//===-- RISCVCInstructions.h ----------------------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #ifndef LLDB_SOURCE_PLUGINS_INSTRUCTION_RISCV_RISCVCINSTRUCTION_H #define LLDB_SOURCE_PLUGINS_INSTRUCTION_RISCV_RISCVCINSTRUCTION_H #include #include #include "Plugins/Process/Utility/lldb-riscv-register-enums.h" #include "RISCVInstructions.h" namespace lldb_private { /// Unified RISC-V C register encoding. struct RxC { uint32_t rd; bool shift = true; operator int() { return rd; } operator Rd() { return Rd{rd + (shift ? 8 : 0)}; } operator Rs() { return Rs{rd + (shift ? 8 : 0)}; } }; // decode register for RVC constexpr RxC DecodeCR_RD(uint32_t inst) { return RxC{DecodeRD(inst), false}; } constexpr RxC DecodeCI_RD(uint32_t inst) { return RxC{DecodeRD(inst), false}; } constexpr RxC DecodeCR_RS1(uint32_t inst) { return RxC{DecodeRD(inst), false}; } constexpr RxC DecodeCI_RS1(uint32_t inst) { return RxC{DecodeRD(inst), false}; } constexpr RxC DecodeCR_RS2(uint32_t inst) { return RxC{(inst & 0x7C) >> 2, false}; } constexpr RxC DecodeCIW_RD(uint32_t inst) { return RxC{(inst & 0x1C) >> 2}; } constexpr RxC DecodeCL_RD(uint32_t inst) { return RxC{DecodeCIW_RD(inst)}; } constexpr RxC DecodeCA_RD(uint32_t inst) { return RxC{(inst & 0x380) >> 7}; } constexpr RxC DecodeCB_RD(uint32_t inst) { return RxC{DecodeCA_RD(inst)}; } constexpr RxC DecodeCL_RS1(uint32_t inst) { return RxC{DecodeCA_RD(inst)}; } constexpr RxC DecodeCS_RS1(uint32_t inst) { return RxC{DecodeCA_RD(inst)}; } constexpr RxC DecodeCA_RS1(uint32_t inst) { return RxC{DecodeCA_RD(inst)}; } constexpr RxC DecodeCB_RS1(uint32_t inst) { return RxC{DecodeCA_RD(inst)}; } constexpr RxC DecodeCSS_RS2(uint32_t inst) { return DecodeCR_RS2(inst); } constexpr RxC DecodeCS_RS2(uint32_t inst) { return RxC{DecodeCIW_RD(inst)}; } constexpr RxC DecodeCA_RS2(uint32_t inst) { return RxC{DecodeCIW_RD(inst)}; } RISCVInst DecodeC_LWSP(uint32_t inst) { auto rd = DecodeCI_RD(inst); uint16_t offset = ((inst << 4) & 0xc0) // offset[7:6] | ((inst >> 7) & 0x20) // offset[5] | ((inst >> 2) & 0x1c); // offset[4:2] if (rd == 0) return RESERVED{inst}; return LW{rd, Rs{gpr_sp_riscv}, uint32_t(offset)}; } RISCVInst DecodeC_LDSP(uint32_t inst) { auto rd = DecodeCI_RD(inst); uint16_t offset = ((inst << 4) & 0x1c0) // offset[8:6] | ((inst >> 7) & 0x20) // offset[5] | ((inst >> 2) & 0x18); // offset[4:3] if (rd == 0) return RESERVED{inst}; return LD{rd, Rs{gpr_sp_riscv}, uint32_t(offset)}; } RISCVInst DecodeC_SWSP(uint32_t inst) { uint16_t offset = ((inst >> 1) & 0xc0) // offset[7:6] | ((inst >> 7) & 0x3c); // offset[5:2] return SW{Rs{gpr_sp_riscv}, DecodeCSS_RS2(inst), uint32_t(offset)}; } RISCVInst DecodeC_SDSP(uint32_t inst) { uint16_t