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// Copyright (c) 2023- PPSSPP Project.
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// This program is free software: you can redistribute it and/or modify
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// it under the terms of the GNU General Public License as published by
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// the Free Software Foundation, version 2.0 or later versions.
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// This program is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
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// GNU General Public License 2.0 for more details.
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// A copy of the GPL 2.0 should have been included with the program.
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// If not, see http://www.gnu.org/licenses/
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// Official git repository and contact information can be found at
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// https://github.com/hrydgard/ppsspp and http://www.ppsspp.org/.
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#include "ppsspp_config.h"
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// In other words, PPSSPP_ARCH(ARM64) || DISASM_ALL.
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#if PPSSPP_ARCH(ARM64) || (PPSSPP_PLATFORM(WINDOWS) && !defined(__LIBRETRO__))
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#include <algorithm>
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#include "Common/CPUDetect.h"
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#include "Core/MemMap.h"
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#include "Core/MIPS/ARM64/Arm64IRJit.h"
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#include "Core/MIPS/ARM64/Arm64IRRegCache.h"
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// This file contains compilation for vector instructions.
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//
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// All functions should have CONDITIONAL_DISABLE, so we can narrow things down to a file quickly.
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// Currently known non working ones should have DISABLE.  No flags because that's in IR already.
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// #define CONDITIONAL_DISABLE { CompIR_Generic(inst); return; }
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#define CONDITIONAL_DISABLE {}
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#define DISABLE { CompIR_Generic(inst); return; }
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#define INVALIDOP { _assert_msg_(false, "Invalid IR inst %d", (int)inst.op); CompIR_Generic(inst); return; }
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namespace MIPSComp {
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using namespace Arm64Gen;
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using namespace Arm64IRJitConstants;
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static bool Overlap(IRReg r1, int l1, IRReg r2, int l2) {
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	return r1 < r2 + l2 && r1 + l1 > r2;
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}
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void Arm64JitBackend::CompIR_VecArith(IRInst inst) {
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	CONDITIONAL_DISABLE;
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	switch (inst.op) {
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	case IROp::Vec4Add:
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		regs_.Map(inst);
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		fp_.FADD(32, regs_.FQ(inst.dest), regs_.FQ(inst.src1), regs_.FQ(inst.src2));
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		break;
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	case IROp::Vec4Sub:
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		regs_.Map(inst);
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		fp_.FSUB(32, regs_.FQ(inst.dest), regs_.FQ(inst.src1), regs_.FQ(inst.src2));
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		break;
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	case IROp::Vec4Mul:
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		regs_.Map(inst);
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		fp_.FMUL(32, regs_.FQ(inst.dest), regs_.FQ(inst.src1), regs_.FQ(inst.src2));
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		break;
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	case IROp::Vec4Div:
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		regs_.Map(inst);
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		fp_.FDIV(32, regs_.FQ(inst.dest), regs_.FQ(inst.src1), regs_.FQ(inst.src2));
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		break;
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	case IROp::Vec4Scale:
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		if (Overlap(inst.dest, 4, inst.src2, 1) || Overlap(inst.src1, 4, inst.src2, 1)) {
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			// ARM64 can handle this, but we have to map specially.
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			regs_.SpillLockFPR(inst.dest, inst.src1);
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			regs_.MapVec4(inst.src1);
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			regs_.MapVec4(inst.src2 & ~3);
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			regs_.MapVec4(inst.dest, MIPSMap::NOINIT);
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			fp_.FMUL(32, regs_.FQ(inst.dest), regs_.FQ(inst.src1), regs_.FQ(inst.src2 & ~3), inst.src2 & 3);
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		} else {
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			regs_.Map(inst);
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			fp_.FMUL(32, regs_.FQ(inst.dest), regs_.FQ(inst.src1), regs_.FQ(inst.src2), 0);
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		}
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		break;
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	case IROp::Vec4Neg:
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		regs_.Map(inst);
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		fp_.FNEG(32, regs_.FQ(inst.dest), regs_.FQ(inst.src1));
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		break;
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	case IROp::Vec4Abs:
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		regs_.Map(inst);
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		fp_.FABS(32, regs_.FQ(inst.dest), regs_.FQ(inst.src1));
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		break;
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	default:
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		INVALIDOP;
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		break;
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	}
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}
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enum class Arm64Shuffle {
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	DUP0_AAAA,
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	DUP1_BBBB,
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	DUP2_CCCC,
