dynarmic/src/backend_x64/emit_x64.cpp

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/* This file is part of the dynarmic project.
* Copyright (c) 2016 MerryMage
* This software may be used and distributed according to the terms of the GNU
* General Public License version 2 or any later version.
*/
#include <unordered_map>
#include "backend_x64/abi.h"
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#include "backend_x64/emit_x64.h"
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#include "backend_x64/jitstate.h"
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#include "common/assert.h"
#include "common/bit_util.h"
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#include "frontend/arm/types.h"
#include "frontend/ir/basic_block.h"
#include "frontend/ir/location_descriptor.h"
#include "frontend/ir/microinstruction.h"
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#include "frontend/ir/opcodes.h"
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// TODO: Have ARM flags in host flags and not have them use up GPR registers unless necessary.
// TODO: Actually implement that proper instruction selector you've always wanted to sweetheart.
namespace Dynarmic {
namespace BackendX64 {
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static Xbyak::Address MJitStateReg(Arm::Reg reg) {
using namespace Xbyak::util;
return dword[r15 + offsetof(JitState, Reg) + sizeof(u32) * static_cast<size_t>(reg)];
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}
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static Xbyak::Address MJitStateExtReg(Arm::ExtReg reg) {
using namespace Xbyak::util;
if (Arm::IsSingleExtReg(reg)) {
size_t index = static_cast<size_t>(reg) - static_cast<size_t>(Arm::ExtReg::S0);
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return dword[r15 + offsetof(JitState, ExtReg) + sizeof(u32) * index];
}
if (Arm::IsDoubleExtReg(reg)) {
size_t index = static_cast<size_t>(reg) - static_cast<size_t>(Arm::ExtReg::D0);
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return qword[r15 + offsetof(JitState, ExtReg) + sizeof(u64) * index];
}
ASSERT_MSG(false, "Should never happen.");
}
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static Xbyak::Address MJitStateCpsr() {
using namespace Xbyak::util;
return dword[r15 + offsetof(JitState, Cpsr)];
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}
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static void EraseInstruction(IR::Block& block, IR::Inst* inst) {
block.Instructions().erase(inst);
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}
EmitX64::BlockDescriptor EmitX64::Emit(IR::Block& block) {
const IR::LocationDescriptor descriptor = block.Location();
reg_alloc.Reset();
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code->align();
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const CodePtr code_ptr = code->getCurr();
basic_blocks[descriptor].code_ptr = code_ptr;
unique_hash_to_code_ptr[descriptor.UniqueHash()] = code_ptr;
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EmitCondPrelude(block);
for (auto iter = block.begin(); iter != block.end(); ++iter) {
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IR::Inst* inst = &*iter;
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// Call the relevant Emit* member function.
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switch (inst->GetOpcode()) {
#define OPCODE(name, type, ...) \
case IR::Opcode::name: \
EmitX64::Emit##name(block, inst); \
break;
#include "frontend/ir/opcodes.inc"
#undef OPCODE
default:
ASSERT_MSG(false, "Invalid opcode %zu", static_cast<size_t>(inst->GetOpcode()));
break;
}
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reg_alloc.EndOfAllocScope();
}
EmitAddCycles(block.CycleCount());
EmitTerminal(block.GetTerminal(), block.Location());
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code->int3();
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reg_alloc.AssertNoMoreUses();
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Patch(descriptor, code_ptr);
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basic_blocks[descriptor].size = std::intptr_t(code->getCurr()) - std::intptr_t(code_ptr);
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return basic_blocks[descriptor];
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}
void EmitX64::EmitBreakpoint(IR::Block&, IR::Inst*) {
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code->int3();
}
void EmitX64::EmitIdentity(IR::Block& block, IR::Inst* inst) {
if (!inst->GetArg(0).IsImmediate()) {
reg_alloc.RegisterAddDef(inst, inst->GetArg(0));
}
}
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void EmitX64::EmitGetRegister(IR::Block&, IR::Inst* inst) {
Arm::Reg reg = inst->GetArg(0).GetRegRef();
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Xbyak::Reg32 result = reg_alloc.DefGpr(inst).cvt32();
code->mov(result, MJitStateReg(reg));
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}
void EmitX64::EmitGetExtendedRegister32(IR::Block& block, IR::Inst* inst) {
Arm::ExtReg reg = inst->GetArg(0).GetExtRegRef();
ASSERT(Arm::IsSingleExtReg(reg));
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Xbyak::Xmm result = reg_alloc.DefXmm(inst);
code->movss(result, MJitStateExtReg(reg));
}
void EmitX64::EmitGetExtendedRegister64(IR::Block&, IR::Inst* inst) {
Arm::ExtReg reg = inst->GetArg(0).GetExtRegRef();
ASSERT(Arm::IsDoubleExtReg(reg));
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Xbyak::Xmm result = reg_alloc.DefXmm(inst);
code->movsd(result, MJitStateExtReg(reg));
}
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void EmitX64::EmitSetRegister(IR::Block&, IR::Inst* inst) {
Arm::Reg reg = inst->GetArg(0).GetRegRef();
IR::Value arg = inst->GetArg(1);
if (arg.IsImmediate()) {
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code->mov(MJitStateReg(reg), arg.GetU32());
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} else {
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Xbyak::Reg32 to_store = reg_alloc.UseGpr(arg).cvt32();
code->mov(MJitStateReg(reg), to_store);
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}
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}
void EmitX64::EmitSetExtendedRegister32(IR::Block&, IR::Inst* inst) {
Arm::ExtReg reg = inst->GetArg(0).GetExtRegRef();
ASSERT(Arm::IsSingleExtReg(reg));
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Xbyak::Xmm source = reg_alloc.UseXmm(inst->GetArg(1));
code->movss(MJitStateExtReg(reg), source);
}
void EmitX64::EmitSetExtendedRegister64(IR::Block&, IR::Inst* inst) {
Arm::ExtReg reg = inst->GetArg(0).GetExtRegRef();
ASSERT(Arm::IsDoubleExtReg(reg));
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Xbyak::Xmm source = reg_alloc.UseXmm(inst->GetArg(1));
code->movsd(MJitStateExtReg(reg), source);
}
void EmitX64::EmitGetCpsr(IR::Block&, IR::Inst* inst) {
Xbyak::Reg32 result = reg_alloc.DefGpr(inst).cvt32();
code->mov(result, MJitStateCpsr());
}
void EmitX64::EmitSetCpsr(IR::Block&, IR::Inst* inst) {
Xbyak::Reg32 arg = reg_alloc.UseGpr(inst->GetArg(0)).cvt32();
code->mov(MJitStateCpsr(), arg);
}
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void EmitX64::EmitGetNFlag(IR::Block&, IR::Inst* inst) {
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Xbyak::Reg32 result = reg_alloc.DefGpr(inst).cvt32();
code->mov(result, MJitStateCpsr());
code->shr(result, 31);
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}
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void EmitX64::EmitSetNFlag(IR::Block&, IR::Inst* inst) {
constexpr size_t flag_bit = 31;
constexpr u32 flag_mask = 1u << flag_bit;
IR::Value arg = inst->GetArg(0);
if (arg.IsImmediate()) {
if (arg.GetU1()) {
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code->or_(MJitStateCpsr(), flag_mask);
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} else {
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code->and_(MJitStateCpsr(), ~flag_mask);
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}
} else {
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Xbyak::Reg32 to_store = reg_alloc.UseScratchGpr(arg).cvt32();
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code->shl(to_store, flag_bit);
code->and_(MJitStateCpsr(), ~flag_mask);
code->or_(MJitStateCpsr(), to_store);
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}
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}
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void EmitX64::EmitGetZFlag(IR::Block&, IR::Inst* inst) {
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Xbyak::Reg32 result = reg_alloc.DefGpr(inst).cvt32();
code->mov(result, MJitStateCpsr());
code->shr(result, 30);
code->and_(result, 1);
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}
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void EmitX64::EmitSetZFlag(IR::Block&, IR::Inst* inst) {
constexpr size_t flag_bit = 30;
constexpr u32 flag_mask = 1u << flag_bit;
IR::Value arg = inst->GetArg(0);
if (arg.IsImmediate()) {
if (arg.GetU1()) {
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code->or_(MJitStateCpsr(), flag_mask);
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} else {
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code->and_(MJitStateCpsr(), ~flag_mask);
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}
} else {
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Xbyak::Reg32 to_store = reg_alloc.UseScratchGpr(arg).cvt32();
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code->shl(to_store, flag_bit);
code->and_(MJitStateCpsr(), ~flag_mask);
code->or_(MJitStateCpsr(), to_store);
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}
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}
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void EmitX64::EmitGetCFlag(IR::Block&, IR::Inst* inst) {
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Xbyak::Reg32 result = reg_alloc.DefGpr(inst).cvt32();
code->mov(result, MJitStateCpsr());
code->shr(result, 29);
code->and_(result, 1);
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}
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void EmitX64::EmitSetCFlag(IR::Block&, IR::Inst* inst) {
constexpr size_t flag_bit = 29;
constexpr u32 flag_mask = 1u << flag_bit;
IR::Value arg = inst->GetArg(0);
if (arg.IsImmediate()) {
if (arg.GetU1()) {
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code->or_(MJitStateCpsr(), flag_mask);
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} else {
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code->and_(MJitStateCpsr(), ~flag_mask);
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}
} else {
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Xbyak::Reg32 to_store = reg_alloc.UseScratchGpr(arg).cvt32();
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code->shl(to_store, flag_bit);
code->and_(MJitStateCpsr(), ~flag_mask);
code->or_(MJitStateCpsr(), to_store);
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}
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}
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void EmitX64::EmitGetVFlag(IR::Block&, IR::Inst* inst) {
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Xbyak::Reg32 result = reg_alloc.DefGpr(inst).cvt32();
code->mov(result, MJitStateCpsr());
code->shr(result, 28);
code->and_(result, 1);
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}
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void EmitX64::EmitSetVFlag(IR::Block&, IR::Inst* inst) {
constexpr size_t flag_bit = 28;
constexpr u32 flag_mask = 1u << flag_bit;
IR::Value arg = inst->GetArg(0);
if (arg.IsImmediate()) {
if (arg.GetU1()) {
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code->or_(MJitStateCpsr(), flag_mask);
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} else {
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code->and_(MJitStateCpsr(), ~flag_mask);
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}
} else {
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Xbyak::Reg32 to_store = reg_alloc.UseScratchGpr(arg).cvt32();
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code->shl(to_store, flag_bit);
code->and_(MJitStateCpsr(), ~flag_mask);
code->or_(MJitStateCpsr(), to_store);
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}
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}
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void EmitX64::EmitOrQFlag(IR::Block&, IR::Inst* inst) {
constexpr size_t flag_bit = 27;
constexpr u32 flag_mask = 1u << flag_bit;
IR::Value arg = inst->GetArg(0);
if (arg.IsImmediate()) {
if (arg.GetU1())
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code->or_(MJitStateCpsr(), flag_mask);
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} else {
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Xbyak::Reg32 to_store = reg_alloc.UseScratchGpr(arg).cvt32();
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code->shl(to_store, flag_bit);
code->or_(MJitStateCpsr(), to_store);
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}
}
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void EmitX64::EmitGetGEFlags(IR::Block&, IR::Inst* inst) {
Xbyak::Reg32 result = reg_alloc.DefGpr(inst).cvt32();
code->mov(result, MJitStateCpsr());
code->shr(result, 16);
code->and_(result, 0xF);
}
void EmitX64::EmitSetGEFlags(IR::Block&, IR::Inst* inst) {
constexpr size_t flag_bit = 16;
constexpr u32 flag_mask = 0xFu << flag_bit;
IR::Value arg = inst->GetArg(0);
if (arg.IsImmediate()) {
u32 imm = (arg.GetU32() << flag_bit) & flag_mask;
code->and_(MJitStateCpsr(), ~flag_mask);
code->or_(MJitStateCpsr(), imm);
} else {
Xbyak::Reg32 to_store = reg_alloc.UseScratchGpr(arg).cvt32();
code->shl(to_store, flag_bit);
code->and_(to_store, flag_mask);
code->and_(MJitStateCpsr(), ~flag_mask);
code->or_(MJitStateCpsr(), to_store);
}
}
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void EmitX64::EmitBXWritePC(IR::Block&, IR::Inst* inst) {
const u32 T_bit = 1 << 5;
auto arg = inst->GetArg(0);
// Pseudocode:
// if (new_pc & 1) {
// new_pc &= 0xFFFFFFFE;
// cpsr.T = true;
// } else {
// new_pc &= 0xFFFFFFFC;
// cpsr.T = false;
// }
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if (arg.IsImmediate()) {
u32 new_pc = arg.GetU32();
if (Common::Bit<0>(new_pc)) {
new_pc &= 0xFFFFFFFE;
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code->mov(MJitStateReg(Arm::Reg::PC), new_pc);
code->or_(MJitStateCpsr(), T_bit);
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} else {
new_pc &= 0xFFFFFFFC;
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code->mov(MJitStateReg(Arm::Reg::PC), new_pc);
code->and_(MJitStateCpsr(), ~T_bit);
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}
} else {
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using Xbyak::util::ptr;
Xbyak::Reg64 new_pc = reg_alloc.UseScratchGpr(arg);
Xbyak::Reg64 tmp1 = reg_alloc.ScratchGpr();
Xbyak::Reg64 tmp2 = reg_alloc.ScratchGpr();
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code->mov(tmp1, MJitStateCpsr());
code->mov(tmp2, tmp1);
code->and_(tmp2, u32(~T_bit)); // CPSR.T = 0
code->or_(tmp1, u32(T_bit)); // CPSR.T = 1
code->test(new_pc, u32(1));
code->cmove(tmp1, tmp2); // CPSR.T = pc & 1
code->mov(MJitStateCpsr(), tmp1);
code->lea(tmp2, ptr[new_pc + new_pc * 1]);
code->or_(tmp2, u32(0xFFFFFFFC)); // tmp2 = pc & 1 ? 0xFFFFFFFE : 0xFFFFFFFC
code->and_(new_pc, tmp2);
code->mov(MJitStateReg(Arm::Reg::PC), new_pc);
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}
}
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void EmitX64::EmitCallSupervisor(IR::Block&, IR::Inst* inst) {
auto imm32 = inst->GetArg(0);
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reg_alloc.HostCall(nullptr, imm32);
code->SwitchMxcsrOnExit();
code->CallFunction(cb.CallSVC);
code->SwitchMxcsrOnEntry();
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}
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static u32 GetFpscrImpl(JitState* jit_state) {
return jit_state->Fpscr();
}
void EmitX64::EmitGetFpscr(IR::Block&, IR::Inst* inst) {
reg_alloc.HostCall(inst);
code->mov(code->ABI_PARAM1, code->r15);
code->SwitchMxcsrOnExit();
code->CallFunction(&GetFpscrImpl);
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code->SwitchMxcsrOnEntry();
}
static void SetFpscrImpl(u32 value, JitState* jit_state) {
jit_state->SetFpscr(value);
}
void EmitX64::EmitSetFpscr(IR::Block&, IR::Inst* inst) {
auto a = inst->GetArg(0);
reg_alloc.HostCall(nullptr, a);
code->mov(code->ABI_PARAM2, code->r15);
code->SwitchMxcsrOnExit();
code->CallFunction(&SetFpscrImpl);
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code->SwitchMxcsrOnEntry();
}
void EmitX64::EmitGetFpscrNZCV(IR::Block&, IR::Inst* inst) {
using namespace Xbyak::util;
Xbyak::Reg32 result = reg_alloc.DefGpr(inst).cvt32();
code->mov(result, dword[r15 + offsetof(JitState, FPSCR_nzcv)]);
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}
void EmitX64::EmitSetFpscrNZCV(IR::Block&, IR::Inst* inst) {
using namespace Xbyak::util;
Xbyak::Reg32 value = reg_alloc.UseGpr(inst->GetArg(0)).cvt32();
code->mov(dword[r15 + offsetof(JitState, FPSCR_nzcv)], value);
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}
void EmitX64::EmitPushRSB(IR::Block&, IR::Inst* inst) {
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using namespace Xbyak::util;
ASSERT(inst->GetArg(0).IsImmediate());
u64 imm64 = inst->GetArg(0).GetU64();
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Xbyak::Reg64 code_ptr_reg = reg_alloc.ScratchGpr({HostLoc::RCX});
Xbyak::Reg64 loc_desc_reg = reg_alloc.ScratchGpr();
Xbyak::Reg32 index_reg = reg_alloc.ScratchGpr().cvt32();
u64 code_ptr = unique_hash_to_code_ptr.find(imm64) != unique_hash_to_code_ptr.end()
? u64(unique_hash_to_code_ptr[imm64])
: u64(code->GetReturnFromRunCodeAddress());
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code->mov(index_reg, dword[r15 + offsetof(JitState, rsb_ptr)]);
code->add(index_reg, 1);
code->and_(index_reg, u32(JitState::RSBSize - 1));
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code->mov(loc_desc_reg, u64(imm64));
CodePtr patch_location = code->getCurr<CodePtr>();
patch_unique_hash_locations[imm64].emplace_back(patch_location);
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code->mov(code_ptr_reg, u64(code_ptr)); // This line has to match up with EmitX64::Patch.
