1*f6aab3d8Srobert //===-- RISCVInstructions.h -----------------------------------------------===//
2*f6aab3d8Srobert //
3*f6aab3d8Srobert // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4*f6aab3d8Srobert // See https://llvm.org/LICENSE.txt for license information.
5*f6aab3d8Srobert // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6*f6aab3d8Srobert //
7*f6aab3d8Srobert //===----------------------------------------------------------------------===//
8*f6aab3d8Srobert
9*f6aab3d8Srobert #ifndef LLDB_SOURCE_PLUGINS_INSTRUCTION_RISCV_RISCVINSTRUCTION_H
10*f6aab3d8Srobert #define LLDB_SOURCE_PLUGINS_INSTRUCTION_RISCV_RISCVINSTRUCTION_H
11*f6aab3d8Srobert
12*f6aab3d8Srobert #include <cstdint>
13*f6aab3d8Srobert #include <optional>
14*f6aab3d8Srobert #include <variant>
15*f6aab3d8Srobert
16*f6aab3d8Srobert #include "llvm/ADT/APFloat.h"
17*f6aab3d8Srobert
18*f6aab3d8Srobert namespace lldb_private {
19*f6aab3d8Srobert
20*f6aab3d8Srobert class EmulateInstructionRISCV;
21*f6aab3d8Srobert
22*f6aab3d8Srobert struct Rd {
23*f6aab3d8Srobert uint32_t rd;
24*f6aab3d8Srobert bool Write(EmulateInstructionRISCV &emulator, uint64_t value);
25*f6aab3d8Srobert bool WriteAPFloat(EmulateInstructionRISCV &emulator, llvm::APFloat value);
26*f6aab3d8Srobert };
27*f6aab3d8Srobert
28*f6aab3d8Srobert struct Rs {
29*f6aab3d8Srobert uint32_t rs;
30*f6aab3d8Srobert std::optional<uint64_t> Read(EmulateInstructionRISCV &emulator);
31*f6aab3d8Srobert std::optional<int32_t> ReadI32(EmulateInstructionRISCV &emulator);
32*f6aab3d8Srobert std::optional<int64_t> ReadI64(EmulateInstructionRISCV &emulator);
33*f6aab3d8Srobert std::optional<uint32_t> ReadU32(EmulateInstructionRISCV &emulator);
34*f6aab3d8Srobert std::optional<llvm::APFloat> ReadAPFloat(EmulateInstructionRISCV &emulator,
35*f6aab3d8Srobert bool isDouble);
36*f6aab3d8Srobert };
37*f6aab3d8Srobert
38*f6aab3d8Srobert #define DERIVE_EQ(NAME) \
39*f6aab3d8Srobert bool operator==(const NAME &r) const { \
40*f6aab3d8Srobert return std::memcmp(this, &r, sizeof(NAME)) == 0; \
41*f6aab3d8Srobert }
42*f6aab3d8Srobert
43*f6aab3d8Srobert #define I_TYPE_INST(NAME) \
44*f6aab3d8Srobert struct NAME { \
45*f6aab3d8Srobert Rd rd; \
46*f6aab3d8Srobert Rs rs1; \
47*f6aab3d8Srobert uint32_t imm; \
48*f6aab3d8Srobert DERIVE_EQ(NAME); \
49*f6aab3d8Srobert }
50*f6aab3d8Srobert #define S_TYPE_INST(NAME) \
51*f6aab3d8Srobert struct NAME { \
52*f6aab3d8Srobert Rs rs1; \
53*f6aab3d8Srobert Rs rs2; \
54*f6aab3d8Srobert uint32_t imm; \
55*f6aab3d8Srobert DERIVE_EQ(NAME); \
56*f6aab3d8Srobert }
57*f6aab3d8Srobert #define U_TYPE_INST(NAME) \
58*f6aab3d8Srobert struct NAME { \
59*f6aab3d8Srobert Rd rd; \
60*f6aab3d8Srobert uint32_t imm; \
61*f6aab3d8Srobert DERIVE_EQ(NAME); \
62*f6aab3d8Srobert }
63*f6aab3d8Srobert /// The memory layout are the same in our code.
