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swiftshader / SwiftShader / a5fe17a11eae0bbbbed481ea31806d45606198c9 / . / src / IceInstX8632.cpp
blob: 9bb136df9ef41393e4cbcaa0db8eb7f32d568d5c [file] [log] [blame]
//===- subzero/src/IceInstX8632.cpp - X86-32 instruction implementation ---===//
//
// The Subzero Code Generator
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file implements the InstX8632 and OperandX8632 classes,
// primarily the constructors and the dump()/emit() methods.
//
//===----------------------------------------------------------------------===//
#include "assembler_ia32.h"
#include "IceCfg.h"
#include "IceCfgNode.h"
#include "IceConditionCodesX8632.h"
#include "IceInst.h"
#include "IceInstX8632.h"
#include "IceRegistersX8632.h"
#include "IceTargetLoweringX8632.h"
#include "IceOperand.h"
namespace Ice {
namespace {
const struct InstX8632BrAttributes_ {
CondX86::BrCond Opposite;
const char *DisplayString;
const char *EmitString;
} InstX8632BrAttributes[] = {
#define X(tag, encode, opp, dump, emit) \
{ CondX86::opp, dump, emit } \
,
ICEINSTX8632BR_TABLE
#undef X
};
const struct InstX8632CmppsAttributes_ {
const char *EmitString;
} InstX8632CmppsAttributes[] = {
#define X(tag, emit) \
{ emit } \
,
ICEINSTX8632CMPPS_TABLE
#undef X
};
const struct TypeX8632Attributes_ {
const char *CvtString; // i (integer), s (single FP), d (double FP)
const char *SdSsString; // ss, sd, or <blank>
const char *PackString; // b, w, d, or <blank>
const char *WidthString; // b, w, l, q, or <blank>
const char *FldString; // s, l, or <blank>
} TypeX8632Attributes[] = {
#define X(tag, elementty, cvt, sdss, pack, width, fld) \
{ cvt, sdss, pack, width, fld } \
,
ICETYPEX8632_TABLE
#undef X
};
const char *InstX8632SegmentRegNames[] = {
#define X(val, name, prefix) name,
SEG_REGX8632_TABLE
#undef X
};
uint8_t InstX8632SegmentPrefixes[] = {
#define X(val, name, prefix) prefix,
SEG_REGX8632_TABLE
#undef X
};
} // end of anonymous namespace
const char *InstX8632::getWidthString(Type Ty) {
return TypeX8632Attributes[Ty].WidthString;
}
const char *InstX8632::getFldString(Type Ty) {
return TypeX8632Attributes[Ty].FldString;
}
OperandX8632Mem::OperandX8632Mem(Cfg *Func, Type Ty, Variable *Base,
Constant *Offset, Variable *Index,
uint16_t Shift, SegmentRegisters SegmentReg)
: OperandX8632(kMem, Ty), Base(Base), Offset(Offset), Index(Index),
Shift(Shift), SegmentReg(SegmentReg) {
assert(Shift <= 3);
Vars = nullptr;
NumVars = 0;
if (Base)
++NumVars;
if (Index)
++NumVars;
if (NumVars) {
Vars = Func->allocateArrayOf<Variable *>(NumVars);
SizeT I = 0;
if (Base)
Vars[I++] = Base;
if (Index)
Vars[I++] = Index;
assert(I == NumVars);
}
}
InstX8632AdjustStack::InstX8632AdjustStack(Cfg *Func, SizeT Amount,
Variable *Esp)
: InstX8632(Func, InstX8632::Adjuststack, 1, Esp), Amount(Amount) {
addSource(Esp);
}
InstX8632Mul::InstX8632Mul(Cfg *Func, Variable *Dest, Variable *Source1,
Operand *Source2)
: InstX8632(Func, InstX8632::Mul, 2, Dest) {
addSource(Source1);
addSource(Source2);
}
InstX8632Shld::InstX8632Shld(Cfg *Func, Variable *Dest, Variable *Source1,
Variable *Source2)
: InstX8632(Func, InstX8632::Shld, 3, Dest) {
addSource(Dest);
addSource(Source1);
addSource(Source2);
}
InstX8632Shrd::InstX8632Shrd(Cfg *Func, Variable *Dest, Variable *Source1,
Variable *Source2)
: InstX8632(Func, InstX8632::Shrd, 3, Dest) {
addSource(Dest);
addSource(Source1);
addSource(Source2);
}
InstX8632Label::InstX8632Label(Cfg *Func, TargetX8632 *Target)
: InstX8632(Func, InstX8632::Label, 0, nullptr),
Number(Target->makeNextLabelNumber()) {}
IceString InstX8632Label::getName(const Cfg *Func) const {
return ".L" + Func->getFunctionName() + "$local$__" + std::to_string(Number);
}
InstX8632Br::InstX8632Br(Cfg *Func, const CfgNode *TargetTrue,
const CfgNode *TargetFalse,
const InstX8632Label *Label, CondX86::BrCond Condition)
: InstX8632(Func, InstX8632::Br, 0, nullptr), Condition(Condition),
TargetTrue(TargetTrue), TargetFalse(TargetFalse), Label(Label) {}
bool InstX8632Br::optimizeBranch(const CfgNode *NextNode) {
// If there is no next block, then there can be no fallthrough to
// optimize.
if (NextNode == nullptr)
return false;
// Intra-block conditional branches can't be optimized.
if (Label)
return false;
// If there is no fallthrough node, such as a non-default case label
// for a switch instruction, then there is no opportunity to
// optimize.
if (getTargetFalse() == nullptr)
return false;
// Unconditional branch to the next node can be removed.
if (Condition == CondX86::Br_None && getTargetFalse() == NextNode) {
assert(getTargetTrue() == nullptr);
setDeleted();
return true;
}
// If the fallthrough is to the next node, set fallthrough to nullptr
// to indicate.
if (getTargetFalse() == NextNode) {
TargetFalse = nullptr;
return true;
}
// If TargetTrue is the next node, and TargetFalse is not nullptr
// (which was already tested above), then invert the branch
// condition, swap the targets, and set new fallthrough to nullptr.
if (getTargetTrue() == NextNode) {
assert(Condition != CondX86::Br_None);
Condition = InstX8632BrAttributes[Condition].Opposite;
TargetTrue = getTargetFalse();
TargetFalse = nullptr;
return true;
}
return false;
}
bool InstX8632Br::repointEdge(CfgNode *OldNode, CfgNode *NewNode) {
if (TargetFalse == OldNode) {
TargetFalse = NewNode;
return true;
} else if (TargetTrue == OldNode) {
TargetTrue = NewNode;
return true;
}
return false;
}
InstX8632Call::InstX8632Call(Cfg *Func, Variable *Dest, Operand *CallTarget)
: InstX8632(Func, InstX8632::Call, 1, Dest) {
HasSideEffects = true;
addSource(CallTarget);
}
InstX8632Cmov::InstX8632Cmov(Cfg *Func, Variable *Dest, Operand *Source,
CondX86::BrCond Condition)
: InstX8632(Func, InstX8632::Cmov, 2, Dest), Condition(Condition) {
// The final result is either the original Dest, or Source, so mark
// both as sources.
addSource(Dest);
addSource(Source);
}
InstX8632Cmpps::InstX8632Cmpps(Cfg *Func, Variable *Dest, Operand *Source,
CondX86::CmppsCond Condition)
: InstX8632(Func, InstX8632::Cmpps, 2, Dest), Condition(Condition) {
addSource(Dest);
addSource(Source);
}
InstX8632Cmpxchg::InstX8632Cmpxchg(Cfg *Func, Operand *DestOrAddr,
Variable *Eax, Variable *Desired,
bool Locked)
: InstX8632Lockable(Func, InstX8632::Cmpxchg, 3,
llvm::dyn_cast<Variable>(DestOrAddr), Locked) {
assert(Eax->getRegNum() == RegX8632::Reg_eax);
addSource(DestOrAddr);
addSource(Eax);
addSource(Desired);
}
InstX8632Cmpxchg8b::InstX8632Cmpxchg8b(Cfg *Func, OperandX8632Mem *Addr,
Variable *Edx, Variable *Eax,
Variable *Ecx, Variable *Ebx,
bool Locked)
: InstX8632Lockable(Func, InstX8632::Cmpxchg, 5, nullptr, Locked) {
assert(Edx->getRegNum() == RegX8632::Reg_edx);
assert(Eax->getRegNum() == RegX8632::Reg_eax);
assert(Ecx->getRegNum() == RegX8632::Reg_ecx);
assert(Ebx->getRegNum() == RegX8632::Reg_ebx);
addSource(Addr);
addSource(Edx);
addSource(Eax);
addSource(Ecx);
addSource(Ebx);
}
InstX8632Cvt::InstX8632Cvt(Cfg *Func, Variable *Dest, Operand *Source,
CvtVariant Variant)
: InstX8632(Func, InstX8632::Cvt, 1, Dest), Variant(Variant) {
addSource(Source);
}
InstX8632Icmp::InstX8632Icmp(Cfg *Func, Operand *Src0, Operand *Src1)
: InstX8632(Func, InstX8632::Icmp, 2, nullptr) {
addSource(Src0);
addSource(Src1);
}
InstX8632Ucomiss::InstX8632Ucomiss(Cfg *Func, Operand *Src0, Operand *Src1)
: InstX8632(Func, InstX8632::Ucomiss, 2, nullptr) {
addSource(Src0);
addSource(Src1);
}
InstX8632UD2::InstX8632UD2(Cfg *Func)
: InstX8632(Func, InstX8632::UD2, 0, nullptr) {}
InstX8632Test::InstX8632Test(Cfg *Func, Operand *Src1, Operand *Src2)
: InstX8632(Func, InstX8632::Test, 2, nullptr) {
addSource(Src1);
addSource(Src2);
}
InstX8632Mfence::InstX8632Mfence(Cfg *Func)
: InstX8632(Func, InstX8632::Mfence, 0, nullptr) {
HasSideEffects = true;
}
InstX8632Store::InstX8632Store(Cfg *Func, Operand *Value, OperandX8632 *Mem)
: InstX8632(Func, InstX8632::Store, 2, nullptr) {
addSource(Value);
addSource(Mem);
}
InstX8632StoreP::InstX8632StoreP(Cfg *Func, Variable *Value,
OperandX8632Mem *Mem)
: InstX8632(Func, InstX8632::StoreP, 2, nullptr) {
addSource(Value);
addSource(Mem);
}
InstX8632StoreQ::InstX8632StoreQ(Cfg *Func, Variable *Value,
OperandX8632Mem *Mem)
: InstX8632(Func, InstX8632::StoreQ, 2, nullptr) {
addSource(Value);
addSource(Mem);
}
InstX8632Nop::InstX8632Nop(Cfg *Func, InstX8632Nop::NopVariant Variant)
: InstX8632(Func, InstX8632::Nop, 0, nullptr), Variant(Variant) {}
InstX8632Fld::InstX8632Fld(Cfg *Func, Operand *Src)
: InstX8632(Func, InstX8632::Fld, 1, nullptr) {
addSource(Src);
}
InstX8632Fstp::InstX8632Fstp(Cfg *Func, Variable *Dest)
: InstX8632(Func, InstX8632::Fstp, 0, Dest) {}
InstX8632Pop::InstX8632Pop(Cfg *Func, Variable *Dest)
: InstX8632(Func, InstX8632::Pop, 0, Dest) {}
InstX8632Push::InstX8632Push(Cfg *Func, Variable *Source)
: InstX8632(Func, InstX8632::Push, 1, nullptr) {
addSource(Source);
}
InstX8632Ret::InstX8632Ret(Cfg *Func, Variable *Source)
: InstX8632(Func, InstX8632::Ret, Source ? 1 : 0, nullptr) {
if (Source)
addSource(Source);
}
InstX8632Xadd::InstX8632Xadd(Cfg *Func, Operand *Dest, Variable *Source,
bool Locked)
: InstX8632Lockable(Func, InstX8632::Xadd, 2,
llvm::dyn_cast<Variable>(Dest), Locked) {
addSource(Dest);
addSource(Source);
}
InstX8632Xchg::InstX8632Xchg(Cfg *Func, Operand *Dest, Variable *Source)
: InstX8632(Func, InstX8632::Xchg, 2, llvm::dyn_cast<Variable>(Dest)) {
addSource(Dest);
addSource(Source);
}
// ======================== Dump routines ======================== //
void InstX8632::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << "[X8632] ";
Inst::dump(Func);
}
void InstX8632Label::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
Str << getName(Func) << ":";
}
void InstX8632Label::emitIAS(const Cfg *Func) const {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
Asm->BindLocalLabel(Number);
}
void InstX8632Label::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << getName(Func) << ":";
}
void InstX8632Br::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
Str << "\t";
if (Condition == CondX86::Br_None) {
Str << "jmp";
} else {
Str << InstX8632BrAttributes[Condition].EmitString;
}
if (Label) {
Str << "\t" << Label->getName(Func);
} else {
if (Condition == CondX86::Br_None) {
Str << "\t" << getTargetFalse()->getAsmName();
} else {
Str << "\t" << getTargetTrue()->getAsmName();
if (getTargetFalse()) {
Str << "\n\tjmp\t" << getTargetFalse()->getAsmName();
}
}
}
}
void InstX8632Br::emitIAS(const Cfg *Func) const {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
if (Label) {
x86::Label *L = Asm->GetOrCreateLocalLabel(Label->getNumber());
// In all these cases, local Labels should only be used for Near.
