1449 lines
48 KiB
C++
1449 lines
48 KiB
C++
// Copyright 2015 Dolphin Emulator Project
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// SPDX-License-Identifier: GPL-2.0-or-later
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#pragma once
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#include <cstring>
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#include <functional>
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#include <optional>
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#include <utility>
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#include "Common/ArmCommon.h"
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#include "Common/Assert.h"
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#include "Common/BitSet.h"
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#include "Common/BitUtils.h"
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#include "Common/CodeBlock.h"
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#include "Common/Common.h"
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#include "Common/CommonTypes.h"
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#include "Common/MathUtil.h"
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namespace Arm64Gen
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{
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// X30 serves a dual purpose as a link register
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// Encoded as <u3:type><u5:reg>
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// Types:
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// 000 - 32bit GPR
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// 001 - 64bit GPR
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// 010 - VFP single precision
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// 100 - VFP double precision
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// 110 - VFP quad precision
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enum class ARM64Reg
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{
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// 32bit registers
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W0 = 0,
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W1,
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W2,
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W3,
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W4,
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W5,
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W6,
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W7,
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W8,
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W9,
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W10,
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W11,
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W12,
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W13,
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W14,
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W15,
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W16,
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W17,
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W18,
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W19,
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W20,
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W21,
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W22,
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W23,
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W24,
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W25,
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W26,
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W27,
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W28,
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W29,
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W30,
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WSP, // 32bit stack pointer
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// 64bit registers
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X0 = 0x20,
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X1,
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X2,
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X3,
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X4,
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X5,
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X6,
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X7,
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X8,
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X9,
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X10,
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X11,
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X12,
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X13,
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X14,
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X15,
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X16,
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X17,
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X18,
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X19,
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X20,
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X21,
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X22,
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X23,
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X24,
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X25,
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X26,
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X27,
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X28,
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X29,
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X30,
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SP, // 64bit stack pointer
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// VFP single precision registers
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S0 = 0x40,
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S1,
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S2,
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S3,
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S4,
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S5,
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S6,
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S7,
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S8,
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S9,
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S10,
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S11,
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S12,
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S13,
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S14,
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S15,
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S16,
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S17,
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S18,
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S19,
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S20,
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S21,
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S22,
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S23,
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S24,
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S25,
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S26,
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S27,
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S28,
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S29,
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S30,
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S31,
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// VFP Double Precision registers
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D0 = 0x80,
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D1,
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D2,
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D3,
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D4,
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D5,
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D6,
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D7,
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D8,
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D9,
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D10,
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D11,
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D12,
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D13,
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D14,
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D15,
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D16,
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D17,
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D18,
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D19,
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D20,
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D21,
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D22,
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D23,
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D24,
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D25,
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D26,
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D27,
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D28,
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D29,
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D30,
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D31,
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// ASIMD Quad-Word registers
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Q0 = 0xC0,
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Q1,
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Q2,
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Q3,
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Q4,
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Q5,
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Q6,
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Q7,
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Q8,
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Q9,
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Q10,
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Q11,
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Q12,
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Q13,
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Q14,
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Q15,
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Q16,
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Q17,
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Q18,
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Q19,
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Q20,
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Q21,
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Q22,
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Q23,
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Q24,
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Q25,
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Q26,
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Q27,
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Q28,
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Q29,
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Q30,
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Q31,
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// For PRFM(prefetch memory) encoding
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// This is encoded in the Rt register
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// Data preload
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PLDL1KEEP = 0,
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PLDL1STRM,
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PLDL2KEEP,
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PLDL2STRM,
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PLDL3KEEP,
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PLDL3STRM,
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// Instruction preload
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PLIL1KEEP = 8,
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PLIL1STRM,
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PLIL2KEEP,
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PLIL2STRM,
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PLIL3KEEP,
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PLIL3STRM,
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// Prepare for store
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PLTL1KEEP = 16,
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PLTL1STRM,
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PLTL2KEEP,
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PLTL2STRM,
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PLTL3KEEP,
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PLTL3STRM,
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WZR = WSP,
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ZR = SP,
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INVALID_REG = -1,
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};
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constexpr int operator&(const ARM64Reg& reg, const int mask)
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{
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return static_cast<int>(reg) & mask;
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}
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constexpr int operator|(const ARM64Reg& reg, const int mask)
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{
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return static_cast<int>(reg) | mask;
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}
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constexpr ARM64Reg operator+(const ARM64Reg& reg, const int addend)
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{
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return static_cast<ARM64Reg>(static_cast<int>(reg) + addend);
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}
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constexpr bool Is64Bit(ARM64Reg reg)
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{
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return (reg & 0x20) != 0;
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}
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constexpr bool IsSingle(ARM64Reg reg)
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{
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return (reg & 0xC0) == 0x40;
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}
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constexpr bool IsDouble(ARM64Reg reg)
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{
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return (reg & 0xC0) == 0x80;
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}
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constexpr bool IsScalar(ARM64Reg reg)
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{
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return IsSingle(reg) || IsDouble(reg);
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}
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constexpr bool IsQuad(ARM64Reg reg)
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{
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return (reg & 0xC0) == 0xC0;
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}
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constexpr bool IsVector(ARM64Reg reg)
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{
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return (reg & 0xC0) != 0;
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}
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constexpr bool IsGPR(ARM64Reg reg)
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{
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return static_cast<int>(reg) < 0x40;
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}
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constexpr int DecodeReg(ARM64Reg reg)
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{
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return reg & 0x1F;
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}
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constexpr ARM64Reg EncodeRegTo32(ARM64Reg reg)
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{
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return static_cast<ARM64Reg>(DecodeReg(reg));
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}
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constexpr ARM64Reg EncodeRegTo64(ARM64Reg reg)
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{
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return static_cast<ARM64Reg>(reg | 0x20);
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}
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constexpr ARM64Reg EncodeRegToSingle(ARM64Reg reg)
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{
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return static_cast<ARM64Reg>(ARM64Reg::S0 | DecodeReg(reg));
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}
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constexpr ARM64Reg EncodeRegToDouble(ARM64Reg reg)
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{
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return static_cast<ARM64Reg>((reg & ~0xC0) | 0x80);
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}
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constexpr ARM64Reg EncodeRegToQuad(ARM64Reg reg)
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{
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return static_cast<ARM64Reg>(reg | 0xC0);
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}
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enum class ShiftType
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{
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// Logical Shift Left
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LSL = 0,
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// Logical Shift Right
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LSR = 1,
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// Arithmetic Shift Right
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ASR = 2,
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// Rotate Right
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ROR = 3,
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};
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enum class IndexType
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{
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Unsigned,
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Post,
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Pre,
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Signed, // used in LDP/STP
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};
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enum class ShiftAmount
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{
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Shift0,
