2022-08-24 17:12:49 +00:00
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// Copyright (c) 2022- 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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#pragma once
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#include <cstdint>
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2022-08-27 02:09:41 +00:00
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#include <cstring>
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#include <type_traits>
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2022-08-24 17:12:49 +00:00
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#include "Common/CodeBlock.h"
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2022-08-25 03:33:36 +00:00
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#include "Common/Common.h"
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2022-08-24 17:12:49 +00:00
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namespace RiscVGen {
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enum RiscVReg {
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X0 = 0, X1, X2, X3, X4, X5, X6, X7,
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X8, X9, X10, X11, X12, X13, X14, X15,
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X16, X17, X18, X19, X20, X21, X22, X23,
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X24, X25, X26, X27, X28, X29, X30, X31,
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R_ZERO = 0,
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R_RA = 1,
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R_SP = 2,
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R_GP = 3,
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R_TP = 4,
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R_FP = 8,
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F0 = 0x20, F1, F2, F3, F4, F5, F6, F7,
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F8, F9, F10, F11, F12, F13, F14, F15,
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F16, F17, F18, F19, F20, F21, F22, F23,
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F24, F25, F26, F27, F28, F29, F30, F31,
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2023-01-21 22:51:52 +00:00
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V0 = 0x40, V1, V2, V3, V4, V5, V6, V7,
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V8, V9, V10, V11, V12, V13, V14, V15,
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V16, V17, V18, V19, V20, V21, V22, V23,
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V24, V25, V26, V27, V28, V29, V30, V31,
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2023-02-12 20:10:29 +00:00
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INVALID_REG = 0xFFFFFFFF,
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2022-08-24 17:12:49 +00:00
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};
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enum class FixupBranchType {
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B,
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J,
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2022-08-27 22:14:22 +00:00
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CB,
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CJ,
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2022-08-24 17:12:49 +00:00
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};
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2022-08-25 03:33:36 +00:00
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enum class Fence {
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I = 0b1000,
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O = 0b0100,
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R = 0b0010,
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W = 0b0001,
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RW = R | W,
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IO = I | O,
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};
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ENUM_CLASS_BITOPS(Fence);
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2022-08-25 05:58:00 +00:00
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enum class Atomic {
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NONE = 0b00,
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ACQUIRE = 0b10,
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RELEASE = 0b01,
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SEQUENTIAL = 0b11,
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};
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2022-08-26 02:26:15 +00:00
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enum class Round {
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NEAREST_EVEN = 0b000,
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TOZERO = 0b001,
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DOWN = 0b010,
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UP = 0b011,
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NEAREST_MAX = 0b100,
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DYNAMIC = 0b111,
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};
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enum class FConv {
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W = 0x0000,
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WU = 0x0001,
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L = 0x0002,
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LU = 0x0003,
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S = 0x1000,
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D = 0x1001,
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2023-01-29 23:46:36 +00:00
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H = 0x1002,
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2022-08-26 02:26:15 +00:00
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Q = 0x1003,
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};
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enum class FMv {
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X,
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H,
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W,
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D,
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};
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2022-08-26 03:30:01 +00:00
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enum class Csr {
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FFlags = 0x001,
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FRm = 0x002,
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FCsr = 0x003,
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2023-01-21 22:51:52 +00:00
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VStart = 0x008,
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VXSat = 0x009,
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VXRm = 0x00A,
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VCsr = 0x00F,
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VL = 0xC20,
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VType = 0xC21,
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VLenB = 0xC22,
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2022-08-26 03:30:01 +00:00
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Cycle = 0xC00,
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Time = 0xC01,
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InstRet = 0xC02,
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CycleH = 0xC80,
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TimeH = 0xC81,
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InstRetH = 0xC82,
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};
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2023-01-21 22:51:52 +00:00
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enum class VLMul {
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M1 = 0b000,
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M2 = 0b001,
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M4 = 0b010,
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M8 = 0b011,
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MF8 = 0b101,
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MF4 = 0b110,
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MF2 = 0b111,
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};
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enum class VSew {
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E8 = 0b000,
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E16 = 0b001,
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E32 = 0b010,
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E64 = 0b011,
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};
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enum class VTail {
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U = 0,
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A = 1,
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};
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enum class VMask {
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U = 0,
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A = 1,
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};
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struct VType {
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constexpr VType(VSew sew, VTail vt, VMask vm)
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: value(((uint32_t)sew << 3) | ((uint32_t)vt << 6) | ((uint32_t)vm << 7)) {
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}
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constexpr VType(VSew sew, VLMul lmul, VTail vt, VMask vm)
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: value((uint32_t)lmul | ((uint32_t)sew << 3) | ((uint32_t)vt << 6) | ((uint32_t)vm << 7)) {
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}
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VType(int bits, VLMul lmul, VTail vt, VMask vm) {
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VSew sew = VSew::E8;
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switch (bits) {
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case 8: sew = VSew::E8; break;
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case 16: sew = VSew::E16; break;
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case 32: sew = VSew::E32; break;
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case 64: sew = VSew::E64; break;