64*f6aab3d8Srobert #define J_TYPE_INST(NAME) U_TYPE_INST(NAME)
65*f6aab3d8Srobert #define R_TYPE_INST(NAME) \
66*f6aab3d8Srobert struct NAME { \
67*f6aab3d8Srobert Rd rd; \
68*f6aab3d8Srobert Rs rs1; \
69*f6aab3d8Srobert Rs rs2; \
70*f6aab3d8Srobert DERIVE_EQ(NAME); \
71*f6aab3d8Srobert }
72*f6aab3d8Srobert #define R_SHAMT_TYPE_INST(NAME) \
73*f6aab3d8Srobert struct NAME { \
74*f6aab3d8Srobert Rd rd; \
75*f6aab3d8Srobert Rs rs1; \
76*f6aab3d8Srobert uint32_t shamt; \
77*f6aab3d8Srobert DERIVE_EQ(NAME); \
78*f6aab3d8Srobert }
79*f6aab3d8Srobert #define R_RS1_TYPE_INST(NAME) \
80*f6aab3d8Srobert struct NAME { \
81*f6aab3d8Srobert Rd rd; \
82*f6aab3d8Srobert Rs rs1; \
83*f6aab3d8Srobert DERIVE_EQ(NAME); \
84*f6aab3d8Srobert }
85*f6aab3d8Srobert #define R4_TYPE_INST(NAME) \
86*f6aab3d8Srobert struct NAME { \
87*f6aab3d8Srobert Rd rd; \
88*f6aab3d8Srobert Rs rs1; \
89*f6aab3d8Srobert Rs rs2; \
90*f6aab3d8Srobert Rs rs3; \
91*f6aab3d8Srobert int32_t rm; \
92*f6aab3d8Srobert DERIVE_EQ(NAME); \
93*f6aab3d8Srobert }
94*f6aab3d8Srobert /// The `inst` fields are used for debugging.
95*f6aab3d8Srobert #define INVALID_INST(NAME) \
96*f6aab3d8Srobert struct NAME { \
97*f6aab3d8Srobert uint32_t inst; \
98*f6aab3d8Srobert DERIVE_EQ(NAME); \
99*f6aab3d8Srobert }
100*f6aab3d8Srobert
101*f6aab3d8Srobert // RV32I instructions (The base integer ISA)
102*f6aab3d8Srobert struct B {
103*f6aab3d8Srobert Rs rs1;
104*f6aab3d8Srobert Rs rs2;
105*f6aab3d8Srobert uint32_t imm;
106*f6aab3d8Srobert uint32_t funct3;
107*f6aab3d8Srobert DERIVE_EQ(B);
108*f6aab3d8Srobert };
109*f6aab3d8Srobert U_TYPE_INST(LUI);
110*f6aab3d8Srobert U_TYPE_INST(AUIPC);
111*f6aab3d8Srobert J_TYPE_INST(JAL);
112*f6aab3d8Srobert I_TYPE_INST(JALR);
113*f6aab3d8Srobert I_TYPE_INST(LB);
114*f6aab3d8Srobert I_TYPE_INST(LH);
115*f6aab3d8Srobert I_TYPE_INST(LW);
116*f6aab3d8Srobert I_TYPE_INST(LBU);
117*f6aab3d8Srobert I_TYPE_INST(LHU);
118*f6aab3d8Srobert S_TYPE_INST(SB);
119*f6aab3d8Srobert S_TYPE_INST(SH);
120*f6aab3d8Srobert S_TYPE_INST(SW);
121*f6aab3d8Srobert I_TYPE_INST(ADDI);
122*f6aab3d8Srobert I_TYPE_INST(SLTI);