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Shift16,
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Shift32,
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Shift48,
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};
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enum class RoundingMode
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{
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A, // round to nearest, ties to away
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M, // round towards -inf
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N, // round to nearest, ties to even
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P, // round towards +inf
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Z, // round towards zero
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};
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struct FixupBranch
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{
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enum class Type : u32
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{
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CBZ,
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CBNZ,
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BConditional,
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TBZ,
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TBNZ,
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B,
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BL,
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};
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u8* ptr;
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Type type;
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// Used with B.cond
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CCFlags cond;
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// Used with TBZ/TBNZ
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u8 bit;
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// Used with Test/Compare and Branch
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ARM64Reg reg;
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};
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enum class PStateField
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{
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SPSel = 0,
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DAIFSet,
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DAIFClr,
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NZCV, // The only system registers accessible from EL0 (user space)
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PMCR_EL0,
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PMCCNTR_EL0,
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FPCR = 0x340,
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FPSR = 0x341,
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};
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enum class SystemHint
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{
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NOP,
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YIELD,
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WFE,
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WFI,
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SEV,
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SEVL,
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};
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enum class BarrierType
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{
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OSHLD = 1,
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OSHST = 2,
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OSH = 3,
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NSHLD = 5,
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NSHST = 6,
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NSH = 7,
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ISHLD = 9,
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ISHST = 10,
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ISH = 11,
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LD = 13,
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ST = 14,
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SY = 15,
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};
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class ArithOption
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{
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private:
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enum class WidthSpecifier
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{
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Default,
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Width32Bit,
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Width64Bit,
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};
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enum class ExtendSpecifier
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{
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UXTB = 0x0,
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UXTH = 0x1,
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UXTW = 0x2, /* Also LSL on 32bit width */
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UXTX = 0x3, /* Also LSL on 64bit width */
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SXTB = 0x4,
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SXTH = 0x5,
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SXTW = 0x6,
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SXTX = 0x7,
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};
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enum class TypeSpecifier
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{
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ExtendedReg,
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Immediate,
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ShiftedReg,
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};
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ARM64Reg m_destReg;
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WidthSpecifier m_width;
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ExtendSpecifier m_extend;
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TypeSpecifier m_type;
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ShiftType m_shifttype;
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u32 m_shift;
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public:
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ArithOption(ARM64Reg Rd, bool index = false)
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{
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// Indexed registers are a certain feature of AARch64
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// On Loadstore instructions that use a register offset
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// We can have the register as an index
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// If we are indexing then the offset register will
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// be shifted to the left so we are indexing at intervals
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// of the size of what we are loading
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// 8-bit: Index does nothing
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// 16-bit: Index LSL 1
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// 32-bit: Index LSL 2
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// 64-bit: Index LSL 3
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if (index)
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m_shift = 4;
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else
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m_shift = 0;
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m_destReg = Rd;
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m_type = TypeSpecifier::ExtendedReg;
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if (Is64Bit(Rd))
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{
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m_width = WidthSpecifier::Width64Bit;
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m_extend = ExtendSpecifier::UXTX;
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}
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else
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{
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m_width = WidthSpecifier::Width32Bit;
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m_extend = ExtendSpecifier::UXTW;
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}
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m_shifttype = ShiftType::LSL;
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}
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ArithOption(ARM64Reg Rd, ShiftType shift_type, u32 shift)
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{
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m_destReg = Rd;
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m_shift = shift;
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m_shifttype = shift_type;
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m_type = TypeSpecifier::ShiftedReg;
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if (Is64Bit(Rd))
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{
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m_width = WidthSpecifier::Width64Bit;
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if (shift == 64)
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m_shift = 0;
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}
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else
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{
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m_width = WidthSpecifier::Width32Bit;
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if (shift == 32)
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m_shift = 0;
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}
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}
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ARM64Reg GetReg() const { return m_destReg; }
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u32 GetData() const
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{
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switch (m_type)
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{
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case TypeSpecifier::ExtendedReg:
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return (static_cast<u32>(m_extend) << 13) | (m_shift << 10);
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case TypeSpecifier::ShiftedReg:
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return (static_cast<u32>(m_shifttype) << 22) | (m_shift << 10);
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default:
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DEBUG_ASSERT_MSG(DYNA_REC, false, "Invalid type in GetData");
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break;
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}
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return 0;
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}
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bool IsExtended() const { return m_type == TypeSpecifier::ExtendedReg; }
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};
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struct LogicalImm
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{
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constexpr LogicalImm() {}
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constexpr LogicalImm(u8 r_, u8 s_, bool n_) : r(r_), s(s_), n(n_), valid(true) {}
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constexpr LogicalImm(u64 value, u32 width)
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{
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bool negate = false;
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// Logical immediates are encoded using parameters n, imm_s and imm_r using
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// the following table:
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//
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// N imms immr size S R
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// 1 ssssss rrrrrr 64 UInt(ssssss) UInt(rrrrrr)
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// 0 0sssss xrrrrr 32 UInt(sssss) UInt(rrrrr)
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// 0 10ssss xxrrrr 16 UInt(ssss) UInt(rrrr)
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// 0 110sss xxxrrr 8 UInt(sss) UInt(rrr)
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// 0 1110ss xxxxrr 4 UInt(ss) UInt(rr)
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// 0 11110s xxxxxr 2 UInt(s) UInt(r)
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// (s bits must not be all set)
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//
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// A pattern is constructed of size bits, where the least significant S+1 bits
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// are set. The pattern is rotated right by R, and repeated across a 32 or
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// 64-bit value, depending on destination register width.
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//
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// Put another way: the basic format of a logical immediate is a single
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// contiguous stretch of 1 bits, repeated across the whole word at intervals
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// given by a power of 2. To identify them quickly, we first locate the
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// lowest stretch of 1 bits, then the next 1 bit above that; that combination
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// is different for every logical immediate, so it gives us all the
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// information we need to identify the only logical immediate that our input
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// could be, and then we simply check if that's the value we actually have.
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//
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// (The rotation parameter does give the possibility of the stretch of 1 bits
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// going 'round the end' of the word. To deal with that, we observe that in
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// any situation where that happens the bitwise NOT of the value is also a
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// valid logical immediate. So we simply invert the input whenever its low bit
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// is set, and then we know that the rotated case can't arise.)
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if (value & 1)
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{
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// If the low bit is 1, negate the value, and set a flag to remember that we
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// did (so that we can adjust the return values appropriately).
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negate = true;
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value = ~value;
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}
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constexpr int kWRegSizeInBits = 32;
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if (width == kWRegSizeInBits)
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{
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// To handle 32-bit logical immediates, the very easiest thing is to repeat
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// the input value twice to make a 64-bit word. The correct encoding of that
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// as a logical immediate will also be the correct encoding of the 32-bit
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// value.
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// The most-significant 32 bits may not be zero (ie. negate is true) so
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// shift the value left before duplicating it.
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value <<= kWRegSizeInBits;
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value |= value >> kWRegSizeInBits;
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}
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// The basic analysis idea: imagine our input word looks like this.
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//
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// 0011111000111110001111100011111000111110001111100011111000111110
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// c b a
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// |<--d-->|
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//
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// We find the lowest set bit (as an actual power-of-2 value, not its index)
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// and call it a. Then we add a to our original number, which wipes out the
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// bottommost stretch of set bits and replaces it with a 1 carried into the
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// next zero bit. Then we look for the new lowest set bit, which is in
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// position b, and subtract it, so now our number is just like the original
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// but with the lowest stretch of set bits completely gone. Now we find the
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// lowest set bit again, which is position c in the diagram above. Then we'll
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// measure the distance d between bit positions a and c (using CLZ), and that
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// tells us that the only valid logical immediate that could possibly be equal
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// to this number is the one in which a stretch of bits running from a to just
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// below b is replicated every d bits.
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u64 a = Common::LargestPowerOf2Divisor(value);
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u64 value_plus_a = value + a;
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u64 b = Common::LargestPowerOf2Divisor(value_plus_a);
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u64 value_plus_a_minus_b = value_plus_a - b;
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u64 c = Common::LargestPowerOf2Divisor(value_plus_a_minus_b);
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int d = 0, clz_a = 0, out_n = 0;
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u64 mask = 0;
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if (c != 0)
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{
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// The general case, in which there is more than one stretch of set bits.