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	DUP3_DDDD,
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	MOV_ABCD,
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	TRN1_AACC,
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	TRN2_BBDD,
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	UZP1_ACAC,
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	UZP2_BDBD,
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	ZIP1_AABB,
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	ZIP2_CCDD,
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	REV64_BADC,
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	EXT4_BCDA,
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	EXT8_CDAB,
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	EXT12_DABC,
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	// These steps are more expensive and use a temp.
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	REV64_EXT8_CDBA,
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	REV64_EXT8_DCAB,
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	EXT4_UZP1_BDAC,
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	EXT4_UZP2_CABD,
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	EXT8_ZIP1_ACBD,
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	EXT8_ZIP2_CADB,
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	// Any that don't fully replace dest must be after this point.
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	INS0_TO_1,
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	INS0_TO_2,
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	INS0_TO_3,
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	INS1_TO_0,
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	INS1_TO_2,
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	INS1_TO_3,
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	INS2_TO_0,
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	INS2_TO_1,
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	INS2_TO_3,
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	INS3_TO_0,
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	INS3_TO_1,
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	INS3_TO_2,
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	XTN2,
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	// These hacks to prevent 4 instructions, but scoring isn't smart enough to avoid.
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	EXT12_ZIP1_ADBA,
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	DUP3_UZP1_DDAC,
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	COUNT_NORMAL = EXT12_ZIP1_ADBA,
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	COUNT_SIMPLE = REV64_EXT8_CDBA,
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	COUNT_NOPREV = INS0_TO_1,
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};
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uint8_t Arm64ShuffleMask(Arm64Shuffle method) {
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	// Hopefully optimized into a lookup table, this is a bit less confusing to read...
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	switch (method) {
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	case Arm64Shuffle::DUP0_AAAA: return 0x00;
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	case Arm64Shuffle::DUP1_BBBB: return 0x55;
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	case Arm64Shuffle::DUP2_CCCC: return 0xAA;
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	case Arm64Shuffle::DUP3_DDDD: return 0xFF;
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	case Arm64Shuffle::MOV_ABCD: return 0xE4;
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	case Arm64Shuffle::TRN1_AACC: return 0xA0;
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	case Arm64Shuffle::TRN2_BBDD: return 0xF5;
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	case Arm64Shuffle::UZP1_ACAC: return 0x88;
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	case Arm64Shuffle::UZP2_BDBD: return 0xDD;
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	case Arm64Shuffle::ZIP1_AABB: return 0x50;
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	case Arm64Shuffle::ZIP2_CCDD: return 0xFA;
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	case Arm64Shuffle::REV64_BADC: return 0xB1;
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	case Arm64Shuffle::EXT4_BCDA: return 0x39;
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	case Arm64Shuffle::EXT8_CDAB: return 0x4E;
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	case Arm64Shuffle::EXT12_DABC: return 0x93;
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	case Arm64Shuffle::REV64_EXT8_CDBA: return 0x1E;
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	case Arm64Shuffle::REV64_EXT8_DCAB: return 0x4B;
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	case Arm64Shuffle::EXT4_UZP1_BDAC: return 0x8D;
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	case Arm64Shuffle::EXT4_UZP2_CABD: return 0xD2;
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	case Arm64Shuffle::EXT8_ZIP1_ACBD: return 0xD8;
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	case Arm64Shuffle::EXT8_ZIP2_CADB: return 0x72;
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	case Arm64Shuffle::INS0_TO_1: return 0xE0;
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	case Arm64Shuffle::INS0_TO_2: return 0xC4;
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	case Arm64Shuffle::INS0_TO_3: return 0x24;
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	case Arm64Shuffle::INS1_TO_0: return 0xE5;
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	case Arm64Shuffle::INS1_TO_2: return 0xD4;
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	case Arm64Shuffle::INS1_TO_3: return 0x64;
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	case Arm64Shuffle::INS2_TO_0: return 0xE6;
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	case Arm64Shuffle::INS2_TO_1: return 0xE8;
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	case Arm64Shuffle::INS2_TO_3: return 0xA4;
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	case Arm64Shuffle::INS3_TO_0: return 0xE7;
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	case Arm64Shuffle::INS3_TO_1: return 0xEC;
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	case Arm64Shuffle::INS3_TO_2: return 0xF4;
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	case Arm64Shuffle::XTN2: return 0x84;
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	case Arm64Shuffle::EXT12_ZIP1_ADBA: return 0x1C;
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	case Arm64Shuffle::DUP3_UZP1_DDAC: return 0x8F;
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	default:
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		_assert_(false);
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		return 0;
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	}
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}
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void Arm64ShuffleApply(ARM64FloatEmitter &fp, Arm64Shuffle method, ARM64Reg vd, ARM64Reg vs) {
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	switch (method) {
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	case Arm64Shuffle::DUP0_AAAA: fp.DUP(32, vd, vs, 0); return;
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	case Arm64Shuffle::DUP1_BBBB: fp.DUP(32, vd, vs, 1); return;