const bool Near = true;
if (Condition == CondX86::Br_None) {
Asm->jmp(L, Near);
} else {
Asm->j(Condition, L, Near);
}
} else {
// Pessimistically assume it's far. This only affects Labels that
// are not Bound.
const bool Near = false;
if (Condition == CondX86::Br_None) {
x86::Label *L =
Asm->GetOrCreateCfgNodeLabel(getTargetFalse()->getIndex());
assert(!getTargetTrue());
Asm->jmp(L, Near);
} else {
x86::Label *L = Asm->GetOrCreateCfgNodeLabel(getTargetTrue()->getIndex());
Asm->j(Condition, L, Near);
if (getTargetFalse()) {
x86::Label *L2 =
Asm->GetOrCreateCfgNodeLabel(getTargetFalse()->getIndex());
Asm->jmp(L2, Near);
}
}
}
}
void InstX8632Br::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << "br ";
if (Condition == CondX86::Br_None) {
Str << "label %"
<< (Label ? Label->getName(Func) : getTargetFalse()->getName());
return;
}
Str << InstX8632BrAttributes[Condition].DisplayString;
if (Label) {
Str << ", label %" << Label->getName(Func);
} else {
Str << ", label %" << getTargetTrue()->getName();
if (getTargetFalse()) {
Str << ", label %" << getTargetFalse()->getName();
}
}
}
void InstX8632Call::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 1);
Str << "\tcall\t";
if (const auto CallTarget =
llvm::dyn_cast<ConstantRelocatable>(getCallTarget())) {
// TODO(stichnot): All constant targets should suppress the '$',
// not just relocatables.
CallTarget->emitWithoutDollar(Func->getContext());
} else {
Str << "*";
getCallTarget()->emit(Func);
}
Func->getTarget()->resetStackAdjustment();
}
void InstX8632Call::emitIAS(const Cfg *Func) const {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
Operand *Target = getCallTarget();
if (const auto Var = llvm::dyn_cast<Variable>(Target)) {
if (Var->hasReg()) {
Asm->call(RegX8632::getEncodedGPR(Var->getRegNum()));
} else {
Asm->call(static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(Var));
}
} else if (const auto Mem = llvm::dyn_cast<OperandX8632Mem>(Target)) {
assert(Mem->getSegmentRegister() == OperandX8632Mem::DefaultSegment);
Asm->call(Mem->toAsmAddress(Asm));
} else if (const auto CR = llvm::dyn_cast<ConstantRelocatable>(Target)) {
assert(CR->getOffset() == 0 && "We only support calling a function");
Asm->call(CR);
} else if (const auto Imm = llvm::dyn_cast<ConstantInteger32>(Target)) {
// NaCl trampoline calls refer to an address within the sandbox directly.
// This is usually only needed for non-IRT builds and otherwise not
// very portable or stable. For this, we would use the 0xE8 opcode
// (relative version of call) and there should be a PC32 reloc too.
// The PC32 reloc will have symbol index 0, and the absolute address
// would be encoded as an offset relative to the next instruction.
// TODO(jvoung): Do we need to support this?
(void)Imm;
llvm_unreachable("Unexpected call to absolute address");
} else {
llvm_unreachable("Unexpected operand type");
}
Func->getTarget()->resetStackAdjustment();
}
void InstX8632Call::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
if (getDest()) {
dumpDest(Func);
Str << " = ";
}
Str << "call ";
getCallTarget()->dump(Func);
}
// The ShiftHack parameter is used to emit "cl" instead of "ecx" for
// shift instructions, in order to be syntactically valid. The
// Opcode parameter needs to be char* and not IceString because of
// template issues.
void emitTwoAddress(const char *Opcode, const Inst *Inst, const Cfg *Func,
bool ShiftHack) {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(Inst->getSrcSize() == 2);
Variable *Dest = Inst->getDest();
assert(Dest == Inst->getSrc(0));
Operand *Src1 = Inst->getSrc(1);
Str << "\t" << Opcode << InstX8632::getWidthString(Dest->getType()) << "\t";
const auto ShiftReg = llvm::dyn_cast<Variable>(Src1);
if (ShiftHack && ShiftReg && ShiftReg->getRegNum() == RegX8632::Reg_ecx)
Str << "%cl";
else
Src1->emit(Func);
Str << ", ";
Dest->emit(Func);
}
void emitIASOpTyGPR(const Cfg *Func, Type Ty, const Operand *Op,
const x86::AssemblerX86::GPREmitterOneOp &Emitter) {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
if (const auto Var = llvm::dyn_cast<Variable>(Op)) {
if (Var->hasReg()) {
// We cheat a little and use GPRRegister even for byte operations.
RegX8632::GPRRegister VarReg =
RegX8632::getEncodedByteRegOrGPR(Ty, Var->getRegNum());
(Asm->*(Emitter.Reg))(Ty, VarReg);
} else {
x86::Address StackAddr(static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(Var));
(Asm->*(Emitter.Addr))(Ty, StackAddr);
}
} else if (const auto Mem = llvm::dyn_cast<OperandX8632Mem>(Op)) {
Mem->emitSegmentOverride(Asm);
(Asm->*(Emitter.Addr))(Ty, Mem->toAsmAddress(Asm));
} else {
llvm_unreachable("Unexpected operand type");
}
}
template <bool VarCanBeByte, bool SrcCanBeByte>
void emitIASRegOpTyGPR(const Cfg *Func, Type Ty, const Variable *Var,
const Operand *Src,
const x86::AssemblerX86::GPREmitterRegOp &Emitter) {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
assert(Var->hasReg());
// We cheat a little and use GPRRegister even for byte operations.
RegX8632::GPRRegister VarReg =
VarCanBeByte ? RegX8632::getEncodedByteRegOrGPR(Ty, Var->getRegNum())
: RegX8632::getEncodedGPR(Var->getRegNum());
if (const auto SrcVar = llvm::dyn_cast<Variable>(Src)) {
if (SrcVar->hasReg()) {
RegX8632::GPRRegister SrcReg =
SrcCanBeByte
? RegX8632::getEncodedByteRegOrGPR(Ty, SrcVar->getRegNum())
: RegX8632::getEncodedGPR(SrcVar->getRegNum());
(Asm->*(Emitter.GPRGPR))(Ty, VarReg, SrcReg);
} else {
x86::Address SrcStackAddr = static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(SrcVar);
(Asm->*(Emitter.GPRAddr))(Ty, VarReg, SrcStackAddr);
}
} else if (const auto Mem = llvm::dyn_cast<OperandX8632Mem>(Src)) {
Mem->emitSegmentOverride(Asm);
(Asm->*(Emitter.GPRAddr))(Ty, VarReg, Mem->toAsmAddress(Asm));
} else if (const auto Imm = llvm::dyn_cast<ConstantInteger32>(Src)) {
(Asm->*(Emitter.GPRImm))(Ty, VarReg, x86::Immediate(Imm->getValue()));
} else if (const auto Reloc = llvm::dyn_cast<ConstantRelocatable>(Src)) {
AssemblerFixup *Fixup = Asm->createFixup(llvm::ELF::R_386_32, Reloc);
(Asm->*(Emitter.GPRImm))(Ty, VarReg,
x86::Immediate(Reloc->getOffset(), Fixup));
} else if (const auto Split = llvm::dyn_cast<VariableSplit>(Src)) {
(Asm->*(Emitter.GPRAddr))(Ty, VarReg, Split->toAsmAddress(Func));
} else {
llvm_unreachable("Unexpected operand type");
}
}
void emitIASAddrOpTyGPR(const Cfg *Func, Type Ty, const x86::Address &Addr,
const Operand *Src,
const x86::AssemblerX86::GPREmitterAddrOp &Emitter) {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
// Src can only be Reg or Immediate.
if (const auto SrcVar = llvm::dyn_cast<Variable>(Src)) {
assert(SrcVar->hasReg());
RegX8632::GPRRegister SrcReg =
RegX8632::getEncodedByteRegOrGPR(Ty, SrcVar->getRegNum());
(Asm->*(Emitter.AddrGPR))(Ty, Addr, SrcReg);
} else if (const auto Imm = llvm::dyn_cast<ConstantInteger32>(Src)) {
(Asm->*(Emitter.AddrImm))(Ty, Addr, x86::Immediate(Imm->getValue()));
} else if (const auto Reloc = llvm::dyn_cast<ConstantRelocatable>(Src)) {
AssemblerFixup *Fixup = Asm->createFixup(llvm::ELF::R_386_32, Reloc);
(Asm->*(Emitter.AddrImm))(Ty, Addr,
x86::Immediate(Reloc->getOffset(), Fixup));
} else {
llvm_unreachable("Unexpected operand type");
}
}
void emitIASAsAddrOpTyGPR(const Cfg *Func, Type Ty, const Operand *Op0,
const Operand *Op1,
const x86::AssemblerX86::GPREmitterAddrOp &Emitter) {
if (const auto Op0Var = llvm::dyn_cast<Variable>(Op0)) {
assert(!Op0Var->hasReg());
x86::Address StackAddr(static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(Op0Var));
emitIASAddrOpTyGPR(Func, Ty, StackAddr, Op1, Emitter);
} else if (const auto Op0Mem = llvm::dyn_cast<OperandX8632Mem>(Op0)) {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
Op0Mem->emitSegmentOverride(Asm);
emitIASAddrOpTyGPR(Func, Ty, Op0Mem->toAsmAddress(Asm), Op1, Emitter);
} else if (const auto Split = llvm::dyn_cast<VariableSplit>(Op0)) {
emitIASAddrOpTyGPR(Func, Ty, Split->toAsmAddress(Func), Op1, Emitter);
} else {
llvm_unreachable("Unexpected operand type");
}
}
void emitIASGPRShift(const Cfg *Func, Type Ty, const Variable *Var,
const Operand *Src,
const x86::AssemblerX86::GPREmitterShiftOp &Emitter) {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
// Technically, the Dest Var can be mem as well, but we only use Reg.
// We can extend this to check Dest if we decide to use that form.
assert(Var->hasReg());
// We cheat a little and use GPRRegister even for byte operations.
RegX8632::GPRRegister VarReg =
RegX8632::getEncodedByteRegOrGPR(Ty, Var->getRegNum());
// Src must be reg == ECX or an Imm8.
// This is asserted by the assembler.
if (const auto SrcVar = llvm::dyn_cast<Variable>(Src)) {
assert(SrcVar->hasReg());
RegX8632::GPRRegister SrcReg =
RegX8632::getEncodedByteRegOrGPR(Ty, SrcVar->getRegNum());
(Asm->*(Emitter.GPRGPR))(Ty, VarReg, SrcReg);
} else if (const auto Imm = llvm::dyn_cast<ConstantInteger32>(Src)) {
(Asm->*(Emitter.GPRImm))(Ty, VarReg, x86::Immediate(Imm->getValue()));
} else {
llvm_unreachable("Unexpected operand type");
}
}
void emitIASGPRShiftDouble(const Cfg *Func, const Variable *Dest,
const Operand *Src1Op, const Operand *Src2Op,
const x86::AssemblerX86::GPREmitterShiftD &Emitter) {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
// Dest can be reg or mem, but we only use the reg variant.
assert(Dest->hasReg());
RegX8632::GPRRegister DestReg = RegX8632::getEncodedGPR(Dest->getRegNum());
// SrcVar1 must be reg.
const auto SrcVar1 = llvm::cast<Variable>(Src1Op);
assert(SrcVar1->hasReg());
RegX8632::GPRRegister SrcReg = RegX8632::getEncodedGPR(SrcVar1->getRegNum());
Type Ty = SrcVar1->getType();
// Src2 can be the implicit CL register or an immediate.