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// Compute the repeat distance d, and set up a bitmask covering the basic
|
|
// unit of repetition (i.e. a word with the bottom d bits set). Also, in all
|
|
// of these cases the N bit of the output will be zero.
|
|
clz_a = Common::CountLeadingZeros(a);
|
|
int clz_c = Common::CountLeadingZeros(c);
|
|
d = clz_a - clz_c;
|
|
mask = ((UINT64_C(1) << d) - 1);
|
|
out_n = 0;
|
|
}
|
|
else
|
|
{
|
|
// Handle degenerate cases.
|
|
//
|
|
// If any of those 'find lowest set bit' operations didn't find a set bit at
|
|
// all, then the word will have been zero thereafter, so in particular the
|
|
// last lowest_set_bit operation will have returned zero. So we can test for
|
|
// all the special case conditions in one go by seeing if c is zero.
|
|
if (a == 0)
|
|
{
|
|
// The input was zero (or all 1 bits, which will come to here too after we
|
|
// inverted it at the start of the function), which is invalid.
|
|
return;
|
|
}
|
|
else
|
|
{
|
|
// Otherwise, if c was zero but a was not, then there's just one stretch
|
|
// of set bits in our word, meaning that we have the trivial case of
|
|
// d == 64 and only one 'repetition'. Set up all the same variables as in
|
|
// the general case above, and set the N bit in the output.
|
|
clz_a = Common::CountLeadingZeros(a);
|
|
d = 64;
|
|
mask = ~UINT64_C(0);
|
|
out_n = 1;
|
|
}
|
|
}
|
|
|
|
// If the repeat period d is not a power of two, it can't be encoded.
|
|
if (!MathUtil::IsPow2<u64>(d))
|
|
return;
|
|
|
|
// If the bit stretch (b - a) does not fit within the mask derived from the
|
|
// repeat period, then fail.
|
|
if (((b - a) & ~mask) != 0)
|
|
return;
|
|
|
|
// The only possible option is b - a repeated every d bits. Now we're going to
|
|
// actually construct the valid logical immediate derived from that
|
|
// specification, and see if it equals our original input.
|
|
//
|
|
// To repeat a value every d bits, we multiply it by a number of the form
|
|
// (1 + 2^d + 2^(2d) + ...), i.e. 0x0001000100010001 or similar. These can
|
|
// be derived using a table lookup on CLZ(d).
|
|
constexpr std::array<u64, 6> multipliers = {{
|
|
0x0000000000000001UL,
|
|
0x0000000100000001UL,
|
|
0x0001000100010001UL,
|
|
0x0101010101010101UL,
|
|
0x1111111111111111UL,
|
|
0x5555555555555555UL,
|
|
}};
|
|
|
|
const int multiplier_idx = Common::CountLeadingZeros((u64)d) - 57;
|
|
|
|
// Ensure that the index to the multipliers array is within bounds.
|
|
DEBUG_ASSERT((multiplier_idx >= 0) &&
|
|
(static_cast<size_t>(multiplier_idx) < multipliers.size()));
|
|
|
|
const u64 multiplier = multipliers[multiplier_idx];
|
|
const u64 candidate = (b - a) * multiplier;
|
|
|
|
// The candidate pattern doesn't match our input value, so fail.
|
|
if (value != candidate)
|
|
return;
|
|
|
|
// We have a match! This is a valid logical immediate, so now we have to
|
|
// construct the bits and pieces of the instruction encoding that generates
|
|
// it.
|
|
n = out_n;
|
|
|
|
// Count the set bits in our basic stretch. The special case of clz(0) == -1
|
|
// makes the answer come out right for stretches that reach the very top of
|
|
// the word (e.g. numbers like 0xffffc00000000000).
|
|
const int clz_b = (b == 0) ? -1 : Common::CountLeadingZeros(b);
|
|
s = clz_a - clz_b;
|
|
|
|
// Decide how many bits to rotate right by, to put the low bit of that basic
|
|
// stretch in position a.
|
|
if (negate)
|
|
{
|
|
// If we inverted the input right at the start of this function, here's
|
|
// where we compensate: the number of set bits becomes the number of clear
|
|
// bits, and the rotation count is based on position b rather than position
|
|
// a (since b is the location of the 'lowest' 1 bit after inversion).
|
|
s = d - s;
|
|
r = (clz_b + 1) & (d - 1);
|
|
}
|
|
else
|
|
{
|
|
r = (clz_a + 1) & (d - 1);
|
|
}
|
|
|
|
// Now we're done, except for having to encode the S output in such a way that
|
|
// it gives both the number of set bits and the length of the repeated
|
|
// segment. The s field is encoded like this:
|
|
//
|
|
// imms size S
|
|
// ssssss 64 UInt(ssssss)
|
|
// 0sssss 32 UInt(sssss)
|
|
// 10ssss 16 UInt(ssss)
|
|
// 110sss 8 UInt(sss)
|
|
// 1110ss 4 UInt(ss)
|
|
// 11110s 2 UInt(s)
|
|
//
|
|
// So we 'or' (-d << 1) with our computed s to form imms.
|
|
s = ((-d << 1) | (s - 1)) & 0x3f;
|
|
|
|
valid = true;
|
|
}
|
|
|
|
constexpr operator bool() const { return valid; }
|
|
|
|
u8 r = 0;
|
|
u8 s = 0;
|
|
bool n = false;
|
|
bool valid = false;
|
|
};
|
|
|
|
class ARM64XEmitter
|
|
{
|
|
friend class ARM64FloatEmitter;
|
|
|
|
private:
|
|
u8* m_code;
|
|
u8* m_lastCacheFlushEnd;
|
|
|
|
void AddImmediate(ARM64Reg Rd, ARM64Reg Rn, u64 imm, bool shift, bool negative, bool flags);
|
|
void EncodeCompareBranchInst(u32 op, ARM64Reg Rt, const void* ptr);
|
|
void EncodeTestBranchInst(u32 op, ARM64Reg Rt, u8 bits, const void* ptr);
|
|
void EncodeUnconditionalBranchInst(u32 op, const void* ptr);
|
|
void EncodeUnconditionalBranchInst(u32 opc, u32 op2, u32 op3, u32 op4, ARM64Reg Rn);
|
|
void EncodeExceptionInst(u32 instenc, u32 imm);
|
|
void EncodeSystemInst(u32 op0, u32 op1, u32 CRn, u32 CRm, u32 op2, ARM64Reg Rt);
|
|
void EncodeArithmeticInst(u32 instenc, bool flags, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm,
|
|
ArithOption Option);
|
|
void EncodeArithmeticCarryInst(u32 op, bool flags, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void EncodeCondCompareImmInst(u32 op, ARM64Reg Rn, u32 imm, u32 nzcv, CCFlags cond);
|
|
void EncodeCondCompareRegInst(u32 op, ARM64Reg Rn, ARM64Reg Rm, u32 nzcv, CCFlags cond);
|
|
void EncodeCondSelectInst(u32 instenc, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, CCFlags cond);
|
|
void EncodeData1SrcInst(u32 instenc, ARM64Reg Rd, ARM64Reg Rn);
|
|
void EncodeData2SrcInst(u32 instenc, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void EncodeData3SrcInst(u32 instenc, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ARM64Reg Ra);
|
|
void EncodeLogicalInst(u32 instenc, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ArithOption Shift);
|
|
void EncodeLoadRegisterInst(u32 bitop, ARM64Reg Rt, u32 imm);
|
|
void EncodeLoadStoreExcInst(u32 instenc, ARM64Reg Rs, ARM64Reg Rt2, ARM64Reg Rn, ARM64Reg Rt);
|
|
void EncodeLoadStorePairedInst(u32 op, ARM64Reg Rt, ARM64Reg Rt2, ARM64Reg Rn, u32 imm);
|
|
void EncodeLoadStoreIndexedInst(u32 op, u32 op2, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void EncodeLoadStoreIndexedInst(u32 op, ARM64Reg Rt, ARM64Reg Rn, s32 imm, u8 size);
|
|
void EncodeMOVWideInst(u32 op, ARM64Reg Rd, u32 imm, ShiftAmount pos);
|
|
void EncodeBitfieldMOVInst(u32 op, ARM64Reg Rd, ARM64Reg Rn, u32 immr, u32 imms);
|
|
void EncodeLoadStoreRegisterOffset(u32 size, u32 opc, ARM64Reg Rt, ARM64Reg Rn, ArithOption Rm);
|
|
void EncodeAddSubImmInst(u32 op, bool flags, u32 shift, u32 imm, ARM64Reg Rn, ARM64Reg Rd);
|
|
void EncodeLogicalImmInst(u32 op, ARM64Reg Rd, ARM64Reg Rn, LogicalImm imm);
|
|
void EncodeLoadStorePair(u32 op, u32 load, IndexType type, ARM64Reg Rt, ARM64Reg Rt2, ARM64Reg Rn,
|
|
s32 imm);
|
|
void EncodeAddressInst(u32 op, ARM64Reg Rd, s32 imm);
|
|
void EncodeLoadStoreUnscaled(u32 size, u32 op, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
|
|
template <typename T>
|
|
void MOVI2RImpl(ARM64Reg Rd, T imm);
|
|
|
|
protected:
|
|
void Write32(u32 value);
|
|
|
|
public:
|
|
ARM64XEmitter() : m_code(nullptr), m_lastCacheFlushEnd(nullptr) {}
|
|
ARM64XEmitter(u8* code_ptr)
|
|
{
|
|
m_code = code_ptr;
|
|
m_lastCacheFlushEnd = code_ptr;
|
|
}
|
|
|
|
virtual ~ARM64XEmitter() {}
|
|
|
|
// 'end' and 'write_failed' are unused in the ARM code emitter at the moment.