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default: _assert_msg_(false, "Invalid vtype width"); break;
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}
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value = (uint32_t)lmul | ((uint32_t)sew << 3) | ((uint32_t)vt << 6) | ((uint32_t)vm << 7);
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}
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uint32_t value;
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};
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enum class VUseMask {
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V0_T = 0,
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NONE = 1,
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};
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2022-08-24 17:12:49 +00:00
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struct FixupBranch {
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FixupBranch() {}
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FixupBranch(const u8 *p, FixupBranchType t) : ptr(p), type(t) {}
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2023-02-17 00:10:04 +00:00
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FixupBranch(FixupBranch &&other);
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FixupBranch(const FixupBranch &) = delete;
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~FixupBranch();
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2023-02-17 00:10:04 +00:00
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FixupBranch &operator =(FixupBranch &&other);
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FixupBranch &operator =(const FixupBranch &other) = delete;
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2022-08-26 02:31:46 +00:00
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const u8 *ptr = nullptr;
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2022-12-11 05:09:50 +00:00
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FixupBranchType type = FixupBranchType::B;
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2022-08-24 17:12:49 +00:00
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};
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class RiscVEmitter {
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public:
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RiscVEmitter() {}
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RiscVEmitter(const u8 *codePtr, u8 *writablePtr);
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virtual ~RiscVEmitter() {}
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void SetCodePointer(const u8 *ptr, u8 *writePtr);
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const u8 *GetCodePointer() const;
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u8 *GetWritableCodePtr();
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void ReserveCodeSpace(u32 bytes);
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const u8 *AlignCode16();
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const u8 *AlignCodePage();
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void FlushIcache();
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void FlushIcacheSection(const u8 *start, const u8 *end);
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2022-08-26 02:31:46 +00:00
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void SetJumpTarget(FixupBranch &branch);
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2022-08-24 17:12:49 +00:00
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bool BInRange(const void *func) const;
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bool JInRange(const void *func) const;
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2023-07-22 07:30:29 +00:00
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void QuickJAL(RiscVReg scratchreg, RiscVReg rd, const u8 *dst);
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void QuickJ(RiscVReg scratchreg, const u8 *dst) {
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QuickJAL(scratchreg, R_ZERO, dst);
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}
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2023-08-07 06:42:58 +00:00
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void QuickCallFunction(const u8 *func, RiscVReg scratchreg = R_RA) {
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QuickJAL(scratchreg, R_RA, func);
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2023-07-22 07:30:29 +00:00
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}
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2023-07-18 06:28:43 +00:00
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template <typename T>
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2023-08-07 06:42:58 +00:00
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void QuickCallFunction(T *func, RiscVReg scratchreg = R_RA) {
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2023-07-18 06:28:43 +00:00
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static_assert(std::is_function<T>::value, "QuickCallFunction without function");
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2023-08-07 06:42:58 +00:00
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QuickCallFunction((const u8 *)func, scratchreg);
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2023-07-18 06:28:43 +00:00
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}
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2022-08-25 01:01:03 +00:00
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void LUI(RiscVReg rd, s32 simm32);
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void AUIPC(RiscVReg rd, s32 simm32);
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void JAL(RiscVReg rd, const void *dst);
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void JALR(RiscVReg rd, RiscVReg rs1, s32 simm12);
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FixupBranch JAL(RiscVReg rd);
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// Psuedo-instructions for convenience/clarity.
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void J(const void *dst) {
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JAL(R_ZERO, dst);
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}
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void JR(RiscVReg rs1, u32 simm12 = 0) {
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JALR(R_ZERO, rs1, simm12);
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}
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void RET() {
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JR(R_RA);
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}
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FixupBranch J() {
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return JAL(R_ZERO);
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}
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void BEQ(RiscVReg rs1, RiscVReg rs2, const void *dst);
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void BNE(RiscVReg rs1, RiscVReg rs2, const void *dst);
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void BLT(RiscVReg rs1, RiscVReg rs2, const void *dst);
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void BGE(RiscVReg rs1, RiscVReg rs2, const void *dst);
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void BLTU(RiscVReg rs1, RiscVReg rs2, const void *dst);
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void BGEU(RiscVReg rs1, RiscVReg rs2, const void *dst);
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FixupBranch BEQ(RiscVReg rs1, RiscVReg rs2);
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FixupBranch BNE(RiscVReg rs1, RiscVReg rs2);
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FixupBranch BLT(RiscVReg rs1, RiscVReg rs2);
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FixupBranch BGE(RiscVReg rs1, RiscVReg rs2);
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FixupBranch BLTU(RiscVReg rs1, RiscVReg rs2);
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FixupBranch BGEU(RiscVReg rs1, RiscVReg rs2);
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2022-08-25 05:58:00 +00:00
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void LB(RiscVReg rd, RiscVReg addr, s32 simm12);
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void LH(RiscVReg rd, RiscVReg addr, s32 simm12);
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void LW(RiscVReg rd, RiscVReg addr, s32 simm12);
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void LBU(RiscVReg rd, RiscVReg addr, s32 simm12);
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void LHU(RiscVReg rd, RiscVReg addr, s32 simm12);
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2022-08-25 02:19:32 +00:00
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2022-08-25 05:58:00 +00:00
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void SB(RiscVReg rs2, RiscVReg addr, s32 simm12);
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void SH(RiscVReg rs2, RiscVReg addr, s32 simm12);
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void SW(RiscVReg rs2, RiscVReg addr, s32 simm12);
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2022-08-25 02:19:32 +00:00
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void ADDI(RiscVReg rd, RiscVReg rs1, s32 simm12);
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void SLTI(RiscVReg rd, RiscVReg rs1, s32 simm12);
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void SLTIU(RiscVReg rd, RiscVReg rs1, s32 simm12);
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void XORI(RiscVReg rd, RiscVReg rs1, s32 simm12);
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void ORI(RiscVReg rd, RiscVReg rs1, s32 simm12);
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void ANDI(RiscVReg rd, RiscVReg rs1, s32 simm12);
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void NOP() {
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ADDI(R_ZERO, R_ZERO, 0);
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}
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void MV(RiscVReg rd, RiscVReg rs1) {
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ADDI(rd, rs1, 0);
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}
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void NOT(RiscVReg rd, RiscVReg rs1) {
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XORI(rd, rs1, -1);
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}
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2022-08-27 02:09:41 +00:00
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// The temp reg is only possibly used for 64-bit values.