123*f6aab3d8Srobert I_TYPE_INST(SLTIU);
124*f6aab3d8Srobert I_TYPE_INST(XORI);
125*f6aab3d8Srobert I_TYPE_INST(ORI);
126*f6aab3d8Srobert I_TYPE_INST(ANDI);
127*f6aab3d8Srobert R_TYPE_INST(ADD);
128*f6aab3d8Srobert R_TYPE_INST(SUB);
129*f6aab3d8Srobert R_TYPE_INST(SLL);
130*f6aab3d8Srobert R_TYPE_INST(SLT);
131*f6aab3d8Srobert R_TYPE_INST(SLTU);
132*f6aab3d8Srobert R_TYPE_INST(XOR);
133*f6aab3d8Srobert R_TYPE_INST(SRL);
134*f6aab3d8Srobert R_TYPE_INST(SRA);
135*f6aab3d8Srobert R_TYPE_INST(OR);
136*f6aab3d8Srobert R_TYPE_INST(AND);
137*f6aab3d8Srobert
138*f6aab3d8Srobert // RV64I inst (The base integer ISA)
139*f6aab3d8Srobert I_TYPE_INST(LWU);
140*f6aab3d8Srobert I_TYPE_INST(LD);
141*f6aab3d8Srobert S_TYPE_INST(SD);
142*f6aab3d8Srobert R_SHAMT_TYPE_INST(SLLI);
143*f6aab3d8Srobert R_SHAMT_TYPE_INST(SRLI);
144*f6aab3d8Srobert R_SHAMT_TYPE_INST(SRAI);
145*f6aab3d8Srobert I_TYPE_INST(ADDIW);
146*f6aab3d8Srobert R_SHAMT_TYPE_INST(SLLIW);
147*f6aab3d8Srobert R_SHAMT_TYPE_INST(SRLIW);
148*f6aab3d8Srobert R_SHAMT_TYPE_INST(SRAIW);
149*f6aab3d8Srobert R_TYPE_INST(ADDW);
150*f6aab3d8Srobert R_TYPE_INST(SUBW);
151*f6aab3d8Srobert R_TYPE_INST(SLLW);
152*f6aab3d8Srobert R_TYPE_INST(SRLW);
153*f6aab3d8Srobert R_TYPE_INST(SRAW);
154*f6aab3d8Srobert
155*f6aab3d8Srobert // RV32M inst (The standard integer multiplication and division extension)
156*f6aab3d8Srobert R_TYPE_INST(MUL);
157*f6aab3d8Srobert R_TYPE_INST(MULH);
158*f6aab3d8Srobert R_TYPE_INST(MULHSU);
159*f6aab3d8Srobert R_TYPE_INST(MULHU);
160*f6aab3d8Srobert R_TYPE_INST(DIV);
161*f6aab3d8Srobert R_TYPE_INST(DIVU);
162*f6aab3d8Srobert R_TYPE_INST(REM);
163*f6aab3d8Srobert R_TYPE_INST(REMU);
164*f6aab3d8Srobert
165*f6aab3d8Srobert // RV64M inst (The standard integer multiplication and division extension)
166*f6aab3d8Srobert R_TYPE_INST(MULW);
167*f6aab3d8Srobert R_TYPE_INST(DIVW);
168*f6aab3d8Srobert R_TYPE_INST(DIVUW);
169*f6aab3d8Srobert R_TYPE_INST(REMW);
170*f6aab3d8Srobert R_TYPE_INST(REMUW);
171*f6aab3d8Srobert
172*f6aab3d8Srobert // RV32A inst (The standard atomic instruction extension)