|
|
// They're just here for interface compatibility with the x64 code emitter.
|
|
void SetCodePtr(u8* ptr, u8* end, bool write_failed = false);
|
|
|
|
void SetCodePtrUnsafe(u8* ptr);
|
|
void ReserveCodeSpace(u32 bytes);
|
|
u8* AlignCode16();
|
|
u8* AlignCodePage();
|
|
const u8* GetCodePtr() const;
|
|
void FlushIcache();
|
|
void FlushIcacheSection(u8* start, u8* end);
|
|
u8* GetWritableCodePtr();
|
|
|
|
// FixupBranch branching
|
|
void SetJumpTarget(FixupBranch const& branch);
|
|
FixupBranch CBZ(ARM64Reg Rt);
|
|
FixupBranch CBNZ(ARM64Reg Rt);
|
|
FixupBranch B(CCFlags cond);
|
|
FixupBranch TBZ(ARM64Reg Rt, u8 bit);
|
|
FixupBranch TBNZ(ARM64Reg Rt, u8 bit);
|
|
FixupBranch B();
|
|
FixupBranch BL();
|
|
|
|
// Compare and Branch
|
|
void CBZ(ARM64Reg Rt, const void* ptr);
|
|
void CBNZ(ARM64Reg Rt, const void* ptr);
|
|
|
|
// Conditional Branch
|
|
void B(CCFlags cond, const void* ptr);
|
|
|
|
// Test and Branch
|
|
void TBZ(ARM64Reg Rt, u8 bits, const void* ptr);
|
|
void TBNZ(ARM64Reg Rt, u8 bits, const void* ptr);
|
|
|
|
// Unconditional Branch
|
|
void B(const void* ptr);
|
|
void BL(const void* ptr);
|
|
|
|
// Unconditional Branch (register)
|
|
void BR(ARM64Reg Rn);
|
|
void BLR(ARM64Reg Rn);
|
|
void RET(ARM64Reg Rn = ARM64Reg::X30);
|
|
void ERET();
|
|
void DRPS();
|
|
|
|
// Exception generation
|
|
void SVC(u32 imm);
|
|
void HVC(u32 imm);
|
|
void SMC(u32 imm);
|
|
void BRK(u32 imm);
|
|
void HLT(u32 imm);
|
|
void DCPS1(u32 imm);
|
|
void DCPS2(u32 imm);
|
|
void DCPS3(u32 imm);
|
|
|
|
// System
|
|
void _MSR(PStateField field, u8 imm);
|
|
void _MSR(PStateField field, ARM64Reg Rt);
|
|
void MRS(ARM64Reg Rt, PStateField field);
|
|
void CNTVCT(ARM64Reg Rt);
|
|
|
|
void HINT(SystemHint op);
|
|
void NOP() { HINT(SystemHint::NOP); }
|
|
void SEV() { HINT(SystemHint::SEV); }
|
|
void SEVL() { HINT(SystemHint::SEVL); }
|
|
void WFE() { HINT(SystemHint::WFE); }
|
|
void WFI() { HINT(SystemHint::WFI); }
|
|
void YIELD() { HINT(SystemHint::YIELD); }
|
|
|
|
void CLREX();
|
|
void DSB(BarrierType type);
|
|
void DMB(BarrierType type);
|
|
void ISB(BarrierType type);
|
|
|
|
// Add/Subtract (Extended/Shifted register)
|
|
void ADD(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void ADD(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ArithOption Option);
|
|
void ADDS(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void ADDS(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ArithOption Option);
|
|
void SUB(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void SUB(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ArithOption Option);
|
|
void SUBS(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void SUBS(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ArithOption Option);
|
|
void CMN(ARM64Reg Rn, ARM64Reg Rm);
|
|
void CMN(ARM64Reg Rn, ARM64Reg Rm, ArithOption Option);
|
|
void CMP(ARM64Reg Rn, ARM64Reg Rm);
|
|
void CMP(ARM64Reg Rn, ARM64Reg Rm, ArithOption Option);
|
|
|
|
// Add/Subtract (with carry)
|
|
void ADC(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void ADCS(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void SBC(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void SBCS(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
|
|
// Conditional Compare (immediate)
|
|
void CCMN(ARM64Reg Rn, u32 imm, u32 nzcv, CCFlags cond);
|
|
void CCMP(ARM64Reg Rn, u32 imm, u32 nzcv, CCFlags cond);
|
|
|
|
// Conditional Compare (register)
|
|
void CCMN(ARM64Reg Rn, ARM64Reg Rm, u32 nzcv, CCFlags cond);
|
|
void CCMP(ARM64Reg Rn, ARM64Reg Rm, u32 nzcv, CCFlags cond);
|
|
|
|
// Conditional Select
|
|
void CSEL(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, CCFlags cond);
|
|
void CSINC(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, CCFlags cond);
|
|
void CSINV(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, CCFlags cond);
|
|
void CSNEG(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, CCFlags cond);
|
|
|
|
// Aliases
|
|
void CSET(ARM64Reg Rd, CCFlags cond)
|
|
{
|
|
ARM64Reg zr = Is64Bit(Rd) ? ARM64Reg::ZR : ARM64Reg::WZR;
|
|
CSINC(Rd, zr, zr, (CCFlags)((u32)cond ^ 1));
|
|
}
|
|
void CSETM(ARM64Reg Rd, CCFlags cond)
|
|
{
|
|
ARM64Reg zr = Is64Bit(Rd) ? ARM64Reg::ZR : ARM64Reg::WZR;
|
|
CSINV(Rd, zr, zr, (CCFlags)((u32)cond ^ 1));
|
|
}
|
|
void NEG(ARM64Reg Rd, ARM64Reg Rs) { SUB(Rd, Is64Bit(Rd) ? ARM64Reg::ZR : ARM64Reg::WZR, Rs); }
|
|
void NEG(ARM64Reg Rd, ARM64Reg Rs, ArithOption Option)
|
|
{
|
|
SUB(Rd, Is64Bit(Rd) ? ARM64Reg::ZR : ARM64Reg::WZR, Rs, Option);
|
|
}
|
|
void NEGS(ARM64Reg Rd, ARM64Reg Rs) { SUBS(Rd, Is64Bit(Rd) ? ARM64Reg::ZR : ARM64Reg::WZR, Rs); }
|
|
void NEGS(ARM64Reg Rd, ARM64Reg Rs, ArithOption Option)
|
|
{
|
|
SUBS(Rd, Is64Bit(Rd) ? ARM64Reg::ZR : ARM64Reg::WZR, Rs, Option);
|
|
}
|
|
// Data-Processing 1 source
|
|
void RBIT(ARM64Reg Rd, ARM64Reg Rn);
|
|
void REV16(ARM64Reg Rd, ARM64Reg Rn);
|
|
void REV32(ARM64Reg Rd, ARM64Reg Rn);
|
|
void REV64(ARM64Reg Rd, ARM64Reg Rn);
|
|
void CLZ(ARM64Reg Rd, ARM64Reg Rn);
|
|
void CLS(ARM64Reg Rd, ARM64Reg Rn);
|
|
|
|
// Data-Processing 2 source
|
|
void UDIV(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void SDIV(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void LSLV(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void LSRV(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void ASRV(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void RORV(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void CRC32B(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void CRC32H(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void CRC32W(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void CRC32CB(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void CRC32CH(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void CRC32CW(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void CRC32X(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void CRC32CX(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