offset = ((inst >> 1) & 0x1c0) // offset[8:6] | ((inst >> 7) & 0x38); // offset[5:3] return SD{Rs{gpr_sp_riscv}, DecodeCSS_RS2(inst), uint32_t(offset)}; } RISCVInst DecodeC_LW(uint32_t inst) { uint16_t offset = ((inst << 1) & 0x40) // imm[6] | ((inst >> 7) & 0x38) // imm[5:3] | ((inst >> 4) & 0x4); // imm[2] return LW{DecodeCL_RD(inst), DecodeCL_RS1(inst), uint32_t(offset)}; } RISCVInst DecodeC_LD(uint32_t inst) { uint16_t offset = ((inst << 1) & 0xc0) // imm[7:6] | ((inst >> 7) & 0x38); // imm[5:3] return LD{DecodeCL_RD(inst), DecodeCL_RS1(inst), uint32_t(offset)}; } RISCVInst DecodeC_SW(uint32_t inst) { uint16_t offset = ((inst << 1) & 0x40) // imm[6] | ((inst >> 7) & 0x38) // imm[5:3] | ((inst >> 4) & 0x4); // imm[2] return SW{DecodeCS_RS1(inst), DecodeCS_RS2(inst), uint32_t(offset)}; } RISCVInst DecodeC_SD(uint32_t inst) { uint16_t offset = ((inst << 1) & 0xc0) // imm[7:6] | ((inst >> 7) & 0x38); // imm[5:3] return SD{DecodeCS_RS1(inst), DecodeCS_RS2(inst), uint32_t(offset)}; } RISCVInst DecodeC_J(uint32_t inst) { uint16_t offset = ((inst >> 1) & 0x800) // offset[11] | ((inst << 2) & 0x400) // offset[10] | ((inst >> 1) & 0x300) // offset[9:8] | ((inst << 1) & 0x80) // offset[7] | ((inst >> 1) & 0x40) // offset[6] | ((inst << 3) & 0x20) // offset[5] | ((inst >> 7) & 0x10) // offset[4] | ((inst >> 2) & 0xe); // offset[3:1] if ((offset & 0x800) == 0) return JAL{Rd{0}, uint32_t(offset)}; return JAL{Rd{0}, uint32_t(int32_t(int16_t(offset | 0xf000)))}; } RISCVInst DecodeC_JR(uint32_t inst) { auto rs1 = DecodeCR_RS1(inst); if (rs1 == 0) return RESERVED{inst}; return JALR{Rd{0}, rs1, 0}; } RISCVInst DecodeC_JALR(uint32_t inst) { auto rs1 = DecodeCR_RS1(inst); if (rs1 == 0) return EBREAK{inst}; return JALR{Rd{1}, rs1, 0}; } constexpr uint16_t BOffset(uint32_t inst) { return ((inst >> 4) & 0x100) // offset[8] | ((inst << 1) & 0xc0) // offset[7:6] | ((inst << 3) & 0x20) // offset[5] | ((inst >> 7) & 0x18) // offset[4:3] | ((inst >> 2) & 0x6); // offset[2:1] } RISCVInst DecodeC_BNEZ(uint32_t inst) { auto rs1 = DecodeCB_RS1(inst); uint16_t offset = BOffset(inst); if ((offset & 0x100) == 0) return B{rs1, Rs{0}, uint32_t(offset), 0b001}; return B{rs1, Rs{0}, uint32_t(int32_t(int16_t(offset | 0xfe00))), 0b001}; } RISCVInst DecodeC_BEQZ(uint32_t inst) { auto rs1 = DecodeCB_RS1(inst); uint16_t offset = BOffset(inst); if ((offset & 0x100) == 0) return B{rs1, Rs{0}, uint32_t(offset), 0b000}; return B{rs1, Rs{0}, uint32_t(int32_t(int16_t(offset | 0xfe00))), 0b000}; } RISCVInst DecodeC_LI(uint32_t inst) { auto rd = DecodeCI_RD(inst); uint16_t imm = ((inst >> 7) & 0x20) | ((inst >> 2) & 0x1f); if ((imm & 0x20) == 0) return ADDI{rd, Rs{0}, uint32_t(imm)}; return