173*f6aab3d8Srobert R_RS1_TYPE_INST(LR_W);
174*f6aab3d8Srobert R_TYPE_INST(SC_W);
175*f6aab3d8Srobert R_TYPE_INST(AMOSWAP_W);
176*f6aab3d8Srobert R_TYPE_INST(AMOADD_W);
177*f6aab3d8Srobert R_TYPE_INST(AMOXOR_W);
178*f6aab3d8Srobert R_TYPE_INST(AMOAND_W);
179*f6aab3d8Srobert R_TYPE_INST(AMOOR_W);
180*f6aab3d8Srobert R_TYPE_INST(AMOMIN_W);
181*f6aab3d8Srobert R_TYPE_INST(AMOMAX_W);
182*f6aab3d8Srobert R_TYPE_INST(AMOMINU_W);
183*f6aab3d8Srobert R_TYPE_INST(AMOMAXU_W);
184*f6aab3d8Srobert
185*f6aab3d8Srobert // RV64A inst (The standard atomic instruction extension)
186*f6aab3d8Srobert R_RS1_TYPE_INST(LR_D);
187*f6aab3d8Srobert R_TYPE_INST(SC_D);
188*f6aab3d8Srobert R_TYPE_INST(AMOSWAP_D);
189*f6aab3d8Srobert R_TYPE_INST(AMOADD_D);
190*f6aab3d8Srobert R_TYPE_INST(AMOXOR_D);
191*f6aab3d8Srobert R_TYPE_INST(AMOAND_D);
192*f6aab3d8Srobert R_TYPE_INST(AMOOR_D);
193*f6aab3d8Srobert R_TYPE_INST(AMOMIN_D);
194*f6aab3d8Srobert R_TYPE_INST(AMOMAX_D);
195*f6aab3d8Srobert R_TYPE_INST(AMOMINU_D);
196*f6aab3d8Srobert R_TYPE_INST(AMOMAXU_D);
197*f6aab3d8Srobert
198*f6aab3d8Srobert // RV32F inst (The standard single-precision floating-point extension)
199*f6aab3d8Srobert I_TYPE_INST(FLW);
200*f6aab3d8Srobert S_TYPE_INST(FSW);
201*f6aab3d8Srobert R4_TYPE_INST(FMADD_S);
202*f6aab3d8Srobert R4_TYPE_INST(FMSUB_S);
203*f6aab3d8Srobert R4_TYPE_INST(FNMADD_S);
204*f6aab3d8Srobert R4_TYPE_INST(FNMSUB_S);
205*f6aab3d8Srobert R_TYPE_INST(FADD_S);
206*f6aab3d8Srobert R_TYPE_INST(FSUB_S);
207*f6aab3d8Srobert R_TYPE_INST(FMUL_S);
208*f6aab3d8Srobert R_TYPE_INST(FDIV_S);
209*f6aab3d8Srobert I_TYPE_INST(FSQRT_S);
210*f6aab3d8Srobert R_TYPE_INST(FSGNJ_S);
211*f6aab3d8Srobert R_TYPE_INST(FSGNJN_S);
212*f6aab3d8Srobert R_TYPE_INST(FSGNJX_S);
213*f6aab3d8Srobert R_TYPE_INST(FMIN_S);
214*f6aab3d8Srobert R_TYPE_INST(FMAX_S);
215*f6aab3d8Srobert I_TYPE_INST(FCVT_W_S);
216*f6aab3d8Srobert I_TYPE_INST(FCVT_WU_S);
217*f6aab3d8Srobert I_TYPE_INST(FMV_X_W);
218*f6aab3d8Srobert R_TYPE_INST(FEQ_S);
219*f6aab3d8Srobert R_TYPE_INST(FLT_S);
220*f6aab3d8Srobert R_TYPE_INST(FLE_S);
221*f6aab3d8Srobert I_TYPE_INST(FCLASS_S);