|
|
// Data-Processing 3 source
|
|
void MADD(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ARM64Reg Ra);
|
|
void MSUB(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ARM64Reg Ra);
|
|
void SMADDL(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ARM64Reg Ra);
|
|
void SMULL(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void SMSUBL(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ARM64Reg Ra);
|
|
void SMULH(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void UMADDL(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ARM64Reg Ra);
|
|
void UMULL(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void UMSUBL(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ARM64Reg Ra);
|
|
void UMULH(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void MUL(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void MNEG(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
|
|
// Logical (shifted register)
|
|
void AND(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ArithOption Shift);
|
|
void BIC(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ArithOption Shift);
|
|
void ORR(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ArithOption Shift);
|
|
void ORN(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ArithOption Shift);
|
|
void EOR(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ArithOption Shift);
|
|
void EON(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ArithOption Shift);
|
|
void ANDS(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ArithOption Shift);
|
|
void BICS(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ArithOption Shift);
|
|
void TST(ARM64Reg Rn, ARM64Reg Rm) { ANDS(Is64Bit(Rn) ? ARM64Reg::ZR : ARM64Reg::WZR, Rn, Rm); }
|
|
void TST(ARM64Reg Rn, ARM64Reg Rm, ArithOption Shift)
|
|
{
|
|
ANDS(Is64Bit(Rn) ? ARM64Reg::ZR : ARM64Reg::WZR, Rn, Rm, Shift);
|
|
}
|
|
|
|
// Wrap the above for saner syntax
|
|
void AND(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm)
|
|
{
|
|
AND(Rd, Rn, Rm, ArithOption(Rd, ShiftType::LSL, 0));
|
|
}
|
|
void BIC(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm)
|
|
{
|
|
BIC(Rd, Rn, Rm, ArithOption(Rd, ShiftType::LSL, 0));
|
|
}
|
|
void ORR(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm)
|
|
{
|
|
ORR(Rd, Rn, Rm, ArithOption(Rd, ShiftType::LSL, 0));
|
|
}
|
|
void ORN(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm)
|
|
{
|
|
ORN(Rd, Rn, Rm, ArithOption(Rd, ShiftType::LSL, 0));
|
|
}
|
|
void EOR(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm)
|
|
{
|
|
EOR(Rd, Rn, Rm, ArithOption(Rd, ShiftType::LSL, 0));
|
|
}
|
|
void EON(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm)
|
|
{
|
|
EON(Rd, Rn, Rm, ArithOption(Rd, ShiftType::LSL, 0));
|
|
}
|
|
void ANDS(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm)
|
|
{
|
|
ANDS(Rd, Rn, Rm, ArithOption(Rd, ShiftType::LSL, 0));
|
|
}
|
|
void BICS(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm)
|
|
{
|
|
BICS(Rd, Rn, Rm, ArithOption(Rd, ShiftType::LSL, 0));
|
|
}
|
|
// Convenience wrappers around ORR. These match the official convenience syntax.
|
|
void MOV(ARM64Reg Rd, ARM64Reg Rm, ArithOption Shift);
|
|
void MOV(ARM64Reg Rd, ARM64Reg Rm);
|
|
void MVN(ARM64Reg Rd, ARM64Reg Rm);
|
|
|
|
// Convenience wrappers around UBFM/EXTR.
|
|
void LSR(ARM64Reg Rd, ARM64Reg Rm, int shift);
|
|
void LSL(ARM64Reg Rd, ARM64Reg Rm, int shift);
|
|
void ASR(ARM64Reg Rd, ARM64Reg Rm, int shift);
|
|
void ROR(ARM64Reg Rd, ARM64Reg Rm, int shift);
|
|
|
|
// Logical (immediate)
|
|
void AND(ARM64Reg Rd, ARM64Reg Rn, LogicalImm imm);
|
|
void ANDS(ARM64Reg Rd, ARM64Reg Rn, LogicalImm imm);
|
|
void EOR(ARM64Reg Rd, ARM64Reg Rn, LogicalImm imm);
|
|
void ORR(ARM64Reg Rd, ARM64Reg Rn, LogicalImm imm);
|
|
void TST(ARM64Reg Rn, LogicalImm imm);
|
|
// Add/subtract (immediate)
|
|
void ADD(ARM64Reg Rd, ARM64Reg Rn, u32 imm, bool shift = false);
|
|
void ADDS(ARM64Reg Rd, ARM64Reg Rn, u32 imm, bool shift = false);
|
|
void SUB(ARM64Reg Rd, ARM64Reg Rn, u32 imm, bool shift = false);
|
|
void SUBS(ARM64Reg Rd, ARM64Reg Rn, u32 imm, bool shift = false);
|
|
void CMP(ARM64Reg Rn, u32 imm, bool shift = false);
|
|
void CMN(ARM64Reg Rn, u32 imm, bool shift = false);
|
|
|
|
// Data Processing (Immediate)
|
|
void MOVZ(ARM64Reg Rd, u32 imm, ShiftAmount pos = ShiftAmount::Shift0);
|
|
void MOVN(ARM64Reg Rd, u32 imm, ShiftAmount pos = ShiftAmount::Shift0);
|
|
void MOVK(ARM64Reg Rd, u32 imm, ShiftAmount pos = ShiftAmount::Shift0);
|
|
|
|
// Bitfield move
|
|
void BFM(ARM64Reg Rd, ARM64Reg Rn, u32 immr, u32 imms);
|
|
void SBFM(ARM64Reg Rd, ARM64Reg Rn, u32 immr, u32 imms);
|
|
void UBFM(ARM64Reg Rd, ARM64Reg Rn, u32 immr, u32 imms);
|
|
void BFI(ARM64Reg Rd, ARM64Reg Rn, u32 lsb, u32 width);
|
|
void BFXIL(ARM64Reg Rd, ARM64Reg Rn, u32 lsb, u32 width);
|
|
void UBFIZ(ARM64Reg Rd, ARM64Reg Rn, u32 lsb, u32 width);
|
|
|
|
// Extract register (ROR with two inputs, if same then faster on A67)
|
|
void EXTR(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, u32 shift);
|
|
|
|
// Aliases
|
|
void SXTB(ARM64Reg Rd, ARM64Reg Rn);
|
|
void SXTH(ARM64Reg Rd, ARM64Reg Rn);
|
|
void SXTW(ARM64Reg Rd, ARM64Reg Rn);
|
|
void UXTB(ARM64Reg Rd, ARM64Reg Rn);
|
|
void UXTH(ARM64Reg Rd, ARM64Reg Rn);
|
|
|
|
void UBFX(ARM64Reg Rd, ARM64Reg Rn, int lsb, int width) { UBFM(Rd, Rn, lsb, lsb + width - 1); }
|
|
// Load Register (Literal)
|
|
void LDR(ARM64Reg Rt, u32 imm);
|
|
void LDRSW(ARM64Reg Rt, u32 imm);
|
|
void PRFM(ARM64Reg Rt, u32 imm);
|
|
|
|
// Load/Store Exclusive
|
|
void STXRB(ARM64Reg Rs, ARM64Reg Rt, ARM64Reg Rn);
|
|
void STLXRB(ARM64Reg Rs, ARM64Reg Rt, ARM64Reg Rn);
|
|
void LDXRB(ARM64Reg Rt, ARM64Reg Rn);
|
|
void LDAXRB(ARM64Reg Rt, ARM64Reg Rn);
|
|
void STLRB(ARM64Reg Rt, ARM64Reg Rn);
|
|
void LDARB(ARM64Reg Rt, ARM64Reg Rn);
|
|
void STXRH(ARM64Reg Rs, ARM64Reg Rt, ARM64Reg Rn);