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	case Arm64Shuffle::DUP2_CCCC: fp.DUP(32, vd, vs, 2); return;
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	case Arm64Shuffle::DUP3_DDDD: fp.DUP(32, vd, vs, 3); return;
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	case Arm64Shuffle::MOV_ABCD: _assert_(vd != vs); fp.MOV(vd, vs); return;
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	case Arm64Shuffle::TRN1_AACC: fp.TRN1(32, vd, vs, vs); return;
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	case Arm64Shuffle::TRN2_BBDD: fp.TRN2(32, vd, vs, vs); return;
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	case Arm64Shuffle::UZP1_ACAC: fp.UZP1(32, vd, vs, vs); return;
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	case Arm64Shuffle::UZP2_BDBD: fp.UZP2(32, vd, vs, vs); return;
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	case Arm64Shuffle::ZIP1_AABB: fp.ZIP1(32, vd, vs, vs); return;
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	case Arm64Shuffle::ZIP2_CCDD: fp.ZIP2(32, vd, vs, vs); return;
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	case Arm64Shuffle::REV64_BADC: fp.REV64(32, vd, vs); return;
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	case Arm64Shuffle::EXT4_BCDA: fp.EXT(vd, vs, vs, 4); return;
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	case Arm64Shuffle::EXT8_CDAB: fp.EXT(vd, vs, vs, 8); return;
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	case Arm64Shuffle::EXT12_DABC: fp.EXT(vd, vs, vs, 12); return;
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	case Arm64Shuffle::REV64_EXT8_CDBA:
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		fp.REV64(32, EncodeRegToQuad(SCRATCHF1), vs);
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		fp.EXT(vd, vs, EncodeRegToQuad(SCRATCHF1), 8);
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		return;
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	case Arm64Shuffle::REV64_EXT8_DCAB:
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		fp.REV64(32, EncodeRegToQuad(SCRATCHF1), vs);
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		fp.EXT(vd, EncodeRegToQuad(SCRATCHF1), vs, 8);
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		return;
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	case Arm64Shuffle::EXT4_UZP1_BDAC:
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		fp.EXT(EncodeRegToQuad(SCRATCHF1), vs, vs, 4);
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		fp.UZP1(32, vd, EncodeRegToQuad(SCRATCHF1), vs);
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		return;
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	case Arm64Shuffle::EXT4_UZP2_CABD:
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		fp.EXT(EncodeRegToQuad(SCRATCHF1), vs, vs, 4);
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		fp.UZP2(32, vd, EncodeRegToQuad(SCRATCHF1), vs);
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		return;
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	case Arm64Shuffle::EXT8_ZIP1_ACBD:
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		fp.EXT(EncodeRegToQuad(SCRATCHF1), vs, vs, 8);
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		fp.ZIP1(32, vd, vs, EncodeRegToQuad(SCRATCHF1));
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		return;
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	case Arm64Shuffle::EXT8_ZIP2_CADB:
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		fp.EXT(EncodeRegToQuad(SCRATCHF1), vs, vs, 8);
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		fp.ZIP2(32, vd, vs, EncodeRegToQuad(SCRATCHF1));
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		return;
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	case Arm64Shuffle::INS0_TO_1: fp.INS(32, vd, 1, vs, 0); return;
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	case Arm64Shuffle::INS0_TO_2: fp.INS(32, vd, 2, vs, 0); return;
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	case Arm64Shuffle::INS0_TO_3: fp.INS(32, vd, 3, vs, 0); return;
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	case Arm64Shuffle::INS1_TO_0: fp.INS(32, vd, 0, vs, 1); return;
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	case Arm64Shuffle::INS1_TO_2: fp.INS(32, vd, 2, vs, 1); return;
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	case Arm64Shuffle::INS1_TO_3: fp.INS(32, vd, 3, vs, 1); return;
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	case Arm64Shuffle::INS2_TO_0: fp.INS(32, vd, 0, vs, 2); return;
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	case Arm64Shuffle::INS2_TO_1: fp.INS(32, vd, 1, vs, 2); return;
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	case Arm64Shuffle::INS2_TO_3: fp.INS(32, vd, 3, vs, 2); return;
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	case Arm64Shuffle::INS3_TO_0: fp.INS(32, vd, 0, vs, 3); return;
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	case Arm64Shuffle::INS3_TO_1: fp.INS(32, vd, 1, vs, 3); return;
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	case Arm64Shuffle::INS3_TO_2: fp.INS(32, vd, 2, vs, 3); return;
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	case Arm64Shuffle::XTN2: fp.XTN2(32, vd, vs); return;
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	case Arm64Shuffle::EXT12_ZIP1_ADBA:
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		fp.EXT(EncodeRegToQuad(SCRATCHF1), vs, vs, 12);
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		fp.ZIP1(32, vd, vs, EncodeRegToQuad(SCRATCHF1));
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		return;
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	case Arm64Shuffle::DUP3_UZP1_DDAC:
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		fp.DUP(32, EncodeRegToQuad(SCRATCHF1), vs, 3);
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		fp.UZP1(32, vd, EncodeRegToQuad(SCRATCHF1), vs);
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		return;
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	default:
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		_assert_(false);
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		return;
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	}
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}
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uint8_t Arm64ShuffleResult(uint8_t mask, uint8_t prev) {
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	if (prev == 0xE4)
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		return mask;
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	uint8_t result = 0;
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	for (int i = 0; i < 4; ++i) {
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		int takeLane = (mask >> (i * 2)) & 3;
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		int lane = (prev >> (takeLane * 2)) & 3;
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		result |= lane << (i * 2);
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	}
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	return result;
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}
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int Arm64ShuffleScore(uint8_t shuf, uint8_t goal, int steps = 1) {
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	if (shuf == goal)
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		return 100;
290