222*f6aab3d8Srobert I_TYPE_INST(FCVT_S_W);
223*f6aab3d8Srobert I_TYPE_INST(FCVT_S_WU);
224*f6aab3d8Srobert I_TYPE_INST(FMV_W_X);
225*f6aab3d8Srobert
226*f6aab3d8Srobert // RV64F inst (The standard single-precision floating-point extension)
227*f6aab3d8Srobert I_TYPE_INST(FCVT_L_S);
228*f6aab3d8Srobert I_TYPE_INST(FCVT_LU_S);
229*f6aab3d8Srobert I_TYPE_INST(FCVT_S_L);
230*f6aab3d8Srobert I_TYPE_INST(FCVT_S_LU);
231*f6aab3d8Srobert
232*f6aab3d8Srobert // RV32D inst (Extension for Double-Precision Floating-Point)
233*f6aab3d8Srobert I_TYPE_INST(FLD);
234*f6aab3d8Srobert S_TYPE_INST(FSD);
235*f6aab3d8Srobert R4_TYPE_INST(FMADD_D);
236*f6aab3d8Srobert R4_TYPE_INST(FMSUB_D);
237*f6aab3d8Srobert R4_TYPE_INST(FNMSUB_D);
238*f6aab3d8Srobert R4_TYPE_INST(FNMADD_D);
239*f6aab3d8Srobert R_TYPE_INST(FADD_D);
240*f6aab3d8Srobert R_TYPE_INST(FSUB_D);
241*f6aab3d8Srobert R_TYPE_INST(FMUL_D);
242*f6aab3d8Srobert R_TYPE_INST(FDIV_D);
243*f6aab3d8Srobert I_TYPE_INST(FSQRT_D);
244*f6aab3d8Srobert R_TYPE_INST(FSGNJ_D);
245*f6aab3d8Srobert R_TYPE_INST(FSGNJN_D);
246*f6aab3d8Srobert R_TYPE_INST(FSGNJX_D);
247*f6aab3d8Srobert R_TYPE_INST(FMIN_D);
248*f6aab3d8Srobert R_TYPE_INST(FMAX_D);
249*f6aab3d8Srobert I_TYPE_INST(FCVT_S_D);
250*f6aab3d8Srobert I_TYPE_INST(FCVT_D_S);
251*f6aab3d8Srobert R_TYPE_INST(FEQ_D);
252*f6aab3d8Srobert R_TYPE_INST(FLT_D);
253*f6aab3d8Srobert R_TYPE_INST(FLE_D);
254*f6aab3d8Srobert I_TYPE_INST(FCLASS_D);
255*f6aab3d8Srobert I_TYPE_INST(FCVT_W_D);
256*f6aab3d8Srobert I_TYPE_INST(FCVT_WU_D);
257*f6aab3d8Srobert I_TYPE_INST(FCVT_D_W);
258*f6aab3d8Srobert I_TYPE_INST(FCVT_D_WU);
259*f6aab3d8Srobert
260*f6aab3d8Srobert // RV64D inst (Extension for Double-Precision Floating-Point)
261*f6aab3d8Srobert I_TYPE_INST(FCVT_L_D);
262*f6aab3d8Srobert I_TYPE_INST(FCVT_LU_D);
263*f6aab3d8Srobert I_TYPE_INST(FMV_X_D);
264*f6aab3d8Srobert I_TYPE_INST(FCVT_D_L);
265*f6aab3d8Srobert I_TYPE_INST(FCVT_D_LU);
266*f6aab3d8Srobert I_TYPE_INST(FMV_D_X);
267*f6aab3d8Srobert
268*f6aab3d8Srobert /// Invalid and reserved instructions, the `inst` fields are used for debugging.
