt(Type Ty, XmmRegister dst, XmmRegister src);
void pcmpgt(Type Ty, XmmRegister dst, const Address &src);
enum RoundingMode {
kRoundToNearest = 0x0,
kRoundDown = 0x1,
kRoundUp = 0x2,
kRoundToZero = 0x3
};
void round(Type Ty, XmmRegister dst, XmmRegister src, const Immediate &mode);
void round(Type Ty, XmmRegister dst, const Address &src,
const Immediate &mode);
//----------------------------------------------------------------------------
//
// Begin: X87 instructions. Only available when Traits::UsesX87.
//
//----------------------------------------------------------------------------
template <typename T = Traits,
typename = typename std::enable_if<T::UsesX87>::type>
void fld(Type Ty, const typename T::Address &src);
template <typename T = Traits,
typename = typename std::enable_if<T::UsesX87>::type>
void fstp(Type Ty, const typename T::Address &dst);
template <typename T = Traits,
typename = typename std::enable_if<T::UsesX87>::type>
void fstp(typename T::X87STRegister st);
template <typename T = Traits,
typename = typename std::enable_if<T::UsesX87>::type>
void fnstcw(const typename T::Address &dst);
template <typename T = Traits,
typename = typename std::enable_if<T::UsesX87>::type>
void fldcw(const typename T::Address &src);
template <typename T = Traits,
typename = typename std::enable_if<T::UsesX87>::type>
void fistpl(const typename T::Address &dst);
template <typename T = Traits,
typename = typename std::enable_if<T::UsesX87>::type>
void fistps(const typename T::Address &dst);
template <typename T = Traits,
typename = typename std::enable_if<T::UsesX87>::type>
void fildl(const typename T::Address &src);
template <typename T = Traits,
typename = typename std::enable_if<T::UsesX87>::type>
void filds(const typename T::Address &src);
template <typename T = Traits,
typename = typename std::enable_if<T::UsesX87>::type>
void fincstp();
//----------------------------------------------------------------------------
//
// End: X87 instructions.
//
//----------------------------------------------------------------------------
void cmp(Type Ty, GPRRegister reg0, GPRRegister reg1);
void cmp(Type Ty, GPRRegister reg, const Address &address);
void cmp(Type Ty, GPRRegister reg, const Immediate &imm);
void cmp(Type Ty, const Address &address, GPRRegister reg);
void cmp(Type Ty, const Address &address, const Immediate &imm);
void test(Type Ty, GPRRegister reg0, GPRRegister reg1);
void test(Type Ty, GPRRegister reg, const Immediate &imm);
void test(Type Ty, const Address &address, GPRRegister reg);
void test(Type Ty, const Address &address, const Immediate &imm);
void And(Type Ty, GPRRegister dst, GPRRegister src);
void And(Type Ty, GPRRegister dst, const Address &address);
void And(Type Ty, GPRRegister dst, const Immediate &imm);
void And(Type Ty, const Address &address, GPRRegister reg);
void And(Type Ty, const Address &address, const Immediate &imm);
void Or(Type Ty, GPRRegister dst, GPRRegister src);
void Or(Type Ty, GPRRegister dst, const Address &address);
void Or(Type Ty, GPRRegister dst, const Immediate &imm);
void Or(Type Ty, const Address &address, GPRRegister reg);
void Or(Type Ty, const Address &address, const Immediate &imm);
void Xor(Type Ty, GPRRegister dst, GPRRegister src);
void Xor(Type Ty, GPRRegister dst, const Address &address);
void Xor(Type Ty, GPRRegister dst, const Immediate &imm);
void Xor(Type Ty, const Address &address, GPRRegister reg);
void Xor(Type Ty, const Address &address, const Immediate &imm);
void add(Type Ty, GPRRegister dst, GPRRegister src);
void add(Type Ty, GPRRegister reg, const Address &address);
void add(Type Ty, GPRRegister reg, const Immediate &imm);
void add(Type Ty, const Address &address, GPRRegister reg);
void add(Type Ty, const Address &address, const Immediate &imm);
void adc(Type Ty, GPRRegister dst, GPRRegister src);
void adc(Type Ty, GPRRegister dst, const Address &address);
void adc(Type Ty, GPRRegister reg, const Immediate &imm);
void adc(Type Ty, const Address &address, GPRRegister reg);
void adc(Type Ty, const Address &address, const Immediate &imm);
void sub(Type Ty, GPRRegister dst, GPRRegister src);
void sub(Type Ty, GPRRegister reg, const Address &address);