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	int score = 0;
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	bool needs[4]{};
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	bool gets[4]{};
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	for (int i = 0; i < 4; ++i) {
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		uint8_t mask = 3 << (i * 2);
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		needs[(goal & mask) >> (i * 2)] = true;
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		gets[(shuf & mask) >> (i * 2)] = true;
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		if ((shuf & mask) == (goal & mask))
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			score += 4;
300
	}
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302
	for (int i = 0; i < 4; ++i) {
303
		if (needs[i] && !gets[i])
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			return 0;
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	}
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307
	// We need to look one level deeper to solve some, such as 1B (common) well.
308
	if (steps > 0) {
309
		int bestNextScore = 0;
310
		for (int m = 0; m < (int)Arm64Shuffle::COUNT_NORMAL; ++m) {
311
			uint8_t next = Arm64ShuffleResult(Arm64ShuffleMask((Arm64Shuffle)m), shuf);
312
			int nextScore = Arm64ShuffleScore(next, goal, steps - 1);
313
			if (nextScore > score) {
314
				bestNextScore = nextScore;
315
				if (bestNextScore == 100) {
316
					// Take the earliest that gives us two steps, it's cheaper (not 2 instructions.)
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					score = 0;
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					break;
319
				}
320
			}
321
		}
322

323
		score += bestNextScore / 2;
324
	}
325

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	return score;
327
}
328

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Arm64Shuffle Arm64BestShuffle(uint8_t goal, uint8_t prev, bool needsCopy) {
330
	// A couple special cases for optimal shuffles.
331
	if (goal == 0x7C && prev == 0xE4)
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		return Arm64Shuffle::REV64_BADC;
333
	if (goal == 0x2B && prev == 0xE4)
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		return Arm64Shuffle::EXT8_CDAB;
335
	if ((goal == 0x07 || goal == 0x1C) && prev == 0xE4)
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		return Arm64Shuffle::EXT12_ZIP1_ADBA;
337
	if ((goal == 0x8F || goal == 0x2F) && prev == 0xE4)
338
		return Arm64Shuffle::DUP3_UZP1_DDAC;
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340
	// needsCopy true means insert isn't possible.
341
	int attempts = needsCopy ? (int)Arm64Shuffle::COUNT_NOPREV : (int)Arm64Shuffle::COUNT_NORMAL;
342

343
	Arm64Shuffle best = Arm64Shuffle::MOV_ABCD;
344
	int bestScore = 0;
345
	for (int m = 0; m < attempts; ++m) {
346
		uint8_t result = Arm64ShuffleResult(Arm64ShuffleMask((Arm64Shuffle)m), prev);
347
		int score = Arm64ShuffleScore(result, goal);
348
		// Slightly discount options that involve an extra instruction.
349
		if (m >= (int)Arm64Shuffle::COUNT_SIMPLE && m < (int)Arm64Shuffle::COUNT_NOPREV)
350
			score--;
351
		if (score > bestScore) {
352
			best = (Arm64Shuffle)m;
353
			bestScore = score;
354
		}
355
	}
356

357
	_assert_(bestScore > 0);
358
	return best;
359
}
360

361

362
static void Arm64ShufflePerform(ARM64FloatEmitter &fp, ARM64Reg vd, ARM64Reg vs, u8 shuf) {
363
	// This performs all shuffles within 3 "steps" (some are two instructions, though.)
364
	_assert_msg_(shuf != 0xE4, "Non-shuffles shouldn't get here");
365

366
	uint8_t state = 0xE4;
367
	// If they're not the same, the first step needs to be a copy.
368
	bool needsCopy = vd != vs;
369
	for (int i = 0; i < 4 && state != shuf; ++i) {
370
		// Figure out the next step and write it out.
371
		Arm64Shuffle method = Arm64BestShuffle(shuf, state, needsCopy);
372
		Arm64ShuffleApply(fp, method, vd, needsCopy ? vs : vd);
373

374
		// Update our state to where we've ended up, for next time.
375
		needsCopy = false;
376
		state = Arm64ShuffleResult(Arm64ShuffleMask(method), state);
377
	}
378

379
	_assert_msg_(state == shuf, "Arm64ShufflePerform failed to resolve shuffle");
380
}
381

382
void Arm64JitBackend::CompIR_VecAssign(IRInst inst) {
383
	CONDITIONAL_DISABLE;
384

385
	switch (inst.op) {
386
	case IROp::Vec4Init:
387
		regs_.Map(inst);
388
		switch (Vec4Init(inst.src1)) {
389
		case Vec4Init::AllZERO:
390
			fp_.MOVI(32, regs_.FQ(inst.dest), 0);
391
			break;
392

393
		case Vec4Init::AllONE:
394
		case Vec4Init::AllMinusONE:
395
			fp_.MOVI2FDUP(regs_.FQ(inst.dest), 1.0f, INVALID_REG, Vec4Init(inst.src1) == Vec4Init::AllMinusONE);
396
			break;
397