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template <typename T>
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void LI(RiscVReg rd, const T &v, RiscVReg temp = R_ZERO) {
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_assert_msg_(rd != R_ZERO, "LI to X0");
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_assert_msg_(rd < F0 && temp < F0, "LI to non-GPR");
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uint64_t value = AsImmediate<T, std::is_signed<T>::value>(v);
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SetRegToImmediate(rd, value, temp);
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}
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2022-08-25 02:19:32 +00:00
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void SLLI(RiscVReg rd, RiscVReg rs1, u32 shamt);
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void SRLI(RiscVReg rd, RiscVReg rs1, u32 shamt);
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void SRAI(RiscVReg rd, RiscVReg rs1, u32 shamt);
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2022-08-25 02:44:29 +00:00
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void ADD(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void SUB(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void SLL(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void SLT(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void SLTU(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void XOR(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void SRL(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void SRA(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void OR(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void AND(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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|
|
2022-08-25 03:33:36 +00:00
|
|
|
void NEG(RiscVReg rd, RiscVReg rs) {
|
|
|
|
SUB(rd, R_ZERO, rs);
|
|
|
|
}
|
2023-06-07 06:48:08 +00:00
|
|
|
void SNEZ(RiscVReg rd, RiscVReg rs) {
|
|
|
|
SLTU(rd, R_ZERO, rs);
|
|
|
|
}
|
|
|
|
void SEQZ(RiscVReg rd, RiscVReg rs) {
|
|
|
|
SLTIU(rd, rs, 1);
|
|
|
|
}
|
2022-08-25 03:33:36 +00:00
|
|
|
|
|
|
|
void FENCE(Fence predecessor, Fence successor);
|
|
|
|
void FENCE_TSO();
|
|
|
|
|
|
|
|
void ECALL();
|
|
|
|
void EBREAK();
|
|
|
|
|
2023-02-13 03:19:12 +00:00
|
|
|
// 64-bit instructions - ones ending in W sign extend result to 32 bits.
|
2022-08-25 05:58:00 +00:00
|
|
|
void LWU(RiscVReg rd, RiscVReg addr, s32 simm12);
|
|
|
|
void LD(RiscVReg rd, RiscVReg addr, s32 simm12);
|
|
|
|
void SD(RiscVReg rs2, RiscVReg addr, s32 simm12);
|
2022-08-25 03:33:36 +00:00
|
|
|
void ADDIW(RiscVReg rd, RiscVReg rs1, s32 simm12);
|
|
|
|
void SLLIW(RiscVReg rd, RiscVReg rs1, u32 shamt);
|
|
|
|
void SRLIW(RiscVReg rd, RiscVReg rs1, u32 shamt);
|
|
|
|
void SRAIW(RiscVReg rd, RiscVReg rs1, u32 shamt);
|
|
|
|
void ADDW(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void SUBW(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void SLLW(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void SRLW(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void SRAW(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
|
|
|
|
void NEGW(RiscVReg rd, RiscVReg rs) {
|
|
|
|
SUBW(rd, R_ZERO, rs);
|
|
|
|
}
|
|
|
|
|
2022-08-25 04:05:19 +00:00
|
|
|
// Integer multiplication and division.
|
|
|
|
void MUL(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void MULH(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void MULHSU(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void MULHU(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void DIV(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void DIVU(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void REM(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void REMU(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
// 64-bit only multiply and divide.
|
|
|
|
void MULW(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void DIVW(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void DIVUW(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void REMW(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void REMUW(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
|
2022-08-25 05:58:00 +00:00
|
|
|
// Atomic memory operations.
|
|
|
|
void LR(int bits, RiscVReg rd, RiscVReg addr, Atomic ordering);
|
|
|
|
void SC(int bits, RiscVReg rd, RiscVReg rs2, RiscVReg addr, Atomic ordering);
|
|
|
|
void AMOSWAP(int bits, RiscVReg rd, RiscVReg rs2, RiscVReg addr, Atomic ordering);
|
|
|
|
void AMOADD(int bits, RiscVReg rd, RiscVReg rs2, RiscVReg addr, Atomic ordering);
|
|
|
|
void AMOAND(int bits, RiscVReg rd, RiscVReg rs2, RiscVReg addr, Atomic ordering);
|
|
|
|
void AMOOR(int bits, RiscVReg rd, RiscVReg rs2, RiscVReg addr, Atomic ordering);
|
|
|
|
void AMOXOR(int bits, RiscVReg rd, RiscVReg rs2, RiscVReg addr, Atomic ordering);
|
|
|
|
void AMOMIN(int bits, RiscVReg rd, RiscVReg rs2, RiscVReg addr, Atomic ordering);
|
|
|
|
void AMOMAX(int bits, RiscVReg rd, RiscVReg rs2, RiscVReg addr, Atomic ordering);
|
|
|
|
void AMOMINU(int bits, RiscVReg rd, RiscVReg rs2, RiscVReg addr, Atomic ordering);
|
|
|
|
void AMOMAXU(int bits, RiscVReg rd, RiscVReg rs2, RiscVReg addr, Atomic ordering);
|
|
|
|
|
2022-08-26 02:26:15 +00:00
|
|
|
// Floating point (same funcs for single/double/quad, if supported.)
|
|
|
|
void FL(int bits, RiscVReg rd, RiscVReg addr, s32 simm12);
|
|
|
|
void FS(int bits, RiscVReg rs2, RiscVReg addr, s32 simm12);
|
|
|
|
void FLW(RiscVReg rd, RiscVReg addr, s32 simm12) {
|
|
|
|
FL(32, rd, addr, simm12);
|
|
|
|
}
|
|
|
|
void FSW(RiscVReg rs2, RiscVReg addr, s32 simm12) {
|
|
|
|
FS(32, rs2, addr, simm12);
|
|
|
|
}
|
|
|
|
|
|
|
|
void FMADD(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2, RiscVReg rs3, Round rm = Round::DYNAMIC);
|
|
|
|
void FMSUB(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2, RiscVReg rs3, Round rm = Round::DYNAMIC);
|
|
|
|
void FNMSUB(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2, RiscVReg rs3, Round rm = Round::DYNAMIC);
|
|
|
|
void FNMADD(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2, RiscVReg rs3, Round rm = Round::DYNAMIC);
|
|
|
|
|
|
|
|
void FADD(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2, Round rm = Round::DYNAMIC);
|
|
|
|
void FSUB(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2, Round rm = Round::DYNAMIC);
|
|
|
|
void FMUL(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2, Round rm = Round::DYNAMIC);
|
|
|
|
void FDIV(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2, Round rm = Round::DYNAMIC);
|
|
|
|
void FSQRT(int bits, RiscVReg rd, RiscVReg rs1, Round rm = Round::DYNAMIC);
|
|
|
|
|
|
|
|
void FSGNJ(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void FSGNJN(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void FSGNJX(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
|
|
|
|
void FMV(int bits, RiscVReg rd, RiscVReg rs) {
|
|
|
|
FSGNJ(bits, rd, rs, rs);
|
|
|
|
}
|
|
|
|
void FNEG(int bits, RiscVReg rd, RiscVReg rs) {
|
|
|
|
FSGNJN(bits, rd, rs, rs);
|
|
|
|
}
|
|
|
|
void FABS(int bits, RiscVReg rd, RiscVReg rs) {
|
|
|
|
FSGNJX(bits, rd, rs, rs);
|
|
|
|
}
|
|
|
|
|
|
|
|
void FMIN(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void FMAX(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
|
|
|
|
void FCVT(FConv to, FConv from, RiscVReg rd, RiscVReg rs1, Round rm = Round::DYNAMIC);
|
|
|
|
void FMV(FMv to, FMv from, RiscVReg rd, RiscVReg rs1);
|
|
|
|
|
|
|
|
void FEQ(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void FLT(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void FLE(int bits, RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
void FCLASS(int bits, RiscVReg rd, RiscVReg rs1);
|
|
|
|
|
2022-08-26 03:30:01 +00:00
|
|
|
// Control state register manipulation.