|
|
void STLXRH(ARM64Reg Rs, ARM64Reg Rt, ARM64Reg Rn);
|
|
void LDXRH(ARM64Reg Rt, ARM64Reg Rn);
|
|
void LDAXRH(ARM64Reg Rt, ARM64Reg Rn);
|
|
void STLRH(ARM64Reg Rt, ARM64Reg Rn);
|
|
void LDARH(ARM64Reg Rt, ARM64Reg Rn);
|
|
void STXR(ARM64Reg Rs, ARM64Reg Rt, ARM64Reg Rn);
|
|
void STLXR(ARM64Reg Rs, ARM64Reg Rt, ARM64Reg Rn);
|
|
void STXP(ARM64Reg Rs, ARM64Reg Rt, ARM64Reg Rt2, ARM64Reg Rn);
|
|
void STLXP(ARM64Reg Rs, ARM64Reg Rt, ARM64Reg Rt2, ARM64Reg Rn);
|
|
void LDXR(ARM64Reg Rt, ARM64Reg Rn);
|
|
void LDAXR(ARM64Reg Rt, ARM64Reg Rn);
|
|
void LDXP(ARM64Reg Rt, ARM64Reg Rt2, ARM64Reg Rn);
|
|
void LDAXP(ARM64Reg Rt, ARM64Reg Rt2, ARM64Reg Rn);
|
|
void STLR(ARM64Reg Rt, ARM64Reg Rn);
|
|
void LDAR(ARM64Reg Rt, ARM64Reg Rn);
|
|
|
|
// Load/Store no-allocate pair (offset)
|
|
void STNP(ARM64Reg Rt, ARM64Reg Rt2, ARM64Reg Rn, u32 imm);
|
|
void LDNP(ARM64Reg Rt, ARM64Reg Rt2, ARM64Reg Rn, u32 imm);
|
|
|
|
// Load/Store register (immediate indexed)
|
|
void STRB(IndexType type, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void LDRB(IndexType type, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void LDRSB(IndexType type, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void STRH(IndexType type, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void LDRH(IndexType type, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void LDRSH(IndexType type, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void STR(IndexType type, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void LDR(IndexType type, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void LDRSW(IndexType type, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
|
|
// Load/Store register (register offset)
|
|
void STRB(ARM64Reg Rt, ARM64Reg Rn, ArithOption Rm);
|
|
void LDRB(ARM64Reg Rt, ARM64Reg Rn, ArithOption Rm);
|
|
void LDRSB(ARM64Reg Rt, ARM64Reg Rn, ArithOption Rm);
|
|
void STRH(ARM64Reg Rt, ARM64Reg Rn, ArithOption Rm);
|
|
void LDRH(ARM64Reg Rt, ARM64Reg Rn, ArithOption Rm);
|
|
void LDRSH(ARM64Reg Rt, ARM64Reg Rn, ArithOption Rm);
|
|
void STR(ARM64Reg Rt, ARM64Reg Rn, ArithOption Rm);
|
|
void LDR(ARM64Reg Rt, ARM64Reg Rn, ArithOption Rm);
|
|
void LDRSW(ARM64Reg Rt, ARM64Reg Rn, ArithOption Rm);
|
|
void PRFM(ARM64Reg Rt, ARM64Reg Rn, ArithOption Rm);
|
|
|
|
// Load/Store register (unscaled offset)
|
|
void STURB(ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void LDURB(ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void LDURSB(ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void STURH(ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void LDURH(ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void LDURSH(ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void STUR(ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void LDUR(ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void LDURSW(ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
|
|
// Load/Store pair
|
|
void LDP(IndexType type, ARM64Reg Rt, ARM64Reg Rt2, ARM64Reg Rn, s32 imm);
|
|
void LDPSW(IndexType type, ARM64Reg Rt, ARM64Reg Rt2, ARM64Reg Rn, s32 imm);
|
|
void STP(IndexType type, ARM64Reg Rt, ARM64Reg Rt2, ARM64Reg Rn, s32 imm);
|
|
|
|
// Address of label/page PC-relative
|
|
void ADR(ARM64Reg Rd, s32 imm);
|
|
void ADRP(ARM64Reg Rd, s64 imm);
|
|
|
|
// Wrapper around ADR/ADRP/MOVZ/MOVN/MOVK
|
|
void MOVI2R(ARM64Reg Rd, u64 imm);
|
|
bool MOVI2R2(ARM64Reg Rd, u64 imm1, u64 imm2);
|
|
template <class P>
|
|
void MOVP2R(ARM64Reg Rd, P* ptr)
|
|
{
|
|
ASSERT_MSG(DYNA_REC, Is64Bit(Rd), "Can't store pointers in 32-bit registers");
|
|
MOVI2R(Rd, (uintptr_t)ptr);
|
|
}
|
|
|
|
// Wrapper around AND x, y, imm etc.
|
|
// If you are sure the imm will work, preferably construct a LogicalImm directly instead,
|
|
// since that is constexpr and thus can be done at compile-time for constant values.
|
|
void ANDI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch);
|
|
void ANDSI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch);
|
|
void TSTI2R(ARM64Reg Rn, u64 imm, ARM64Reg scratch)
|
|
{
|
|
ANDSI2R(Is64Bit(Rn) ? ARM64Reg::ZR : ARM64Reg::WZR, Rn, imm, scratch);
|
|
}
|
|
void ORRI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch);
|
|
void EORI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch);
|
|
|
|
void ADDI2R_internal(ARM64Reg Rd, ARM64Reg Rn, u64 imm, bool negative, bool flags,
|
|
ARM64Reg scratch);
|
|
void ADDI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch = ARM64Reg::INVALID_REG);
|
|
void ADDSI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch = ARM64Reg::INVALID_REG);
|
|
void SUBI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch = ARM64Reg::INVALID_REG);
|
|
void SUBSI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch = ARM64Reg::INVALID_REG);
|
|
void CMPI2R(ARM64Reg Rn, u64 imm, ARM64Reg scratch = ARM64Reg::INVALID_REG);
|
|
|
|
bool TryADDI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm);
|
|
bool TrySUBI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm);
|
|
bool TryCMPI2R(ARM64Reg Rn, u64 imm);
|
|
|
|
bool TryANDI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm);
|
|
bool TryORRI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm);
|
|
bool TryEORI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm);
|
|
|
|
// ABI related
|
|
void ABI_PushRegisters(BitSet32 registers);
|
|
void ABI_PopRegisters(BitSet32 registers, BitSet32 ignore_mask = BitSet32(0));
|
|
|
|
// Utility to generate a call to a std::function object.
|
|
//
|
|
// Unfortunately, calling operator() directly is undefined behavior in C++
|
|
// (this method might be a thunk in the case of multi-inheritance) so we
|
|
// have to go through a trampoline function.
|
|
template <typename T, typename... Args>
|
|
static T CallLambdaTrampoline(const std::function<T(Args...)>* f, Args... args)
|
|
{
|
|
return (*f)(args...);
|
|
}
|
|
|
|
// This function expects you to have set up the state.