269*f6aab3d8Srobert INVALID_INST(INVALID);
270*f6aab3d8Srobert INVALID_INST(RESERVED);
271*f6aab3d8Srobert INVALID_INST(EBREAK);
272*f6aab3d8Srobert INVALID_INST(HINT);
273*f6aab3d8Srobert INVALID_INST(NOP);
274*f6aab3d8Srobert
275*f6aab3d8Srobert using RISCVInst = std::variant<
276*f6aab3d8Srobert LUI, AUIPC, JAL, JALR, B, LB, LH, LW, LBU, LHU, SB, SH, SW, ADDI, SLTI,
277*f6aab3d8Srobert SLTIU, XORI, ORI, ANDI, ADD, SUB, SLL, SLT, SLTU, XOR, SRL, SRA, OR, AND,
278*f6aab3d8Srobert LWU, LD, SD, SLLI, SRLI, SRAI, ADDIW, SLLIW, SRLIW, SRAIW, ADDW, SUBW, SLLW,
279*f6aab3d8Srobert SRLW, SRAW, MUL, MULH, MULHSU, MULHU, DIV, DIVU, REM, REMU, MULW, DIVW,
280*f6aab3d8Srobert DIVUW, REMW, REMUW, LR_W, SC_W, AMOSWAP_W, AMOADD_W, AMOXOR_W, AMOAND_W,
281*f6aab3d8Srobert AMOOR_W, AMOMIN_W, AMOMAX_W, AMOMINU_W, AMOMAXU_W, LR_D, SC_D, AMOSWAP_D,
282*f6aab3d8Srobert AMOADD_D, AMOXOR_D, AMOAND_D, AMOOR_D, AMOMIN_D, AMOMAX_D, AMOMINU_D,
283*f6aab3d8Srobert AMOMAXU_D, FLW, FSW, FMADD_S, FMSUB_S, FNMADD_S, FNMSUB_S, FADD_S, FSUB_S,
284*f6aab3d8Srobert FMUL_S, FDIV_S, FSQRT_S, FSGNJ_S, FSGNJN_S, FSGNJX_S, FMIN_S, FMAX_S,
285*f6aab3d8Srobert FCVT_W_S, FCVT_WU_S, FMV_X_W, FEQ_S, FLT_S, FLE_S, FCLASS_S, FCVT_S_W,
286*f6aab3d8Srobert FCVT_S_WU, FMV_W_X, FCVT_L_S, FCVT_LU_S, FCVT_S_L, FCVT_S_LU, FLD, FSD,
287*f6aab3d8Srobert FMADD_D, FMSUB_D, FNMSUB_D, FNMADD_D, FADD_D, FSUB_D, FMUL_D, FDIV_D,
288*f6aab3d8Srobert FSQRT_D, FSGNJ_D, FSGNJN_D, FSGNJX_D, FMIN_D, FMAX_D, FCVT_S_D, FCVT_D_S,
289*f6aab3d8Srobert FEQ_D, FLT_D, FLE_D, FCLASS_D, FCVT_W_D, FCVT_WU_D, FCVT_D_W, FCVT_D_WU,
290*f6aab3d8Srobert FCVT_L_D, FCVT_LU_D, FMV_X_D, FCVT_D_L, FCVT_D_LU, FMV_D_X, INVALID, EBREAK,
291*f6aab3d8Srobert RESERVED, HINT, NOP>;
292*f6aab3d8Srobert
293*f6aab3d8Srobert constexpr uint8_t RV32 = 1;
294*f6aab3d8Srobert constexpr uint8_t RV64 = 2;
295*f6aab3d8Srobert constexpr uint8_t RV128 = 4;
296*f6aab3d8Srobert
297*f6aab3d8Srobert struct InstrPattern {
298*f6aab3d8Srobert const char *name;
299*f6aab3d8Srobert /// Bit mask to check the type of a instruction (B-Type, I-Type, J-Type, etc.)
300*f6aab3d8Srobert uint32_t type_mask;
301*f6aab3d8Srobert /// Characteristic value after bitwise-and with type_mask.
302*f6aab3d8Srobert uint32_t eigen;
303*f6aab3d8Srobert RISCVInst (*decode)(uint32_t inst);
304*f6aab3d8Srobert /// If not specified, the inst will be supported by all RV versions.