if (const auto Imm = llvm::dyn_cast<ConstantInteger32>(Src2Op)) {
(Asm->*(Emitter.GPRGPRImm))(Ty, DestReg, SrcReg,
x86::Immediate(Imm->getValue()));
} else {
assert(llvm::cast<Variable>(Src2Op)->getRegNum() == RegX8632::Reg_ecx);
(Asm->*(Emitter.GPRGPR))(Ty, DestReg, SrcReg);
}
}
void emitIASXmmShift(const Cfg *Func, Type Ty, const Variable *Var,
const Operand *Src,
const x86::AssemblerX86::XmmEmitterShiftOp &Emitter) {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
assert(Var->hasReg());
RegX8632::XmmRegister VarReg = RegX8632::getEncodedXmm(Var->getRegNum());
if (const auto SrcVar = llvm::dyn_cast<Variable>(Src)) {
if (SrcVar->hasReg()) {
RegX8632::XmmRegister SrcReg =
RegX8632::getEncodedXmm(SrcVar->getRegNum());
(Asm->*(Emitter.XmmXmm))(Ty, VarReg, SrcReg);
} else {
x86::Address SrcStackAddr = static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(SrcVar);
(Asm->*(Emitter.XmmAddr))(Ty, VarReg, SrcStackAddr);
}
} else if (const auto Mem = llvm::dyn_cast<OperandX8632Mem>(Src)) {
assert(Mem->getSegmentRegister() == OperandX8632Mem::DefaultSegment);
(Asm->*(Emitter.XmmAddr))(Ty, VarReg, Mem->toAsmAddress(Asm));
} else if (const auto Imm = llvm::dyn_cast<ConstantInteger32>(Src)) {
(Asm->*(Emitter.XmmImm))(Ty, VarReg, x86::Immediate(Imm->getValue()));
} else {
llvm_unreachable("Unexpected operand type");
}
}
void emitIASRegOpTyXMM(const Cfg *Func, Type Ty, const Variable *Var,
const Operand *Src,
const x86::AssemblerX86::XmmEmitterRegOp &Emitter) {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
assert(Var->hasReg());
RegX8632::XmmRegister VarReg = RegX8632::getEncodedXmm(Var->getRegNum());
if (const auto SrcVar = llvm::dyn_cast<Variable>(Src)) {
if (SrcVar->hasReg()) {
RegX8632::XmmRegister SrcReg =
RegX8632::getEncodedXmm(SrcVar->getRegNum());
(Asm->*(Emitter.XmmXmm))(Ty, VarReg, SrcReg);
} else {
x86::Address SrcStackAddr = static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(SrcVar);
(Asm->*(Emitter.XmmAddr))(Ty, VarReg, SrcStackAddr);
}
} else if (const auto Mem = llvm::dyn_cast<OperandX8632Mem>(Src)) {
assert(Mem->getSegmentRegister() == OperandX8632Mem::DefaultSegment);
(Asm->*(Emitter.XmmAddr))(Ty, VarReg, Mem->toAsmAddress(Asm));
} else if (const auto Imm = llvm::dyn_cast<Constant>(Src)) {
(Asm->*(Emitter.XmmAddr))(Ty, VarReg, x86::Address::ofConstPool(Asm, Imm));
} else {
llvm_unreachable("Unexpected operand type");
}
}
template <typename DReg_t, typename SReg_t, DReg_t (*destEnc)(int32_t),
SReg_t (*srcEnc)(int32_t)>
void emitIASCastRegOp(
const Cfg *Func, Type DispatchTy, const Variable *Dest, const Operand *Src,
const x86::AssemblerX86::CastEmitterRegOp<DReg_t, SReg_t> Emitter) {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
assert(Dest->hasReg());
DReg_t DestReg = destEnc(Dest->getRegNum());
if (const auto SrcVar = llvm::dyn_cast<Variable>(Src)) {
if (SrcVar->hasReg()) {
SReg_t SrcReg = srcEnc(SrcVar->getRegNum());
(Asm->*(Emitter.RegReg))(DispatchTy, DestReg, SrcReg);
} else {
x86::Address SrcStackAddr = static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(SrcVar);
(Asm->*(Emitter.RegAddr))(DispatchTy, DestReg, SrcStackAddr);
}
} else if (const auto Mem = llvm::dyn_cast<OperandX8632Mem>(Src)) {
Mem->emitSegmentOverride(Asm);
(Asm->*(Emitter.RegAddr))(DispatchTy, DestReg, Mem->toAsmAddress(Asm));
} else {
llvm_unreachable("Unexpected operand type");
}
}
template <typename DReg_t, typename SReg_t, DReg_t (*destEnc)(int32_t),
SReg_t (*srcEnc)(int32_t)>
void emitIASThreeOpImmOps(
const Cfg *Func, Type DispatchTy, const Variable *Dest, const Operand *Src0,
const Operand *Src1,
const x86::AssemblerX86::ThreeOpImmEmitter<DReg_t, SReg_t> Emitter) {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
// This only handles Dest being a register, and Src1 being an immediate.
assert(Dest->hasReg());
DReg_t DestReg = destEnc(Dest->getRegNum());
x86::Immediate Imm(llvm::cast<ConstantInteger32>(Src1)->getValue());
if (const auto SrcVar = llvm::dyn_cast<Variable>(Src0)) {
if (SrcVar->hasReg()) {
SReg_t SrcReg = srcEnc(SrcVar->getRegNum());
(Asm->*(Emitter.RegRegImm))(DispatchTy, DestReg, SrcReg, Imm);
} else {
x86::Address SrcStackAddr = static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(SrcVar);
(Asm->*(Emitter.RegAddrImm))(DispatchTy, DestReg, SrcStackAddr, Imm);
}
} else if (const auto Mem = llvm::dyn_cast<OperandX8632Mem>(Src0)) {
Mem->emitSegmentOverride(Asm);
(Asm->*(Emitter.RegAddrImm))(DispatchTy, DestReg, Mem->toAsmAddress(Asm),
Imm);
} else {
llvm_unreachable("Unexpected operand type");
}
}
void emitIASMovlikeXMM(const Cfg *Func, const Variable *Dest,
const Operand *Src,
const x86::AssemblerX86::XmmEmitterMovOps Emitter) {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
if (Dest->hasReg()) {
RegX8632::XmmRegister DestReg = RegX8632::getEncodedXmm(Dest->getRegNum());
if (const auto SrcVar = llvm::dyn_cast<Variable>(Src)) {
if (SrcVar->hasReg()) {
(Asm->*(Emitter.XmmXmm))(DestReg,
RegX8632::getEncodedXmm(SrcVar->getRegNum()));
} else {
x86::Address StackAddr(static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(SrcVar));
(Asm->*(Emitter.XmmAddr))(DestReg, StackAddr);
}
} else if (const auto SrcMem = llvm::dyn_cast<OperandX8632Mem>(Src)) {
assert(SrcMem->getSegmentRegister() == OperandX8632Mem::DefaultSegment);
(Asm->*(Emitter.XmmAddr))(DestReg, SrcMem->toAsmAddress(Asm));
} else {
llvm_unreachable("Unexpected operand type");
}
} else {
x86::Address StackAddr(static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(Dest));
// Src must be a register in this case.
const auto SrcVar = llvm::cast<Variable>(Src);
assert(SrcVar->hasReg());
(Asm->*(Emitter.AddrXmm))(StackAddr,
RegX8632::getEncodedXmm(SrcVar->getRegNum()));
}
}
bool checkForRedundantAssign(const Variable *Dest, const Operand *Source) {
const auto SrcVar = llvm::dyn_cast<const Variable>(Source);
if (!SrcVar)
return false;
if (Dest->hasReg() && Dest->getRegNum() == SrcVar->getRegNum()) {
// TODO: On x86-64, instructions like "mov eax, eax" are used to
// clear the upper 32 bits of rax. We need to recognize and
// preserve these.
return true;
}
if (!Dest->hasReg() && !SrcVar->hasReg() &&
Dest->getStackOffset() == SrcVar->getStackOffset())
return true;
return false;
}
// In-place ops
template <> const char *InstX8632Bswap::Opcode = "bswap";
template <> const char *InstX8632Neg::Opcode = "neg";
// Unary ops
template <> const char *InstX8632Bsf::Opcode = "bsf";
template <> const char *InstX8632Bsr::Opcode = "bsr";
template <> const char *InstX8632Lea::Opcode = "lea";
template <> const char *InstX8632Movd::Opcode = "movd";
template <> const char *InstX8632Movsx::Opcode = "movs";
template <> const char *InstX8632Movzx::Opcode = "movz";
template <> const char *InstX8632Sqrtss::Opcode = "sqrtss";
template <> const char *InstX8632Cbwdq::Opcode = "cbw/cwd/cdq";
// Mov-like ops
template <> const char *InstX8632Mov::Opcode = "mov";
template <> const char *InstX8632Movp::Opcode = "movups";
template <> const char *InstX8632Movq::Opcode = "movq";
// Binary ops
template <> const char *InstX8632Add::Opcode = "add";
template <> const char *InstX8632Addps::Opcode = "addps";
template <> const char *InstX8632Adc::Opcode = "adc";
template <> const char *InstX8632Addss::Opcode = "addss";
template <> const char *InstX8632Padd::Opcode = "padd";
template <> const char *InstX8632Sub::Opcode = "sub";
template <> const char *InstX8632Subps::Opcode = "subps";
template <> const char *InstX8632Subss::Opcode = "subss";
template <> const char *InstX8632Sbb::Opcode = "sbb";
template <> const char *InstX8632Psub::Opcode = "psub";
template <> const char *InstX8632And::Opcode = "and";
template <> const char *InstX8632Pand::Opcode = "pand";
template <> const char *InstX8632Pandn::Opcode = "pandn";
template <> const char *InstX8632Or::Opcode = "or";
template <> const char *InstX8632Por::Opcode = "por";
template <> const char *InstX8632Xor::Opcode = "xor";
template <> const char *InstX8632Pxor::Opcode = "pxor";
template <> const char *InstX8632Imul::Opcode = "imul";
template <> const char *InstX8632Mulps::Opcode = "mulps";
template <> const char *InstX8632Mulss::Opcode = "mulss";
template <> const char *InstX8632Pmull::Opcode = "pmull";
template <> const char *InstX8632Pmuludq::Opcode = "pmuludq";
template <> const char *InstX8632Div::Opcode = "div";
template <> const char *InstX8632Divps::Opcode = "divps";
template <> const char *InstX8632Idiv::Opcode = "idiv";
template <> const char *InstX8632Divss::Opcode = "divss";
template <> const char *InstX8632Rol::Opcode = "rol";
template <> const char *InstX8632Shl::Opcode = "shl";
template <> const char *InstX8632Psll::Opcode = "psll";
template <> const char *InstX8632Shr::Opcode = "shr";
template <> const char *InstX8632Sar::Opcode = "sar";
template <> const char *InstX8632Psra::Opcode = "psra";
template <> const char *InstX8632Pcmpeq::Opcode = "pcmpeq";
template <> const char *InstX8632Pcmpgt::Opcode = "pcmpgt";
template <> const char *InstX8632MovssRegs::Opcode = "movss";
// Ternary ops
template <> const char *InstX8632Insertps::Opcode = "insertps";
template <> const char *InstX8632Shufps::Opcode = "shufps";
template <> const char *InstX8632Pinsr::Opcode = "pinsr";
template <> const char *InstX8632Blendvps::Opcode = "blendvps";
template <> const char *InstX8632Pblendvb::Opcode = "pblendvb";
// Three address ops
template <> const char *InstX8632Pextr::Opcode = "pextr";
template <> const char *InstX8632Pshufd::Opcode = "pshufd";
// Inplace GPR ops
template <>
const x86::AssemblerX86::GPREmitterOneOp InstX8632Bswap::Emitter = {
&x86::AssemblerX86::bswap, nullptr /* only a reg form exists */};
template <>
const x86::AssemblerX86::GPREmitterOneOp InstX8632Neg::Emitter = {
&x86::AssemblerX86::neg, &x86::AssemblerX86::neg};
// Unary GPR ops
template <>
const x86::AssemblerX86::GPREmitterRegOp InstX8632Bsf::Emitter = {
&x86::AssemblerX86::bsf, &x86::AssemblerX86::bsf, nullptr};
template <>
const x86::AssemblerX86::GPREmitterRegOp InstX8632Bsr::Emitter = {
&x86::AssemblerX86::bsr, &x86::AssemblerX86::bsr, nullptr};
template <>
const x86::AssemblerX86::GPREmitterRegOp InstX8632Lea::Emitter = {
/* reg/reg and reg/imm are illegal */ nullptr, &x86::AssemblerX86::lea,
nullptr};
template <>
const x86::AssemblerX86::GPREmitterRegOp InstX8632Movsx::Emitter = {
&x86::AssemblerX86::movsx, &x86::AssemblerX86::movsx, nullptr};
template <>
const x86::AssemblerX86::GPREmitterRegOp InstX8632Movzx::Emitter = {
&x86::AssemblerX86::movzx, &x86::AssemblerX86::movzx, nullptr};
// Unary XMM ops
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Sqrtss::Emitter = {
&x86::AssemblerX86::sqrtss, &x86::AssemblerX86::sqrtss
};
// Binary GPR ops
template <>
const x86::AssemblerX86::GPREmitterRegOp InstX8632Add::Emitter = {
&x86::AssemblerX86::add, &x86::AssemblerX86::add, &x86::AssemblerX86::add};
template <>
const x86::AssemblerX86::GPREmitterRegOp InstX8632Adc::Emitter = {
&x86::AssemblerX86::adc, &x86::AssemblerX86::adc, &x86::AssemblerX86::adc};
template <>
const x86::AssemblerX86::GPREmitterRegOp InstX8632And::Emitter = {
&x86::AssemblerX86::And, &x86::AssemblerX86::And, &x86::AssemblerX86::And};
template <>
const x86::AssemblerX86::GPREmitterRegOp InstX8632Or::Emitter = {