|
|
|
|
void CSRRW(RiscVReg rd, Csr csr, RiscVReg rs1);
|
|
|
|
void CSRRS(RiscVReg rd, Csr csr, RiscVReg rs1);
|
|
|
|
void CSRRC(RiscVReg rd, Csr csr, RiscVReg rs1);
|
|
|
|
void CSRRWI(RiscVReg rd, Csr csr, u8 uimm5);
|
|
|
|
void CSRRSI(RiscVReg rd, Csr csr, u8 uimm5);
|
|
|
|
void CSRRCI(RiscVReg rd, Csr csr, u8 uimm5);
|
|
|
|
|
|
|
|
void FRRM(RiscVReg rd) {
|
2022-08-27 02:09:41 +00:00
|
|
|
CSRRS(rd, Csr::FRm, R_ZERO);
|
2022-08-26 03:30:01 +00:00
|
|
|
}
|
|
|
|
void FSRM(RiscVReg rs) {
|
2022-08-27 02:09:41 +00:00
|
|
|
CSRRW(R_ZERO, Csr::FRm, rs);
|
2022-08-26 03:30:01 +00:00
|
|
|
}
|
|
|
|
void FSRMI(RiscVReg rd, Round rm) {
|
|
|
|
_assert_msg_(rm != Round::DYNAMIC, "Cannot set FRm to DYNAMIC");
|
|
|
|
CSRRWI(rd, Csr::FRm, (uint8_t)rm);
|
|
|
|
}
|
|
|
|
void FSRMI(Round rm) {
|
2022-08-27 02:09:41 +00:00
|
|
|
FSRMI(R_ZERO, rm);
|
2022-08-26 03:30:01 +00:00
|
|
|
}
|
|
|
|
|
2023-01-21 22:51:52 +00:00
|
|
|
// Vector instructions.
|
|
|
|
void VSETVLI(RiscVReg rd, RiscVReg rs1, VType vtype);
|
|
|
|
void VSETIVLI(RiscVReg rd, u8 uimm5, VType vtype);
|
|
|
|
void VSETVL(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
|
|
|
|
|
|
|
|
// Load contiguous registers, unordered.
|
|
|
|
void VLE_V(int dataBits, RiscVReg vd, RiscVReg rs1, VUseMask vm = VUseMask::NONE) {
|
|
|
|
VLSEGE_V(1, dataBits, vd, rs1, vm);
|
|
|
|
}
|
|
|
|
// Load registers with stride (note: rs2/stride can be X0/zero to broadcast.)
|
|
|
|
void VLSE_V(int dataBits, RiscVReg vd, RiscVReg rs1, RiscVReg rs2, VUseMask vm = VUseMask::NONE) {
|
|
|
|
VLSSEGE_V(1, dataBits, vd, rs1, rs2, vm);
|
|
|
|
}
|
|
|
|
// Load indexed registers (gather), unordered.
|
|
|
|
void VLUXEI_V(int indexBits, RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE) {
|
|
|
|
VLUXSEGEI_V(1, indexBits, vd, rs1, vs2, vm);
|
|
|
|
}
|
|
|
|
// Load indexed registers (gather), ordered.
|
|
|
|
void VLOXEI_V(int indexBits, RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE) {
|
|
|
|
VLOXSEGEI_V(1, indexBits, vd, rs1, vs2, vm);
|
|
|
|
}
|
|
|
|
// Load mask (force 8 bit, EMUL=1, TA)
|
|
|
|
void VLM_V(RiscVReg vd, RiscVReg rs1);
|
|
|
|
// Load but ignore faults after first element.
|
|
|
|
void VLEFF_V(int dataBits, RiscVReg vd, RiscVReg rs1, VUseMask vm = VUseMask::NONE) {
|
|
|
|
VLSEGEFF_V(1, dataBits, vd, rs1, vm);
|
|
|
|
}
|
|
|
|
// Load fields into subsequent registers (destructure.)
|
|
|
|
void VLSEGE_V(int fields, int dataBits, RiscVReg vd, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VLSSEGE_V(int fields, int dataBits, RiscVReg vd, RiscVReg rs1, RiscVReg rs2, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VLUXSEGEI_V(int fields, int indexBits, RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VLOXSEGEI_V(int fields, int indexBits, RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VLSEGEFF_V(int fields, int dataBits, RiscVReg vd, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
// Load entire registers (implementation dependent size.)