void sub(Type Ty, GPRRegister reg, const Immediate &imm);
void sub(Type Ty, const Address &address, GPRRegister reg);
void sub(Type Ty, const Address &address, const Immediate &imm);
void sbb(Type Ty, GPRRegister dst, GPRRegister src);
void sbb(Type Ty, GPRRegister reg, const Address &address);
void sbb(Type Ty, GPRRegister reg, const Immediate &imm);
void sbb(Type Ty, const Address &address, GPRRegister reg);
void sbb(Type Ty, const Address &address, const Immediate &imm);
void cbw();
void cwd();
void cdq();
template <typename T = Traits>
typename std::enable_if<T::Is64Bit, void>::type cqo();
template <typename T = Traits>
typename std::enable_if<!T::Is64Bit, void>::type cqo() {
llvm::report_fatal_error("CQO is only available in 64-bit x86 backends.");
}
void div(Type Ty, GPRRegister reg);
void div(Type Ty, const Address &address);
void idiv(Type Ty, GPRRegister reg);
void idiv(Type Ty, const Address &address);
void imul(Type Ty, GPRRegister dst, GPRRegister src);
void imul(Type Ty, GPRRegister reg, const Immediate &imm);
void imul(Type Ty, GPRRegister reg, const Address &address);
void imul(Type Ty, GPRRegister reg);
void imul(Type Ty, const Address &address);
void imul(Type Ty, GPRRegister dst, GPRRegister src, const Immediate &imm);
void imul(Type Ty, GPRRegister dst, const Address &address,
const Immediate &imm);
void mul(Type Ty, GPRRegister reg);
void mul(Type Ty, const Address &address);
template <class T = Traits,
typename = typename std::enable_if<!T::Is64Bit>::type>
void incl(GPRRegister reg);
void incl(const Address &address);
template <class T = Traits,
typename = typename std::enable_if<!T::Is64Bit>::type>
void decl(GPRRegister reg);
void decl(const Address &address);
void rol(Type Ty, GPRRegister reg, const Immediate &imm);
void rol(Type Ty, GPRRegister operand, GPRRegister shifter);
void rol(Type Ty, const Address &operand, GPRRegister shifter);
void shl(Type Ty, GPRRegister reg, const Immediate &imm);
void shl(Type Ty, GPRRegister operand, GPRRegister shifter);
void shl(Type Ty, const Address &operand, GPRRegister shifter);
void shr(Type Ty, GPRRegister reg, const Immediate &imm);
void shr(Type Ty, GPRRegister operand, GPRRegister shifter);
void shr(Type Ty, const Address &operand, GPRRegister shifter);
void sar(Type Ty, GPRRegister reg, const Immediate &imm);
void sar(Type Ty, GPRRegister operand, GPRRegister shifter);
void sar(Type Ty, const Address &address, GPRRegister shifter);
void shld(Type Ty, GPRRegister dst, GPRRegister src);
void shld(Type Ty, GPRRegister dst, GPRRegister src, const Immediate &imm);
void shld(Type Ty, const Address &operand, GPRRegister src);
void shrd(Type Ty, GPRRegister dst, GPRRegister src);
void shrd(Type Ty, GPRRegister dst, GPRRegister src, const Immediate &imm);
void shrd(Type Ty, const Address &dst, GPRRegister src);
void neg(Type Ty, GPRRegister reg);
void neg(Type Ty, const Address &addr);
void notl(GPRRegister reg);
void bsf(Type Ty, GPRRegister dst, GPRRegister src);
void bsf(Type Ty, GPRRegister dst, const Address &src);
void bsr(Type Ty, GPRRegister dst, GPRRegister src);
void bsr(Type Ty, GPRRegister dst, const Address &src);
void bswap(Type Ty, GPRRegister reg);
void bt(GPRRegister base, GPRRegister offset);
void ret();
void ret(const Immediate &imm);
// 'size' indicates size in bytes and must be in the range 1..8.
void nop(int size = 1);
void int3();
void hlt();
void ud2();
// j(Label) is fully tested.
void j(BrCond condition, Label *label, bool near = kFarJump);
void j(BrCond condition, const ConstantRelocatable *label); // not testable.
void jmp(GPRRegister reg);
void jmp(Label *label, bool near = kFarJump);
void jmp(const ConstantRelocatable *label); // not testable.
void jmp(const Immediate &abs_address);
void mfence();
void lock();
void cmpxchg(Type Ty, const Address &address, GPRRegister reg, bool Locked);
void cmpxchg8b(const Address &address, bool Locked);
void xadd(Type Ty, const Address &address, GPRRegister reg, bool Locked);
void xchg(Type Ty, GPRRegister reg0, GPRRegister reg1);
void xchg(Type Ty, const Address &address, GPRRegister reg);
/// \name Intel Architecture Code Analyzer markers.