code->EnsurePatchLocationSize(patch_location, 10);
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Xbyak::Label label;
for (size_t i = 0; i < JitState::RSBSize; ++i) {
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code->cmp(loc_desc_reg, qword[r15 + offsetof(JitState, rsb_location_descriptors) + i * sizeof(u64)]);
code->je(label, code->T_SHORT);
}
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code->mov(dword[r15 + offsetof(JitState, rsb_ptr)], index_reg);
code->mov(qword[r15 + index_reg.cvt64() * 8 + offsetof(JitState, rsb_location_descriptors)], loc_desc_reg);
code->mov(qword[r15 + index_reg.cvt64() * 8 + offsetof(JitState, rsb_codeptrs)], code_ptr_reg);
code->L(label);
}
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void EmitX64::EmitGetCarryFromOp(IR::Block&, IR::Inst*) {
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ASSERT_MSG(false, "should never happen");
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}
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void EmitX64::EmitGetOverflowFromOp(IR::Block&, IR::Inst*) {
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ASSERT_MSG(false, "should never happen");
}
void EmitX64::EmitGetGEFromOp(IR::Block&, IR::Inst*) {
ASSERT_MSG(false, "should never happen");
}
void EmitX64::EmitPack2x32To1x64(IR::Block&, IR::Inst* inst) {
OpArg lo;
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Xbyak::Reg64 result;
if (inst->GetArg(0).IsImmediate()) {
// TODO: Optimize
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result = reg_alloc.UseDefGpr(inst->GetArg(0), inst);
lo = result.cvt32();
} else {
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std::tie(lo, result) = reg_alloc.UseDefOpArgGpr(inst->GetArg(0), inst);
}
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lo.setBit(32);
Xbyak::Reg64 hi = reg_alloc.UseScratchGpr(inst->GetArg(1));
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code->shl(hi, 32);
code->mov(result.cvt32(), *lo); // Zero extend to 64-bits
code->or_(result, hi);
}
void EmitX64::EmitLeastSignificantWord(IR::Block&, IR::Inst* inst) {
reg_alloc.RegisterAddDef(inst, inst->GetArg(0));
}
void EmitX64::EmitMostSignificantWord(IR::Block& block, IR::Inst* inst) {
auto carry_inst = inst->GetAssociatedPseudoOperation(IR::Opcode::GetCarryFromOp);
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Xbyak::Reg64 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst);
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code->shr(result, 32);
if (carry_inst) {
EraseInstruction(block, carry_inst);
inst->DecrementRemainingUses();
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Xbyak::Reg64 carry = reg_alloc.DefGpr(carry_inst);
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code->setc(carry.cvt8());
}
}
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void EmitX64::EmitLeastSignificantHalf(IR::Block&, IR::Inst* inst) {
reg_alloc.RegisterAddDef(inst, inst->GetArg(0));
}
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void EmitX64::EmitLeastSignificantByte(IR::Block&, IR::Inst* inst) {
reg_alloc.RegisterAddDef(inst, inst->GetArg(0));
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}
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void EmitX64::EmitMostSignificantBit(IR::Block&, IR::Inst* inst) {
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
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// TODO: Flag optimization
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code->shr(result, 31);
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}
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void EmitX64::EmitIsZero(IR::Block&, IR::Inst* inst) {
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
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// TODO: Flag optimization
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code->test(result, result);
code->sete(result.cvt8());
code->movzx(result, result.cvt8());
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}
void EmitX64::EmitIsZero64(IR::Block&, IR::Inst* inst) {
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Xbyak::Reg64 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst);
// TODO: Flag optimization
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code->test(result, result);
code->sete(result.cvt8());
code->movzx(result, result.cvt8());
}
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void EmitX64::EmitLogicalShiftLeft(IR::Block& block, IR::Inst* inst) {
auto carry_inst = inst->GetAssociatedPseudoOperation(IR::Opcode::GetCarryFromOp);
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// TODO: Consider using BMI2 instructions like SHLX when arm-in-host flags is implemented.
if (!carry_inst) {
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if (!inst->GetArg(2).IsImmediate()) {
// TODO: Remove redundant argument.
inst->GetArg(2).GetInst()->DecrementRemainingUses();
2016-07-22 23:55:00 +01:00
}
auto shift_arg = inst->GetArg(1);
if (shift_arg.IsImmediate()) {
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
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u8 shift = shift_arg.GetU8();
if (shift <= 31) {
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code->shl(result, shift);
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} else {
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code->xor_(result, result);
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}
} else {
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Xbyak::Reg8 shift = reg_alloc.UseGpr(shift_arg, {HostLoc::RCX}).cvt8();
Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
Xbyak::Reg32 zero = reg_alloc.ScratchGpr().cvt32();
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// The 32-bit x64 SHL instruction masks the shift count by 0x1F before performing the shift.
// ARM differs from the behaviour: It does not mask the count, so shifts above 31 result in zeros.
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code->shl(result, shift);
code->xor_(zero, zero);
code->cmp(shift, 32);
code->cmovnb(result, zero);
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}
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} else {
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EraseInstruction(block, carry_inst);
inst->DecrementRemainingUses();
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auto shift_arg = inst->GetArg(1);
if (shift_arg.IsImmediate()) {
u8 shift = shift_arg.GetU8();
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
Xbyak::Reg32 carry = reg_alloc.UseDefGpr(inst->GetArg(2), carry_inst).cvt32();
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if (shift == 0) {
// There is nothing more to do.
} else if (shift < 32) {
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code->bt(carry.cvt32(), 0);
code->shl(result, shift);
code->setc(carry.cvt8());
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} else if (shift > 32) {
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code->xor_(result, result);
code->xor_(carry, carry);
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} else {
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code->mov(carry, result);
code->xor_(result, result);
code->and_(carry, 1);
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}
} else {
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Xbyak::Reg8 shift = reg_alloc.UseGpr(shift_arg, {HostLoc::RCX}).cvt8();
Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
Xbyak::Reg32 carry = reg_alloc.UseDefGpr(inst->GetArg(2), carry_inst).cvt32();
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// TODO: Optimize this.
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code->inLocalLabel();
code->cmp(shift, 32);
code->ja(".Rs_gt32");
code->je(".Rs_eq32");
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// if (Rs & 0xFF < 32) {
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code->bt(carry.cvt32(), 0); // Set the carry flag for correct behaviour in the case when Rs & 0xFF == 0
code->shl(result, shift);
code->setc(carry.cvt8());
code->jmp(".end");
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// } else if (Rs & 0xFF > 32) {
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code->L(".Rs_gt32");
code->xor_(result, result);
code->xor_(carry, carry);
code->jmp(".end");
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// } else if (Rs & 0xFF == 32) {
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code->L(".Rs_eq32");
code->mov(carry, result);
code->and_(carry, 1);
code->xor_(result, result);
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// }
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code->L(".end");
code->outLocalLabel();
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}
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}
}
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void EmitX64::EmitLogicalShiftRight(IR::Block& block, IR::Inst* inst) {
auto carry_inst = inst->GetAssociatedPseudoOperation(IR::Opcode::GetCarryFromOp);
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if (!carry_inst) {
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if (!inst->GetArg(2).IsImmediate()) {
// TODO: Remove redundant argument.
inst->GetArg(2).GetInst()->DecrementRemainingUses();
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}
auto shift_arg = inst->GetArg(1);
if (shift_arg.IsImmediate()) {
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
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u8 shift = shift_arg.GetU8();
if (shift <= 31) {
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code->shr(result, shift);
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} else {
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code->xor_(result, result);
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}
} else {
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Xbyak::Reg8 shift = reg_alloc.UseGpr(shift_arg, {HostLoc::RCX}).cvt8();
Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
Xbyak::Reg32 zero = reg_alloc.ScratchGpr().cvt32();
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// The 32-bit x64 SHR instruction masks the shift count by 0x1F before performing the shift.
// ARM differs from the behaviour: It does not mask the count, so shifts above 31 result in zeros.
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code->shr(result, shift);
code->xor_(zero, zero);
code->cmp(shift, 32);
code->cmovnb(result, zero);
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}
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} else {
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EraseInstruction(block, carry_inst);
inst->DecrementRemainingUses();
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auto shift_arg = inst->GetArg(1);
if (shift_arg.IsImmediate()) {
u8 shift = shift_arg.GetU8();
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
Xbyak::Reg32 carry = reg_alloc.UseDefGpr(inst->GetArg(2), carry_inst).cvt32();
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if (shift == 0) {
// There is nothing more to do.
} else if (shift < 32) {
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code->shr(result, shift);
code->setc(carry.cvt8());
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} else if (shift == 32) {
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code->bt(result, 31);
code->setc(carry.cvt8());
code->mov(result, 0);
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} else {
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code->xor_(result, result);
code->xor_(carry, carry);
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}
} else {
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Xbyak::Reg8 shift = reg_alloc.UseGpr(shift_arg, {HostLoc::RCX}).cvt8();
Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
Xbyak::Reg32 carry = reg_alloc.UseDefGpr(inst->GetArg(2), carry_inst).cvt32();
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// TODO: Optimize this.