|
|
// Overwrites X0 and X8
|
|
template <typename T, typename... Args>
|
|
ARM64Reg ABI_SetupLambda(const std::function<T(Args...)>* f)
|
|
{
|
|
auto trampoline = &ARM64XEmitter::CallLambdaTrampoline<T, Args...>;
|
|
MOVP2R(ARM64Reg::X8, trampoline);
|
|
MOVP2R(ARM64Reg::X0, const_cast<void*>((const void*)f));
|
|
return ARM64Reg::X8;
|
|
}
|
|
|
|
// Plain function call
|
|
void QuickCallFunction(ARM64Reg scratchreg, const void* func);
|
|
template <typename T>
|
|
void QuickCallFunction(ARM64Reg scratchreg, T func)
|
|
{
|
|
QuickCallFunction(scratchreg, (const void*)func);
|
|
}
|
|
};
|
|
|
|
class ARM64FloatEmitter
|
|
{
|
|
public:
|
|
ARM64FloatEmitter(ARM64XEmitter* emit) : m_emit(emit) {}
|
|
void LDR(u8 size, IndexType type, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void STR(u8 size, IndexType type, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
|
|
// Loadstore unscaled
|
|
void LDUR(u8 size, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void STUR(u8 size, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
|
|
// Loadstore single structure
|
|
void LD1(u8 size, ARM64Reg Rt, u8 index, ARM64Reg Rn);
|
|
void LD1(u8 size, ARM64Reg Rt, u8 index, ARM64Reg Rn, ARM64Reg Rm);
|
|
void LD1R(u8 size, ARM64Reg Rt, ARM64Reg Rn);
|
|
void LD2R(u8 size, ARM64Reg Rt, ARM64Reg Rn);
|
|
void LD1R(u8 size, ARM64Reg Rt, ARM64Reg Rn, ARM64Reg Rm);
|
|
void LD2R(u8 size, ARM64Reg Rt, ARM64Reg Rn, ARM64Reg Rm);
|
|
void ST1(u8 size, ARM64Reg Rt, u8 index, ARM64Reg Rn);
|
|
void ST1(u8 size, ARM64Reg Rt, u8 index, ARM64Reg Rn, ARM64Reg Rm);
|
|
|
|
// Loadstore multiple structure
|
|
void LD1(u8 size, u8 count, ARM64Reg Rt, ARM64Reg Rn);
|
|
void LD1(u8 size, u8 count, IndexType type, ARM64Reg Rt, ARM64Reg Rn, ARM64Reg Rm = ARM64Reg::SP);
|
|
void ST1(u8 size, u8 count, ARM64Reg Rt, ARM64Reg Rn);
|
|
void ST1(u8 size, u8 count, IndexType type, ARM64Reg Rt, ARM64Reg Rn, ARM64Reg Rm = ARM64Reg::SP);
|
|
|
|
// Loadstore paired
|
|
void LDP(u8 size, IndexType type, ARM64Reg Rt, ARM64Reg Rt2, ARM64Reg Rn, s32 imm);
|
|
void STP(u8 size, IndexType type, ARM64Reg Rt, ARM64Reg Rt2, ARM64Reg Rn, s32 imm);
|
|
|
|
// Loadstore register offset
|
|
void STR(u8 size, ARM64Reg Rt, ARM64Reg Rn, ArithOption Rm);
|
|
void LDR(u8 size, ARM64Reg Rt, ARM64Reg Rn, ArithOption Rm);
|
|
|
|
// Scalar - 1 Source
|
|
void FABS(ARM64Reg Rd, ARM64Reg Rn);
|
|
void FNEG(ARM64Reg Rd, ARM64Reg Rn);
|
|
void FSQRT(ARM64Reg Rd, ARM64Reg Rn);
|
|
void FMOV(ARM64Reg Rd, ARM64Reg Rn, bool top = false); // Also generalized move between GPR/FP
|
|
void FRECPE(ARM64Reg Rd, ARM64Reg Rn);
|
|
void FRSQRTE(ARM64Reg Rd, ARM64Reg Rn);
|
|
|
|
// Scalar - 2 Source
|
|
void ADD(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FADD(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FMUL(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FSUB(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FDIV(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FMAX(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FMIN(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FMAXNM(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FMINNM(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FNMUL(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
|
|
// Scalar - 3 Source. Note - the accumulator is last on ARM!
|
|
void FMADD(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ARM64Reg Ra);
|
|
void FMSUB(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ARM64Reg Ra);
|
|
void FNMADD(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ARM64Reg Ra);
|
|
void FNMSUB(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ARM64Reg Ra);
|
|
|
|
// Scalar floating point immediate
|
|
void FMOV(ARM64Reg Rd, uint8_t imm8);
|
|
|
|
// Vector
|
|
void ADD(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void AND(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void BIC(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void BIF(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void BIT(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void BSL(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void DUP(u8 size, ARM64Reg Rd, ARM64Reg Rn, u8 index);
|
|
void FABS(u8 size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void FADD(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FMAX(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FMLA(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FMLS(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FMIN(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FCVTL(u8 size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void FCVTL2(u8 size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void FCVTN(u8 dest_size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void FCVTN2(u8 dest_size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void FCVTZS(u8 size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void FCVTZU(u8 size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void FDIV(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FMUL(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void FNEG(u8 size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void FRECPE(u8 size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void FRSQRTE(u8 size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void FSUB(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void NOT(ARM64Reg Rd, ARM64Reg Rn);
|
|
void ORR(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void ORN(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void MOV(ARM64Reg Rd, ARM64Reg Rn) { ORR(Rd, Rn, Rn); }
|
|
void REV16(u8 size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void REV32(u8 size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void REV64(u8 size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void SCVTF(u8 size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void UCVTF(u8 size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void SCVTF(u8 size, ARM64Reg Rd, ARM64Reg Rn, int scale);
|
|
void UCVTF(u8 size, ARM64Reg Rd, ARM64Reg Rn, int scale);
|
|
void SQXTN(u8 dest_size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void SQXTN2(u8 dest_size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void UQXTN(u8 dest_size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void UQXTN2(u8 dest_size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void XTN(u8 dest_size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void XTN2(u8 dest_size, ARM64Reg Rd, ARM64Reg Rn);
|
|
|
|
// Move
|
|
void DUP(u8 size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void INS(u8 size, ARM64Reg Rd, u8 index, ARM64Reg Rn);
|
|
void INS(u8 size, ARM64Reg Rd, u8 index1, ARM64Reg Rn, u8 index2);
|
|
void UMOV(u8 size, ARM64Reg Rd, ARM64Reg Rn, u8 index);
|
|
void SMOV(u8 size, ARM64Reg Rd, ARM64Reg Rn, u8 index);
|
|
|
|
// One source
|
|
void FCVT(u8 size_to, u8 size_from, ARM64Reg Rd, ARM64Reg Rn);
|
|
|
|
// Scalar convert float to int, in a lot of variants.
|
|
// Note that the scalar version of this operation has two encodings, one that goes to an integer
|
|
// register
|
|
// and one that outputs to a scalar fp register.
|
|
void FCVTS(ARM64Reg Rd, ARM64Reg Rn, RoundingMode round);
|
|
void FCVTU(ARM64Reg Rd, ARM64Reg Rn, RoundingMode round);
|
|
|
|
// Scalar convert int to float. No rounding mode specifier necessary.
|
|
void SCVTF(ARM64Reg Rd, ARM64Reg Rn);
|
|
void UCVTF(ARM64Reg Rd, ARM64Reg Rn);
|
|
|
|
// Scalar fixed point to float. scale is the number of fractional bits.