&x86::AssemblerX86::Or, &x86::AssemblerX86::Or, &x86::AssemblerX86::Or};
template <>
const x86::AssemblerX86::GPREmitterRegOp InstX8632Sbb::Emitter = {
&x86::AssemblerX86::sbb, &x86::AssemblerX86::sbb, &x86::AssemblerX86::sbb};
template <>
const x86::AssemblerX86::GPREmitterRegOp InstX8632Sub::Emitter = {
&x86::AssemblerX86::sub, &x86::AssemblerX86::sub, &x86::AssemblerX86::sub};
template <>
const x86::AssemblerX86::GPREmitterRegOp InstX8632Xor::Emitter = {
&x86::AssemblerX86::Xor, &x86::AssemblerX86::Xor, &x86::AssemblerX86::Xor};
// Binary Shift GPR ops
template <>
const x86::AssemblerX86::GPREmitterShiftOp InstX8632Rol::Emitter = {
&x86::AssemblerX86::rol, &x86::AssemblerX86::rol};
template <>
const x86::AssemblerX86::GPREmitterShiftOp InstX8632Sar::Emitter = {
&x86::AssemblerX86::sar, &x86::AssemblerX86::sar};
template <>
const x86::AssemblerX86::GPREmitterShiftOp InstX8632Shl::Emitter = {
&x86::AssemblerX86::shl, &x86::AssemblerX86::shl};
template <>
const x86::AssemblerX86::GPREmitterShiftOp InstX8632Shr::Emitter = {
&x86::AssemblerX86::shr, &x86::AssemblerX86::shr};
// Binary XMM ops
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Addss::Emitter = {
&x86::AssemblerX86::addss, &x86::AssemblerX86::addss
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Addps::Emitter = {
&x86::AssemblerX86::addps, &x86::AssemblerX86::addps
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Divss::Emitter = {
&x86::AssemblerX86::divss, &x86::AssemblerX86::divss
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Divps::Emitter = {
&x86::AssemblerX86::divps, &x86::AssemblerX86::divps
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Mulss::Emitter = {
&x86::AssemblerX86::mulss, &x86::AssemblerX86::mulss
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Mulps::Emitter = {
&x86::AssemblerX86::mulps, &x86::AssemblerX86::mulps
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Padd::Emitter = {
&x86::AssemblerX86::padd, &x86::AssemblerX86::padd
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Pand::Emitter = {
&x86::AssemblerX86::pand, &x86::AssemblerX86::pand
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Pandn::Emitter = {
&x86::AssemblerX86::pandn, &x86::AssemblerX86::pandn
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Pcmpeq::Emitter = {
&x86::AssemblerX86::pcmpeq, &x86::AssemblerX86::pcmpeq
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Pcmpgt::Emitter = {
&x86::AssemblerX86::pcmpgt, &x86::AssemblerX86::pcmpgt
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Pmull::Emitter = {
&x86::AssemblerX86::pmull, &x86::AssemblerX86::pmull
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Pmuludq::Emitter = {
&x86::AssemblerX86::pmuludq, &x86::AssemblerX86::pmuludq
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Por::Emitter = {
&x86::AssemblerX86::por, &x86::AssemblerX86::por
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Psub::Emitter = {
&x86::AssemblerX86::psub, &x86::AssemblerX86::psub
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Pxor::Emitter = {
&x86::AssemblerX86::pxor, &x86::AssemblerX86::pxor
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Subss::Emitter = {
&x86::AssemblerX86::subss, &x86::AssemblerX86::subss
};
template <>
const x86::AssemblerX86::XmmEmitterRegOp InstX8632Subps::Emitter = {
&x86::AssemblerX86::subps, &x86::AssemblerX86::subps
};
// Binary XMM Shift ops
template <>
const x86::AssemblerX86::XmmEmitterShiftOp InstX8632Psll::Emitter = {
&x86::AssemblerX86::psll, &x86::AssemblerX86::psll,
&x86::AssemblerX86::psll};
template <>
const x86::AssemblerX86::XmmEmitterShiftOp InstX8632Psra::Emitter = {
&x86::AssemblerX86::psra, &x86::AssemblerX86::psra,
&x86::AssemblerX86::psra};
template <> void InstX8632Sqrtss::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 1);
Type Ty = getSrc(0)->getType();
assert(isScalarFloatingType(Ty));
Str << "\tsqrt" << TypeX8632Attributes[Ty].SdSsString << "\t";
getSrc(0)->emit(Func);
Str << ", ";
getDest()->emit(Func);
}
template <> void InstX8632Addss::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
char buf[30];
snprintf(buf, llvm::array_lengthof(buf), "add%s",
TypeX8632Attributes[getDest()->getType()].SdSsString);
emitTwoAddress(buf, this, Func);
}
template <> void InstX8632Padd::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
char buf[30];
snprintf(buf, llvm::array_lengthof(buf), "padd%s",
TypeX8632Attributes[getDest()->getType()].PackString);
emitTwoAddress(buf, this, Func);
}
template <> void InstX8632Pmull::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
char buf[30];
bool TypesAreValid = getDest()->getType() == IceType_v4i32 ||
getDest()->getType() == IceType_v8i16;
bool InstructionSetIsValid =
getDest()->getType() == IceType_v8i16 ||
static_cast<TargetX8632 *>(Func->getTarget())->getInstructionSet() >=
TargetX8632::SSE4_1;
(void)TypesAreValid;
(void)InstructionSetIsValid;
assert(TypesAreValid);
assert(InstructionSetIsValid);
snprintf(buf, llvm::array_lengthof(buf), "pmull%s",
TypeX8632Attributes[getDest()->getType()].PackString);
emitTwoAddress(buf, this, Func);
}
template <> void InstX8632Pmull::emitIAS(const Cfg *Func) const {
Type Ty = getDest()->getType();
bool TypesAreValid = Ty == IceType_v4i32 || Ty == IceType_v8i16;
bool InstructionSetIsValid =
Ty == IceType_v8i16 ||
static_cast<TargetX8632 *>(Func->getTarget())->getInstructionSet() >=
TargetX8632::SSE4_1;
(void)TypesAreValid;
(void)InstructionSetIsValid;
assert(TypesAreValid);
assert(InstructionSetIsValid);
assert(getSrcSize() == 2);
Type ElementTy = typeElementType(Ty);
emitIASRegOpTyXMM(Func, ElementTy, getDest(), getSrc(1), Emitter);
}
template <> void InstX8632Subss::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
char buf[30];
snprintf(buf, llvm::array_lengthof(buf), "sub%s",
TypeX8632Attributes[getDest()->getType()].SdSsString);
emitTwoAddress(buf, this, Func);
}
template <> void InstX8632Psub::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
char buf[30];
snprintf(buf, llvm::array_lengthof(buf), "psub%s",
TypeX8632Attributes[getDest()->getType()].PackString);
emitTwoAddress(buf, this, Func);
}
template <> void InstX8632Mulss::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
char buf[30];
snprintf(buf, llvm::array_lengthof(buf), "mul%s",
TypeX8632Attributes[getDest()->getType()].SdSsString);
emitTwoAddress(buf, this, Func);
}
template <> void InstX8632Pmuludq::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
assert(getSrc(0)->getType() == IceType_v4i32 &&
getSrc(1)->getType() == IceType_v4i32);
emitTwoAddress(Opcode, this, Func);
}
template <> void InstX8632Divss::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
char buf[30];
snprintf(buf, llvm::array_lengthof(buf), "div%s",
TypeX8632Attributes[getDest()->getType()].SdSsString);
emitTwoAddress(buf, this, Func);
}
template <> void InstX8632Div::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 3);
Operand *Src1 = getSrc(1);
Str << "\t" << Opcode << getWidthString(Src1->getType()) << "\t";
Src1->emit(Func);
}
template <> void InstX8632Div::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 3);
const Operand *Src = getSrc(1);
Type Ty = Src->getType();
const static x86::AssemblerX86::GPREmitterOneOp Emitter = {
&x86::AssemblerX86::div, &x86::AssemblerX86::div};
emitIASOpTyGPR(Func, Ty, Src, Emitter);
}
template <> void InstX8632Idiv::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 3);
Operand *Src1 = getSrc(1);
Str << "\t" << Opcode << getWidthString(Src1->getType()) << "\t";
Src1->emit(Func);
}
template <> void InstX8632Idiv::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 3);
const Operand *Src = getSrc(1);
Type Ty = Src->getType();
const static x86::AssemblerX86::GPREmitterOneOp Emitter = {
&x86::AssemblerX86::idiv, &x86::AssemblerX86::idiv};
emitIASOpTyGPR(Func, Ty, Src, Emitter);
}
namespace {
// pblendvb and blendvps take xmm0 as a final implicit argument.
void emitVariableBlendInst(const char *Opcode, const Inst *Inst,
const Cfg *Func) {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(Inst->getSrcSize() == 3);
assert(llvm::cast<Variable>(Inst->getSrc(2))->getRegNum() ==
RegX8632::Reg_xmm0);
Str << "\t" << Opcode << "\t";
Inst->getSrc(1)->emit(Func);
Str << ", ";
Inst->getDest()->emit(Func);
}
void
emitIASVariableBlendInst(const Inst *Inst, const Cfg *Func,
const x86::AssemblerX86::XmmEmitterRegOp &Emitter) {
assert(Inst->getSrcSize() == 3);
assert(llvm::cast<Variable>(Inst->getSrc(2))->getRegNum() ==
RegX8632::Reg_xmm0);
const Variable *Dest = Inst->getDest();
const Operand *Src = Inst->getSrc(1);
emitIASRegOpTyXMM(Func, Dest->getType(), Dest, Src, Emitter);
}
} // end anonymous namespace
template <> void InstX8632Blendvps::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
assert(static_cast<TargetX8632 *>(Func->getTarget())->getInstructionSet() >=
TargetX8632::SSE4_1);
emitVariableBlendInst(Opcode, this, Func);
}
template <> void InstX8632Blendvps::emitIAS(const Cfg *Func) const {
assert(static_cast<TargetX8632 *>(Func->getTarget())->getInstructionSet() >=
TargetX8632::SSE4_1);
static const x86::AssemblerX86::XmmEmitterRegOp Emitter = {
&x86::AssemblerX86::blendvps, &x86::AssemblerX86::blendvps};
emitIASVariableBlendInst(this, Func, Emitter);
}
template <> void InstX8632Pblendvb::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
assert(static_cast<TargetX8632 *>(Func->getTarget())->getInstructionSet() >=
TargetX8632::SSE4_1);
emitVariableBlendInst(Opcode, this, Func);
}
template <> void InstX8632Pblendvb::emitIAS(const Cfg *Func) const {
assert(static_cast<TargetX8632 *>(Func->getTarget())->getInstructionSet() >=
TargetX8632::SSE4_1);
static const x86::AssemblerX86::XmmEmitterRegOp Emitter = {
&x86::AssemblerX86::pblendvb, &x86::AssemblerX86::pblendvb};
emitIASVariableBlendInst(this, Func, Emitter);
}
template <> void InstX8632Imul::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 2);
Variable *Dest = getDest();
if (isByteSizedArithType(Dest->getType())) {
// The 8-bit version of imul only allows the form "imul r/m8".
const auto Src0Var = llvm::dyn_cast<Variable>(getSrc(0));
(void)Src0Var;
assert(Src0Var && Src0Var->getRegNum() == RegX8632::Reg_eax);
Str << "\timulb\t";
getSrc(1)->emit(Func);
} else if (llvm::isa<Constant>(getSrc(1))) {
Str << "\timul" << getWidthString(Dest->getType()) << "\t";
getSrc(1)->emit(Func);
Str << ", ";
getSrc(0)->emit(Func);
Str << ", ";
Dest->emit(Func);
} else {
emitTwoAddress("imul", this, Func);
}
}
template <> void InstX8632Imul::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 2);
const Variable *Var = getDest();
Type Ty = Var->getType();
const Operand *Src = getSrc(1);
if (isByteSizedArithType(Ty)) {
// The 8-bit version of imul only allows the form "imul r/m8".
const auto Src0Var = llvm::dyn_cast<Variable>(getSrc(0));
(void)Src0Var;
assert(Src0Var && Src0Var->getRegNum() == RegX8632::Reg_eax);
const x86::AssemblerX86::GPREmitterOneOp Emitter = {
&x86::AssemblerX86::imul, &x86::AssemblerX86::imul};
emitIASOpTyGPR(Func, Ty, getSrc(1), Emitter);
} else {
// We only use imul as a two-address instruction even though
// there is a 3 operand version when one of the operands is a constant.