/// @{
void iaca_start();
void iaca_end();
/// @}
void emitSegmentOverride(uint8_t prefix);
intptr_t preferredLoopAlignment() { return 16; }
void align(intptr_t alignment, intptr_t offset);
void bind(Label *label);
intptr_t CodeSize() const { return Buffer.size(); }
protected:
inline void emitUint8(uint8_t value);
private:
ENABLE_MAKE_UNIQUE;
// EmidAddrSizeOverridePrefix directs the emission of the 0x67 prefix to
// force 32-bit registers when accessing memory. This is only used in native
// 64-bit.
const bool EmitAddrSizeOverridePrefix;
static constexpr Type RexTypeIrrelevant = IceType_i32;
static constexpr Type RexTypeForceRexW = IceType_i64;
static constexpr GPRRegister RexRegIrrelevant =
Traits::GPRRegister::Encoded_Reg_eax;
inline void emitInt16(int16_t value);
inline void emitInt32(int32_t value);
inline void emitRegisterOperand(int rm, int reg);
template <typename RegType, typename RmType>
inline void emitXmmRegisterOperand(RegType reg, RmType rm);
inline void emitOperandSizeOverride();
void emitOperand(int rm, const Operand &operand, RelocOffsetT Addend = 0);
void emitImmediate(Type ty, const Immediate &imm);
void emitComplexI8(int rm, const Operand &operand,
const Immediate &immediate);
void emitComplex(Type Ty, int rm, const Operand &operand,
const Immediate &immediate);
void emitLabel(Label *label, intptr_t instruction_size);
void emitLabelLink(Label *label);
void emitNearLabelLink(Label *label);
void emitGenericShift(int rm, Type Ty, GPRRegister reg, const Immediate &imm);
void emitGenericShift(int rm, Type Ty, const Operand &operand,
GPRRegister shifter);
using LabelVector = std::vector<Label *>;
// A vector of pool-allocated x86 labels for CFG nodes.
LabelVector CfgNodeLabels;
// A vector of pool-allocated x86 labels for Local labels.
LabelVector LocalLabels;
Label *getOrCreateLabel(SizeT Number, LabelVector &Labels);
void emitAddrSizeOverridePrefix() {
if (!Traits::Is64Bit || !EmitAddrSizeOverridePrefix) {
return;
}
static constexpr uint8_t AddrSizeOverridePrefix = 0x67;
emitUint8(AddrSizeOverridePrefix);
}
// The arith_int() methods factor out the commonality between the encodings
// of add(), Or(), adc(), sbb(), And(), sub(), Xor(), and cmp(). The Tag
// parameter is statically asserted to be less than 8.
template <uint32_t Tag>
void arith_int(Type Ty, GPRRegister reg, const Immediate &imm);
template <uint32_t Tag>
void arith_int(Type Ty, GPRRegister reg0, GPRRegister reg1);
template <uint32_t Tag>
void arith_int(Type Ty, GPRRegister reg, const Address &address);
template <uint32_t Tag>
void arith_int(Type Ty, const Address &address, GPRRegister reg);
template <uint32_t Tag>
void arith_int(Type Ty, const Address &address, const Immediate &imm);
// gprEncoding returns Reg encoding for operand emission. For x86-64 we mask
// out the 4th bit as it is encoded in the REX.[RXB] bits. No other bits are
// touched because we don't want to mask errors.
template <typename RegType, typename T = Traits>
typename std::enable_if<T::Is64Bit, typename T::GPRRegister>::type
gprEncoding(const RegType Reg) {
return static_cast<GPRRegister>(static_cast<uint8_t>(Reg) & ~0x08);
}
template <typename RegType, typename T = Traits>
typename std::enable_if<!T::Is64Bit, typename T::GPRRegister>::type
gprEncoding(const RegType Reg) {
return static_cast<typename T::GPRRegister>(Reg);
}
template <typename RegType>
bool is8BitRegisterRequiringRex(const Type Ty, const RegType Reg) {
static constexpr bool IsGPR =
std::is_same<typename std::decay<RegType>::type, ByteRegister>::value ||
std::is_same<typename std::decay<RegType>::type, GPRRegister>::value;
// At this point in the assembler, we have encoded regs, so it is not
// possible to distinguish between the "new" low byte registers introduced
// in x86-64 and the legacy [abcd]h registers. Because x86, we may still
// see ah (div) in the assembler, so we whitelist it here.