|
|
|
|
void VLR_V(int regs, int hintBits, RiscVReg vd, RiscVReg rs1);
|
|
|
|
|
|
|
|
void VSE_V(int dataBits, RiscVReg vs3, RiscVReg rs1, VUseMask vm = VUseMask::NONE) {
|
|
|
|
VSSEGE_V(1, dataBits, vs3, rs1, vm);
|
|
|
|
}
|
|
|
|
void VSSE_V(int dataBits, RiscVReg vs3, RiscVReg rs1, RiscVReg rs2, VUseMask vm = VUseMask::NONE) {
|
|
|
|
VSSSEGE_V(1, dataBits, vs3, rs1, rs2, vm);
|
|
|
|
}
|
|
|
|
void VSUXEI_V(int indexBits, RiscVReg vs3, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE) {
|
|
|
|
VSUXSEGEI_V(1, indexBits, vs3, rs1, vs2, vm);
|
|
|
|
}
|
|
|
|
void VSOXEI_V(int indexBits, RiscVReg vs3, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE) {
|
|
|
|
VSOXSEGEI_V(1, indexBits, vs3, rs1, vs2, vm);
|
|
|
|
}
|
|
|
|
void VSM_V(RiscVReg vs3, RiscVReg rs1);
|
|
|
|
void VSSEGE_V(int fields, int dataBits, RiscVReg vs3, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VSSSEGE_V(int fields, int dataBits, RiscVReg vs3, RiscVReg rs1, RiscVReg rs2, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VSUXSEGEI_V(int fields, int indexBits, RiscVReg vs3, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VSOXSEGEI_V(int fields, int indexBits, RiscVReg vs3, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VSR_V(int regs, RiscVReg vs3, RiscVReg rs1);
|
|
|
|
|
2023-01-22 01:42:27 +00:00
|
|
|
void VADD_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VADD_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VADD_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VSUB_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VSUB_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VRSUB_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VRSUB_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VNEG_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE) {
|
|
|
|
VRSUB_VX(vd, vs2, X0, vm);
|
|
|
|
}
|
|
|
|
|
|
|
|
void VWADDU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VWADDU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VWSUBU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VWSUBU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VWADD_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VWADD_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VWSUB_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VWSUB_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VWADDU_WV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VWADDU_WX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VWSUBU_WV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VWSUBU_WX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VWADD_WV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VWADD_WX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VWSUB_WV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VWSUB_WX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
|
|
|
|
|
|
|
void VZEXT_V(int frac, RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
|
|
|
|
void VSEXT_V(int frac, RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
|
|
|
|
|
|
|
|
// vmask must be V0, provided for clarity/reminder.
|
|
|
|
void VADC_VVM(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, RiscVReg vmask);
|
|
|
|
void VADC_VXM(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, RiscVReg vmask);
|
|
|
|
void VADC_VIM(RiscVReg vd, RiscVReg vs2, s8 simm5, RiscVReg vmask);
|
|
|
|
void VMADC_VVM(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, RiscVReg vmask);
|
|
|
|
void VMADC_VXM(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, RiscVReg vmask);
|
|
|
|
void VMADC_VIM(RiscVReg vd, RiscVReg vs2, s8 simm5, RiscVReg vmask);
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void VMADC_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1);
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void VMADC_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1);
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void VMADC_VI(RiscVReg vd, RiscVReg vs2, s8 simm5);
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void VSBC_VVM(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, RiscVReg vmask);
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void VSBC_VXM(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, RiscVReg vmask);
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void VMSBC_VVM(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, RiscVReg vmask);
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void VMSBC_VXM(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, RiscVReg vmask);
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void VMSBC_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1);
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void VMSBC_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1);
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2023-01-22 03:02:02 +00:00
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void VAND_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VAND_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VAND_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
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void VOR_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VOR_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VOR_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
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void VXOR_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VXOR_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VXOR_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
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void VNOT_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE) {
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VXOR_VI(vd, vs2, -1, vm);
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}
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void VSLL_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VSLL_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VSLL_VI(RiscVReg vd, RiscVReg vs2, u8 uimm5, VUseMask vm = VUseMask::NONE);
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void VSRL_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VSRL_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VSRL_VI(RiscVReg vd, RiscVReg vs2, u8 uimm5, VUseMask vm = VUseMask::NONE);
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void VSRA_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VSRA_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VSRA_VI(RiscVReg vd, RiscVReg vs2, u8 uimm5, VUseMask vm = VUseMask::NONE);
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void VNSRL_WV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VNSRL_WX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VNSRL_WI(RiscVReg vd, RiscVReg vs2, u8 uimm5, VUseMask vm = VUseMask::NONE);
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void VNSRA_WV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VNSRA_WX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VNSRA_WI(RiscVReg vd, RiscVReg vs2, u8 uimm5, VUseMask vm = VUseMask::NONE);
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// Using a mask creates an AND condition, assuming vtype has MU not MA.
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// Note: VV and VI don't have all comparison ops, VX does (there's no GE/GEU at all, though.)
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void VMSEQ_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMSNE_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMSLTU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMSLT_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMSLEU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMSLE_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMSEQ_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMSNE_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMSLTU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMSLT_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMSLEU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMSLE_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMSGTU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMSGT_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMSEQ_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
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void VMSNE_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
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void VMSLEU_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
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void VMSLE_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
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void VMSGTU_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
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void VMSGT_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
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void VMINU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMINU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMIN_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMIN_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMAXU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMAXU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMAX_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMAX_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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2023-01-22 03:35:41 +00:00
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void VMUL_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMUL_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMULH_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMULH_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMULHU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMULHU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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// Takes vs2 as signed, vs1 as unsigned.
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void VMULHSU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMULHSU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VDIVU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VDIVU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VDIV_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VDIV_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VREMU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VREMU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VREM_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VREM_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VWMUL_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VWMUL_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VWMULU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VWMULU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VWMULSU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VWMULSU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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// Multiply and add - vd += vs1 * vs2.
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void VMACC_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VMACC_VX(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Multiply and sub - vd -= vs1 * vs2.
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void VNMSAC_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VNMSAC_VX(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Multiply and add - vd = vd * vs1 + vs2.
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void VMADD_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VMADD_VX(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Multiply and sub - vd = -(vd * vs1) + vs2.
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void VNMSUB_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VNMSUB_VX(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Widening multiply and add - vd(wide) += vs1 * vs2.