assert(Var == getSrc(0));
const x86::AssemblerX86::GPREmitterRegOp Emitter = {
&x86::AssemblerX86::imul, &x86::AssemblerX86::imul,
&x86::AssemblerX86::imul};
emitIASRegOpTyGPR(Func, Ty, Var, Src, Emitter);
}
}
template <> void InstX8632Insertps::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 3);
assert(static_cast<TargetX8632 *>(Func->getTarget())->getInstructionSet() >=
TargetX8632::SSE4_1);
const Variable *Dest = getDest();
assert(Dest == getSrc(0));
Type Ty = Dest->getType();
static const x86::AssemblerX86::ThreeOpImmEmitter<
RegX8632::XmmRegister, RegX8632::XmmRegister> Emitter = {
&x86::AssemblerX86::insertps, &x86::AssemblerX86::insertps};
emitIASThreeOpImmOps<RegX8632::XmmRegister, RegX8632::XmmRegister,
RegX8632::getEncodedXmm, RegX8632::getEncodedXmm>(
Func, Ty, Dest, getSrc(1), getSrc(2), Emitter);
}
template <> void InstX8632Cbwdq::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 1);
Operand *Src0 = getSrc(0);
assert(llvm::isa<Variable>(Src0));
assert(llvm::cast<Variable>(Src0)->getRegNum() == RegX8632::Reg_eax);
switch (Src0->getType()) {
default:
llvm_unreachable("unexpected source type!");
break;
case IceType_i8:
assert(getDest()->getRegNum() == RegX8632::Reg_eax);
Str << "\tcbtw";
break;
case IceType_i16:
assert(getDest()->getRegNum() == RegX8632::Reg_edx);
Str << "\tcwtd";
break;
case IceType_i32:
assert(getDest()->getRegNum() == RegX8632::Reg_edx);
Str << "\tcltd";
break;
}
}
template <> void InstX8632Cbwdq::emitIAS(const Cfg *Func) const {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
assert(getSrcSize() == 1);
Operand *Src0 = getSrc(0);
assert(llvm::isa<Variable>(Src0));
assert(llvm::cast<Variable>(Src0)->getRegNum() == RegX8632::Reg_eax);
switch (Src0->getType()) {
default:
llvm_unreachable("unexpected source type!");
break;
case IceType_i8:
assert(getDest()->getRegNum() == RegX8632::Reg_eax);
Asm->cbw();
break;
case IceType_i16:
assert(getDest()->getRegNum() == RegX8632::Reg_edx);
Asm->cwd();
break;
case IceType_i32:
assert(getDest()->getRegNum() == RegX8632::Reg_edx);
Asm->cdq();
break;
}
}
void InstX8632Mul::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 2);
assert(llvm::isa<Variable>(getSrc(0)));
assert(llvm::cast<Variable>(getSrc(0))->getRegNum() == RegX8632::Reg_eax);
assert(getDest()->getRegNum() == RegX8632::Reg_eax); // TODO: allow edx?
Str << "\tmul" << getWidthString(getDest()->getType()) << "\t";
getSrc(1)->emit(Func);
}
void InstX8632Mul::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 2);
assert(llvm::isa<Variable>(getSrc(0)));
assert(llvm::cast<Variable>(getSrc(0))->getRegNum() == RegX8632::Reg_eax);
assert(getDest()->getRegNum() == RegX8632::Reg_eax); // TODO: allow edx?
const Operand *Src = getSrc(1);
Type Ty = Src->getType();
const static x86::AssemblerX86::GPREmitterOneOp Emitter = {
&x86::AssemblerX86::mul, &x86::AssemblerX86::mul};
emitIASOpTyGPR(Func, Ty, Src, Emitter);
}
void InstX8632Mul::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
dumpDest(Func);
Str << " = mul." << getDest()->getType() << " ";
dumpSources(Func);
}
void InstX8632Shld::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
Variable *Dest = getDest();
assert(getSrcSize() == 3);
assert(Dest == getSrc(0));
Str << "\tshld" << getWidthString(Dest->getType()) << "\t";
if (const auto ShiftReg = llvm::dyn_cast<Variable>(getSrc(2))) {
(void)ShiftReg;
assert(ShiftReg->getRegNum() == RegX8632::Reg_ecx);
Str << "%cl";
} else {
getSrc(2)->emit(Func);
}
Str << ", ";
getSrc(1)->emit(Func);
Str << ", ";
Dest->emit(Func);
}
void InstX8632Shld::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 3);
assert(getDest() == getSrc(0));
const Variable *Dest = getDest();
const Operand *Src1 = getSrc(1);
const Operand *Src2 = getSrc(2);
static const x86::AssemblerX86::GPREmitterShiftD Emitter = {
&x86::AssemblerX86::shld, &x86::AssemblerX86::shld};
emitIASGPRShiftDouble(Func, Dest, Src1, Src2, Emitter);
}
void InstX8632Shld::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
dumpDest(Func);
Str << " = shld." << getDest()->getType() << " ";
dumpSources(Func);
}
void InstX8632Shrd::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
Variable *Dest = getDest();
assert(getSrcSize() == 3);
assert(Dest == getSrc(0));
Str << "\tshrd" << getWidthString(Dest->getType()) << "\t";
if (const auto ShiftReg = llvm::dyn_cast<Variable>(getSrc(2))) {
(void)ShiftReg;
assert(ShiftReg->getRegNum() == RegX8632::Reg_ecx);
Str << "%cl";
} else {
getSrc(2)->emit(Func);
}
Str << ", ";
getSrc(1)->emit(Func);
Str << ", ";
Dest->emit(Func);
}
void InstX8632Shrd::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 3);
assert(getDest() == getSrc(0));
const Variable *Dest = getDest();
const Operand *Src1 = getSrc(1);
const Operand *Src2 = getSrc(2);
static const x86::AssemblerX86::GPREmitterShiftD Emitter = {
&x86::AssemblerX86::shrd, &x86::AssemblerX86::shrd};
emitIASGPRShiftDouble(Func, Dest, Src1, Src2, Emitter);
}
void InstX8632Shrd::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
dumpDest(Func);
Str << " = shrd." << getDest()->getType() << " ";
dumpSources(Func);
}
void InstX8632Cmov::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
Variable *Dest = getDest();
Str << "\t";
assert(Condition != CondX86::Br_None);
assert(getDest()->hasReg());
Str << "cmov" << InstX8632BrAttributes[Condition].DisplayString
<< getWidthString(Dest->getType()) << "\t";
getSrc(1)->emit(Func);
Str << ", ";
Dest->emit(Func);
}
void InstX8632Cmov::emitIAS(const Cfg *Func) const {
assert(Condition != CondX86::Br_None);
assert(getDest()->hasReg());
assert(getSrcSize() == 2);
// Only need the reg/reg form now.
const auto SrcVar = llvm::cast<Variable>(getSrc(1));
assert(SrcVar->hasReg());
assert(SrcVar->getType() == IceType_i32);
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
Asm->cmov(Condition, RegX8632::getEncodedGPR(getDest()->getRegNum()),
RegX8632::getEncodedGPR(SrcVar->getRegNum()));
}
void InstX8632Cmov::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << "cmov" << InstX8632BrAttributes[Condition].DisplayString << ".";
Str << getDest()->getType() << " ";
dumpDest(Func);
Str << ", ";
dumpSources(Func);
}
void InstX8632Cmpps::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 2);
assert(Condition < CondX86::Cmpps_Invalid);
Str << "\t";
Str << "cmp" << InstX8632CmppsAttributes[Condition].EmitString << "ps"
<< "\t";
getSrc(1)->emit(Func);
Str << ", ";
getDest()->emit(Func);
}
void InstX8632Cmpps::emitIAS(const Cfg *Func) const {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
assert(getSrcSize() == 2);
assert(Condition < CondX86::Cmpps_Invalid);
// Assuming there isn't any load folding for cmpps, and vector constants
// are not allowed in PNaCl.
assert(llvm::isa<Variable>(getSrc(1)));
const auto SrcVar = llvm::cast<Variable>(getSrc(1));
if (SrcVar->hasReg()) {
Asm->cmpps(RegX8632::getEncodedXmm(getDest()->getRegNum()),
RegX8632::getEncodedXmm(SrcVar->getRegNum()), Condition);
} else {
x86::Address SrcStackAddr = static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(SrcVar);
Asm->cmpps(RegX8632::getEncodedXmm(getDest()->getRegNum()), SrcStackAddr,
Condition);
}
}
void InstX8632Cmpps::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
assert(Condition < CondX86::Cmpps_Invalid);
dumpDest(Func);
Str << " = cmp" << InstX8632CmppsAttributes[Condition].EmitString << "ps"
<< "\t";
dumpSources(Func);
}
void InstX8632Cmpxchg::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 3);
if (Locked) {
Str << "\tlock";
}
Str << "\tcmpxchg" << getWidthString(getSrc(0)->getType()) << "\t";
getSrc(2)->emit(Func);
Str << ", ";
getSrc(0)->emit(Func);
}
void InstX8632Cmpxchg::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 3);
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
Type Ty = getSrc(0)->getType();
const auto Mem = llvm::cast<OperandX8632Mem>(getSrc(0));
assert(Mem->getSegmentRegister() == OperandX8632Mem::DefaultSegment);
const x86::Address Addr = Mem->toAsmAddress(Asm);
const auto VarReg = llvm::cast<Variable>(getSrc(2));
assert(VarReg->hasReg());
const RegX8632::GPRRegister Reg =
RegX8632::getEncodedGPR(VarReg->getRegNum());
if (Locked) {
Asm->LockCmpxchg(Ty, Addr, Reg);
} else {
Asm->cmpxchg(Ty, Addr, Reg);
}
}
void InstX8632Cmpxchg::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
if (Locked) {
Str << "lock ";
}
Str << "cmpxchg." << getSrc(0)->getType() << " ";
dumpSources(Func);
}
void InstX8632Cmpxchg8b::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 5);
if (Locked) {
Str << "\tlock";
}
Str << "\tcmpxchg8b\t";
getSrc(0)->emit(Func);
}
void InstX8632Cmpxchg8b::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 5);
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
const auto Mem = llvm::cast<OperandX8632Mem>(getSrc(0));
assert(Mem->getSegmentRegister() == OperandX8632Mem::DefaultSegment);
const x86::Address Addr = Mem->toAsmAddress(Asm);
if (Locked) {
Asm->lock();
}
Asm->cmpxchg8b(Addr);
}
void InstX8632Cmpxchg8b::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
if (Locked) {
Str << "lock ";
}
Str << "cmpxchg8b ";
dumpSources(Func);
}
void InstX8632Cvt::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 1);
Str << "\tcvt";
if (isTruncating())
Str << "t";
Str << TypeX8632Attributes[getSrc(0)->getType()].CvtString << "2"
<< TypeX8632Attributes[getDest()->getType()].CvtString << "\t";
getSrc(0)->emit(Func);
Str << ", ";
getDest()->emit(Func);
}
void InstX8632Cvt::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 1);
const Variable *Dest = getDest();
const Operand *Src = getSrc(0);
Type DestTy = Dest->getType();
Type SrcTy = Src->getType();
switch (Variant) {
case Si2ss: {
assert(isScalarIntegerType(SrcTy));
assert(typeWidthInBytes(SrcTy) <= 4);
assert(isScalarFloatingType(DestTy));
static const x86::AssemblerX86::CastEmitterRegOp<
RegX8632::XmmRegister, RegX8632::GPRRegister> Emitter = {
&x86::AssemblerX86::cvtsi2ss, &x86::AssemblerX86::cvtsi2ss};
emitIASCastRegOp<RegX8632::XmmRegister, RegX8632::GPRRegister,
RegX8632::getEncodedXmm, RegX8632::getEncodedGPR>(
Func, DestTy, Dest, Src, Emitter);
return;
}
case Tss2si: {
assert(isScalarFloatingType(SrcTy));
assert(isScalarIntegerType(DestTy));
assert(typeWidthInBytes(DestTy) <= 4);
static const x86::AssemblerX86::CastEmitterRegOp<
RegX8632::GPRRegister, RegX8632::XmmRegister> Emitter = {
&x86::AssemblerX86::cvttss2si, &x86::AssemblerX86::cvttss2si};
emitIASCastRegOp<RegX8632::GPRRegister, RegX8632::XmmRegister,
RegX8632::getEncodedGPR, RegX8632::getEncodedXmm>(
Func, SrcTy, Dest, Src, Emitter);
return;
}
case Float2float: {
assert(isScalarFloatingType(SrcTy));
assert(isScalarFloatingType(DestTy));
assert(DestTy != SrcTy);
static const x86::AssemblerX86::XmmEmitterRegOp Emitter = {
&x86::AssemblerX86::cvtfloat2float, &x86::AssemblerX86::cvtfloat2float};
emitIASRegOpTyXMM(Func, SrcTy, Dest, Src, Emitter);
return;
}
case Dq2ps: {
assert(isVectorIntegerType(SrcTy));
assert(isVectorFloatingType(DestTy));
static const x86::AssemblerX86::XmmEmitterRegOp Emitter = {
&x86::AssemblerX86::cvtdq2ps, &x86::AssemblerX86::cvtdq2ps};
emitIASRegOpTyXMM(Func, DestTy, Dest, Src, Emitter);
return;
}
case Tps2dq: {
assert(isVectorFloatingType(SrcTy));
assert(isVectorIntegerType(DestTy));
static const x86::AssemblerX86::XmmEmitterRegOp Emitter = {
&x86::AssemblerX86::cvttps2dq, &x86::AssemblerX86::cvttps2dq};
emitIASRegOpTyXMM(Func, DestTy, Dest, Src, Emitter);
return;
}
}
}
void InstX8632Cvt::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
dumpDest(Func);
Str << " = cvt";
if (isTruncating())
Str << "t";
Str << TypeX8632Attributes[getSrc(0)->getType()].CvtString << "2"
<< TypeX8632Attributes[getDest()->getType()].CvtString << " ";
dumpSources(Func);
}
void InstX8632Icmp::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 2);
Str << "\tcmp" << getWidthString(getSrc(0)->getType()) << "\t";
getSrc(1)->emit(Func);
Str << ", ";
getSrc(0)->emit(Func);
}
void InstX8632Icmp::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 2);
const Operand *Src0 = getSrc(0);
const Operand *Src1 = getSrc(1);
Type Ty = Src0->getType();
static const x86::AssemblerX86::GPREmitterRegOp RegEmitter = {
&x86::AssemblerX86::cmp, &x86::AssemblerX86::cmp, &x86::AssemblerX86::cmp
};
static const x86::AssemblerX86::GPREmitterAddrOp AddrEmitter = {
&x86::AssemblerX86::cmp, &x86::AssemblerX86::cmp
};
if (const auto SrcVar0 = llvm::dyn_cast<Variable>(Src0)) {
if (SrcVar0->hasReg()) {
emitIASRegOpTyGPR(Func, Ty, SrcVar0, Src1, RegEmitter);
return;
}
}
emitIASAsAddrOpTyGPR(Func, Ty, Src0, Src1, AddrEmitter);
}
void InstX8632Icmp::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << "cmp." << getSrc(0)->getType() << " ";
dumpSources(Func);
}
void InstX8632Ucomiss::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 2);
Str << "\tucomi" << TypeX8632Attributes[getSrc(0)->getType()].SdSsString
<< "\t";
getSrc(1)->emit(Func);
Str << ", ";
getSrc(0)->emit(Func);
}
void InstX8632Ucomiss::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 2);
// Currently src0 is always a variable by convention, to avoid having
// two memory operands.