398
		case Vec4Init::Set_1000:
399
		case Vec4Init::Set_0100:
400
		case Vec4Init::Set_0010:
401
		case Vec4Init::Set_0001:
402
			fp_.MOVI(32, regs_.FQ(inst.dest), 0);
403
			fp_.MOVI2FDUP(EncodeRegToQuad(SCRATCHF1), 1.0f);
404
			fp_.INS(32, regs_.FQ(inst.dest), inst.src1 - (int)Vec4Init::Set_1000, EncodeRegToQuad(SCRATCHF1), inst.src1 - (int)Vec4Init::Set_1000);
405
			break;
406

407
		default:
408
			_assert_msg_(false, "Unexpected Vec4Init value %d", inst.src1);
409
			DISABLE;
410
		}
411
		break;
412

413
	case IROp::Vec4Shuffle:
414
		// There's not really an easy shuffle op on ARM64...
415
		if (regs_.GetFPRLaneCount(inst.src1) == 1 && (inst.src1 & 3) == 0 && inst.src2 == 0x00) {
416
			// This is a broadcast.  If dest == src1, this won't clear it.
417
			regs_.SpillLockFPR(inst.src1);
418
			regs_.MapVec4(inst.dest, MIPSMap::NOINIT);
419
			fp_.DUP(32, regs_.FQ(inst.dest), regs_.FQ(inst.src1), 0);
420
		} else if (inst.src2 == 0xE4) {
421
			if (inst.dest != inst.src1) {
422
				regs_.Map(inst);
423
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src1));
424
			}
425
		} else {
426
			regs_.Map(inst);
427
			Arm64ShufflePerform(fp_, regs_.FQ(inst.dest), regs_.FQ(inst.src1), inst.src2);
428
		}
429
		break;
430

431
	case IROp::Vec4Blend:
432
		regs_.Map(inst);
433
		if (inst.src1 == inst.src2) {
434
			// Shouldn't really happen, just making sure the below doesn't have to think about it.
435
			if (inst.dest != inst.src1)
436
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src1));
437
			break;
438
		}
439

440
		// To reduce overlap cases to consider, let's inverse src1/src2 if dest == src2.
441
		// Thus, dest could be src1, but no other overlap is possible.
442
		if (inst.dest == inst.src2) {
443
			std::swap(inst.src1, inst.src2);
444
			inst.constant ^= 0xF;
445
		}
446

447
		switch (inst.constant & 0xF) {
448
		case 0b0000:
449
			if (inst.dest != inst.src1)
450
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src1));
451
			break;
452

453
		case 0b0001:
454
			if (inst.dest != inst.src1)
455
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src1));
456
			fp_.INS(32, regs_.FQ(inst.dest), 0, regs_.FQ(inst.src2), 0);
457
			break;
458

459
		case 0b0010:
460
			if (inst.dest != inst.src1)
461
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src1));
462
			fp_.INS(32, regs_.FQ(inst.dest), 1, regs_.FQ(inst.src2), 1);
463
			break;
464

465
		case 0b0011:
466
			if (inst.dest != inst.src1)
467
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src1));
468
			fp_.INS(64, regs_.FQ(inst.dest), 0, regs_.FQ(inst.src2), 0);
469
			break;
470

471
		case 0b0100:
472
			if (inst.dest != inst.src1)
473
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src1));
474
			fp_.INS(32, regs_.FQ(inst.dest), 2, regs_.FQ(inst.src2), 2);
475
			break;
476

477
		case 0b0101:
478
			// To get AbCd: REV64 to BADC, then TRN2 xAxC, xbxd.
479
			fp_.REV64(32, EncodeRegToQuad(SCRATCHF1), regs_.FQ(inst.src2));
480
			fp_.TRN2(32, regs_.FQ(inst.dest), EncodeRegToQuad(SCRATCHF1), regs_.FQ(inst.src1));
481
			break;
482

483
		case 0b0110:
484
			if (inst.dest != inst.src1)
485
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src1));
486
			fp_.INS(32, regs_.FQ(inst.dest), 1, regs_.FQ(inst.src2), 1);
487
			fp_.INS(32, regs_.FQ(inst.dest), 2, regs_.FQ(inst.src2), 2);
488
			break;
489

490
		case 0b0111:
491
			if (inst.dest != inst.src1) {
492
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src2));
493
				fp_.INS(32, regs_.FQ(inst.dest), 3, regs_.FQ(inst.src1), 3);
494
			} else {
495
				fp_.MOV(EncodeRegToQuad(SCRATCHF1), regs_.FQ(inst.src1));
496
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src2));
497
				fp_.INS(32, regs_.FQ(inst.dest), 3, EncodeRegToQuad(SCRATCHF1), 3);
498
			}
499
			break;
500

501
		case 0b1000:
502
			if (inst.dest != inst.src1)
503
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src1));
504
			fp_.INS(32, regs_.FQ(inst.dest), 3, regs_.FQ(inst.src2), 3);
505
			break;
506