ADDI{rd, Rs{0}, uint32_t(int32_t(int8_t(imm | 0xc0)))}; } RISCVInst DecodeC_LUI_ADDI16SP(uint32_t inst) { auto rd = DecodeCI_RD(inst); if (rd == 0) return HINT{inst}; if (rd == 2) { uint16_t nzimm = ((inst >> 3) & 0x200) // nzimm[9] | ((inst >> 2) & 0x10) // nzimm[4] | ((inst << 1) & 0x40) // nzimm[6] | ((inst << 4) & 0x180) // nzimm[8:7] | ((inst << 3) & 0x20); // nzimm[5] if (nzimm == 0) return RESERVED{inst}; if ((nzimm & 0x200) == 0) return ADDI{Rd{gpr_sp_riscv}, Rs{gpr_sp_riscv}, uint32_t(nzimm)}; return ADDI{Rd{gpr_sp_riscv}, Rs{gpr_sp_riscv}, uint32_t(int32_t(int16_t(nzimm | 0xfc00)))}; } uint32_t imm = ((uint32_t(inst) << 5) & 0x20000) | ((uint32_t(inst) << 10) & 0x1f000); if ((imm & 0x20000) == 0) return LUI{rd, imm}; return LUI{rd, uint32_t(int32_t(imm | 0xfffc0000))}; } RISCVInst DecodeC_ADDI(uint32_t inst) { auto rd = DecodeCI_RD(inst); if (rd == 0) return NOP{inst}; uint16_t imm = ((inst >> 7) & 0x20) | ((inst >> 2) & 0x1f); if ((imm & 0x20) == 0) return ADDI{rd, rd, uint32_t(imm)}; return ADDI{rd, rd, uint32_t(int32_t(int8_t(imm | 0xc0)))}; } RISCVInst DecodeC_ADDIW(uint32_t inst) { auto rd = DecodeCI_RD(inst); if (rd == 0) return RESERVED{inst}; uint16_t imm = ((inst >> 7) & 0x20) | ((inst >> 2) & 0x1f); if ((imm & 0x20) == 0) return ADDIW{rd, rd, uint32_t(imm)}; return ADDIW{rd, rd, uint32_t(int32_t(int8_t(imm | 0xc0)))}; } RISCVInst DecodeC_ADDI4SPN(uint32_t inst) { auto rd = DecodeCIW_RD(inst); uint16_t nzuimm = ((inst >> 1) & 0x3c0) // nzuimm[9:6] | ((inst >> 7) & 0x30) // nzuimm[5:4] | ((inst >> 2) & 0x8) // nzuimm[3] | ((inst >> 4) & 0x4); // nzuimm[2] if (rd == 0 && nzuimm == 0) return INVALID{inst}; if (nzuimm == 0) return RESERVED{inst}; return ADDI{rd, Rs{gpr_sp_riscv}, uint32_t(nzuimm)}; } RISCVInst DecodeC_SLLI(uint32_t inst) { auto rd = DecodeCI_RD(inst); uint16_t shamt = ((inst >> 7) & 0x20) | ((inst >> 2) & 0x1f); if (rd == 0 || shamt == 0) return HINT{inst}; return SLLI{rd, rd, uint8_t(shamt)}; } RISCVInst DecodeC_SRLI(uint32_t inst) { auto rd = DecodeCB_RD(inst); uint16_t shamt = ((inst >> 7) & 0x20) | ((inst >> 2) & 0x1f); if (shamt == 0) return HINT{inst}; return SRLI{rd, rd, uint8_t(shamt)}; } RISCVInst DecodeC_SRAI(uint32_t inst) { auto rd = DecodeCB_RD(inst); uint16_t shamt = ((inst >> 7) & 0x20) | ((inst >> 2) & 0x1f); if (shamt == 0) return HINT{inst}; return SRAI{rd, rd, uint8_t(shamt)}; } RISCVInst DecodeC_ANDI(uint32_t inst) { auto rd = DecodeCB_RD(inst); uint16_t imm = ((inst >> 7) & 0x20) | ((inst >> 2) & 0x1f); if ((imm & 0x20) == 0) return ANDI{rd, rd, uint32_t(imm)}; return ANDI{rd, rd, uint32_t(int32_t(int8_t(imm | 0xc0)))}; } RISCVInst DecodeC_MV(uint32_t inst) { auto rd = DecodeCR_RD(inst); auto rs2 = DecodeCR_RS2(inst); if (rd == 0) return HINT{inst}; return ADD{rd, Rs{0}, rs2}; } RISCVInst DecodeC_ADD(uint32_t inst) { auto rd = DecodeCR_RD(inst); return ADD{rd, rd, DecodeCR_RS2(inst)}; } RISCVInst DecodeC_AND(uint32_t inst) { auto rd = DecodeCA_RD(inst); return AND{rd, rd, DecodeCA_RS2(inst)}; } RISCVInst DecodeC_OR(uint32_t inst) { auto rd = DecodeCA_RD(inst); return OR{rd, rd, DecodeCA_RS2(inst)}; } RISCVInst DecodeC_XOR(uint32_t inst) { auto rd = DecodeCA_RD(inst); return XOR{rd, rd, DecodeCA_RS2(inst)}; } RISCVInst DecodeC_SUB(uint32_t inst) { auto rd = DecodeCA_RD(inst); return SUB{rd, rd, DecodeCA_RS2(inst)}; } RISCVInst DecodeC_SUBW(uint32_t inst) { auto rd = DecodeCA_RD(inst); return SUBW{rd, rd, DecodeCA_RS2(inst)}; } RISCVInst DecodeC_ADDW(uint32_t inst) { auto rd = DecodeCA_RD(inst); return ADDW{rd, rd, DecodeCA_RS2(inst)}; } RISCVInst DecodeC_FLW(uint32_t inst) { uint16_t offset = ((inst << 1) & 0x40) // imm[6] | ((inst >> 7) & 0x38) // imm[5:3] | ((inst >> 4) & 0x4); // imm[2] return FLW{DecodeCL_RD(inst), DecodeCL_RS1(inst), uint32_t(offset)}; } RISCVInst DecodeC_FSW(uint32_t inst) { uint16_t offset = ((inst << 1) & 0x40) // imm[6] | ((inst >> 7) & 0x38) // imm[5:3] | ((inst >> 4) & 0x4); // imm[2] return FSW{DecodeCS_RS1(inst), DecodeCS_RS2(inst), uint32_t(offset)}; } RISCVInst DecodeC_FLWSP(uint32_t inst) { auto rd = DecodeCI_RD(inst); uint16_t offset = ((inst << 4) & 0xc0) // offset[7:6] | ((inst >> 7) & 0x20) // offset[5] | ((inst >> 2) & 0x1c); // offset[4:2] return FLW{rd, Rs{gpr_sp_riscv}, uint32_t(offset)}; } RISCVInst DecodeC_FSWSP(uint32_t inst) { uint16_t offset = ((inst >> 1) & 0xc0) // offset[7:6] | ((inst >> 7) & 0x3c); // offset[5:2] return FSW{Rs{gpr_sp_riscv}, DecodeCSS_RS2(inst), uint32_t(offset)}; } RISCVInst DecodeC_FLDSP(uint32_t inst) { auto rd = DecodeCI_RD(inst); uint16_t offset = ((inst << 4) & 0x1c0) // offset[8:6] | ((inst >> 7) & 0x20) // offset[5] | ((inst >> 2) & 0x18); // offset[4:3] return FLD{rd, Rs{gpr_sp_riscv}, uint32_t(offset)}; } RISCVInst DecodeC_FSDSP(uint32_t inst) { uint16_t offset = ((inst >> 1) & 0x1c0) // offset[8:6] | ((inst >> 7) & 0x38); // offset[5:3] return FSD{Rs{gpr_sp_riscv}, DecodeCSS_RS2(inst), uint32_t(offset)}; } RISCVInst DecodeC_FLD(uint32_t inst) { uint16_t offset = ((inst << 1) & 0xc0) // imm[7:6] | ((inst >> 7) & 0x38); // imm[5:3] return FLD{DecodeCL_RD(inst), DecodeCL_RS1(inst), uint32_t(offset)}; } RISCVInst DecodeC_FSD(uint32_t inst) { uint16_t offset = ((inst << 1) & 0xc0) // imm[7:6] | ((inst >> 7) & 0x38); // imm[5:3] return FSD{DecodeCS_RS1(inst), DecodeCS_RS2(inst), uint32_t(offset)}; } } // namespace lldb_private #endif // LLDB_SOURCE_PLUGINS_INSTRUCTION_RISCV_RISCVCINSTRUCTION_H