assert(llvm::isa<Variable>(getSrc(0)));
const auto Src0Var = llvm::cast<Variable>(getSrc(0));
Type Ty = Src0Var->getType();
const static x86::AssemblerX86::XmmEmitterRegOp Emitter = {
&x86::AssemblerX86::ucomiss, &x86::AssemblerX86::ucomiss
};
emitIASRegOpTyXMM(Func, Ty, Src0Var, getSrc(1), Emitter);
}
void InstX8632Ucomiss::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << "ucomiss." << getSrc(0)->getType() << " ";
dumpSources(Func);
}
void InstX8632UD2::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 0);
Str << "\tud2";
}
void InstX8632UD2::emitIAS(const Cfg *Func) const {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
Asm->ud2();
}
void InstX8632UD2::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << "ud2\n";
}
void InstX8632Test::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 2);
Str << "\ttest" << getWidthString(getSrc(0)->getType()) << "\t";
getSrc(1)->emit(Func);
Str << ", ";
getSrc(0)->emit(Func);
}
void InstX8632Test::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 2);
const Operand *Src0 = getSrc(0);
const Operand *Src1 = getSrc(1);
Type Ty = Src0->getType();
// The Reg/Addr form of test is not encodeable.
static const x86::AssemblerX86::GPREmitterRegOp RegEmitter = {
&x86::AssemblerX86::test, nullptr, &x86::AssemblerX86::test};
static const x86::AssemblerX86::GPREmitterAddrOp AddrEmitter = {
&x86::AssemblerX86::test, &x86::AssemblerX86::test
};
if (const auto SrcVar0 = llvm::dyn_cast<Variable>(Src0)) {
if (SrcVar0->hasReg()) {
emitIASRegOpTyGPR(Func, Ty, SrcVar0, Src1, RegEmitter);
return;
}
}
llvm_unreachable("Nothing actually generates this so it's untested");
emitIASAsAddrOpTyGPR(Func, Ty, Src0, Src1, AddrEmitter);
}
void InstX8632Test::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << "test." << getSrc(0)->getType() << " ";
dumpSources(Func);
}
void InstX8632Mfence::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 0);
Str << "\tmfence";
}
void InstX8632Mfence::emitIAS(const Cfg *Func) const {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
Asm->mfence();
}
void InstX8632Mfence::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << "mfence\n";
}
void InstX8632Store::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 2);
Type Ty = getSrc(0)->getType();
Str << "\tmov" << getWidthString(Ty) << TypeX8632Attributes[Ty].SdSsString
<< "\t";
getSrc(0)->emit(Func);
Str << ", ";
getSrc(1)->emit(Func);
}
void InstX8632Store::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 2);
const Operand *Dest = getSrc(1);
const Operand *Src = getSrc(0);
Type DestTy = Dest->getType();
if (isScalarFloatingType(DestTy)) {
// Src must be a register, since Dest is a Mem operand of some kind.
const auto SrcVar = llvm::cast<Variable>(Src);
assert(SrcVar->hasReg());
RegX8632::XmmRegister SrcReg = RegX8632::getEncodedXmm(SrcVar->getRegNum());
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
if (const auto DestVar = llvm::dyn_cast<Variable>(Dest)) {
assert(!DestVar->hasReg());
x86::Address StackAddr(static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(DestVar));
Asm->movss(DestTy, StackAddr, SrcReg);
} else {
const auto DestMem = llvm::cast<OperandX8632Mem>(Dest);
assert(DestMem->getSegmentRegister() == OperandX8632Mem::DefaultSegment);
Asm->movss(DestTy, DestMem->toAsmAddress(Asm), SrcReg);
}
return;
} else {
assert(isScalarIntegerType(DestTy));
static const x86::AssemblerX86::GPREmitterAddrOp GPRAddrEmitter = {
&x86::AssemblerX86::mov, &x86::AssemblerX86::mov};
emitIASAsAddrOpTyGPR(Func, DestTy, Dest, Src, GPRAddrEmitter);
}
}
void InstX8632Store::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << "mov." << getSrc(0)->getType() << " ";
getSrc(1)->dump(Func);
Str << ", ";
getSrc(0)->dump(Func);
}
void InstX8632StoreP::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 2);
Str << "\tmovups\t";
getSrc(0)->emit(Func);
Str << ", ";
getSrc(1)->emit(Func);
}
void InstX8632StoreP::emitIAS(const Cfg *Func) const {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
assert(getSrcSize() == 2);
const auto SrcVar = llvm::cast<Variable>(getSrc(0));
const auto DestMem = llvm::cast<OperandX8632Mem>(getSrc(1));
assert(DestMem->getSegmentRegister() == OperandX8632Mem::DefaultSegment);
assert(SrcVar->hasReg());
Asm->movups(DestMem->toAsmAddress(Asm),
RegX8632::getEncodedXmm(SrcVar->getRegNum()));
}
void InstX8632StoreP::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << "storep." << getSrc(0)->getType() << " ";
getSrc(1)->dump(Func);
Str << ", ";
getSrc(0)->dump(Func);
}
void InstX8632StoreQ::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 2);
assert(getSrc(1)->getType() == IceType_i64 ||
getSrc(1)->getType() == IceType_f64);
Str << "\tmovq\t";
getSrc(0)->emit(Func);
Str << ", ";
getSrc(1)->emit(Func);
}
void InstX8632StoreQ::emitIAS(const Cfg *Func) const {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
assert(getSrcSize() == 2);
const auto SrcVar = llvm::cast<Variable>(getSrc(0));
const auto DestMem = llvm::cast<OperandX8632Mem>(getSrc(1));
assert(DestMem->getSegmentRegister() == OperandX8632Mem::DefaultSegment);
assert(SrcVar->hasReg());
Asm->movq(DestMem->toAsmAddress(Asm),
RegX8632::getEncodedXmm(SrcVar->getRegNum()));
}
void InstX8632StoreQ::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << "storeq." << getSrc(0)->getType() << " ";
getSrc(1)->dump(Func);
Str << ", ";
getSrc(0)->dump(Func);
}
template <> void InstX8632Lea::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 1);
assert(getDest()->hasReg());
Str << "\tleal\t";
Operand *Src0 = getSrc(0);
if (const auto Src0Var = llvm::dyn_cast<Variable>(Src0)) {
Type Ty = Src0Var->getType();
// lea on x86-32 doesn't accept mem128 operands, so cast VSrc0 to an
// acceptable type.
Src0Var->asType(isVectorType(Ty) ? IceType_i32 : Ty)->emit(Func);
} else {
Src0->emit(Func);
}
Str << ", ";
getDest()->emit(Func);
}
template <> void InstX8632Mov::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 1);
Operand *Src = getSrc(0);
Type SrcTy = Src->getType();
Type DestTy = getDest()->getType();
Str << "\tmov" << (!isScalarFloatingType(DestTy)
? getWidthString(SrcTy)
: TypeX8632Attributes[DestTy].SdSsString) << "\t";
// For an integer truncation operation, src is wider than dest.
// Ideally, we use a mov instruction whose data width matches the
// narrower dest. This is a problem if e.g. src is a register like
// esi or si where there is no 8-bit version of the register. To be
// safe, we instead widen the dest to match src. This works even
// for stack-allocated dest variables because typeWidthOnStack()
// pads to a 4-byte boundary even if only a lower portion is used.
// TODO: This assert disallows usages such as copying a floating point
// value between a vector and a scalar (which movss is used for).
// Clean this up.
assert(Func->getTarget()->typeWidthInBytesOnStack(DestTy) ==
Func->getTarget()->typeWidthInBytesOnStack(SrcTy));
Src->emit(Func);
Str << ", ";
getDest()->asType(SrcTy)->emit(Func);
}
template <> void InstX8632Mov::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 1);
const Variable *Dest = getDest();
const Operand *Src = getSrc(0);
Type DestTy = Dest->getType();
Type SrcTy = Src->getType();
// Mov can be used for GPRs or XMM registers. Also, the type does not
// necessarily match (Mov can be used for bitcasts). However, when
// the type does not match, one of the operands must be a register.
// Thus, the strategy is to find out if Src or Dest are a register,
// then use that register's type to decide on which emitter set to use.
// The emitter set will include reg-reg movs, but that case should
// be unused when the types don't match.
static const x86::AssemblerX86::XmmEmitterRegOp XmmRegEmitter = {
&x86::AssemblerX86::movss, &x86::AssemblerX86::movss};
static const x86::AssemblerX86::GPREmitterRegOp GPRRegEmitter = {
&x86::AssemblerX86::mov, &x86::AssemblerX86::mov,
&x86::AssemblerX86::mov};
static const x86::AssemblerX86::GPREmitterAddrOp GPRAddrEmitter = {
&x86::AssemblerX86::mov, &x86::AssemblerX86::mov};
// For an integer truncation operation, src is wider than dest.
// Ideally, we use a mov instruction whose data width matches the
// narrower dest. This is a problem if e.g. src is a register like
// esi or si where there is no 8-bit version of the register. To be
// safe, we instead widen the dest to match src. This works even
// for stack-allocated dest variables because typeWidthOnStack()
// pads to a 4-byte boundary even if only a lower portion is used.
// TODO: This assert disallows usages such as copying a floating point
// value between a vector and a scalar (which movss is used for).
// Clean this up.
assert(Func->getTarget()->typeWidthInBytesOnStack(getDest()->getType()) ==
Func->getTarget()->typeWidthInBytesOnStack(Src->getType()));
if (Dest->hasReg()) {
if (isScalarFloatingType(DestTy)) {
emitIASRegOpTyXMM(Func, DestTy, Dest, Src, XmmRegEmitter);
return;
} else {
assert(isScalarIntegerType(DestTy));
// Widen DestTy for truncation (see above note). We should only do this
// when both Src and Dest are integer types.
if (isScalarIntegerType(SrcTy)) {
DestTy = SrcTy;
}
emitIASRegOpTyGPR(Func, DestTy, Dest, Src, GPRRegEmitter);
return;
}
} else {
// Dest must be Stack and Src *could* be a register. Use Src's type
// to decide on the emitters.
x86::Address StackAddr(static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(Dest));
if (isScalarFloatingType(SrcTy)) {
// Src must be a register.
const auto SrcVar = llvm::cast<Variable>(Src);
assert(SrcVar->hasReg());
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
Asm->movss(SrcTy, StackAddr,
RegX8632::getEncodedXmm(SrcVar->getRegNum()));
return;
} else {
// Src can be a register or immediate.
assert(isScalarIntegerType(SrcTy));
emitIASAddrOpTyGPR(Func, SrcTy, StackAddr, Src, GPRAddrEmitter);
return;
}
return;
}
}
template <> void InstX8632Movd::emitIAS(const Cfg *Func) const {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
assert(getSrcSize() == 1);
const Variable *Dest = getDest();
const auto SrcVar = llvm::cast<Variable>(getSrc(0));
// For insert/extract element (one of Src/Dest is an Xmm vector and
// the other is an int type).
if (SrcVar->getType() == IceType_i32) {
assert(isVectorType(Dest->getType()));
assert(Dest->hasReg());
RegX8632::XmmRegister DestReg = RegX8632::getEncodedXmm(Dest->getRegNum());
if (SrcVar->hasReg()) {
Asm->movd(DestReg, RegX8632::getEncodedGPR(SrcVar->getRegNum()));
} else {
x86::Address StackAddr(static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(SrcVar));
Asm->movd(DestReg, StackAddr);
}
} else {
assert(isVectorType(SrcVar->getType()));
assert(SrcVar->hasReg());
assert(Dest->getType() == IceType_i32);
RegX8632::XmmRegister SrcReg = RegX8632::getEncodedXmm(SrcVar->getRegNum());
if (Dest->hasReg()) {
Asm->movd(RegX8632::getEncodedGPR(Dest->getRegNum()), SrcReg);
} else {
x86::Address StackAddr(static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(Dest));
Asm->movd(StackAddr, SrcReg);
}
}
}
template <> void InstX8632Movp::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
// TODO(wala,stichnot): movups works with all vector operands, but
// there exist other instructions (movaps, movdqa, movdqu) that may
// perform better, depending on the data type and alignment of the
// operands.