507
		case 0b1001:
508
			if (inst.dest != inst.src1)
509
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src1));
510
			fp_.INS(32, regs_.FQ(inst.dest), 0, regs_.FQ(inst.src2), 0);
511
			fp_.INS(32, regs_.FQ(inst.dest), 3, regs_.FQ(inst.src2), 3);
512
			break;
513

514
		case 0b1010:
515
			// To get aBcD: REV64 to badc, then TRN2 xaxc, xBxD.
516
			fp_.REV64(32, regs_.FQ(inst.dest), regs_.FQ(inst.src1));
517
			fp_.TRN2(32, regs_.FQ(inst.dest), regs_.FQ(inst.dest), regs_.FQ(inst.src2));
518
			break;
519

520
		case 0b1011:
521
			if (inst.dest != inst.src1) {
522
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src2));
523
				fp_.INS(32, regs_.FQ(inst.dest), 2, regs_.FQ(inst.src1), 2);
524
			} else {
525
				fp_.MOV(EncodeRegToQuad(SCRATCHF1), regs_.FQ(inst.src1));
526
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src2));
527
				fp_.INS(32, regs_.FQ(inst.dest), 2, EncodeRegToQuad(SCRATCHF1), 2);
528
			}
529
			break;
530

531
		case 0b1100:
532
			if (inst.dest != inst.src1)
533
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src1));
534
			fp_.INS(64, regs_.FQ(inst.dest), 1, regs_.FQ(inst.src2), 1);
535
			break;
536

537
		case 0b1101:
538
			if (inst.dest != inst.src1) {
539
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src2));
540
				fp_.INS(32, regs_.FQ(inst.dest), 1, regs_.FQ(inst.src1), 1);
541
			} else {
542
				fp_.MOV(EncodeRegToQuad(SCRATCHF1), regs_.FQ(inst.src1));
543
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src2));
544
				fp_.INS(32, regs_.FQ(inst.dest), 1, EncodeRegToQuad(SCRATCHF1), 1);
545
			}
546
			break;
547

548
		case 0b1110:
549
			if (inst.dest != inst.src1) {
550
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src2));
551
				fp_.INS(32, regs_.FQ(inst.dest), 0, regs_.FQ(inst.src1), 0);
552
			} else {
553
				fp_.MOV(EncodeRegToQuad(SCRATCHF1), regs_.FQ(inst.src1));
554
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src2));
555
				fp_.INS(32, regs_.FQ(inst.dest), 0, EncodeRegToQuad(SCRATCHF1), 0);
556
			}
557
			break;
558

559
		case 0b1111:
560
			if (inst.dest != inst.src2)
561
				fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src2));
562
			break;
563
		}
564
		break;
565

566
	case IROp::Vec4Mov:
567
		if (inst.dest != inst.src1) {
568
			regs_.Map(inst);
569
			fp_.MOV(regs_.FQ(inst.dest), regs_.FQ(inst.src1));
570
		}
571
		break;
572

573
	default:
574
		INVALIDOP;
575
		break;
576
	}
577
}
578

579
void Arm64JitBackend::CompIR_VecClamp(IRInst inst) {
580
	CONDITIONAL_DISABLE;
581

582
	switch (inst.op) {
583
	case IROp::Vec4ClampToZero:
584
		regs_.Map(inst);
585
		fp_.MOVI(32, EncodeRegToQuad(SCRATCHF1), 0);
586
		fp_.SMAX(32, regs_.FQ(inst.dest), regs_.FQ(inst.src1), EncodeRegToQuad(SCRATCHF1));
587
		break;
588

589
	case IROp::Vec2ClampToZero:
590
		regs_.Map(inst);
591
		fp_.MOVI(32, EncodeRegToDouble(SCRATCHF1), 0);
592
		fp_.SMAX(32, regs_.FD(inst.dest), regs_.FD(inst.src1), EncodeRegToDouble(SCRATCHF1));
593
		break;
594

595
	default:
596
		INVALIDOP;
597
		break;
598
	}
599
}
600

601
void Arm64JitBackend::CompIR_VecHoriz(IRInst inst) {
602
	CONDITIONAL_DISABLE;
603

604
	switch (inst.op) {
605
	case IROp::Vec4Dot:
606
		if (Overlap(inst.dest, 1, inst.src1, 4) || Overlap(inst.dest, 1, inst.src2, 4)) {
607
			// To avoid overlap problems, map a little carefully.
608
			regs_.SpillLockFPR(inst.src1, inst.src2);
609
			regs_.MapVec4(inst.src1);
610
			regs_.MapVec4(inst.src2);
611
			regs_.MapVec4(inst.dest & ~3, MIPSMap::DIRTY);
612
			fp_.FMUL(32, EncodeRegToQuad(SCRATCHF1), regs_.FQ(inst.src1), regs_.FQ(inst.src2));
613
			fp_.FADDP(32, EncodeRegToQuad(SCRATCHF1), EncodeRegToQuad(SCRATCHF1), EncodeRegToQuad(SCRATCHF1));
614
			fp_.FADDP(32, EncodeRegToQuad(SCRATCHF1), EncodeRegToQuad(SCRATCHF1), EncodeRegToQuad(SCRATCHF1));
615
			fp_.INS(32, regs_.FQ(inst.dest & ~3), inst.dest & 3, EncodeRegToQuad(SCRATCHF1), 0);
616
		} else {
617
			regs_.Map(inst);
618
			fp_.FMUL(32, regs_.FQ(inst.dest), regs_.FQ(inst.src1), regs_.FQ(inst.src2));
619
			fp_.FADDP(32, regs_.FQ(inst.dest), regs_.FQ(inst.dest), regs_.FQ(inst.dest));
620
			fp_.FADDP(32, regs_.FQ(inst.dest), regs_.FQ(inst.dest), regs_.FQ(inst.dest));
621
		}
622
		break;
623