2016-08-24 20:07:08 +01:00
code->inLocalLabel();
code->cmp(shift, 32);
code->ja(".Rs_gt32");
code->je(".Rs_eq32");
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// if (Rs & 0xFF == 0) goto end;
2016-08-24 20:07:08 +01:00
code->test(shift, shift);
code->jz(".end");
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// if (Rs & 0xFF < 32) {
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code->shr(result, shift);
code->setc(carry.cvt8());
code->jmp(".end");
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// } else if (Rs & 0xFF > 32) {
2016-08-24 20:07:08 +01:00
code->L(".Rs_gt32");
code->xor_(result, result);
code->xor_(carry, carry);
code->jmp(".end");
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// } else if (Rs & 0xFF == 32) {
2016-08-24 20:07:08 +01:00
code->L(".Rs_eq32");
code->bt(result, 31);
code->setc(carry.cvt8());
code->xor_(result, result);
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// }
2016-08-24 20:07:08 +01:00
code->L(".end");
code->outLocalLabel();
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}
2016-07-01 14:01:06 +01:00
}
}
void EmitX64::EmitLogicalShiftRight64(IR::Block& block, IR::Inst* inst) {
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Xbyak::Reg64 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst);
auto shift_arg = inst->GetArg(1);
ASSERT_MSG(shift_arg.IsImmediate(), "variable 64 bit shifts are not implemented");
u8 shift = shift_arg.GetU8();
ASSERT_MSG(shift < 64, "shift width clamping is not implemented");
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code->shr(result.cvt64(), shift);
}
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void EmitX64::EmitArithmeticShiftRight(IR::Block& block, IR::Inst* inst) {
auto carry_inst = inst->GetAssociatedPseudoOperation(IR::Opcode::GetCarryFromOp);
if (!carry_inst) {
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if (!inst->GetArg(2).IsImmediate()) {
// TODO: Remove redundant argument.
inst->GetArg(2).GetInst()->DecrementRemainingUses();
2016-07-22 23:55:00 +01:00
}
auto shift_arg = inst->GetArg(1);
if (shift_arg.IsImmediate()) {
u8 shift = shift_arg.GetU8();
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
2016-07-22 23:55:00 +01:00
2016-08-24 20:07:08 +01:00
code->sar(result, u8(shift < 31 ? shift : 31));
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} else {
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Xbyak::Reg32 shift = reg_alloc.UseScratchGpr(shift_arg, {HostLoc::RCX}).cvt32();
Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
Xbyak::Reg32 const31 = reg_alloc.ScratchGpr().cvt32();
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// The 32-bit x64 SAR instruction masks the shift count by 0x1F before performing the shift.
// ARM differs from the behaviour: It does not mask the count.
// We note that all shift values above 31 have the same behaviour as 31 does, so we saturate `shift` to 31.
2016-08-24 20:07:08 +01:00
code->mov(const31, 31);
code->movzx(shift, shift.cvt8());
code->cmp(shift, u32(31));
code->cmovg(shift, const31);
code->sar(result, shift.cvt8());
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}
} else {
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EraseInstruction(block, carry_inst);
inst->DecrementRemainingUses();
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auto shift_arg = inst->GetArg(1);
if (shift_arg.IsImmediate()) {
u8 shift = shift_arg.GetU8();
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
Xbyak::Reg8 carry = reg_alloc.UseDefGpr(inst->GetArg(2), carry_inst).cvt8();
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if (shift == 0) {
// There is nothing more to do.
} else if (shift <= 31) {
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code->sar(result, shift);
code->setc(carry);
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} else {
2016-08-24 20:07:08 +01:00
code->sar(result, 31);
code->bt(result, 31);
code->setc(carry);
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}
} else {
2016-08-24 20:07:08 +01:00
Xbyak::Reg8 shift = reg_alloc.UseGpr(shift_arg, {HostLoc::RCX}).cvt8();
Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
Xbyak::Reg8 carry = reg_alloc.UseDefGpr(inst->GetArg(2), carry_inst).cvt8();
2016-07-22 23:55:00 +01:00
// TODO: Optimize this.
2016-08-24 20:07:08 +01:00
code->inLocalLabel();
code->cmp(shift, u32(31));
code->ja(".Rs_gt31");
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// if (Rs & 0xFF == 0) goto end;
2016-08-24 20:07:08 +01:00
code->test(shift, shift);
code->jz(".end");
2016-07-22 23:55:00 +01:00
// if (Rs & 0xFF <= 31) {
2016-08-24 20:07:08 +01:00
code->sar(result, shift);
code->setc(carry);
code->jmp(".end");
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// } else if (Rs & 0xFF > 31) {
2016-08-24 20:07:08 +01:00
code->L(".Rs_gt31");
code->sar(result, 31); // 31 produces the same results as anything above 31
code->bt(result, 31);
code->setc(carry);
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// }
2016-08-24 20:07:08 +01:00
code->L(".end");
code->outLocalLabel();
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}
2016-07-10 01:18:17 +01:00
}
}
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void EmitX64::EmitRotateRight(IR::Block& block, IR::Inst* inst) {
auto carry_inst = inst->GetAssociatedPseudoOperation(IR::Opcode::GetCarryFromOp);
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if (!carry_inst) {
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if (!inst->GetArg(2).IsImmediate()) {
// TODO: Remove redundant argument.
inst->GetArg(2).GetInst()->DecrementRemainingUses();
2016-07-22 23:55:00 +01:00
}
auto shift_arg = inst->GetArg(1);
if (shift_arg.IsImmediate()) {
u8 shift = shift_arg.GetU8();
2016-08-24 20:07:08 +01:00
Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
2016-07-10 01:18:17 +01:00
2016-08-24 20:07:08 +01:00
code->ror(result, u8(shift & 0x1F));
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} else {
2016-08-24 20:07:08 +01:00
Xbyak::Reg8 shift = reg_alloc.UseGpr(shift_arg, {HostLoc::RCX}).cvt8();
Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
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// x64 ROR instruction does (shift & 0x1F) for us.
2016-08-24 20:07:08 +01:00
code->ror(result, shift);
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}
2016-07-10 01:18:17 +01:00
} else {
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EraseInstruction(block, carry_inst);
inst->DecrementRemainingUses();
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auto shift_arg = inst->GetArg(1);
if (shift_arg.IsImmediate()) {
u8 shift = shift_arg.GetU8();
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
Xbyak::Reg8 carry = reg_alloc.UseDefGpr(inst->GetArg(2), carry_inst).cvt8();
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if (shift == 0) {
// There is nothing more to do.
} else if ((shift & 0x1F) == 0) {
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code->bt(result, u8(31));
code->setc(carry);
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} else {
2016-08-24 20:07:08 +01:00
code->ror(result, shift);
code->setc(carry);
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}
} else {
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Xbyak::Reg8 shift = reg_alloc.UseScratchGpr(shift_arg, {HostLoc::RCX}).cvt8();
Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
Xbyak::Reg8 carry = reg_alloc.UseDefGpr(inst->GetArg(2), carry_inst).cvt8();
2016-07-22 23:55:00 +01:00
// TODO: Optimize
2016-08-24 20:07:08 +01:00
code->inLocalLabel();
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// if (Rs & 0xFF == 0) goto end;
2016-08-24 20:07:08 +01:00
code->test(shift, shift);
code->jz(".end");
2016-07-22 23:55:00 +01:00
2016-08-24 20:07:08 +01:00
code->and_(shift.cvt32(), u32(0x1F));
code->jz(".zero_1F");
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// if (Rs & 0x1F != 0) {
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code->ror(result, shift);
code->setc(carry);
code->jmp(".end");
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// } else {
2016-08-24 20:07:08 +01:00
code->L(".zero_1F");
code->bt(result, u8(31));
code->setc(carry);
2016-07-22 23:55:00 +01:00
// }
2016-08-24 20:07:08 +01:00
code->L(".end");
code->outLocalLabel();
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}
}
}
void EmitX64::EmitRotateRightExtended(IR::Block& block, IR::Inst* inst) {
auto carry_inst = inst->GetAssociatedPseudoOperation(IR::Opcode::GetCarryFromOp);
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
Xbyak::Reg8 carry = carry_inst
? reg_alloc.UseDefGpr(inst->GetArg(1), carry_inst).cvt8()
: reg_alloc.UseGpr(inst->GetArg(1)).cvt8();
2016-08-24 20:07:08 +01:00
code->bt(carry.cvt32(), 0);
code->rcr(result, 1);
if (carry_inst) {
EraseInstruction(block, carry_inst);
inst->DecrementRemainingUses();
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code->setc(carry);
}
}
2016-08-24 20:07:08 +01:00
const Xbyak::Reg64 INVALID_REG = Xbyak::Reg64(-1);
static Xbyak::Reg8 DoCarry(RegAlloc& reg_alloc, const IR::Value& carry_in, IR::Inst* carry_out) {
2016-07-22 23:55:00 +01:00
if (carry_in.IsImmediate()) {
2016-08-24 20:07:08 +01:00
return carry_out ? reg_alloc.DefGpr(carry_out).cvt8() : INVALID_REG.cvt8();
2016-07-22 23:55:00 +01:00
} else {
2016-08-24 20:07:08 +01:00
return carry_out ? reg_alloc.UseDefGpr(carry_in, carry_out).cvt8() : reg_alloc.UseGpr(carry_in).cvt8();
2016-07-22 23:55:00 +01:00
}
}
void EmitX64::EmitAddWithCarry(IR::Block& block, IR::Inst* inst) {
auto carry_inst = inst->GetAssociatedPseudoOperation(IR::Opcode::GetCarryFromOp);
auto overflow_inst = inst->GetAssociatedPseudoOperation(IR::Opcode::GetOverflowFromOp);
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IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
IR::Value carry_in = inst->GetArg(2);
2016-08-24 20:07:08 +01:00
Xbyak::Reg32 result = reg_alloc.UseDefGpr(a, inst).cvt32();
Xbyak::Reg8 carry = DoCarry(reg_alloc, carry_in, carry_inst);
Xbyak::Reg8 overflow = overflow_inst ? reg_alloc.DefGpr(overflow_inst).cvt8() : INVALID_REG.cvt8();
// TODO: Consider using LEA.
2016-08-24 20:07:08 +01:00
if (b.IsImmediate()) {
u32 op_arg = b.GetU32();
if (carry_in.IsImmediate()) {
if (carry_in.GetU1()) {
code->stc();
code->adc(result, op_arg);
} else {
code->add(result, op_arg);
}
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} else {
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code->bt(carry.cvt32(), 0);
code->adc(result, op_arg);
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}
} else {
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OpArg op_arg = reg_alloc.UseOpArg(b, any_gpr);
op_arg.setBit(32);
if (carry_in.IsImmediate()) {
if (carry_in.GetU1()) {
code->stc();
code->adc(result, *op_arg);
} else {
code->add(result, *op_arg);
}
} else {
code->bt(carry.cvt32(), 0);
code->adc(result, *op_arg);
}
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}
if (carry_inst) {
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EraseInstruction(block, carry_inst);
inst->DecrementRemainingUses();
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code->setc(carry);
}
if (overflow_inst) {
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EraseInstruction(block, overflow_inst);
inst->DecrementRemainingUses();
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code->seto(overflow);
}
}
void EmitX64::EmitAdd64(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
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Xbyak::Reg64 result = reg_alloc.UseDefGpr(a, inst);
Xbyak::Reg64 op_arg = reg_alloc.UseGpr(b);
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code->add(result, op_arg);
}
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void EmitX64::EmitSubWithCarry(IR::Block& block, IR::Inst* inst) {
auto carry_inst = inst->GetAssociatedPseudoOperation(IR::Opcode::GetCarryFromOp);
auto overflow_inst = inst->GetAssociatedPseudoOperation(IR::Opcode::GetOverflowFromOp);
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IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
IR::Value carry_in = inst->GetArg(2);
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(a, inst).cvt32();
Xbyak::Reg8 carry = DoCarry(reg_alloc, carry_in, carry_inst);
Xbyak::Reg8 overflow = overflow_inst ? reg_alloc.DefGpr(overflow_inst).cvt8() : INVALID_REG.cvt8();
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// TODO: Consider using LEA.
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// TODO: Optimize CMP case.
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// Note that x64 CF is inverse of what the ARM carry flag is here.