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void VWMACCU_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VWMACCU_VX(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Widening multiply and add - vd(wide) += vs1 * vs2.
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void VWMACC_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VWMACC_VX(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Widening multiply and add - vd(wide) += S(vs1) * U(vs2).
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void VWMACCSU_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VWMACCSU_VX(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Widening multiply and add - vd(wide) += U(rs1) * S(vs2).
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void VWMACCUS_VX(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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2023-01-22 03:46:50 +00:00
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// Masked bits (1) take vs1/rs1/simm5, vmask must be V0.
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void VMERGE_VVM(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, RiscVReg vmask);
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void VMERGE_VXM(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, RiscVReg vmask);
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void VMERGE_VIM(RiscVReg vd, RiscVReg vs2, s8 simm5, RiscVReg vmask);
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// Simple register copy, can be used as a hint to internally prepare size if vd == vs1.
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void VMV_VV(RiscVReg vd, RiscVReg vs1);
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// These broadcast a value to all lanes of vd.
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void VMV_VX(RiscVReg vd, RiscVReg rs1);
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void VMV_VI(RiscVReg vd, s8 simm5);
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2023-01-22 04:22:50 +00:00
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void VSADDU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VSADDU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VSADDU_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
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void VSADD_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VSADD_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VSADD_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
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void VSSUBU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VSSUBU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VSSUB_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VSSUB_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VAADDU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VAADDU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VAADD_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VAADD_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VASUBU_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VASUBU_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VASUB_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VASUB_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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|
// Fixed-point multiply, sra's product by SEW-1 before writing result.
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void VSMUL_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VSMUL_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VSSRL_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VSSRL_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VSSRL_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
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void VSSRA_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VSSRA_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VSSRA_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
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void VNCLIPU_WV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VNCLIPU_WX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VNCLIPU_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
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void VNCLIP_WV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VNCLIP_WX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VNCLIP_VI(RiscVReg vd, RiscVReg vs2, s8 simm5, VUseMask vm = VUseMask::NONE);
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2023-01-22 04:48:49 +00:00
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void VFADD_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFADD_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VFSUB_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFSUB_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VFRSUB_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VFWADD_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFWADD_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VFWSUB_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFWSUB_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VFWADD_WV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFWADD_WF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VFWSUB_WV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFWSUB_WF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VFMUL_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFMUL_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VFDIV_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFDIV_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VFRDIV_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VFWMUL_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFWMUL_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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// Fused multiply and accumulate: vd = +vd + vs1 * vs2.
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void VFMACC_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFMACC_VF(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Fused multiply and accumulate, negated: vd = -vd - vs1 * vs2.
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void VFNMACC_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFNMACC_VF(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Fused multiply and subtract accumuluator: vd = -vd + vs1 * vs2.
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void VFMSAC_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFMSAC_VF(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Fused multiply and subtract accumuluator, negated: vd = +vd - vs1 * vs2.
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void VFNMSAC_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFNMSAC_VF(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Fused multiply and add: vd = +(vs1 * vd) + vs2.
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void VFMADD_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFMADD_VF(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Fused multiply and add, negated: vd = -(vs1 * vd) - vs2.
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void VFNMADD_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFNMADD_VF(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Fused multiply and subtract: vd = +(vs1 * vd) - vs2.
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void VFMSUB_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFMSUB_VF(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Fused multiply and subtract, negated: vd = -(vs1 * vd) + vs2.
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void VFNMSUB_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFNMSUB_VF(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Fused widening multiply and accumulate: vd(wide) = +vd + vs1 * vs2.
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void VFWMACC_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFWMACC_VF(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Fused widening multiply and accumulate, negated: vd(wide) = -vd - vs1 * vs2.
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void VFWNMACC_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFWNMACC_VF(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Fused widening multiply and subtract accumulator: vd(wide) = -vd + vs1 * vs2.
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void VFWMSAC_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFWMSAC_VF(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// Fused widening multiply and subtract accumulator, negated: vd(wide) = +vd - vs1 * vs2.
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void VFWNMSAC_VV(RiscVReg vd, RiscVReg vs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFWNMSAC_VF(RiscVReg vd, RiscVReg rs1, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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2023-01-22 06:05:13 +00:00
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void VFSQRT_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFRSQRT7_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFREC7_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFMIN_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFMIN_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VFMAX_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFMAX_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VFSGNJ_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFSGNJ_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VFSGNJN_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFSGNJN_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VFSGNJX_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFSGNJX_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMFEQ_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMFEQ_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMFNE_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMFNE_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMFLT_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMFLT_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMFLE_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VMFLE_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMFGT_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VMFGE_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
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void VFCLASS_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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// vmask must be V0, takes rs1 where mask bits are set (1).
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void VFMERGE_VFM(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, RiscVReg vmask);
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// Broadcast/splat.