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 1);
Str << "\tmovups\t";
getSrc(0)->emit(Func);
Str << ", ";
getDest()->emit(Func);
}
template <> void InstX8632Movp::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 1);
assert(isVectorType(getDest()->getType()));
const Variable *Dest = getDest();
const Operand *Src = getSrc(0);
const static x86::AssemblerX86::XmmEmitterMovOps Emitter = {
&x86::AssemblerX86::movups, &x86::AssemblerX86::movups,
&x86::AssemblerX86::movups
};
emitIASMovlikeXMM(Func, Dest, Src, Emitter);
}
template <> void InstX8632Movq::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 1);
assert(getDest()->getType() == IceType_i64 ||
getDest()->getType() == IceType_f64);
Str << "\tmovq\t";
getSrc(0)->emit(Func);
Str << ", ";
getDest()->emit(Func);
}
template <> void InstX8632Movq::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 1);
assert(getDest()->getType() == IceType_i64 ||
getDest()->getType() == IceType_f64);
const Variable *Dest = getDest();
const Operand *Src = getSrc(0);
const static x86::AssemblerX86::XmmEmitterMovOps Emitter = {
&x86::AssemblerX86::movq, &x86::AssemblerX86::movq, &x86::AssemblerX86::movq
};
emitIASMovlikeXMM(Func, Dest, Src, Emitter);
}
template <> void InstX8632MovssRegs::emitIAS(const Cfg *Func) const {
// This is Binop variant is only intended to be used for reg-reg moves
// where part of the Dest register is untouched.
assert(getSrcSize() == 2);
const Variable *Dest = getDest();
assert(Dest == getSrc(0));
const auto SrcVar = llvm::cast<Variable>(getSrc(1));
assert(Dest->hasReg() && SrcVar->hasReg());
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
Asm->movss(IceType_f32, RegX8632::getEncodedXmm(Dest->getRegNum()),
RegX8632::getEncodedXmm(SrcVar->getRegNum()));
}
template <> void InstX8632Movsx::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 1);
const Variable *Dest = getDest();
const Operand *Src = getSrc(0);
// Dest must be a > 8-bit register, but Src can be 8-bit. In practice
// we just use the full register for Dest to avoid having an
// OperandSizeOverride prefix. It also allows us to only dispatch on SrcTy.
Type SrcTy = Src->getType();
assert(typeWidthInBytes(Dest->getType()) > 1);
assert(typeWidthInBytes(Dest->getType()) > typeWidthInBytes(SrcTy));
emitIASRegOpTyGPR<false, true>(Func, SrcTy, Dest, Src, Emitter);
}
template <> void InstX8632Movzx::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 1);
const Variable *Dest = getDest();
const Operand *Src = getSrc(0);
Type SrcTy = Src->getType();
assert(typeWidthInBytes(Dest->getType()) > 1);
assert(typeWidthInBytes(Dest->getType()) > typeWidthInBytes(SrcTy));
emitIASRegOpTyGPR<false, true>(Func, SrcTy, Dest, Src, Emitter);
}
void InstX8632Nop::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
// TODO: Emit the right code for each variant.
Str << "\tnop\t# variant = " << Variant;
}
void InstX8632Nop::emitIAS(const Cfg *Func) const {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
// TODO: Emit the right code for the variant.
Asm->nop();
}
void InstX8632Nop::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << "nop (variant = " << Variant << ")";
}
void InstX8632Fld::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 1);
Type Ty = getSrc(0)->getType();
SizeT Width = typeWidthInBytes(Ty);
const auto Var = llvm::dyn_cast<Variable>(getSrc(0));
if (Var && Var->hasReg()) {
// This is a physical xmm register, so we need to spill it to a
// temporary stack slot.
Str << "\tsubl\t$" << Width << ", %esp"
<< "\n";
Str << "\tmov" << TypeX8632Attributes[Ty].SdSsString << "\t";
Var->emit(Func);
Str << ", (%esp)\n";
Str << "\tfld" << getFldString(Ty) << "\t"
<< "(%esp)\n";
Str << "\taddl\t$" << Width << ", %esp";
return;
}
Str << "\tfld" << getFldString(Ty) << "\t";
getSrc(0)->emit(Func);
}
void InstX8632Fld::emitIAS(const Cfg *Func) const {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
assert(getSrcSize() == 1);
const Operand *Src = getSrc(0);
Type Ty = Src->getType();
if (const auto Var = llvm::dyn_cast<Variable>(Src)) {
if (Var->hasReg()) {
// This is a physical xmm register, so we need to spill it to a
// temporary stack slot.
x86::Immediate Width(typeWidthInBytes(Ty));
Asm->sub(IceType_i32, RegX8632::Encoded_Reg_esp, Width);
x86::Address StackSlot = x86::Address(RegX8632::Encoded_Reg_esp, 0);
Asm->movss(Ty, StackSlot, RegX8632::getEncodedXmm(Var->getRegNum()));
Asm->fld(Ty, StackSlot);
Asm->add(IceType_i32, RegX8632::Encoded_Reg_esp, Width);
} else {
x86::Address StackAddr(static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(Var));
Asm->fld(Ty, StackAddr);
}
} else if (const auto Mem = llvm::dyn_cast<OperandX8632Mem>(Src)) {
assert(Mem->getSegmentRegister() == OperandX8632Mem::DefaultSegment);
Asm->fld(Ty, Mem->toAsmAddress(Asm));
} else if (const auto Imm = llvm::dyn_cast<Constant>(Src)) {
Asm->fld(Ty, x86::Address::ofConstPool(Asm, Imm));
} else {
llvm_unreachable("Unexpected operand type");
}
}
void InstX8632Fld::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << "fld." << getSrc(0)->getType() << " ";
dumpSources(Func);
}
void InstX8632Fstp::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 0);
// TODO(jvoung,stichnot): Utilize this by setting Dest to nullptr to
// "partially" delete the fstp if the Dest is unused.
// Even if Dest is unused, the fstp should be kept for the SideEffects
// of popping the stack.
if (!getDest()) {
Str << "\tfstp\tst(0)";
return;
}
Type Ty = getDest()->getType();
size_t Width = typeWidthInBytes(Ty);
if (!getDest()->hasReg()) {
Str << "\tfstp" << getFldString(Ty) << "\t";
getDest()->emit(Func);
return;
}
// Dest is a physical (xmm) register, so st(0) needs to go through
// memory. Hack this by creating a temporary stack slot, spilling
// st(0) there, loading it into the xmm register, and deallocating
// the stack slot.
Str << "\tsubl\t$" << Width << ", %esp\n";
Str << "\tfstp" << getFldString(Ty) << "\t"
<< "(%esp)\n";
Str << "\tmov" << TypeX8632Attributes[Ty].SdSsString << "\t"
<< "(%esp), ";
getDest()->emit(Func);
Str << "\n";
Str << "\taddl\t$" << Width << ", %esp";
}
void InstX8632Fstp::emitIAS(const Cfg *Func) const {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
assert(getSrcSize() == 0);
const Variable *Dest = getDest();
// TODO(jvoung,stichnot): Utilize this by setting Dest to nullptr to
// "partially" delete the fstp if the Dest is unused.
// Even if Dest is unused, the fstp should be kept for the SideEffects
// of popping the stack.
if (!Dest) {
Asm->fstp(RegX8632::getEncodedSTReg(0));
return;
}
Type Ty = Dest->getType();
if (!Dest->hasReg()) {
x86::Address StackAddr(static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(Dest));
Asm->fstp(Ty, StackAddr);
} else {
// Dest is a physical (xmm) register, so st(0) needs to go through
// memory. Hack this by creating a temporary stack slot, spilling
// st(0) there, loading it into the xmm register, and deallocating
// the stack slot.
x86::Immediate Width(typeWidthInBytes(Ty));
Asm->sub(IceType_i32, RegX8632::Encoded_Reg_esp, Width);
x86::Address StackSlot = x86::Address(RegX8632::Encoded_Reg_esp, 0);
Asm->fstp(Ty, StackSlot);
Asm->movss(Ty, RegX8632::getEncodedXmm(Dest->getRegNum()), StackSlot);
Asm->add(IceType_i32, RegX8632::Encoded_Reg_esp, Width);
}
}
void InstX8632Fstp::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
dumpDest(Func);
Str << " = fstp." << getDest()->getType() << ", st(0)";
Str << "\n";
}
template <> void InstX8632Pcmpeq::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
char buf[30];
snprintf(buf, llvm::array_lengthof(buf), "pcmpeq%s",
TypeX8632Attributes[getDest()->getType()].PackString);
emitTwoAddress(buf, this, Func);
}
template <> void InstX8632Pcmpgt::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
char buf[30];
snprintf(buf, llvm::array_lengthof(buf), "pcmpgt%s",
TypeX8632Attributes[getDest()->getType()].PackString);
emitTwoAddress(buf, this, Func);
}
template <> void InstX8632Pextr::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 2);
// pextrb and pextrd are SSE4.1 instructions.
assert(getSrc(0)->getType() == IceType_v8i16 ||
getSrc(0)->getType() == IceType_v8i1 ||
static_cast<TargetX8632 *>(Func->getTarget())->getInstructionSet()
>= TargetX8632::SSE4_1);
Str << "\t" << Opcode
<< TypeX8632Attributes[getSrc(0)->getType()].PackString << "\t";
getSrc(1)->emit(Func);
Str << ", ";
getSrc(0)->emit(Func);
Str << ", ";
Variable *Dest = getDest();
// pextrw must take a register dest. There is an SSE4.1 version that takes
// a memory dest, but we aren't using it. For uniformity, just restrict
// them all to have a register dest for now.
assert(Dest->hasReg());
Dest->asType(IceType_i32)->emit(Func);
}
template <> void InstX8632Pextr::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 2);
// pextrb and pextrd are SSE4.1 instructions.
const Variable *Dest = getDest();
Type DispatchTy = Dest->getType();
assert(DispatchTy == IceType_i16 ||
static_cast<TargetX8632 *>(Func->getTarget())->getInstructionSet() >=
TargetX8632::SSE4_1);
// pextrw must take a register dest. There is an SSE4.1 version that takes
// a memory dest, but we aren't using it. For uniformity, just restrict
// them all to have a register dest for now.
assert(Dest->hasReg());
// pextrw's Src(0) must be a register (both SSE4.1 and SSE2).
assert(llvm::cast<Variable>(getSrc(0))->hasReg());
static const x86::AssemblerX86::ThreeOpImmEmitter<
RegX8632::GPRRegister, RegX8632::XmmRegister> Emitter = {
&x86::AssemblerX86::pextr, nullptr};
emitIASThreeOpImmOps<RegX8632::GPRRegister, RegX8632::XmmRegister,
RegX8632::getEncodedGPR, RegX8632::getEncodedXmm>(
Func, DispatchTy, Dest, getSrc(0), getSrc(1), Emitter);
}
template <> void InstX8632Pinsr::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 3);
// pinsrb and pinsrd are SSE4.1 instructions.
assert(getDest()->getType() == IceType_v8i16 ||
getDest()->getType() == IceType_v8i1 ||
static_cast<TargetX8632 *>(Func->getTarget())->getInstructionSet()
>= TargetX8632::SSE4_1);
Str << "\t" << Opcode
<< TypeX8632Attributes[getDest()->getType()].PackString << "\t";
getSrc(2)->emit(Func);
Str << ", ";
Operand *Src1 = getSrc(1);
if (const auto Src1Var = llvm::dyn_cast<Variable>(Src1)) {
// If src1 is a register, it should always be r32.
if (Src1Var->hasReg()) {
Src1Var->asType(IceType_i32)->emit(Func);
} else {
Src1Var->emit(Func);
}
} else {
Src1->emit(Func);
}
Str << ", ";
getDest()->emit(Func);
}
template <> void InstX8632Pinsr::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 3);
assert(getDest() == getSrc(0));
// pinsrb and pinsrd are SSE4.1 instructions.