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if (b.IsImmediate()) {
u32 op_arg = b.GetU32();
if (carry_in.IsImmediate()) {
if (carry_in.GetU1()) {
code->sub(result, op_arg);
} else {
code->stc();
code->sbb(result, op_arg);
}
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} else {
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code->bt(carry.cvt32(), 0);
code->cmc();
code->sbb(result, op_arg);
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}
} else {
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OpArg op_arg = reg_alloc.UseOpArg(b, any_gpr);
op_arg.setBit(32);
if (carry_in.IsImmediate()) {
if (carry_in.GetU1()) {
code->sub(result, *op_arg);
} else {
code->stc();
code->sbb(result, *op_arg);
}
} else {
code->bt(carry.cvt32(), 0);
code->cmc();
code->sbb(result, *op_arg);
}
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}
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if (carry_inst) {
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EraseInstruction(block, carry_inst);
inst->DecrementRemainingUses();
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code->setnc(carry);
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}
if (overflow_inst) {
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EraseInstruction(block, overflow_inst);
inst->DecrementRemainingUses();
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code->seto(overflow);
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}
}
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void EmitX64::EmitSub64(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
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Xbyak::Reg64 result = reg_alloc.UseDefGpr(a, inst);
Xbyak::Reg64 op_arg = reg_alloc.UseGpr(b);
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code->sub(result, op_arg);
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}
void EmitX64::EmitMul(IR::Block&, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
if (a.IsImmediate())
std::swap(a, b);
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(a, inst).cvt32();
if (b.IsImmediate()) {
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code->imul(result, result, b.GetU32());
} else {
OpArg op_arg = reg_alloc.UseOpArg(b, any_gpr);
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op_arg.setBit(32);
code->imul(result, *op_arg);
}
}
void EmitX64::EmitMul64(IR::Block&, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
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Xbyak::Reg64 result = reg_alloc.UseDefGpr(a, inst);
OpArg op_arg = reg_alloc.UseOpArg(b, any_gpr);
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code->imul(result, *op_arg);
}
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void EmitX64::EmitAnd(IR::Block&, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(a, inst).cvt32();
if (b.IsImmediate()) {
u32 op_arg = b.GetU32();
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code->and_(result, op_arg);
} else {
OpArg op_arg = reg_alloc.UseOpArg(b, any_gpr);
op_arg.setBit(32);
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code->and_(result, *op_arg);
}
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}
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void EmitX64::EmitEor(IR::Block&, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(a, inst).cvt32();
if (b.IsImmediate()) {
u32 op_arg = b.GetU32();
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code->xor_(result, op_arg);
} else {
OpArg op_arg = reg_alloc.UseOpArg(b, any_gpr);
op_arg.setBit(32);
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code->xor_(result, *op_arg);
}
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}
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void EmitX64::EmitOr(IR::Block&, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(a, inst).cvt32();
if (b.IsImmediate()) {
u32 op_arg = b.GetU32();
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code->or_(result, op_arg);
} else {
OpArg op_arg = reg_alloc.UseOpArg(b, any_gpr);
op_arg.setBit(32);
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code->or_(result, *op_arg);
}
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}
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void EmitX64::EmitNot(IR::Block&, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
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if (a.IsImmediate()) {
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Xbyak::Reg32 result = reg_alloc.DefGpr(inst).cvt32();
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code->mov(result, u32(~a.GetU32()));
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} else {
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(a, inst).cvt32();
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code->not_(result);
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}
}
void EmitX64::EmitSignExtendWordToLong(IR::Block&, IR::Inst* inst) {
OpArg source;
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Xbyak::Reg64 result;
if (inst->GetArg(0).IsImmediate()) {
// TODO: Optimize
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result = reg_alloc.UseDefGpr(inst->GetArg(0), inst);
source = result;
} else {
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std::tie(source, result) = reg_alloc.UseDefOpArgGpr(inst->GetArg(0), inst);
}
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source.setBit(32);
code->movsxd(result.cvt64(), *source);
}
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void EmitX64::EmitSignExtendHalfToWord(IR::Block&, IR::Inst* inst) {
OpArg source;
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Xbyak::Reg64 result;
if (inst->GetArg(0).IsImmediate()) {
// TODO: Optimize
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result = reg_alloc.UseDefGpr(inst->GetArg(0), inst);
source = result;
} else {
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std::tie(source, result) = reg_alloc.UseDefOpArgGpr(inst->GetArg(0), inst);
}
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source.setBit(16);
code->movsx(result.cvt32(), *source);
}
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void EmitX64::EmitSignExtendByteToWord(IR::Block&, IR::Inst* inst) {
OpArg source;
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Xbyak::Reg64 result;
if (inst->GetArg(0).IsImmediate()) {
// TODO: Optimize
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result = reg_alloc.UseDefGpr(inst->GetArg(0), inst);
source = result;
} else {
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std::tie(source, result) = reg_alloc.UseDefOpArgGpr(inst->GetArg(0), inst);
}
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source.setBit(8);
code->movsx(result.cvt32(), *source);
}
void EmitX64::EmitZeroExtendWordToLong(IR::Block&, IR::Inst* inst) {
OpArg source;
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Xbyak::Reg64 result;
if (inst->GetArg(0).IsImmediate()) {
// TODO: Optimize
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result = reg_alloc.UseDefGpr(inst->GetArg(0), inst);
source = result;
} else {
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std::tie(source, result) = reg_alloc.UseDefOpArgGpr(inst->GetArg(0), inst);
}
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source.setBit(32);
code->mov(result.cvt32(), *source); // x64 zeros upper 32 bits on a 32-bit move
}
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void EmitX64::EmitZeroExtendHalfToWord(IR::Block&, IR::Inst* inst) {
OpArg source;
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Xbyak::Reg64 result;
if (inst->GetArg(0).IsImmediate()) {
// TODO: Optimize
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result = reg_alloc.UseDefGpr(inst->GetArg(0), inst);
source = result;
} else {
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std::tie(source, result) = reg_alloc.UseDefOpArgGpr(inst->GetArg(0), inst);
}
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source.setBit(16);
code->movzx(result.cvt32(), *source);
}
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void EmitX64::EmitZeroExtendByteToWord(IR::Block&, IR::Inst* inst) {
OpArg source;
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Xbyak::Reg64 result;
if (inst->GetArg(0).IsImmediate()) {
// TODO: Optimize
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result = reg_alloc.UseDefGpr(inst->GetArg(0), inst);
source = result;
} else {
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std::tie(source, result) = reg_alloc.UseDefOpArgGpr(inst->GetArg(0), inst);
}
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source.setBit(8);
code->movzx(result.cvt32(), *source);
}
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void EmitX64::EmitByteReverseWord(IR::Block&, IR::Inst* inst) {
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Xbyak::Reg32 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt32();
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code->bswap(result);
}
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void EmitX64::EmitByteReverseHalf(IR::Block&, IR::Inst* inst) {
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Xbyak::Reg16 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst).cvt16();
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code->rol(result, 8);
}
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void EmitX64::EmitByteReverseDual(IR::Block&, IR::Inst* inst) {
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Xbyak::Reg64 result = reg_alloc.UseDefGpr(inst->GetArg(0), inst);
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code->bswap(result);
}
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void EmitX64::EmitPackedAddU8(IR::Block& block, IR::Inst* inst) {
auto ge_inst = inst->GetAssociatedPseudoOperation(IR::Opcode::GetGEFromOp);
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IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
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Xbyak::Reg32 reg_a = reg_alloc.UseScratchGpr(a).cvt32();
Xbyak::Reg32 reg_b = reg_alloc.UseScratchGpr(b).cvt32();
Xbyak::Reg32 result = reg_alloc.DefGpr(inst).cvt32();
Xbyak::Reg32 reg_ge, tmp;
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if (ge_inst) {
EraseInstruction(block, ge_inst);
inst->DecrementRemainingUses();
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reg_ge = reg_alloc.DefGpr(ge_inst).cvt32();
tmp = reg_alloc.ScratchGpr().cvt32();
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code->mov(reg_ge, reg_a);
code->and_(reg_ge, reg_b);
}
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// SWAR Arithmetic
code->mov(result, reg_a);
code->xor_(result, reg_b);
code->and_(result, 0x80808080);
code->and_(reg_a, 0x7F7F7F7F);
code->and_(reg_b, 0x7F7F7F7F);
code->add(reg_a, reg_b);
if (ge_inst) {
code->mov(tmp, result);
code->and_(tmp, reg_a);
code->or_(reg_ge, tmp);
}
code->xor_(result, reg_a);
if (ge_inst) {
if (cpu_info.has(Xbyak::util::Cpu::tBMI2)) {
code->mov(tmp, 0x80808080);
code->pext(reg_ge, reg_ge, tmp);
} else {
code->and_(reg_ge, 0x80808080);
code->imul(reg_ge, reg_ge, 0x0204081);
code->shr(reg_ge, 28);
}
}
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}
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void EmitX64::EmitPackedSubU8(IR::Block& block, IR::Inst* inst) {
auto ge_inst = inst->GetAssociatedPseudoOperation(IR::Opcode::GetGEFromOp);
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
Xbyak::Reg32 reg_a = reg_alloc.UseDefGpr(a, inst).cvt32();
Xbyak::Reg32 reg_b = reg_alloc.UseGpr(b).cvt32();
Xbyak::Reg32 reg_ge;
Xbyak::Xmm xmm_a = reg_alloc.ScratchXmm();
Xbyak::Xmm xmm_b = reg_alloc.ScratchXmm();
Xbyak::Xmm xmm_ge;
if (ge_inst) {
EraseInstruction(block, ge_inst);
inst->DecrementRemainingUses();
reg_ge = reg_alloc.DefGpr(ge_inst).cvt32();
xmm_ge = reg_alloc.ScratchXmm();
}
code->movd(xmm_a, reg_a);
code->movd(xmm_b, reg_b);
if (ge_inst) {
code->movdqa(xmm_ge, xmm_a);
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code->pmaxub(xmm_ge, xmm_b);
code->pcmpeqb(xmm_ge, xmm_a);
code->movd(reg_ge, xmm_ge);
}
code->psubb(xmm_a, xmm_b);
code->movd(reg_a, xmm_a);
if (ge_inst) {
if (cpu_info.has(Xbyak::util::Cpu::tBMI2)) {
Xbyak::Reg32 tmp = reg_alloc.ScratchGpr().cvt32();
code->mov(tmp, 0x80808080);
code->pext(reg_ge, reg_ge, tmp);
} else {
code->and_(reg_ge, 0x80808080);
code->imul(reg_ge, reg_ge, 0x0204081);
code->shr(reg_ge, 28);
}
}
}
void EmitX64::EmitPackedHalvingAddU8(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
// This code path requires SSSE3 because of the PSHUFB instruction.
// A fallback implementation is provided below.
if (cpu_info.has(Xbyak::util::Cpu::tSSSE3)) {
Xbyak::Reg32 result = reg_alloc.UseDefGpr(a, inst).cvt32();
Xbyak::Reg32 arg = reg_alloc.UseGpr(b).cvt32();
// Load the operands into Xmm registers
Xbyak::Xmm xmm_scratch_a = reg_alloc.ScratchXmm();
Xbyak::Xmm xmm_scratch_b = reg_alloc.ScratchXmm();
Xbyak::Xmm xmm_mask = reg_alloc.ScratchXmm();
Xbyak::Reg64 mask = reg_alloc.ScratchGpr();
code->movd(xmm_scratch_a, result);
code->movd(xmm_scratch_b, arg);
// Set the mask to expand the values
// 0xAABBCCDD becomes 0x00AA00BB00CC00DD
code->mov(mask, 0x8003800280018000);
code->movq(xmm_mask, mask);
// Expand each 8-bit value to 16-bit
code->pshufb(xmm_scratch_a, xmm_mask);
code->pshufb(xmm_scratch_b, xmm_mask);
// Add the individual 16-bit values
code->paddw(xmm_scratch_a, xmm_scratch_b);
// Shift the 16-bit values to the right to halve them
code->psrlw(xmm_scratch_a, 1);
// Set the mask to pack the values again
// 0x00AA00BB00CC00DD becomes 0xAABBCCDD
code->mov(mask, 0x06040200);
code->movq(xmm_mask, mask);
// Shuffle them back to 8-bit values
code->pshufb(xmm_scratch_a, xmm_mask);
code->movd(result, xmm_scratch_a);
return;
}
// Fallback implementation in case the CPU doesn't support SSSE3
Xbyak::Reg32 reg_a = reg_alloc.UseDefGpr(a, inst).cvt32();
Xbyak::Reg32 reg_b = reg_alloc.UseGpr(b).cvt32();
Xbyak::Reg32 xor_a_b = reg_alloc.ScratchGpr().cvt32();
Xbyak::Reg32 and_a_b = reg_a;
Xbyak::Reg32 result = reg_a;
code->mov(xor_a_b, reg_a);
code->and(and_a_b, reg_b);
code->xor(xor_a_b, reg_b);
code->shr(xor_a_b, 1);
code->and(xor_a_b, 0x7F7F7F7F);
code->add(result, xor_a_b);
}
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void EmitX64::EmitPackedHalvingAddU16(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
Xbyak::Reg32 reg_a = reg_alloc.UseDefGpr(a, inst).cvt32();
Xbyak::Reg32 reg_b = reg_alloc.UseGpr(b).cvt32();
Xbyak::Reg32 xor_a_b = reg_alloc.ScratchGpr().cvt32();
Xbyak::Reg32 and_a_b = reg_a;
Xbyak::Reg32 result = reg_a;
// This relies on the equality x+y == ((x&y) << 1) + (x^y).
// Note that x^y always contains the LSB of the result.
// Since we want to calculate (x+y)/2, we can instead calculate (x&y) + ((x^y)>>1).
// We mask by 0x7FFF to remove the LSB so that it doesn't leak into the field below.
code->mov(xor_a_b, reg_a);
code->and(and_a_b, reg_b);
code->xor(xor_a_b, reg_b);
code->shr(xor_a_b, 1);
code->and(xor_a_b, 0x7FFF7FFF);
code->add(result, xor_a_b);
}
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void EmitX64::EmitPackedHalvingAddS8(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
Xbyak::Reg32 reg_a = reg_alloc.UseDefGpr(a, inst).cvt32();
Xbyak::Reg32 reg_b = reg_alloc.UseGpr(b).cvt32();
Xbyak::Reg32 xor_a_b = reg_alloc.ScratchGpr().cvt32();
Xbyak::Reg32 and_a_b = reg_a;
Xbyak::Reg32 result = reg_a;
Xbyak::Reg32 carry = reg_alloc.ScratchGpr().cvt32();
// This relies on the equality x+y == ((x&y) << 1) + (x^y).
// Note that x^y always contains the LSB of the result.
// Since we want to calculate (x+y)/2, we can instead calculate (x&y) + ((x^y)>>1).
// We mask by 0x7F to remove the LSB so that it doesn't leak into the field below.