//
// The "local" uint32_t Encoded_Reg_ah is needed because RegType is an
// enum that is not necessarily the same type of
// Traits::RegisterSet::Encoded_Reg_ah.
constexpr uint32_t Encoded_Reg_ah = Traits::RegisterSet::Encoded_Reg_ah;
return IsGPR && (Reg & 0x04) != 0 && (Reg & 0x08) == 0 &&
isByteSizedType(Ty) && (Reg != Encoded_Reg_ah);
}
// assembleAndEmitRex is used for determining which (if any) rex prefix
// should be emitted for the current instruction. It allows different types
// for Reg and Rm because they could be of different types (e.g., in
// mov[sz]x instructions.) If Addr is not nullptr, then Rm is ignored, and
// Rex.B is determined by Addr instead. TyRm is still used to determine
// Addr's size.
template <typename RegType, typename RmType, typename T = Traits>
typename std::enable_if<T::Is64Bit, void>::type
assembleAndEmitRex(const Type TyReg, const RegType Reg, const Type TyRm,
const RmType Rm,
const typename T::Address *Addr = nullptr) {
const uint8_t W = (TyReg == IceType_i64 || TyRm == IceType_i64)
? T::Operand::RexW
: T::Operand::RexNone;
const uint8_t R = (Reg & 0x08) ? T::Operand::RexR : T::Operand::RexNone;
const uint8_t X = (Addr != nullptr)
? (typename T::Operand::RexBits)Addr->rexX()
: T::Operand::RexNone;
const uint8_t B =
(Addr != nullptr)
? (typename T::Operand::RexBits)Addr->rexB()
: (Rm & 0x08) ? T::Operand::RexB : T::Operand::RexNone;
const uint8_t Prefix = W | R | X | B;
if (Prefix != T::Operand::RexNone) {
emitUint8(Prefix);
} else if (is8BitRegisterRequiringRex(TyReg, Reg) ||
(Addr == nullptr && is8BitRegisterRequiringRex(TyRm, Rm))) {
emitUint8(T::Operand::RexBase);
}
}
template <typename RegType, typename RmType, typename T = Traits>
typename std::enable_if<!T::Is64Bit, void>::type
assembleAndEmitRex(const Type, const RegType, const Type, const RmType,
const typename T::Address * = nullptr) {}
// emitRexRB is used for emitting a Rex prefix instructions with two
// explicit register operands in its mod-rm byte.
template <typename RegType, typename RmType>
void emitRexRB(const Type Ty, const RegType Reg, const RmType Rm) {
assembleAndEmitRex(Ty, Reg, Ty, Rm);
}
template <typename RegType, typename RmType>
void emitRexRB(const Type TyReg, const RegType Reg, const Type TyRm,
const RmType Rm) {
assembleAndEmitRex(TyReg, Reg, TyRm, Rm);
}
// emitRexB is used for emitting a Rex prefix if one is needed on encoding
// the Reg field in an x86 instruction. It is invoked by the template when
// Reg is the single register operand in the instruction (e.g., push Reg.)
template <typename RmType> void emitRexB(const Type Ty, const RmType Rm) {
emitRexRB(Ty, RexRegIrrelevant, Ty, Rm);
}
// emitRex is used for emitting a Rex prefix for an address and a GPR. The
// address may contain zero, one, or two registers.
template <typename RegType>
void emitRex(const Type Ty, const Address &Addr, const RegType Reg) {
assembleAndEmitRex(Ty, Reg, Ty, RexRegIrrelevant, &Addr);
}
template <typename RegType>
void emitRex(const Type AddrTy, const Address &Addr, const Type TyReg,
const RegType Reg) {
assembleAndEmitRex(TyReg, Reg, AddrTy, RexRegIrrelevant, &Addr);
}
};
template <typename TraitsType>
inline void AssemblerX86Base<TraitsType>::emitUint8(uint8_t value) {
Buffer.emit<uint8_t>(value);
}
template <typename TraitsType>
inline void AssemblerX86Base<TraitsType>::emitInt16(int16_t value) {
Buffer.emit<int16_t>(value);
}
template <typename TraitsType>
inline void AssemblerX86Base<TraitsType>::emitInt32(int32_t value) {
Buffer.emit<int32_t>(value);
}
template <typename TraitsType>
inline void AssemblerX86Base<TraitsType>::emitRegisterOperand(int reg, int rm) {
assert(reg >= 0 && reg < 8);
assert(rm >= 0 && rm < 8);
Buffer.emit<uint8_t>(0xC0 + (reg << 3) + rm);
}
template <typename TraitsType>
template <typename RegType, typename RmType>
inline void AssemblerX86Base<TraitsType>::emitXmmRegisterOperand(RegType reg,
RmType rm) {
emitRegisterOperand(gprEncoding(reg), gprEncoding(rm));
}
template <typename TraitsType>
inline void AssemblerX86Base<TraitsType>::emitOperandSizeOverride() {
emitUint8(0x66);
}
} // end of namespace X86NAMESPACE
} // end of namespace Ice
#include "IceAssemblerX86BaseImpl.h"
#endif // SUBZERO_SRC_ICEASSEMBLERX86BASE_H