624
	default:
625
		INVALIDOP;
626
		break;
627
	}
628
}
629

630
void Arm64JitBackend::CompIR_VecPack(IRInst inst) {
631
	CONDITIONAL_DISABLE;
632

633
	switch (inst.op) {
634
	case IROp::Vec4DuplicateUpperBitsAndShift1:
635
		// This operation swizzles the high 8 bits and converts to a signed int.
636
		// It's always after Vec4Unpack8To32.
637
		// 000A000B000C000D -> AAAABBBBCCCCDDDD and then shift right one (to match INT_MAX.)
638
		regs_.Map(inst);
639
		// First, USHR+ORR to get 0A0A0B0B0C0C0D0D.
640
		fp_.USHR(32, EncodeRegToQuad(SCRATCHF1), regs_.FQ(inst.src1), 16);
641
		fp_.ORR(EncodeRegToQuad(SCRATCHF1), EncodeRegToQuad(SCRATCHF1), regs_.FQ(inst.src1));
642
		// Now again, but by 8.
643
		fp_.USHR(32, regs_.FQ(inst.dest), EncodeRegToQuad(SCRATCHF1), 8);
644
		fp_.ORR(regs_.FQ(inst.dest), regs_.FQ(inst.dest), EncodeRegToQuad(SCRATCHF1));
645
		// Finally, shift away the sign.  The goal is to saturate 0xFF -> 0x7FFFFFFF.
646
		fp_.USHR(32, regs_.FQ(inst.dest), regs_.FQ(inst.dest), 1);
647
		break;
648

649
	case IROp::Vec2Pack31To16:
650
		// Same as Vec2Pack32To16, but we shift left 1 first to nuke the sign bit.
651
		if (Overlap(inst.dest, 1, inst.src1, 2)) {
652
			regs_.MapVec2(inst.src1, MIPSMap::DIRTY);
653
			fp_.SHL(32, EncodeRegToDouble(SCRATCHF1), regs_.FD(inst.src1), 1);
654
			fp_.UZP2(16, EncodeRegToDouble(SCRATCHF1), EncodeRegToDouble(SCRATCHF1), EncodeRegToDouble(SCRATCHF1));
655
			fp_.INS(32, regs_.FD(inst.dest & ~1), inst.dest & 1, EncodeRegToDouble(SCRATCHF1), 0);
656
		} else {
657
			regs_.Map(inst);
658
			fp_.SHL(32, regs_.FD(inst.dest), regs_.FD(inst.src1), 1);
659
			fp_.UZP2(16, regs_.FD(inst.dest), regs_.FD(inst.dest), regs_.FD(inst.dest));
660
		}
661
		break;
662

663
	case IROp::Vec2Pack32To16:
664
		// Viewed as 16 bit lanes: xAxB -> AB00... that's UZP2.
665
		if (Overlap(inst.dest, 1, inst.src1, 2)) {
666
			regs_.MapVec2(inst.src1, MIPSMap::DIRTY);
667
			fp_.UZP2(16, EncodeRegToDouble(SCRATCHF1), regs_.FD(inst.src1), regs_.FD(inst.src1));
668
			fp_.INS(32, regs_.FD(inst.dest & ~1), inst.dest & 1, EncodeRegToDouble(SCRATCHF1), 0);
669
		} else {
670
			regs_.Map(inst);
671
			fp_.UZP2(16, regs_.FD(inst.dest), regs_.FD(inst.src1), regs_.FD(inst.src1));
672
		}
673
		break;
674

675
	case IROp::Vec4Pack31To8:
676
		if (Overlap(inst.dest, 1, inst.src1, 4)) {
677
			regs_.MapVec4(inst.src1, MIPSMap::DIRTY);
678
		} else {
679
			regs_.Map(inst);
680
		}
681