// carry propagates the sign bit from (x^y)>>1 upwards by one.
code->mov(xor_a_b, reg_a);
code->and(and_a_b, reg_b);
code->xor(xor_a_b, reg_b);
code->mov(carry, xor_a_b);
code->and(carry, 0x80808080);
code->shr(xor_a_b, 1);
code->and(xor_a_b, 0x7F7F7F7F);
code->add(result, xor_a_b);
code->xor(result, carry);
}
void EmitX64::EmitPackedHalvingAddS16(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
Xbyak::Reg32 reg_a = reg_alloc.UseDefGpr(a, inst).cvt32();
Xbyak::Reg32 reg_b = reg_alloc.UseGpr(b).cvt32();
Xbyak::Reg32 xor_a_b = reg_alloc.ScratchGpr().cvt32();
Xbyak::Reg32 and_a_b = reg_a;
Xbyak::Reg32 result = reg_a;
Xbyak::Reg32 carry = reg_alloc.ScratchGpr().cvt32();
// This relies on the equality x+y == ((x&y) << 1) + (x^y).
// Note that x^y always contains the LSB of the result.
// Since we want to calculate (x+y)/2, we can instead calculate (x&y) + ((x^y)>>1).
// We mask by 0x7FFF to remove the LSB so that it doesn't leak into the field below.
// carry propagates the sign bit from (x^y)>>1 upwards by one.
code->mov(xor_a_b, reg_a);
code->and(and_a_b, reg_b);
code->xor(xor_a_b, reg_b);
code->mov(carry, xor_a_b);
code->and(carry, 0x80008000);
code->shr(xor_a_b, 1);
code->and(xor_a_b, 0x7FFF7FFF);
code->add(result, xor_a_b);
code->xor(result, carry);
}
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void EmitX64::EmitPackedHalvingSubU8(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
Xbyak::Reg32 minuend = reg_alloc.UseDefGpr(a, inst).cvt32();
Xbyak::Reg32 subtrahend = reg_alloc.UseScratchGpr(b).cvt32();
// This relies on the equality x-y == (x^y) - (((x^y)&y) << 1).
// Note that x^y always contains the LSB of the result.
// Since we want to calculate (x+y)/2, we can instead calculate ((x^y)>>1) - ((x^y)&y).
code->xor(minuend, subtrahend);
code->and(subtrahend, minuend);
code->shr(minuend, 1);
// At this point,
// minuend := (a^b) >> 1
// subtrahend := (a^b) & b
// We must now perform a partitioned subtraction.
// We can do this because minuend contains 7 bit fields.
// We use the extra bit in minuend as a bit to borrow from; we set this bit.
// We invert this bit at the end as this tells us if that bit was borrowed from.
code->or(minuend, 0x80808080);
code->sub(minuend, subtrahend);
code->xor(minuend, 0x80808080);
// minuend now contains the desired result.
}
void EmitX64::EmitPackedHalvingSubU16(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
Xbyak::Reg32 minuend = reg_alloc.UseDefGpr(a, inst).cvt32();
Xbyak::Reg32 subtrahend = reg_alloc.UseScratchGpr(b).cvt32();
// This relies on the equality x-y == (x^y) - (((x^y)&y) << 1).
// Note that x^y always contains the LSB of the result.
// Since we want to calculate (x+y)/2, we can instead calculate ((x^y)>>1) - ((x^y)&y).
code->xor(minuend, subtrahend);
code->and(subtrahend, minuend);
code->shr(minuend, 1);
// At this point,
// minuend := (a^b) >> 1
// subtrahend := (a^b) & b
// We must now perform a partitioned subtraction.
// We can do this because minuend contains 15 bit fields.
// We use the extra bit in minuend as a bit to borrow from; we set this bit.
// We invert this bit at the end as this tells us if that bit was borrowed from.
code->or(minuend, 0x80008000);
code->sub(minuend, subtrahend);
code->xor(minuend, 0x80008000);
// minuend now contains the desired result.
}
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static void EmitPackedOperation(BlockOfCode* code, RegAlloc& reg_alloc, IR::Inst* inst, void (Xbyak::CodeGenerator::*fn)(const Xbyak::Mmx& mmx, const Xbyak::Operand&)) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
Xbyak::Reg32 result = reg_alloc.UseDefGpr(a, inst).cvt32();
Xbyak::Reg32 arg = reg_alloc.UseGpr(b).cvt32();
Xbyak::Xmm xmm_scratch_a = reg_alloc.ScratchXmm();
Xbyak::Xmm xmm_scratch_b = reg_alloc.ScratchXmm();
code->movd(xmm_scratch_a, result);
code->movd(xmm_scratch_b, arg);
(code->*fn)(xmm_scratch_a, xmm_scratch_b);
code->movd(result, xmm_scratch_a);
}
void EmitX64::EmitPackedSaturatedAddU8(IR::Block& block, IR::Inst* inst) {
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EmitPackedOperation(code, reg_alloc, inst, &Xbyak::CodeGenerator::paddusb);
}
void EmitX64::EmitPackedSaturatedAddS8(IR::Block& block, IR::Inst* inst) {
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EmitPackedOperation(code, reg_alloc, inst, &Xbyak::CodeGenerator::paddsb);
}
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void EmitX64::EmitPackedSaturatedSubU8(IR::Block& block, IR::Inst* inst) {
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EmitPackedOperation(code, reg_alloc, inst, &Xbyak::CodeGenerator::psubusb);
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}
void EmitX64::EmitPackedSaturatedSubS8(IR::Block& block, IR::Inst* inst) {
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EmitPackedOperation(code, reg_alloc, inst, &Xbyak::CodeGenerator::psubsb);
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}
void EmitX64::EmitPackedSaturatedAddU16(IR::Block& block, IR::Inst* inst) {
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EmitPackedOperation(code, reg_alloc, inst, &Xbyak::CodeGenerator::paddusw);
}
void EmitX64::EmitPackedSaturatedAddS16(IR::Block& block, IR::Inst* inst) {
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EmitPackedOperation(code, reg_alloc, inst, &Xbyak::CodeGenerator::paddsw);
}
void EmitX64::EmitPackedSaturatedSubU16(IR::Block& block, IR::Inst* inst) {
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EmitPackedOperation(code, reg_alloc, inst, &Xbyak::CodeGenerator::psubusw);
}
void EmitX64::EmitPackedSaturatedSubS16(IR::Block& block, IR::Inst* inst) {
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EmitPackedOperation(code, reg_alloc, inst, &Xbyak::CodeGenerator::psubsw);
}
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void EmitX64::EmitCountLeadingZeros(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
if (cpu_info.has(Xbyak::util::Cpu::tLZCNT)) {
Xbyak::Reg32 source = reg_alloc.UseGpr(a).cvt32();
Xbyak::Reg32 result = reg_alloc.DefGpr(inst).cvt32();
code->lzcnt(result, source);
} else {
Xbyak::Reg32 source = reg_alloc.UseScratchGpr(a).cvt32();
Xbyak::Reg32 result = reg_alloc.DefGpr(inst).cvt32();
// The result of a bsr of zero is undefined, but zf is set after it.
code->bsr(result, source);
code->mov(source, 0xFFFFFFFF);
code->cmovz(result, source);
code->neg(result);
code->add(result, 31);
}
}
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static void DenormalsAreZero32(BlockOfCode* code, Xbyak::Xmm xmm_value, Xbyak::Reg32 gpr_scratch) {
using namespace Xbyak::util;
Xbyak::Label end;
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// We need to report back whether we've found a denormal on input.
// SSE doesn't do this for us when SSE's DAZ is enabled.
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code->movd(gpr_scratch, xmm_value);
code->and_(gpr_scratch, u32(0x7FFFFFFF));
code->sub(gpr_scratch, u32(1));
code->cmp(gpr_scratch, u32(0x007FFFFE));
code->ja(end);
code->pxor(xmm_value, xmm_value);
code->mov(dword[r15 + offsetof(JitState, FPSCR_IDC)], u32(1 << 7));
code->L(end);
}
static void DenormalsAreZero64(BlockOfCode* code, Xbyak::Xmm xmm_value, Xbyak::Reg64 gpr_scratch) {
using namespace Xbyak::util;
Xbyak::Label end;
auto mask = code->MFloatNonSignMask64();
mask.setBit(64);
auto penult_denormal = code->MFloatPenultimatePositiveDenormal64();
penult_denormal.setBit(64);
code->movq(gpr_scratch, xmm_value);
code->and_(gpr_scratch, mask);
code->sub(gpr_scratch, u32(1));
code->cmp(gpr_scratch, penult_denormal);
code->ja(end);
code->pxor(xmm_value, xmm_value);
code->mov(dword[r15 + offsetof(JitState, FPSCR_IDC)], u32(1 << 7));
code->L(end);
}
static void FlushToZero32(BlockOfCode* code, Xbyak::Xmm xmm_value, Xbyak::Reg32 gpr_scratch) {
using namespace Xbyak::util;
Xbyak::Label end;
code->movd(gpr_scratch, xmm_value);
code->and_(gpr_scratch, u32(0x7FFFFFFF));
code->sub(gpr_scratch, u32(1));
code->cmp(gpr_scratch, u32(0x007FFFFE));
code->ja(end);
code->pxor(xmm_value, xmm_value);
code->mov(dword[r15 + offsetof(JitState, FPSCR_UFC)], u32(1 << 3));
code->L(end);
}
static void FlushToZero64(BlockOfCode* code, Xbyak::Xmm xmm_value, Xbyak::Reg64 gpr_scratch) {
using namespace Xbyak::util;
Xbyak::Label end;
auto mask = code->MFloatNonSignMask64();
mask.setBit(64);
auto penult_denormal = code->MFloatPenultimatePositiveDenormal64();
penult_denormal.setBit(64);
code->movq(gpr_scratch, xmm_value);
code->and_(gpr_scratch, mask);
code->sub(gpr_scratch, u32(1));
code->cmp(gpr_scratch, penult_denormal);
code->ja(end);
code->pxor(xmm_value, xmm_value);
code->mov(dword[r15 + offsetof(JitState, FPSCR_UFC)], u32(1 << 3));
code->L(end);
}
static void DefaultNaN32(BlockOfCode* code, Xbyak::Xmm xmm_value) {
Xbyak::Label end;
code->ucomiss(xmm_value, xmm_value);
code->jnp(end);
code->movaps(xmm_value, code->MFloatNaN32());
code->L(end);
}
static void DefaultNaN64(BlockOfCode* code, Xbyak::Xmm xmm_value) {
Xbyak::Label end;
code->ucomisd(xmm_value, xmm_value);
code->jnp(end);
code->movaps(xmm_value, code->MFloatNaN64());
code->L(end);
}
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static void ZeroIfNaN64(BlockOfCode* code, Xbyak::Xmm xmm_value, Xbyak::Xmm xmm_scratch) {
code->pxor(xmm_scratch, xmm_scratch);
code->cmpordsd(xmm_scratch, xmm_value); // true mask when ordered (i.e.: when not an NaN)
code->pand(xmm_value, xmm_scratch);
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}
static void FPThreeOp32(BlockOfCode* code, RegAlloc& reg_alloc, IR::Block& block, IR::Inst* inst, void (Xbyak::CodeGenerator::*fn)(const Xbyak::Xmm&, const Xbyak::Operand&)) {
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IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
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Xbyak::Xmm result = reg_alloc.UseDefXmm(a, inst);
Xbyak::Xmm operand = reg_alloc.UseXmm(b);
Xbyak::Reg32 gpr_scratch = reg_alloc.ScratchGpr().cvt32();
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if (block.Location().FPSCR().FTZ()) {
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DenormalsAreZero32(code, result, gpr_scratch);
DenormalsAreZero32(code, operand, gpr_scratch);
}
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(code->*fn)(result, operand);
if (block.Location().FPSCR().FTZ()) {
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FlushToZero32(code, result, gpr_scratch);
}
if (block.Location().FPSCR().DN()) {
DefaultNaN32(code, result);
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}
}
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static void FPThreeOp64(BlockOfCode* code, RegAlloc& reg_alloc, IR::Block& block, IR::Inst* inst, void (Xbyak::CodeGenerator::*fn)(const Xbyak::Xmm&, const Xbyak::Operand&)) {
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IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
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Xbyak::Xmm result = reg_alloc.UseDefXmm(a, inst);
Xbyak::Xmm operand = reg_alloc.UseXmm(b);
Xbyak::Reg64 gpr_scratch = reg_alloc.ScratchGpr();
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if (block.Location().FPSCR().FTZ()) {
DenormalsAreZero64(code, result, gpr_scratch);
DenormalsAreZero64(code, operand, gpr_scratch);
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}
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(code->*fn)(result, operand);
if (block.Location().FPSCR().FTZ()) {
FlushToZero64(code, result, gpr_scratch);
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}
if (block.Location().FPSCR().DN()) {
DefaultNaN64(code, result);
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}
}
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static void FPTwoOp32(BlockOfCode* code, RegAlloc& reg_alloc, IR::Block& block, IR::Inst* inst, void (Xbyak::CodeGenerator::*fn)(const Xbyak::Xmm&, const Xbyak::Operand&)) {
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IR::Value a = inst->GetArg(0);
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Xbyak::Xmm result = reg_alloc.UseDefXmm(a, inst);
Xbyak::Reg32 gpr_scratch = reg_alloc.ScratchGpr().cvt32();
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if (block.Location().FPSCR().FTZ()) {
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DenormalsAreZero32(code, result, gpr_scratch);
}
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(code->*fn)(result, result);
if (block.Location().FPSCR().FTZ()) {
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FlushToZero32(code, result, gpr_scratch);
}
if (block.Location().FPSCR().DN()) {
DefaultNaN32(code, result);
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}
}
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static void FPTwoOp64(BlockOfCode* code, RegAlloc& reg_alloc, IR::Block& block, IR::Inst* inst, void (Xbyak::CodeGenerator::*fn)(const Xbyak::Xmm&, const Xbyak::Operand&)) {
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IR::Value a = inst->GetArg(0);
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Xbyak::Xmm result = reg_alloc.UseDefXmm(a, inst);
Xbyak::Reg64 gpr_scratch = reg_alloc.ScratchGpr();
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if (block.Location().FPSCR().FTZ()) {
DenormalsAreZero64(code, result, gpr_scratch);
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}
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(code->*fn)(result, result);
if (block.Location().FPSCR().FTZ()) {
FlushToZero64(code, result, gpr_scratch);
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}
if (block.Location().FPSCR().DN()) {
DefaultNaN64(code, result);
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}
}
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void EmitX64::EmitTransferFromFP32(IR::Block& block, IR::Inst* inst) {
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Xbyak::Reg32 result = reg_alloc.DefGpr(inst).cvt32();
Xbyak::Xmm source = reg_alloc.UseXmm(inst->GetArg(0));
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// TODO: Eliminate this.