const Operand *Src0 = getSrc(1);
Type DispatchTy = Src0->getType();
assert(DispatchTy == IceType_i16 ||
static_cast<TargetX8632 *>(Func->getTarget())->getInstructionSet() >=
TargetX8632::SSE4_1);
// If src1 is a register, it should always be r32 (this should fall out
// from the encodings for ByteRegs overlapping the encodings for r32),
// but we have to trust the regalloc to not choose "ah", where it
// doesn't overlap.
static const x86::AssemblerX86::ThreeOpImmEmitter<
RegX8632::XmmRegister, RegX8632::GPRRegister> Emitter = {
&x86::AssemblerX86::pinsr, &x86::AssemblerX86::pinsr};
emitIASThreeOpImmOps<RegX8632::XmmRegister, RegX8632::GPRRegister,
RegX8632::getEncodedXmm, RegX8632::getEncodedGPR>(
Func, DispatchTy, getDest(), Src0, getSrc(2), Emitter);
}
template <> void InstX8632Pshufd::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 2);
const Variable *Dest = getDest();
Type Ty = Dest->getType();
static const x86::AssemblerX86::ThreeOpImmEmitter<
RegX8632::XmmRegister, RegX8632::XmmRegister> Emitter = {
&x86::AssemblerX86::pshufd, &x86::AssemblerX86::pshufd};
emitIASThreeOpImmOps<RegX8632::XmmRegister, RegX8632::XmmRegister,
RegX8632::getEncodedXmm, RegX8632::getEncodedXmm>(
Func, Ty, Dest, getSrc(0), getSrc(1), Emitter);
}
template <> void InstX8632Shufps::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 3);
const Variable *Dest = getDest();
assert(Dest == getSrc(0));
Type Ty = Dest->getType();
static const x86::AssemblerX86::ThreeOpImmEmitter<
RegX8632::XmmRegister, RegX8632::XmmRegister> Emitter = {
&x86::AssemblerX86::shufps, &x86::AssemblerX86::shufps};
emitIASThreeOpImmOps<RegX8632::XmmRegister, RegX8632::XmmRegister,
RegX8632::getEncodedXmm, RegX8632::getEncodedXmm>(
Func, Ty, Dest, getSrc(1), getSrc(2), Emitter);
}
void InstX8632Pop::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 0);
Str << "\tpop\t";
getDest()->emit(Func);
}
void InstX8632Pop::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 0);
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
if (getDest()->hasReg()) {
Asm->popl(RegX8632::getEncodedGPR(getDest()->getRegNum()));
} else {
Asm->popl(static_cast<TargetX8632 *>(Func->getTarget())
->stackVarToAsmOperand(getDest()));
}
}
void InstX8632Pop::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
dumpDest(Func);
Str << " = pop." << getDest()->getType() << " ";
}
void InstX8632AdjustStack::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
Str << "\tsubl\t$" << Amount << ", %esp";
Func->getTarget()->updateStackAdjustment(Amount);
}
void InstX8632AdjustStack::emitIAS(const Cfg *Func) const {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
Asm->sub(IceType_i32, RegX8632::Encoded_Reg_esp, x86::Immediate(Amount));
Func->getTarget()->updateStackAdjustment(Amount);
}
void InstX8632AdjustStack::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << "esp = sub.i32 esp, " << Amount;
}
void InstX8632Push::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(getSrcSize() == 1);
// Push is currently only used for saving GPRs.
const auto Var = llvm::cast<Variable>(getSrc(0));
assert(Var->hasReg());
Str << "\tpush\t";
Var->emit(Func);
}
void InstX8632Push::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 1);
// Push is currently only used for saving GPRs.
const auto Var = llvm::cast<Variable>(getSrc(0));
assert(Var->hasReg());
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
Asm->pushl(RegX8632::getEncodedGPR(Var->getRegNum()));
}
void InstX8632Push::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Str << "push." << getSrc(0)->getType() << " ";
dumpSources(Func);
}
template <> void InstX8632Psll::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
assert(getDest()->getType() == IceType_v8i16 ||
getDest()->getType() == IceType_v8i1 ||
getDest()->getType() == IceType_v4i32 ||
getDest()->getType() == IceType_v4i1);
char buf[30];
snprintf(buf, llvm::array_lengthof(buf), "psll%s",
TypeX8632Attributes[getDest()->getType()].PackString);
emitTwoAddress(buf, this, Func);
}
template <> void InstX8632Psra::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
assert(getDest()->getType() == IceType_v8i16 ||
getDest()->getType() == IceType_v8i1 ||
getDest()->getType() == IceType_v4i32 ||
getDest()->getType() == IceType_v4i1);
char buf[30];
snprintf(buf, llvm::array_lengthof(buf), "psra%s",
TypeX8632Attributes[getDest()->getType()].PackString);
emitTwoAddress(buf, this, Func);
}
void InstX8632Ret::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
Str << "\tret";
}
void InstX8632Ret::emitIAS(const Cfg *Func) const {
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
Asm->ret();
}
void InstX8632Ret::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Type Ty = (getSrcSize() == 0 ? IceType_void : getSrc(0)->getType());
Str << "ret." << Ty << " ";
dumpSources(Func);
}
void InstX8632Xadd::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
if (Locked) {
Str << "\tlock";
}
Str << "\txadd" << getWidthString(getSrc(0)->getType()) << "\t";
getSrc(1)->emit(Func);
Str << ", ";
getSrc(0)->emit(Func);
}
void InstX8632Xadd::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 2);
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
Type Ty = getSrc(0)->getType();
const auto Mem = llvm::cast<OperandX8632Mem>(getSrc(0));
assert(Mem->getSegmentRegister() == OperandX8632Mem::DefaultSegment);
const x86::Address Addr = Mem->toAsmAddress(Asm);
const auto VarReg = llvm::cast<Variable>(getSrc(1));
assert(VarReg->hasReg());
const RegX8632::GPRRegister Reg =
RegX8632::getEncodedGPR(VarReg->getRegNum());
if (Locked) {
Asm->lock();
}
Asm->xadd(Ty, Addr, Reg);
}
void InstX8632Xadd::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
if (Locked) {
Str << "lock ";
}
Type Ty = getSrc(0)->getType();
Str << "xadd." << Ty << " ";
dumpSources(Func);
}
void InstX8632Xchg::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
Str << "\txchg" << getWidthString(getSrc(0)->getType()) << "\t";
getSrc(1)->emit(Func);
Str << ", ";
getSrc(0)->emit(Func);
}
void InstX8632Xchg::emitIAS(const Cfg *Func) const {
assert(getSrcSize() == 2);
x86::AssemblerX86 *Asm = Func->getAssembler<x86::AssemblerX86>();
Type Ty = getSrc(0)->getType();
const auto Mem = llvm::cast<OperandX8632Mem>(getSrc(0));
assert(Mem->getSegmentRegister() == OperandX8632Mem::DefaultSegment);
const x86::Address Addr = Mem->toAsmAddress(Asm);
const auto VarReg = llvm::cast<Variable>(getSrc(1));
assert(VarReg->hasReg());
const RegX8632::GPRRegister Reg =
RegX8632::getEncodedGPR(VarReg->getRegNum());
Asm->xchg(Ty, Addr, Reg);
}
void InstX8632Xchg::dump(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrDump();
Type Ty = getSrc(0)->getType();
Str << "xchg." << Ty << " ";
dumpSources(Func);
}
void OperandX8632Mem::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
if (SegmentReg != DefaultSegment) {
assert(SegmentReg >= 0 && SegmentReg < SegReg_NUM);
Str << InstX8632SegmentRegNames[SegmentReg] << ":";
}
// Emit as Offset(Base,Index,1<<Shift).
// Offset is emitted without the leading '$'.
// Omit the (Base,Index,1<<Shift) part if Base==nullptr.
if (!Offset) {
// No offset, emit nothing.
} else if (const auto CI = llvm::dyn_cast<ConstantInteger32>(Offset)) {
if (CI->getValue())
// Emit a non-zero offset without a leading '$'.
Str << CI->getValue();
} else if (const auto CR = llvm::dyn_cast<ConstantRelocatable>(Offset)) {
CR->emitWithoutDollar(Func->getContext());
} else {
llvm_unreachable("Invalid offset type for x86 mem operand");
}
if (Base) {
Str << "(";
Base->emit(Func);
if (Index) {
Str << ",";
Index->emit(Func);
if (Shift)
Str << "," << (1u << Shift);
}
Str << ")";
}
}
void OperandX8632Mem::dump(const Cfg *Func, Ostream &Str) const {
if (!ALLOW_DUMP)
return;
if (SegmentReg != DefaultSegment) {
assert(SegmentReg >= 0 && SegmentReg < SegReg_NUM);
Str << InstX8632SegmentRegNames[SegmentReg] << ":";
}
bool Dumped = false;
Str << "[";
if (Base) {
if (Func)
Base->dump(Func);
else
Base->dump(Str);
Dumped = true;
}
if (Index) {
assert(Base);
Str << "+";
if (Shift > 0)
Str << (1u << Shift) << "*";
if (Func)
Index->dump(Func);
else
Index->dump(Str);
Dumped = true;
}
// Pretty-print the Offset.
bool OffsetIsZero = false;
bool OffsetIsNegative = false;
if (!Offset) {
OffsetIsZero = true;
} else if (const auto CI = llvm::dyn_cast<ConstantInteger32>(Offset)) {
OffsetIsZero = (CI->getValue() == 0);
OffsetIsNegative = (static_cast<int32_t>(CI->getValue()) < 0);
} else {
assert(llvm::isa<ConstantRelocatable>(Offset));
}
if (Dumped) {
if (!OffsetIsZero) { // Suppress if Offset is known to be 0
if (!OffsetIsNegative) // Suppress if Offset is known to be negative
Str << "+";
Offset->dump(Func, Str);
}
} else {
// There is only the offset.
Offset->dump(Func, Str);
}
Str << "]";
}
void OperandX8632Mem::emitSegmentOverride(x86::AssemblerX86 *Asm) const {
if (SegmentReg != DefaultSegment) {
assert(SegmentReg >= 0 && SegmentReg < SegReg_NUM);
Asm->EmitSegmentOverride(InstX8632SegmentPrefixes[SegmentReg]);
}
}
x86::Address OperandX8632Mem::toAsmAddress(Assembler *Asm) const {
int32_t Disp = 0;
AssemblerFixup *Fixup = nullptr;
// Determine the offset (is it relocatable?)
if (getOffset()) {
if (const auto CI = llvm::dyn_cast<ConstantInteger32>(getOffset())) {
Disp = static_cast<int32_t>(CI->getValue());
} else if (const auto CR =
llvm::dyn_cast<ConstantRelocatable>(getOffset())) {
Disp = CR->getOffset();
Fixup = Asm->createFixup(llvm::ELF::R_386_32, CR);
} else {
llvm_unreachable("Unexpected offset type");
}
}
// Now convert to the various possible forms.
if (getBase() && getIndex()) {
return x86::Address(RegX8632::getEncodedGPR(getBase()->getRegNum()),
RegX8632::getEncodedGPR(getIndex()->getRegNum()),
x86::ScaleFactor(getShift()), Disp);
} else if (getBase()) {
return x86::Address(RegX8632::getEncodedGPR(getBase()->getRegNum()), Disp);
} else if (getIndex()) {
return x86::Address(RegX8632::getEncodedGPR(getIndex()->getRegNum()),
x86::ScaleFactor(getShift()), Disp);
} else if (Fixup) {
return x86::Address::Absolute(Disp, Fixup);
} else {
return x86::Address::Absolute(Disp);
}
}
x86::Address VariableSplit::toAsmAddress(const Cfg *Func) const {
assert(!Var->hasReg());
const TargetLowering *Target = Func->getTarget();
int32_t Offset =
Var->getStackOffset() + Target->getStackAdjustment() + getOffset();
return x86::Address(RegX8632::getEncodedGPR(Target->getFrameOrStackReg()),
Offset);
}
void VariableSplit::emit(const Cfg *Func) const {
if (!ALLOW_DUMP)
return;
Ostream &Str = Func->getContext()->getStrEmit();
assert(!Var->hasReg());
// The following is copied/adapted from TargetX8632::emitVariable().
const TargetLowering *Target = Func->getTarget();
const Type Ty = IceType_i32;
int32_t Offset =
Var->getStackOffset() + Target->getStackAdjustment() + getOffset();
if (Offset)
Str << Offset;
Str << "(%" << Target->getRegName(Target->getFrameOrStackReg(), Ty) << ")";
}
void VariableSplit::dump(const Cfg *Func, Ostream &Str) const {
if (!ALLOW_DUMP)
return;
switch (Part) {
case Low:
Str << "low";
break;
case High:
Str << "high";
break;
}
Str << "(";
if (Func)
Var->dump(Func);
else
Var->dump(Str);
Str << ")";
}
} // end of namespace Ice