682
		// Viewed as 8-bit lanes, after a shift by 23: AxxxBxxxCxxxDxxx.
683
		// So: UZP1 -> AxBxCxDx -> UZP1 again -> ABCD
684
		fp_.USHR(32, EncodeRegToQuad(SCRATCHF1), regs_.FQ(inst.src1), 23);
685
		fp_.UZP1(8, EncodeRegToQuad(SCRATCHF1), EncodeRegToQuad(SCRATCHF1), EncodeRegToQuad(SCRATCHF1));
686
		// Second one directly to dest, if we can.
687
		if (Overlap(inst.dest, 1, inst.src1, 4)) {
688
			fp_.UZP1(8, EncodeRegToQuad(SCRATCHF1), EncodeRegToQuad(SCRATCHF1), EncodeRegToQuad(SCRATCHF1));
689
			fp_.INS(32, regs_.FQ(inst.dest & ~3), inst.dest & 3, EncodeRegToQuad(SCRATCHF1), 0);
690
		} else {
691
			fp_.UZP1(8, regs_.FQ(inst.dest), EncodeRegToQuad(SCRATCHF1), EncodeRegToQuad(SCRATCHF1));
692
		}
693
		break;
694

695
	case IROp::Vec4Pack32To8:
696
		if (Overlap(inst.dest, 1, inst.src1, 4)) {
697
			regs_.MapVec4(inst.src1, MIPSMap::DIRTY);
698
		} else {
699
			regs_.Map(inst);
700
		}
701

702
		// Viewed as 8-bit lanes, after a shift by 24: AxxxBxxxCxxxDxxx.
703
		// Same as Vec4Pack31To8, just a different shift.
704
		fp_.USHR(32, EncodeRegToQuad(SCRATCHF1), regs_.FQ(inst.src1), 24);
705
		fp_.UZP1(8, EncodeRegToQuad(SCRATCHF1), EncodeRegToQuad(SCRATCHF1), EncodeRegToQuad(SCRATCHF1));
706
		// Second one directly to dest, if we can.
707
		if (Overlap(inst.dest, 1, inst.src1, 4)) {
708
			fp_.UZP1(8, EncodeRegToQuad(SCRATCHF1), EncodeRegToQuad(SCRATCHF1), EncodeRegToQuad(SCRATCHF1));
709
			fp_.INS(32, regs_.FQ(inst.dest & ~3), inst.dest & 3, EncodeRegToQuad(SCRATCHF1), 0);
710
		} else {
711
			fp_.UZP1(8, regs_.FQ(inst.dest), EncodeRegToQuad(SCRATCHF1), EncodeRegToQuad(SCRATCHF1));
712
		}
713
		break;
714

715
	case IROp::Vec2Unpack16To31:
716
		// Viewed as 16-bit: ABxx -> 0A0B, then shift a zero into the sign place.
717
		if (Overlap(inst.dest, 2, inst.src1, 1)) {
718
			regs_.MapVec2(inst.dest, MIPSMap::DIRTY);
719
		} else {
720
			regs_.Map(inst);
721
		}
722
		if (inst.src1 == inst.dest + 1) {
723
			fp_.USHLL2(16, regs_.FQ(inst.dest), regs_.FD(inst.src1), 15);
724
		} else {
725
			fp_.USHLL(16, regs_.FQ(inst.dest), regs_.FD(inst.src1), 15);
726
		}
727
		break;
728

729
	case IROp::Vec2Unpack16To32:
730
		// Just Vec2Unpack16To31, without the shift.
731
		if (Overlap(inst.dest, 2, inst.src1, 1)) {
732
			regs_.MapVec2(inst.dest, MIPSMap::DIRTY);
733
		} else {
734
			regs_.Map(inst);
735
		}
736
		if (inst.src1 == inst.dest + 1) {
737
			fp_.SHLL2(16, regs_.FQ(inst.dest), regs_.FD(inst.src1));
738
		} else {
739
			fp_.SHLL(16, regs_.FQ(inst.dest), regs_.FD(inst.src1));
740
		}
741
		break;
742

743
	case IROp::Vec4Unpack8To32:
744
		// Viewed as 8-bit: ABCD -> 000A000B000C000D.
745
		if (Overlap(inst.dest, 4, inst.src1, 1)) {
746
			regs_.MapVec4(inst.dest, MIPSMap::DIRTY);
747
			if (inst.dest == inst.src1 + 2) {
748
				fp_.SHLL2(8, regs_.FQ(inst.dest), regs_.FD(inst.src1 & ~3));
749
			} else if (inst.dest != inst.src1) {
750
				fp_.DUP(32, regs_.FQ(inst.dest), regs_.FQ(inst.src1), inst.src1 & 3);
751
				fp_.SHLL(8, regs_.FQ(inst.dest), regs_.FD(inst.dest));
752
			} else {
753
				fp_.SHLL(8, regs_.FQ(inst.dest), regs_.FD(inst.src1));
754
			}
755
			fp_.SHLL(16, regs_.FQ(inst.dest), regs_.FD(inst.dest));
756
		} else {
757
			regs_.Map(inst);
758
			// Two steps: ABCD -> 0A0B0C0D, then to 000A000B000C000D.
759
			fp_.SHLL(8, regs_.FQ(inst.dest), regs_.FD(inst.src1));
760
			fp_.SHLL(16, regs_.FQ(inst.dest), regs_.FD(inst.dest));
761
		}
762
		break;
763

764
	default:
765
		INVALIDOP;
766
		break;
767
	}
768
}
769

770
} // namespace MIPSComp
771

772
#endif
773

774