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code->movd(result, source);
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}
void EmitX64::EmitTransferFromFP64(IR::Block& block, IR::Inst* inst) {
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Xbyak::Reg64 result = reg_alloc.DefGpr(inst);
Xbyak::Xmm source = reg_alloc.UseXmm(inst->GetArg(0));
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// TODO: Eliminate this.
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code->movq(result, source);
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}
void EmitX64::EmitTransferToFP32(IR::Block& block, IR::Inst* inst) {
if (inst->GetArg(0).IsImmediate() && inst->GetArg(0).GetU32() == 0) {
Xbyak::Xmm result = reg_alloc.DefXmm(inst);
code->xorps(result, result);
} else {
Xbyak::Xmm result = reg_alloc.DefXmm(inst);
Xbyak::Reg32 source = reg_alloc.UseGpr(inst->GetArg(0)).cvt32();
// TODO: Eliminate this.
code->movd(result, source);
}
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}
void EmitX64::EmitTransferToFP64(IR::Block& block, IR::Inst* inst) {
if (inst->GetArg(0).IsImmediate() && inst->GetArg(0).GetU64() == 0) {
Xbyak::Xmm result = reg_alloc.DefXmm(inst);
code->xorpd(result, result);
} else {
Xbyak::Xmm result = reg_alloc.DefXmm(inst);
Xbyak::Reg64 source = reg_alloc.UseGpr(inst->GetArg(0));
// TODO: Eliminate this.
code->movq(result, source);
}
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}
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void EmitX64::EmitFPAbs32(IR::Block&, IR::Inst* inst) {
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IR::Value a = inst->GetArg(0);
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Xbyak::Xmm result = reg_alloc.UseDefXmm(a, inst);
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code->pand(result, code->MFloatNonSignMask32());
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}
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void EmitX64::EmitFPAbs64(IR::Block&, IR::Inst* inst) {
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IR::Value a = inst->GetArg(0);
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Xbyak::Xmm result = reg_alloc.UseDefXmm(a, inst);
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code->pand(result, code->MFloatNonSignMask64());
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}
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void EmitX64::EmitFPNeg32(IR::Block&, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
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Xbyak::Xmm result = reg_alloc.UseDefXmm(a, inst);
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code->pxor(result, code->MFloatNegativeZero32());
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}
void EmitX64::EmitFPNeg64(IR::Block&, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
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Xbyak::Xmm result = reg_alloc.UseDefXmm(a, inst);
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code->pxor(result, code->MFloatNegativeZero64());
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}
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void EmitX64::EmitFPAdd32(IR::Block& block, IR::Inst* inst) {
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FPThreeOp32(code, reg_alloc, block, inst, &Xbyak::CodeGenerator::addss);
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}
void EmitX64::EmitFPAdd64(IR::Block& block, IR::Inst* inst) {
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FPThreeOp64(code, reg_alloc, block, inst, &Xbyak::CodeGenerator::addsd);
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}
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void EmitX64::EmitFPDiv32(IR::Block& block, IR::Inst* inst) {
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FPThreeOp32(code, reg_alloc, block, inst, &Xbyak::CodeGenerator::divss);
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}
void EmitX64::EmitFPDiv64(IR::Block& block, IR::Inst* inst) {
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FPThreeOp64(code, reg_alloc, block, inst, &Xbyak::CodeGenerator::divsd);
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}
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void EmitX64::EmitFPMul32(IR::Block& block, IR::Inst* inst) {
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FPThreeOp32(code, reg_alloc, block, inst, &Xbyak::CodeGenerator::mulss);
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}
void EmitX64::EmitFPMul64(IR::Block& block, IR::Inst* inst) {
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FPThreeOp64(code, reg_alloc, block, inst, &Xbyak::CodeGenerator::mulsd);
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}
void EmitX64::EmitFPSqrt32(IR::Block& block, IR::Inst* inst) {
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FPTwoOp32(code, reg_alloc, block, inst, &Xbyak::CodeGenerator::sqrtss);
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}
void EmitX64::EmitFPSqrt64(IR::Block& block, IR::Inst* inst) {
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FPTwoOp64(code, reg_alloc, block, inst, &Xbyak::CodeGenerator::sqrtsd);
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}
void EmitX64::EmitFPSub32(IR::Block& block, IR::Inst* inst) {
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FPThreeOp32(code, reg_alloc, block, inst, &Xbyak::CodeGenerator::subss);
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}
void EmitX64::EmitFPSub64(IR::Block& block, IR::Inst* inst) {
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FPThreeOp64(code, reg_alloc, block, inst, &Xbyak::CodeGenerator::subsd);
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}
static void SetFpscrNzcvFromFlags(BlockOfCode* code, RegAlloc& reg_alloc) {
reg_alloc.ScratchGpr({HostLoc::RAX}); // lahf requires use of ah
Xbyak::Reg32 nzcv_imm = reg_alloc.ScratchGpr().cvt32();
Xbyak::Reg32 nzcv = reg_alloc.ScratchGpr().cvt32();
using namespace Xbyak::util;
code->lahf();
code->mov(nzcv_imm, 0x30000000);
code->cmp(ah, 0b01000111);
code->cmove(nzcv, nzcv_imm);
code->mov(nzcv_imm, 0x20000000);
code->cmp(ah, 0b00000010);
code->cmove(nzcv, nzcv_imm);
code->mov(nzcv_imm, 0x80000000);
code->cmp(ah, 0b00000011);
code->cmove(nzcv, nzcv_imm);
code->mov(nzcv_imm, 0x60000000);
code->cmp(ah, 0b01000010);
code->cmove(nzcv, nzcv_imm);
code->mov(dword[r15 + offsetof(JitState, FPSCR_nzcv)], nzcv);
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}
void EmitX64::EmitFPCompare32(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
bool quiet = inst->GetArg(2).GetU1();
Xbyak::Xmm reg_a = reg_alloc.UseXmm(a);
Xbyak::Xmm reg_b = reg_alloc.UseXmm(b);
if (quiet) {
code->ucomiss(reg_a, reg_b);
} else {
code->comiss(reg_a, reg_b);
}
SetFpscrNzcvFromFlags(code, reg_alloc);
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}
void EmitX64::EmitFPCompare64(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
IR::Value b = inst->GetArg(1);
bool quiet = inst->GetArg(2).GetU1();
Xbyak::Xmm reg_a = reg_alloc.UseXmm(a);
Xbyak::Xmm reg_b = reg_alloc.UseXmm(b);
if (quiet) {
code->ucomisd(reg_a, reg_b);
} else {
code->comisd(reg_a, reg_b);
}
SetFpscrNzcvFromFlags(code, reg_alloc);
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}
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void EmitX64::EmitFPSingleToDouble(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
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Xbyak::Xmm result = reg_alloc.UseDefXmm(a, inst);
Xbyak::Reg64 gpr_scratch = reg_alloc.ScratchGpr();
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if (block.Location().FPSCR().FTZ()) {
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DenormalsAreZero32(code, result, gpr_scratch.cvt32());
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}
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code->cvtss2sd(result, result);
if (block.Location().FPSCR().FTZ()) {
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FlushToZero64(code, result, gpr_scratch);
}
if (block.Location().FPSCR().DN()) {
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DefaultNaN64(code, result);
}
}
void EmitX64::EmitFPDoubleToSingle(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
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Xbyak::Xmm result = reg_alloc.UseDefXmm(a, inst);
Xbyak::Reg64 gpr_scratch = reg_alloc.ScratchGpr();
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if (block.Location().FPSCR().FTZ()) {
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DenormalsAreZero64(code, result, gpr_scratch);
}
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code->cvtsd2ss(result, result);
if (block.Location().FPSCR().FTZ()) {
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FlushToZero32(code, result, gpr_scratch.cvt32());
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}
if (block.Location().FPSCR().DN()) {
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DefaultNaN32(code, result);
}
}
void EmitX64::EmitFPSingleToS32(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
bool round_towards_zero = inst->GetArg(1).GetU1();
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Xbyak::Xmm from = reg_alloc.UseScratchXmm(a);
Xbyak::Xmm to = reg_alloc.DefXmm(inst);
Xbyak::Reg32 gpr_scratch = reg_alloc.ScratchGpr().cvt32();
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Xbyak::Xmm xmm_scratch = reg_alloc.ScratchXmm();
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// ARM saturates on conversion; this differs from x64 which returns a sentinel value.
// Conversion to double is lossless, and allows for clamping.
if (block.Location().FPSCR().FTZ()) {
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DenormalsAreZero32(code, from, gpr_scratch);
}
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code->cvtss2sd(from, from);
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// First time is to set flags
if (round_towards_zero) {
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code->cvttsd2si(gpr_scratch, from); // 32 bit gpr
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} else {
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code->cvtsd2si(gpr_scratch, from); // 32 bit gpr
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}
// Clamp to output range
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ZeroIfNaN64(code, from, xmm_scratch);
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code->minsd(from, code->MFloatMaxS32());
code->maxsd(from, code->MFloatMinS32());
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// Second time is for real
if (round_towards_zero) {
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code->cvttsd2si(gpr_scratch, from); // 32 bit gpr
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} else {
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code->cvtsd2si(gpr_scratch, from); // 32 bit gpr
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}
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code->movd(to, gpr_scratch);
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}
void EmitX64::EmitFPSingleToU32(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
bool round_towards_zero = inst->GetArg(1).GetU1();
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Xbyak::Xmm from = reg_alloc.UseScratchXmm(a);
Xbyak::Xmm to = reg_alloc.DefXmm(inst);
Xbyak::Reg32 gpr_scratch = reg_alloc.ScratchGpr().cvt32();
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Xbyak::Xmm xmm_scratch = reg_alloc.ScratchXmm();
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// ARM saturates on conversion; this differs from x64 which returns a sentinel value.
// Conversion to double is lossless, and allows for accurate clamping.
//
// Since SSE2 doesn't provide an unsigned conversion, we shift the range as appropriate.
//
// FIXME: Inexact exception not correctly signalled with the below code
if (block.Location().FPSCR().RMode() != Arm::FPSCR::RoundingMode::TowardsZero && !round_towards_zero) {
if (block.Location().FPSCR().FTZ()) {
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DenormalsAreZero32(code, from, gpr_scratch);
}
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code->cvtss2sd(from, from);
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ZeroIfNaN64(code, from, xmm_scratch);
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// Bring into SSE range
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code->addsd(from, code->MFloatMinS32());
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// First time is to set flags
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code->cvtsd2si(gpr_scratch, from); // 32 bit gpr
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// Clamp to output range
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code->minsd(from, code->MFloatMaxS32());
code->maxsd(from, code->MFloatMinS32());
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// Actually convert
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code->cvtsd2si(gpr_scratch, from); // 32 bit gpr
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// Bring back into original range
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code->add(gpr_scratch, u32(2147483648u));
code->movd(to, gpr_scratch);
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} else {
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Xbyak::Xmm xmm_mask = reg_alloc.ScratchXmm();
Xbyak::Reg32 gpr_mask = reg_alloc.ScratchGpr().cvt32();
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if (block.Location().FPSCR().FTZ()) {
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DenormalsAreZero32(code, from, gpr_scratch);
}
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code->cvtss2sd(from, from);
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ZeroIfNaN64(code, from, xmm_scratch);
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// Generate masks if out-of-signed-range
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code->movaps(xmm_mask, code->MFloatMaxS32());
code->cmpltsd(xmm_mask, from);
code->movd(gpr_mask, xmm_mask);
code->pand(xmm_mask, code->MFloatMinS32());
code->and_(gpr_mask, u32(2147483648u));
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// Bring into range if necessary
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code->addsd(from, xmm_mask);
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// First time is to set flags
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code->cvttsd2si(gpr_scratch, from); // 32 bit gpr
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// Clamp to output range
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code->minsd(from, code->MFloatMaxS32());
code->maxsd(from, code->MFloatMinU32());
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// Actually convert
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code->cvttsd2si(gpr_scratch, from); // 32 bit gpr
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// Bring back into original range if necessary
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code->add(gpr_scratch, gpr_mask);
code->movd(to, gpr_scratch);
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}
}
void EmitX64::EmitFPDoubleToS32(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
bool round_towards_zero = inst->GetArg(1).GetU1();
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Xbyak::Xmm from = reg_alloc.UseScratchXmm(a);
Xbyak::Xmm to = reg_alloc.DefXmm(inst);
Xbyak::Reg32 gpr_scratch = reg_alloc.ScratchGpr().cvt32();
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Xbyak::Xmm xmm_scratch = reg_alloc.ScratchXmm();
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// ARM saturates on conversion; this differs from x64 which returns a sentinel value.
if (block.Location().FPSCR().FTZ()) {
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DenormalsAreZero64(code, from, gpr_scratch.cvt64());
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}
// First time is to set flags
if (round_towards_zero) {
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code->cvttsd2si(gpr_scratch, from); // 32 bit gpr
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} else {
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code->cvtsd2si(gpr_scratch, from); // 32 bit gpr
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}
// Clamp to output range
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ZeroIfNaN64(code, from, xmm_scratch);
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code->minsd(from, code->MFloatMaxS32());
code->maxsd(from, code->MFloatMinS32());
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// Second time is for real
if (round_towards_zero) {
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code->cvttsd2si(gpr_scratch, from); // 32 bit gpr
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} else {
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code->cvtsd2si(gpr_scratch, from); // 32 bit gpr
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}
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code->movd(to, gpr_scratch);
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}
void EmitX64::EmitFPDoubleToU32(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
bool round_towards_zero = inst->GetArg(1).GetU1();
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Xbyak::Xmm from = reg_alloc.UseScratchXmm(a);
Xbyak::Xmm to = reg_alloc.DefXmm(inst);
Xbyak::Reg32 gpr_scratch = reg_alloc.ScratchGpr().cvt32();
Xbyak::Xmm xmm_scratch = reg_alloc.ScratchXmm();
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// ARM saturates on conversion; this differs from x64 which returns a sentinel value.