|
|
void SCVTF(ARM64Reg Rd, ARM64Reg Rn, int scale);
|
|
void UCVTF(ARM64Reg Rd, ARM64Reg Rn, int scale);
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|
|
|
// Float comparison
|
|
void FCMP(ARM64Reg Rn, ARM64Reg Rm);
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|
void FCMP(ARM64Reg Rn);
|
|
void FCMPE(ARM64Reg Rn, ARM64Reg Rm);
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|
void FCMPE(ARM64Reg Rn);
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|
void FCMEQ(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
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void FCMEQ(u8 size, ARM64Reg Rd, ARM64Reg Rn);
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void FCMGE(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
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|
void FCMGE(u8 size, ARM64Reg Rd, ARM64Reg Rn);
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|
void FCMGT(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
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|
void FCMGT(u8 size, ARM64Reg Rd, ARM64Reg Rn);
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|
void FCMLE(u8 size, ARM64Reg Rd, ARM64Reg Rn);
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|
void FCMLT(u8 size, ARM64Reg Rd, ARM64Reg Rn);
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|
void FACGE(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
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|
void FACGT(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
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|
|
|
// Conditional select
|
|
void FCSEL(ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, CCFlags cond);
|
|
|
|
// Permute
|
|
void UZP1(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
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|
void TRN1(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void ZIP1(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void UZP2(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void TRN2(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void ZIP2(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
|
|
// Shift by immediate
|
|
void SSHLL(u8 src_size, ARM64Reg Rd, ARM64Reg Rn, u32 shift);
|
|
void SSHLL2(u8 src_size, ARM64Reg Rd, ARM64Reg Rn, u32 shift);
|
|
void USHLL(u8 src_size, ARM64Reg Rd, ARM64Reg Rn, u32 shift);
|
|
void USHLL2(u8 src_size, ARM64Reg Rd, ARM64Reg Rn, u32 shift);
|
|
void SHRN(u8 dest_size, ARM64Reg Rd, ARM64Reg Rn, u32 shift);
|
|
void SHRN2(u8 dest_size, ARM64Reg Rd, ARM64Reg Rn, u32 shift);
|
|
void SXTL(u8 src_size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void SXTL2(u8 src_size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void UXTL(u8 src_size, ARM64Reg Rd, ARM64Reg Rn);
|
|
void UXTL2(u8 src_size, ARM64Reg Rd, ARM64Reg Rn);
|
|
|
|
// vector x indexed element
|
|
void FMUL(u8 size, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, u8 index);
|
|
void FMLA(u8 esize, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, u8 index);
|
|
|
|
// Modified Immediate
|
|
void MOVI(u8 size, ARM64Reg Rd, u64 imm, u8 shift = 0);
|
|
void ORR(u8 size, ARM64Reg Rd, u8 imm, u8 shift = 0);
|
|
void BIC(u8 size, ARM64Reg Rd, u8 imm, u8 shift = 0);
|
|
|
|
void MOVI2F(ARM64Reg Rd, float value, ARM64Reg scratch = ARM64Reg::INVALID_REG,
|
|
bool negate = false);
|
|
void MOVI2FDUP(ARM64Reg Rd, float value, ARM64Reg scratch = ARM64Reg::INVALID_REG);
|
|
|
|
// ABI related
|
|
void ABI_PushRegisters(BitSet32 registers, ARM64Reg tmp = ARM64Reg::INVALID_REG);
|
|
void ABI_PopRegisters(BitSet32 registers, ARM64Reg tmp = ARM64Reg::INVALID_REG);
|
|
|
|
private:
|
|
ARM64XEmitter* m_emit;
|
|
inline void Write32(u32 value) { m_emit->Write32(value); }
|
|
// Emitting functions
|
|
void EmitLoadStoreImmediate(u8 size, u32 opc, IndexType type, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void EmitScalar2Source(bool M, bool S, u32 type, u32 opcode, ARM64Reg Rd, ARM64Reg Rn,
|
|
ARM64Reg Rm);
|
|
void EmitScalarThreeSame(bool U, u32 size, u32 opcode, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void EmitThreeSame(bool U, u32 size, u32 opcode, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void EmitCopy(bool Q, u32 op, u32 imm5, u32 imm4, ARM64Reg Rd, ARM64Reg Rn);
|
|
void EmitScalar2RegMisc(bool U, u32 size, u32 opcode, ARM64Reg Rd, ARM64Reg Rn);
|
|
void Emit2RegMisc(bool Q, bool U, u32 size, u32 opcode, ARM64Reg Rd, ARM64Reg Rn);
|
|
void EmitLoadStoreSingleStructure(bool L, bool R, u32 opcode, bool S, u32 size, ARM64Reg Rt,
|
|
ARM64Reg Rn);
|
|
void EmitLoadStoreSingleStructure(bool L, bool R, u32 opcode, bool S, u32 size, ARM64Reg Rt,
|
|
ARM64Reg Rn, ARM64Reg Rm);
|
|
void Emit1Source(bool M, bool S, u32 type, u32 opcode, ARM64Reg Rd, ARM64Reg Rn);
|
|
void EmitConversion(bool sf, bool S, u32 type, u32 rmode, u32 opcode, ARM64Reg Rd, ARM64Reg Rn);
|
|
void EmitConversion2(bool sf, bool S, bool direction, u32 type, u32 rmode, u32 opcode, int scale,
|
|
ARM64Reg Rd, ARM64Reg Rn);
|
|
void EmitCompare(bool M, bool S, u32 op, u32 opcode2, ARM64Reg Rn, ARM64Reg Rm);
|
|
void EmitCondSelect(bool M, bool S, CCFlags cond, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void EmitPermute(u32 size, u32 op, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm);
|
|
void EmitScalarImm(bool M, bool S, u32 type, u32 imm5, ARM64Reg Rd, u32 imm8);
|
|
void EmitShiftImm(bool Q, bool U, u32 immh, u32 immb, u32 opcode, ARM64Reg Rd, ARM64Reg Rn);
|
|
void EmitScalarShiftImm(bool U, u32 immh, u32 immb, u32 opcode, ARM64Reg Rd, ARM64Reg Rn);
|
|
void EmitLoadStoreMultipleStructure(u32 size, bool L, u32 opcode, ARM64Reg Rt, ARM64Reg Rn);
|
|
void EmitLoadStoreMultipleStructurePost(u32 size, bool L, u32 opcode, ARM64Reg Rt, ARM64Reg Rn,
|
|
ARM64Reg Rm);
|
|
void EmitScalar1Source(bool M, bool S, u32 type, u32 opcode, ARM64Reg Rd, ARM64Reg Rn);
|
|
void EmitVectorxElement(bool U, u32 size, bool L, u32 opcode, bool H, ARM64Reg Rd, ARM64Reg Rn,
|
|
ARM64Reg Rm);
|
|
void EmitLoadStoreUnscaled(u32 size, u32 op, ARM64Reg Rt, ARM64Reg Rn, s32 imm);
|
|
void EmitConvertScalarToInt(ARM64Reg Rd, ARM64Reg Rn, RoundingMode round, bool sign);
|
|
void EmitScalar3Source(bool isDouble, ARM64Reg Rd, ARM64Reg Rn, ARM64Reg Rm, ARM64Reg Ra,
|
|
int opcode);
|
|
void EncodeLoadStorePair(u32 size, bool load, IndexType type, ARM64Reg Rt, ARM64Reg Rt2,
|
|
ARM64Reg Rn, s32 imm);
|
|
void EncodeLoadStoreRegisterOffset(u32 size, bool load, ARM64Reg Rt, ARM64Reg Rn, ArithOption Rm);
|
|
void EncodeModImm(bool Q, u8 op, u8 cmode, u8 o2, ARM64Reg Rd, u8 abcdefgh);
|
|
|
|
void ORR_BIC(u8 size, ARM64Reg Rd, u8 imm, u8 shift, u8 op);
|
|
|
|
void SSHLL(u8 src_size, ARM64Reg Rd, ARM64Reg Rn, u32 shift, bool upper);
|
|
void USHLL(u8 src_size, ARM64Reg Rd, ARM64Reg Rn, u32 shift, bool upper);
|
|
void SHRN(u8 dest_size, ARM64Reg Rd, ARM64Reg Rn, u32 shift, bool upper);
|
|
void SXTL(u8 src_size, ARM64Reg Rd, ARM64Reg Rn, bool upper);
|
|
void UXTL(u8 src_size, ARM64Reg Rd, ARM64Reg Rn, bool upper);
|
|
};
|
|
|
|
class ARM64CodeBlock : public Common::CodeBlock<ARM64XEmitter>
|
|
{
|
|
private:
|
|
void PoisonMemory() override
|
|
{
|
|
// If our memory isn't a multiple of u32 then this won't write the last remaining bytes with
|
|
// anything
|
|
// Less than optimal, but there would be nothing we could do but throw a runtime warning anyway.
|
|
// AArch64: 0xD4200000 = BRK 0
|
|
constexpr u32 brk_0 = 0xD4200000;
|
|
|
|
for (size_t i = 0; i < region_size; i += sizeof(u32))
|
|
{
|
|
std::memcpy(region + i, &brk_0, sizeof(u32));
|
|
}
|
|
}
|
|
};
|
|
} // namespace Arm64Gen
|