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void VFMV_VF(RiscVReg vd, RiscVReg rs1);
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void VFCVT_XU_F_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFCVT_X_F_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFCVT_RTZ_XU_F_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFCVT_RTZ_X_F_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFCVT_F_XU_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFCVT_F_X_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFWCVT_XU_F_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFWCVT_X_F_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFWCVT_RTZ_XU_F_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFWCVT_RTZ_X_F_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFWCVT_F_XU_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFWCVT_F_X_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFWCVT_F_F_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFNCVT_XU_F_W(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFNCVT_X_F_W(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFNCVT_RTZ_XU_F_W(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFNCVT_RTZ_X_F_W(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFNCVT_F_XU_W(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFNCVT_F_X_W(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFNCVT_F_F_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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void VFNCVT_ROD_F_F_V(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
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|
2023-01-22 06:35:38 +00:00
|
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void VREDSUM_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VREDMAXU_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VREDMAX_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VREDMINU_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VREDMIN_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VREDAND_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VREDOR_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VREDXOR_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VWREDSUMU_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VWREDSUM_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFREDOSUM_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFREDUSUM_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFREDMAX_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFREDMIN_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFWREDOSUM_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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void VFWREDUSUM_VS(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
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|
2023-01-22 07:23:58 +00:00
|
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|
void VMAND_MM(RiscVReg vd, RiscVReg vs2, RiscVReg vs1);
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void VMNAND_MM(RiscVReg vd, RiscVReg vs2, RiscVReg vs1);
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void VMANDN_MM(RiscVReg vd, RiscVReg vs2, RiscVReg vs1);
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void VMXOR_MM(RiscVReg vd, RiscVReg vs2, RiscVReg vs1);
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void VMOR_MM(RiscVReg vd, RiscVReg vs2, RiscVReg vs1);
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void VMNOR_MM(RiscVReg vd, RiscVReg vs2, RiscVReg vs1);
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void VMORN_MM(RiscVReg vd, RiscVReg vs2, RiscVReg vs1);
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void VMXNOR_MM(RiscVReg vd, RiscVReg vs2, RiscVReg vs1);
|
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|
void VMMV_M(RiscVReg vd, RiscVReg vs1) {
|
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|
|
VMAND_MM(vd, vs1, vs1);
|
|
|
|
}
|
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|
|
void VMCLR_M(RiscVReg vd, RiscVReg vs1) {
|
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|
|
VMXOR_MM(vd, vs1, vs1);
|
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|
|
}
|
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|
|
void VMSET_M(RiscVReg vd, RiscVReg vs1) {
|
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|
|
VMXNOR_MM(vd, vs1, vs1);
|
|
|
|
}
|
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|
|
void VMNOT_M(RiscVReg vd, RiscVReg vs1) {
|
|
|
|
VMNAND_MM(vd, vs1, vs1);
|
|
|
|
}
|
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|
|
void VCPOP_M(RiscVReg rd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
|
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|
void VFIRST_M(RiscVReg rd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
|
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|
void VMSBF_M(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
|
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void VMSIF_M(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
|
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void VMSOF_M(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
|
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|
void VIOTA_M(RiscVReg vd, RiscVReg vs2, VUseMask vm = VUseMask::NONE);
|
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|
void VID_M(RiscVReg vd, VUseMask vm = VUseMask::NONE);
|
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|
|
2023-01-22 08:17:40 +00:00
|
|
|
void VMV_X_S(RiscVReg rd, RiscVReg vs2);
|
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|
void VMV_S_X(RiscVReg vd, RiscVReg rs1);
|
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|
void VFMV_F_S(RiscVReg rd, RiscVReg vs2);
|
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|
void VFMV_S_F(RiscVReg vd, RiscVReg rs1);
|
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void VSLIDEUP_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
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|
void VSLIDEUP_VI(RiscVReg vd, RiscVReg vs2, u8 uimm5, VUseMask vm = VUseMask::NONE);
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void VSLIDEDOWN_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
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void VSLIDEDOWN_VI(RiscVReg vd, RiscVReg vs2, u8 uimm5, VUseMask vm = VUseMask::NONE);
|
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void VSLIDE1UP_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
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|
void VFSLIDE1UP_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
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|
void VSLIDE1DOWN_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
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void VFSLIDE1DOWN_VF(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
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void VRGATHER_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
|
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|
void VRGATHEREI16_VV(RiscVReg vd, RiscVReg vs2, RiscVReg vs1, VUseMask vm = VUseMask::NONE);
|
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|
void VRGATHER_VX(RiscVReg vd, RiscVReg vs2, RiscVReg rs1, VUseMask vm = VUseMask::NONE);
|
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|
void VRGATHER_VI(RiscVReg vd, RiscVReg vs2, u8 uimm5, VUseMask vm = VUseMask::NONE);
|
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|
|
void VCOMPRESS_VM(RiscVReg vd, RiscVReg vs2, RiscVReg vs1);
|
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|
void VMVR_V(int regs, RiscVReg vd, RiscVReg vs2);
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2023-01-22 20:37:47 +00:00
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// Bitmanip instructions.
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void ADD_UW(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void SH_ADD(int shift, RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void SH_ADD_UW(int shift, RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void SLLI_UW(RiscVReg rd, RiscVReg rs1, u32 shamt);
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void ANDN(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void ORN(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void XNOR(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void CLZ(RiscVReg rd, RiscVReg rs);
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void CLZW(RiscVReg rd, RiscVReg rs);
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void CTZ(RiscVReg rd, RiscVReg rs);
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void CTZW(RiscVReg rd, RiscVReg rs);
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void CPOP(RiscVReg rd, RiscVReg rs);
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void CPOPW(RiscVReg rd, RiscVReg rs);
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void MAX(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void MAXU(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void MIN(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void MINU(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void SEXT_B(RiscVReg rd, RiscVReg rs);
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void SEXT_H(RiscVReg rd, RiscVReg rs);
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2023-06-07 06:48:08 +00:00
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void SEXT_W(RiscVReg rd, RiscVReg rs) {
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ADDIW(rd, rs, 0);
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}
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2023-01-22 20:37:47 +00:00
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void ZEXT_H(RiscVReg rd, RiscVReg rs);
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void ZEXT_W(RiscVReg rd, RiscVReg rs) {
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ADD_UW(rd, rs, R_ZERO);
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}
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void ROL(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void ROLW(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void ROR(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void RORW(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void RORI(RiscVReg rd, RiscVReg rs1, u32 shamt);
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void RORIW(RiscVReg rd, RiscVReg rs1, u32 shamt);
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void ORC_B(RiscVReg rd, RiscVReg rs);
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void REV8(RiscVReg rd, RiscVReg rs);
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void CLMUL(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void CLMULH(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void CLMULR(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void BCLR(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void BCLRI(RiscVReg rd, RiscVReg rs1, u32 shamt);
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void BEXT(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void BEXTI(RiscVReg rd, RiscVReg rs1, u32 shamt);
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void BINV(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void BINVI(RiscVReg rd, RiscVReg rs1, u32 shamt);
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void BSET(RiscVReg rd, RiscVReg rs1, RiscVReg rs2);
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void BSETI(RiscVReg rd, RiscVReg rs1, u32 shamt);
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2022-08-27 22:14:22 +00:00
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// Compressed instructions.