// TODO: Use VCVTPD2UDQ when AVX512VL is available.
// FIXME: Inexact exception not correctly signalled with the below code
if (block.Location().FPSCR().RMode() != Arm::FPSCR::RoundingMode::TowardsZero && !round_towards_zero) {
if (block.Location().FPSCR().FTZ()) {
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DenormalsAreZero64(code, from, gpr_scratch.cvt64());
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}
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ZeroIfNaN64(code, from, xmm_scratch);
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// Bring into SSE range
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code->addsd(from, code->MFloatMinS32());
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// First time is to set flags
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code->cvtsd2si(gpr_scratch, from); // 32 bit gpr
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// Clamp to output range
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code->minsd(from, code->MFloatMaxS32());
code->maxsd(from, code->MFloatMinS32());
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// Actually convert
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code->cvtsd2si(gpr_scratch, from); // 32 bit gpr
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// Bring back into original range
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code->add(gpr_scratch, u32(2147483648u));
code->movd(to, gpr_scratch);
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} else {
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Xbyak::Xmm xmm_mask = reg_alloc.ScratchXmm();
Xbyak::Reg32 gpr_mask = reg_alloc.ScratchGpr().cvt32();
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if (block.Location().FPSCR().FTZ()) {
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DenormalsAreZero64(code, from, gpr_scratch.cvt64());
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}
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ZeroIfNaN64(code, from, xmm_scratch);
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// Generate masks if out-of-signed-range
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code->movaps(xmm_mask, code->MFloatMaxS32());
code->cmpltsd(xmm_mask, from);
code->movd(gpr_mask, xmm_mask);
code->pand(xmm_mask, code->MFloatMinS32());
code->and_(gpr_mask, u32(2147483648u));
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// Bring into range if necessary
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code->addsd(from, xmm_mask);
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// First time is to set flags
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code->cvttsd2si(gpr_scratch, from); // 32 bit gpr
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// Clamp to output range
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code->minsd(from, code->MFloatMaxS32());
code->maxsd(from, code->MFloatMinU32());
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// Actually convert
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code->cvttsd2si(gpr_scratch, from); // 32 bit gpr
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// Bring back into original range if necessary
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code->add(gpr_scratch, gpr_mask);
code->movd(to, gpr_scratch);
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}
}
void EmitX64::EmitFPS32ToSingle(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
bool round_to_nearest = inst->GetArg(1).GetU1();
ASSERT_MSG(!round_to_nearest, "round_to_nearest unimplemented");
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Xbyak::Xmm from = reg_alloc.UseXmm(a);
Xbyak::Xmm to = reg_alloc.DefXmm(inst);
Xbyak::Reg32 gpr_scratch = reg_alloc.ScratchGpr().cvt32();
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code->movd(gpr_scratch, from);
code->cvtsi2ss(to, gpr_scratch);
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}
void EmitX64::EmitFPU32ToSingle(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
bool round_to_nearest = inst->GetArg(1).GetU1();
ASSERT_MSG(!round_to_nearest, "round_to_nearest unimplemented");
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Xbyak::Xmm from = reg_alloc.UseXmm(a);
Xbyak::Xmm to = reg_alloc.DefXmm(inst);
// Use a 64-bit register to ensure we don't end up treating the input as signed
Xbyak::Reg64 gpr_scratch = reg_alloc.ScratchGpr();
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code->movq(gpr_scratch, from);
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code->cvtsi2ss(to, gpr_scratch);
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}
void EmitX64::EmitFPS32ToDouble(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
bool round_to_nearest = inst->GetArg(1).GetU1();
ASSERT_MSG(!round_to_nearest, "round_to_nearest unimplemented");
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Xbyak::Xmm from = reg_alloc.UseXmm(a);
Xbyak::Xmm to = reg_alloc.DefXmm(inst);
Xbyak::Reg32 gpr_scratch = reg_alloc.ScratchGpr().cvt32();
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code->movd(gpr_scratch, from);
code->cvtsi2sd(to, gpr_scratch);
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}
void EmitX64::EmitFPU32ToDouble(IR::Block& block, IR::Inst* inst) {
IR::Value a = inst->GetArg(0);
bool round_to_nearest = inst->GetArg(1).GetU1();
ASSERT_MSG(!round_to_nearest, "round_to_nearest unimplemented");
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Xbyak::Xmm from = reg_alloc.UseXmm(a);
Xbyak::Xmm to = reg_alloc.DefXmm(inst);
// Use a 64-bit register to ensure we don't end up treating the input as signed
Xbyak::Reg64 gpr_scratch = reg_alloc.ScratchGpr();
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code->movq(gpr_scratch, from);
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code->cvtsi2sd(to, gpr_scratch);
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}
void EmitX64::EmitClearExclusive(IR::Block&, IR::Inst*) {
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using namespace Xbyak::util;
code->mov(code->byte[r15 + offsetof(JitState, exclusive_state)], u8(0));
}
void EmitX64::EmitSetExclusive(IR::Block&, IR::Inst* inst) {
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using namespace Xbyak::util;
ASSERT(inst->GetArg(1).IsImmediate());
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Xbyak::Reg32 address = reg_alloc.UseGpr(inst->GetArg(0)).cvt32();
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code->mov(code->byte[r15 + offsetof(JitState, exclusive_state)], u8(1));
code->mov(dword[r15 + offsetof(JitState, exclusive_address)], address);
}
template <typename FunctionPointer>
static void ReadMemory(BlockOfCode* code, RegAlloc& reg_alloc, IR::Inst* inst, UserCallbacks& cb, size_t bit_size, FunctionPointer fn) {
if (!cb.page_table) {
reg_alloc.HostCall(inst, inst->GetArg(0));
code->CallFunction(fn);
return;
}
using namespace Xbyak::util;
Xbyak::Reg64 result = reg_alloc.DefGpr(inst, { ABI_RETURN });
Xbyak::Reg32 vaddr = reg_alloc.UseScratchGpr(inst->GetArg(0), { ABI_PARAM1 }).cvt32();
Xbyak::Reg64 page_index = reg_alloc.ScratchGpr();
Xbyak::Reg64 page_offset = reg_alloc.ScratchGpr();
Xbyak::Label abort, end;
code->mov(rax, u64(cb.page_table));
code->mov(page_index.cvt32(), vaddr);
code->shr(page_index.cvt32(), 12);
code->mov(rax, qword[rax + page_index * 8]);
code->test(rax, rax);
code->jz(abort);
code->mov(page_offset.cvt32(), vaddr);
code->and_(page_offset.cvt32(), 4095);
switch (bit_size) {
case 8:
code->movzx(result, code->byte[rax + page_offset]);
break;
case 16:
code->movzx(result, word[rax + page_offset]);
break;
case 32:
code->mov(result.cvt32(), dword[rax + page_offset]);
break;
case 64:
code->mov(result.cvt64(), qword[rax + page_offset]);
break;
default:
ASSERT_MSG(false, "Invalid bit_size");
break;
}
code->jmp(end);
code->L(abort);
code->call(code->GetMemoryReadCallback(bit_size));
code->L(end);
}
template<typename FunctionPointer>
static void WriteMemory(BlockOfCode* code, RegAlloc& reg_alloc, IR::Inst* inst, UserCallbacks& cb, size_t bit_size, FunctionPointer fn) {
if (!cb.page_table) {
reg_alloc.HostCall(inst, inst->GetArg(0), inst->GetArg(1));
code->CallFunction(fn);
return;
}
using namespace Xbyak::util;
reg_alloc.ScratchGpr({ HostLoc::RAX });
Xbyak::Reg32 vaddr = reg_alloc.UseScratchGpr(inst->GetArg(0), { ABI_PARAM1 }).cvt32();
Xbyak::Reg64 value = reg_alloc.UseScratchGpr(inst->GetArg(1), { ABI_PARAM2 });
Xbyak::Reg64 page_index = reg_alloc.ScratchGpr();
Xbyak::Reg64 page_offset = reg_alloc.ScratchGpr();
Xbyak::Label abort, end;
code->mov(rax, u64(cb.page_table));
code->mov(page_index.cvt32(), vaddr);
code->shr(page_index.cvt32(), 12);
code->mov(rax, qword[rax + page_index * 8]);
code->test(rax, rax);
code->jz(abort);
code->mov(page_offset.cvt32(), vaddr);
code->and_(page_offset.cvt32(), 4095);
switch (bit_size) {
case 8:
code->mov(code->byte[rax + page_offset], value.cvt8());
break;
case 16:
code->mov(word[rax + page_offset], value.cvt16());
break;
case 32:
code->mov(dword[rax + page_offset], value.cvt32());
break;
case 64:
code->mov(qword[rax + page_offset], value.cvt64());
break;
default:
ASSERT_MSG(false, "Invalid bit_size");
break;
}
code->jmp(end);
code->L(abort);
code->call(code->GetMemoryWriteCallback(bit_size));
code->L(end);
}
void EmitX64::EmitReadMemory8(IR::Block&, IR::Inst* inst) {
ReadMemory(code, reg_alloc, inst, cb, 8, cb.MemoryRead8);
}
void EmitX64::EmitReadMemory16(IR::Block&, IR::Inst* inst) {
ReadMemory(code, reg_alloc, inst, cb, 16, cb.MemoryRead16);
}
void EmitX64::EmitReadMemory32(IR::Block&, IR::Inst* inst) {
ReadMemory(code, reg_alloc, inst, cb, 32, cb.MemoryRead32);
}
void EmitX64::EmitReadMemory64(IR::Block&, IR::Inst* inst) {
ReadMemory(code, reg_alloc, inst, cb, 64, cb.MemoryRead64);
}
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void EmitX64::EmitWriteMemory8(IR::Block&, IR::Inst* inst) {
WriteMemory(code, reg_alloc, inst, cb, 8, cb.MemoryWrite8);
}
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void EmitX64::EmitWriteMemory16(IR::Block&, IR::Inst* inst) {
WriteMemory(code, reg_alloc, inst, cb, 16, cb.MemoryWrite16);
}
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void EmitX64::EmitWriteMemory32(IR::Block&, IR::Inst* inst) {
WriteMemory(code, reg_alloc, inst, cb, 32, cb.MemoryWrite32);
}
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void EmitX64::EmitWriteMemory64(IR::Block&, IR::Inst* inst) {
WriteMemory(code, reg_alloc, inst, cb, 64, cb.MemoryWrite64);
}
template <typename FunctionPointer>
static void ExclusiveWrite(BlockOfCode* code, RegAlloc& reg_alloc, IR::Inst* inst, FunctionPointer fn) {
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using namespace Xbyak::util;
Xbyak::Label end;
reg_alloc.HostCall(nullptr, inst->GetArg(0), inst->GetArg(1));
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Xbyak::Reg32 passed = reg_alloc.DefGpr(inst).cvt32();
Xbyak::Reg32 tmp = code->ABI_RETURN.cvt32(); // Use one of the unusued HostCall registers.