305*f6aab3d8Srobert uint8_t inst_type = RV32 | RV64 | RV128;
306*f6aab3d8Srobert };
307*f6aab3d8Srobert
308*f6aab3d8Srobert struct DecodeResult {
309*f6aab3d8Srobert RISCVInst decoded;
310*f6aab3d8Srobert uint32_t inst;
311*f6aab3d8Srobert bool is_rvc;
312*f6aab3d8Srobert InstrPattern pattern;
313*f6aab3d8Srobert };
314*f6aab3d8Srobert
DecodeRD(uint32_t inst)315*f6aab3d8Srobert constexpr uint32_t DecodeRD(uint32_t inst) { return (inst & 0xF80) >> 7; }
DecodeRS1(uint32_t inst)316*f6aab3d8Srobert constexpr uint32_t DecodeRS1(uint32_t inst) { return (inst & 0xF8000) >> 15; }
DecodeRS2(uint32_t inst)317*f6aab3d8Srobert constexpr uint32_t DecodeRS2(uint32_t inst) { return (inst & 0x1F00000) >> 20; }
DecodeRS3(uint32_t inst)318*f6aab3d8Srobert constexpr uint32_t DecodeRS3(uint32_t inst) {
319*f6aab3d8Srobert return (inst & 0xF0000000) >> 27;
320*f6aab3d8Srobert }
DecodeFunct3(uint32_t inst)321*f6aab3d8Srobert constexpr uint32_t DecodeFunct3(uint32_t inst) { return (inst & 0x7000) >> 12; }
DecodeFunct2(uint32_t inst)322*f6aab3d8Srobert constexpr uint32_t DecodeFunct2(uint32_t inst) {
323*f6aab3d8Srobert return (inst & 0xE000000) >> 25;
324*f6aab3d8Srobert }
DecodeFunct7(uint32_t inst)325*f6aab3d8Srobert constexpr uint32_t DecodeFunct7(uint32_t inst) {
326*f6aab3d8Srobert return (inst & 0xFE000000) >> 25;
327*f6aab3d8Srobert }
328*f6aab3d8Srobert
DecodeRM(uint32_t inst)329*f6aab3d8Srobert constexpr int32_t DecodeRM(uint32_t inst) { return DecodeFunct3(inst); }
330*f6aab3d8Srobert
331*f6aab3d8Srobert /// RISC-V spec: The upper bits of a valid NaN-boxed value must be all 1s.
NanBoxing(uint64_t val)332*f6aab3d8Srobert constexpr uint64_t NanBoxing(uint64_t val) {
333*f6aab3d8Srobert return val | 0xFFFF'FFFF'0000'0000;
334*f6aab3d8Srobert }
335*f6aab3d8Srobert constexpr uint32_t NanUnBoxing(uint64_t val) {
336*f6aab3d8Srobert return val & (~0xFFFF'FFFF'0000'0000);
337*f6aab3d8Srobert }
338*f6aab3d8Srobert
339*f6aab3d8Srobert #undef R_TYPE_INST
340*f6aab3d8Srobert #undef R_SHAMT_TYPE_INST
341*f6aab3d8Srobert #undef R_RS1_TYPE_INST
342*f6aab3d8Srobert #undef R4_TYPE_INST
343*f6aab3d8Srobert #undef I_TYPE_INST
344*f6aab3d8Srobert #undef S_TYPE_INST
345*f6aab3d8Srobert #undef B_TYPE_INST
346*f6aab3d8Srobert #undef U_TYPE_INST
347*f6aab3d8Srobert #undef J_TYPE_INST
348*f6aab3d8Srobert #undef INVALID_INST
349*f6aab3d8Srobert #undef DERIVE_EQ
350*f6aab3d8Srobert
351*f6aab3d8Srobert } // namespace lldb_private
352*f6aab3d8Srobert #endif // LLDB_SOURCE_PLUGINS_INSTRUCTION_RISCV_RISCVINSTRUCTION_H
353