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void C_ADDI4SPN(RiscVReg rd, u32 nzuimm10);
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void C_FLD(RiscVReg rd, RiscVReg addr, u8 uimm8);
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void C_LW(RiscVReg rd, RiscVReg addr, u8 uimm7);
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void C_FLW(RiscVReg rd, RiscVReg addr, u8 uimm7);
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void C_LD(RiscVReg rd, RiscVReg addr, u8 uimm8);
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void C_FSD(RiscVReg rs2, RiscVReg addr, u8 uimm8);
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void C_SW(RiscVReg rs2, RiscVReg addr, u8 uimm7);
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void C_FSW(RiscVReg rs2, RiscVReg addr, u8 uimm7);
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void C_SD(RiscVReg rs2, RiscVReg addr, u8 uimm8);
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void C_NOP();
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void C_ADDI(RiscVReg rd, s8 nzsimm6);
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void C_JAL(const void *dst);
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FixupBranch C_JAL();
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void C_ADDIW(RiscVReg rd, s8 simm6);
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void C_LI(RiscVReg rd, s8 simm6);
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void C_ADDI16SP(s32 nzsimm10);
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void C_LUI(RiscVReg rd, s32 nzsimm18);
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void C_SRLI(RiscVReg rd, u8 nzuimm6);
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void C_SRAI(RiscVReg rd, u8 nzuimm6);
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void C_ANDI(RiscVReg rd, s8 simm6);
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void C_SUB(RiscVReg rd, RiscVReg rs2);
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void C_XOR(RiscVReg rd, RiscVReg rs2);
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void C_OR(RiscVReg rd, RiscVReg rs2);
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void C_AND(RiscVReg rd, RiscVReg rs2);
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void C_SUBW(RiscVReg rd, RiscVReg rs2);
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void C_ADDW(RiscVReg rd, RiscVReg rs2);
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void C_J(const void *dst);
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void C_BEQZ(RiscVReg rs1, const void *dst);
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void C_BNEZ(RiscVReg rs1, const void *dst);
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FixupBranch C_J();
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FixupBranch C_BEQZ(RiscVReg rs1);
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FixupBranch C_BNEZ(RiscVReg rs1);
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void C_SLLI(RiscVReg rd, u8 nzuimm6);
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void C_FLDSP(RiscVReg rd, u32 uimm9);
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void C_LWSP(RiscVReg rd, u8 uimm8);
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void C_FLWSP(RiscVReg rd, u8 uimm8);
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void C_LDSP(RiscVReg rd, u32 uimm9);
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void C_JR(RiscVReg rs1);
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void C_MV(RiscVReg rd, RiscVReg rs2);
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void C_EBREAK();
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void C_JALR(RiscVReg rs1);
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void C_ADD(RiscVReg rd, RiscVReg rs2);
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void C_FSDSP(RiscVReg rs2, u32 uimm9);
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void C_SWSP(RiscVReg rs2, u8 uimm8);
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void C_FSWSP(RiscVReg rs2, u8 uimm8);
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void C_SDSP(RiscVReg rs2, u32 uimm9);
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bool CBInRange(const void *func) const;
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bool CJInRange(const void *func) const;
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bool SetAutoCompress(bool flag) {
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bool prev = autoCompress_;
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autoCompress_ = flag;
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return prev;
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}
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bool AutoCompress() const;
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2022-08-24 17:12:49 +00:00
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private:
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2022-08-26 02:31:46 +00:00
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void SetJumpTarget(FixupBranch &branch, const void *dst);
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2022-08-24 17:12:49 +00:00
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bool BInRange(const void *src, const void *dst) const;
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bool JInRange(const void *src, const void *dst) const;
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2022-08-27 22:14:22 +00:00
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bool CBInRange(const void *src, const void *dst) const;
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bool CJInRange(const void *src, const void *dst) const;
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2022-08-24 17:12:49 +00:00
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2022-08-27 02:09:41 +00:00
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void SetRegToImmediate(RiscVReg rd, uint64_t value, RiscVReg temp);
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template <typename T, bool extend>
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uint64_t AsImmediate(const T &v) {
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static_assert(std::is_trivial<T>::value, "Immediate argument must be a simple type");
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static_assert(sizeof(T) <= 8, "Immediate argument size should be 8, 16, 32, or 64 bits");
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// Copy the type to allow floats and avoid endian issues.
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if (sizeof(T) == 8) {
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uint64_t value;
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memcpy(&value, &v, sizeof(value));
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return value;
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} else if (sizeof(T) == 4) {
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uint32_t value;
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memcpy(&value, &v, sizeof(value));
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if (extend)
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return (int64_t)(int32_t)value;
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return value;
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} else if (sizeof(T) == 2) {
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uint16_t value;
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memcpy(&value, &v, sizeof(value));
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if (extend)
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return (int64_t)(int16_t)value;
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return value;
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} else if (sizeof(T) == 1) {
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uint8_t value;
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memcpy(&value, &v, sizeof(value));
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if (extend)
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return (int64_t)(int8_t)value;
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return value;
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}
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return (uint64_t)v;
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}
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2022-08-24 17:12:49 +00:00
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inline void Write32(u32 value) {
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2022-08-27 22:14:22 +00:00
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Write16(value & 0x0000FFFF);
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Write16(value >> 16);
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2022-08-24 17:12:49 +00:00
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}
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inline void Write16(u16 value) {
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*(u16 *)writable_ = value;
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code_ += 2;
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writable_ += 2;
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}
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2023-02-12 20:10:29 +00:00
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protected:
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2022-08-24 17:12:49 +00:00
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const u8 *code_ = nullptr;
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u8 *writable_ = nullptr;
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const u8 *lastCacheFlushEnd_ = nullptr;
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2022-08-27 22:14:22 +00:00
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bool autoCompress_ = false;
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2022-08-24 17:12:49 +00:00
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};
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2023-02-12 20:10:29 +00:00
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class RiscVCodeBlock : public CodeBlock<RiscVEmitter> {
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2022-08-24 17:12:49 +00:00
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private:
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void PoisonMemory(int offset) override;
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};
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};
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