code->mov(passed, u32(1));
code->cmp(code->byte[r15 + offsetof(JitState, exclusive_state)], u8(0));
code->je(end);
code->mov(tmp, code->ABI_PARAM1);
code->xor_(tmp, dword[r15 + offsetof(JitState, exclusive_address)]);
code->test(tmp, JitState::RESERVATION_GRANULE_MASK);
code->jne(end);
code->mov(code->byte[r15 + offsetof(JitState, exclusive_state)], u8(0));
code->CallFunction(fn);
code->xor_(passed, passed);
code->L(end);
}
void EmitX64::EmitExclusiveWriteMemory8(IR::Block&, IR::Inst* inst) {
ExclusiveWrite(code, reg_alloc, inst, cb.MemoryWrite8);
}
void EmitX64::EmitExclusiveWriteMemory16(IR::Block&, IR::Inst* inst) {
ExclusiveWrite(code, reg_alloc, inst, cb.MemoryWrite16);
}
void EmitX64::EmitExclusiveWriteMemory32(IR::Block&, IR::Inst* inst) {
ExclusiveWrite(code, reg_alloc, inst, cb.MemoryWrite32);
}
void EmitX64::EmitExclusiveWriteMemory64(IR::Block&, IR::Inst* inst) {
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using namespace Xbyak::util;
Xbyak::Label end;
reg_alloc.HostCall(nullptr, inst->GetArg(0), inst->GetArg(1));
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Xbyak::Reg32 passed = reg_alloc.DefGpr(inst).cvt32();
Xbyak::Reg64 value_hi = reg_alloc.UseScratchGpr(inst->GetArg(2));
Xbyak::Reg64 value = code->ABI_PARAM2;
Xbyak::Reg32 tmp = code->ABI_RETURN.cvt32(); // Use one of the unusued HostCall registers.
code->mov(passed, u32(1));
code->cmp(code->byte[r15 + offsetof(JitState, exclusive_state)], u8(0));
code->je(end);
code->mov(tmp, code->ABI_PARAM1);
code->xor_(tmp, dword[r15 + offsetof(JitState, exclusive_address)]);
code->test(tmp, JitState::RESERVATION_GRANULE_MASK);
code->jne(end);
code->mov(code->byte[r15 + offsetof(JitState, exclusive_state)], u8(0));
code->mov(value.cvt32(), value.cvt32()); // zero extend to 64-bits
code->shl(value_hi, 32);
code->or_(value, value_hi);
code->CallFunction(cb.MemoryWrite64);
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code->xor_(passed, passed);
code->L(end);
}
void EmitX64::EmitAddCycles(size_t cycles) {
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using namespace Xbyak::util;
ASSERT(cycles < std::numeric_limits<u32>::max());
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code->sub(qword[r15 + offsetof(JitState, cycles_remaining)], static_cast<u32>(cycles));
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}
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static Xbyak::Label EmitCond(BlockOfCode* code, Arm::Cond cond) {
using namespace Xbyak::util;
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Xbyak::Label label;
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const Xbyak::Reg32 cpsr = eax;
code->mov(cpsr, MJitStateCpsr());
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constexpr size_t n_shift = 31;
constexpr size_t z_shift = 30;
constexpr size_t c_shift = 29;
constexpr size_t v_shift = 28;
constexpr u32 n_mask = 1u << n_shift;
constexpr u32 z_mask = 1u << z_shift;
constexpr u32 c_mask = 1u << c_shift;
constexpr u32 v_mask = 1u << v_shift;
switch (cond) {
case Arm::Cond::EQ: //z
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code->test(cpsr, z_mask);
code->jnz(label);
break;
case Arm::Cond::NE: //!z
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code->test(cpsr, z_mask);
code->jz(label);
break;
case Arm::Cond::CS: //c
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code->test(cpsr, c_mask);
code->jnz(label);
break;
case Arm::Cond::CC: //!c
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code->test(cpsr, c_mask);
code->jz(label);
break;
case Arm::Cond::MI: //n
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code->test(cpsr, n_mask);
code->jnz(label);
break;
case Arm::Cond::PL: //!n
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code->test(cpsr, n_mask);
code->jz(label);
break;
case Arm::Cond::VS: //v
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code->test(cpsr, v_mask);
code->jnz(label);
break;
case Arm::Cond::VC: //!v
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code->test(cpsr, v_mask);
code->jz(label);
break;
case Arm::Cond::HI: { //c & !z
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code->and_(cpsr, z_mask | c_mask);
code->cmp(cpsr, c_mask);
code->je(label);
break;
}
case Arm::Cond::LS: { //!c | z
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code->and_(cpsr, z_mask | c_mask);
code->cmp(cpsr, c_mask);
code->jne(label);
break;
}
case Arm::Cond::GE: { // n == v
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code->and_(cpsr, n_mask | v_mask);
code->jz(label);
code->cmp(cpsr, n_mask | v_mask);
code->je(label);
break;
}
case Arm::Cond::LT: { // n != v
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Xbyak::Label fail;
code->and_(cpsr, n_mask | v_mask);
code->jz(fail);
code->cmp(cpsr, n_mask | v_mask);
code->jne(label);
code->L(fail);
break;
}
case Arm::Cond::GT: { // !z & (n == v)
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const Xbyak::Reg32 tmp1 = ebx;
const Xbyak::Reg32 tmp2 = esi;
code->mov(tmp1, cpsr);
code->mov(tmp2, cpsr);
code->shr(tmp1, n_shift);
code->shr(tmp2, v_shift);
code->shr(cpsr, z_shift);
code->xor_(tmp1, tmp2);
code->or_(tmp1, cpsr);
code->test(tmp1, 1);
code->jz(label);
break;
}
case Arm::Cond::LE: { // z | (n != v)
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const Xbyak::Reg32 tmp1 = ebx;
const Xbyak::Reg32 tmp2 = esi;
code->mov(tmp1, cpsr);
code->mov(tmp2, cpsr);
code->shr(tmp1, n_shift);
code->shr(tmp2, v_shift);
code->shr(cpsr, z_shift);
code->xor_(tmp1, tmp2);
code->or_(tmp1, cpsr);
code->test(tmp1, 1);
code->jnz(label);
break;
}
default:
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ASSERT_MSG(false, "Unknown cond %zu", static_cast<size_t>(cond));
break;
}
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return label;
}
void EmitX64::EmitCondPrelude(const IR::Block& block) {
if (block.GetCondition() == Arm::Cond::AL) {
ASSERT(!block.HasConditionFailedLocation());
return;
}
ASSERT(block.HasConditionFailedLocation());
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Xbyak::Label pass = EmitCond(code, block.GetCondition());
EmitAddCycles(block.ConditionFailedCycleCount());
EmitTerminalLinkBlock(IR::Term::LinkBlock{block.ConditionFailedLocation()}, block.Location());
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code->L(pass);
}
void EmitX64::EmitTerminal(IR::Terminal terminal, IR::LocationDescriptor initial_location) {
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switch (terminal.which()) {
case 1:
EmitTerminalInterpret(boost::get<IR::Term::Interpret>(terminal), initial_location);
return;
case 2:
EmitTerminalReturnToDispatch(boost::get<IR::Term::ReturnToDispatch>(terminal), initial_location);
return;
case 3:
EmitTerminalLinkBlock(boost::get<IR::Term::LinkBlock>(terminal), initial_location);
return;
case 4:
EmitTerminalLinkBlockFast(boost::get<IR::Term::LinkBlockFast>(terminal), initial_location);
return;
case 5:
EmitTerminalPopRSBHint(boost::get<IR::Term::PopRSBHint>(terminal), initial_location);
return;
case 6:
EmitTerminalIf(boost::get<IR::Term::If>(terminal), initial_location);
return;
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case 7:
EmitTerminalCheckHalt(boost::get<IR::Term::CheckHalt>(terminal), initial_location);
return;
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default:
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ASSERT_MSG(false, "Invalid Terminal. Bad programmer.");
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return;
}
}
void EmitX64::EmitTerminalInterpret(IR::Term::Interpret terminal, IR::LocationDescriptor initial_location) {
ASSERT_MSG(terminal.next.TFlag() == initial_location.TFlag(), "Unimplemented");
ASSERT_MSG(terminal.next.EFlag() == initial_location.EFlag(), "Unimplemented");
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code->mov(code->ABI_PARAM1.cvt32(), terminal.next.PC());
code->mov(code->ABI_PARAM2, reinterpret_cast<u64>(jit_interface));
code->mov(code->ABI_PARAM3, reinterpret_cast<u64>(cb.user_arg));
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code->mov(MJitStateReg(Arm::Reg::PC), code->ABI_PARAM1.cvt32());
code->SwitchMxcsrOnExit();
code->CallFunction(cb.InterpreterFallback);
code->ReturnFromRunCode(false); // TODO: Check cycles
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}
void EmitX64::EmitTerminalReturnToDispatch(IR::Term::ReturnToDispatch, IR::LocationDescriptor initial_location) {
code->ReturnFromRunCode();
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}
void EmitX64::EmitTerminalLinkBlock(IR::Term::LinkBlock terminal, IR::LocationDescriptor initial_location) {
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using namespace Xbyak::util;
if (terminal.next.TFlag() != initial_location.TFlag()) {
if (terminal.next.TFlag()) {
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code->or_(MJitStateCpsr(), u32(1 << 5));
} else {
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code->and_(MJitStateCpsr(), u32(~(1 << 5)));
}
}
if (terminal.next.EFlag() != initial_location.EFlag()) {
if (terminal.next.EFlag()) {
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code->or_(MJitStateCpsr(), u32(1 << 9));
} else {
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code->and_(MJitStateCpsr(), u32(~(1 << 9)));
}
}
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code->cmp(qword[r15 + offsetof(JitState, cycles_remaining)], 0);
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CodePtr patch_location = code->getCurr();
patch_jg_locations[terminal.next].emplace_back(patch_location);
if (auto next_bb = GetBasicBlock(terminal.next)) {
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code->jg(next_bb->code_ptr);
}
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code->EnsurePatchLocationSize(patch_location, 6);
code->mov(MJitStateReg(Arm::Reg::PC), terminal.next.PC());
code->ReturnFromRunCode(); // TODO: Check cycles, Properly do a link
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}
void EmitX64::EmitTerminalLinkBlockFast(IR::Term::LinkBlockFast terminal, IR::LocationDescriptor initial_location) {
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using namespace Xbyak::util;
if (terminal.next.TFlag() != initial_location.TFlag()) {
if (terminal.next.TFlag()) {
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code->or_(MJitStateCpsr(), u32(1 << 5));
} else {
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code->and_(MJitStateCpsr(), u32(~(1 << 5)));
}
}
if (terminal.next.EFlag() != initial_location.EFlag()) {
if (terminal.next.EFlag()) {
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code->or_(MJitStateCpsr(), u32(1 << 9));
} else {
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code->and_(MJitStateCpsr(), u32(~(1 << 9)));
}
}
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CodePtr patch_location = code->getCurr();
patch_jmp_locations[terminal.next].emplace_back(patch_location);
if (auto next_bb = GetBasicBlock(terminal.next)) {
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code->jmp(next_bb->code_ptr);
code->EnsurePatchLocationSize(patch_location, 5);
} else {
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code->mov(MJitStateReg(Arm::Reg::PC), terminal.next.PC());
code->jmp(code->GetReturnFromRunCodeAddress());
code->nop(3);
}
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}
void EmitX64::EmitTerminalPopRSBHint(IR::Term::PopRSBHint, IR::LocationDescriptor initial_location) {
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using namespace Xbyak::util;
// This calculation has to match up with IREmitter::PushRSB
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code->mov(ebx, MJitStateCpsr());
code->mov(ecx, MJitStateReg(Arm::Reg::PC));
code->and_(ebx, u32((1 << 5) | (1 << 9)));
code->shr(ebx, 2);
code->or_(ebx, dword[r15 + offsetof(JitState, FPSCR_mode)]);
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code->shl(rbx, 32);
code->or_(rbx, rcx);
code->mov(rax, u64(code->GetReturnFromRunCodeAddress()));
for (size_t i = 0; i < JitState::RSBSize; ++i) {
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code->cmp(rbx, qword[r15 + offsetof(JitState, rsb_location_descriptors) + i * sizeof(u64)]);
code->cmove(rax, qword[r15 + offsetof(JitState, rsb_codeptrs) + i * sizeof(u64)]);
}
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code->jmp(rax);
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}
void EmitX64::EmitTerminalIf(IR::Term::If terminal, IR::LocationDescriptor initial_location) {
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Xbyak::Label pass = EmitCond(code, terminal.if_);
EmitTerminal(terminal.else_, initial_location);
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code->L(pass);
EmitTerminal(terminal.then_, initial_location);
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}
void EmitX64::EmitTerminalCheckHalt(IR::Term::CheckHalt terminal, IR::LocationDescriptor initial_location) {
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using namespace Xbyak::util;
code->cmp(code->byte[r15 + offsetof(JitState, halt_requested)], u8(0));
code->jne(code->GetReturnFromRunCodeAddress());
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EmitTerminal(terminal.else_, initial_location);
}
void EmitX64::Patch(IR::LocationDescriptor desc, CodePtr bb) {
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using namespace Xbyak::util;
const CodePtr save_code_ptr = code->getCurr();
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for (CodePtr location : patch_jg_locations[desc]) {
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code->SetCodePtr(location);
code->jg(bb);
code->EnsurePatchLocationSize(location, 6);
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}
for (CodePtr location : patch_jmp_locations[desc]) {
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code->SetCodePtr(location);
code->jmp(bb);
code->EnsurePatchLocationSize(location, 5);
}
for (CodePtr location : patch_unique_hash_locations[desc.UniqueHash()]) {
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code->SetCodePtr(location);
code->mov(rcx, u64(bb));
code->EnsurePatchLocationSize(location, 10);
}
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code->SetCodePtr(save_code_ptr);
}
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void EmitX64::ClearCache() {
unique_hash_to_code_ptr.clear();
patch_unique_hash_locations.clear();
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basic_blocks.clear();
patch_jg_locations.clear();
patch_jmp_locations.clear();
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}
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} // namespace BackendX64
} // namespace Dynarmic