/* RISC-V simulator. Copyright (C) 2005-2022 Free Software Foundation, Inc. Contributed by Mike Frysinger. This file is part of simulators. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ /* This file contains the main simulator decoding logic. i.e. everything that is architecture specific. */ /* This must come before any other includes. */ #include "defs.h" #include #include #include "sim-main.h" #include "sim-signal.h" #include "sim-syscall.h" #include "opcode/riscv.h" #include "gdb/sim-riscv.h" #define TRACE_REG(cpu, reg) \ TRACE_REGISTER (cpu, "wrote %s = %#" PRIxTW, riscv_gpr_names_abi[reg], \ cpu->regs[reg]) static const struct riscv_opcode *riscv_hash[OP_MASK_OP + 1]; #define OP_HASH_IDX(i) ((i) & (riscv_insn_length (i) == 2 ? 0x3 : 0x7f)) #define RISCV_ASSERT_RV32(cpu, fmt, args...) \ do { \ if (RISCV_XLEN (cpu) != 32) \ { \ SIM_DESC sd = CPU_STATE (cpu); \ TRACE_INSN (cpu, "RV32I-only " fmt, ## args); \ sim_engine_halt (sd, cpu, NULL, cpu->pc, sim_signalled, SIM_SIGILL); \ } \ } while (0) #define RISCV_ASSERT_RV64(cpu, fmt, args...) \ do { \ if (RISCV_XLEN (cpu) != 64) \ { \ SIM_DESC sd = CPU_STATE (cpu); \ TRACE_INSN (cpu, "RV64I-only " fmt, ## args); \ sim_engine_halt (sd, cpu, NULL, cpu->pc, sim_signalled, SIM_SIGILL); \ } \ } while (0) static INLINE void store_rd (SIM_CPU *cpu, int rd, unsigned_word val) { if (rd) { cpu->regs[rd] = val; TRACE_REG (cpu, rd); } } static INLINE unsigned_word fetch_csr (SIM_CPU *cpu, const char *name, int csr, unsigned_word *reg) { /* Handle pseudo registers. */ switch (csr) { /* Allow certain registers only in respective modes. */ case CSR_CYCLEH: case CSR_INSTRETH: case CSR_TIMEH: RISCV_ASSERT_RV32 (cpu, "CSR: %s", name); break; } return *reg; } static INLINE void store_csr (SIM_CPU *cpu, const char *name, int csr, unsigned_word *reg, unsigned_word val) { switch (csr) { /* These are pseudo registers that modify sub-fields of fcsr. */ case CSR_FRM: val &= 0x7; *reg = val; cpu->csr.fcsr = (cpu->csr.fcsr & ~0xe0) | (val << 5); break; case CSR_FFLAGS: val &= 0x1f; *reg = val; cpu->csr.fcsr = (cpu->csr.fcsr & ~0x1f) | val; break; /* Keep the sub-fields in sync. */ case CSR_FCSR: *reg = val; cpu->csr.frm = (val >> 5) & 0x7; cpu->csr.fflags = val & 0x1f; break; /* Allow certain registers only in respective modes. */ case CSR_CYCLEH: case CSR_INSTRETH: case CSR_TIMEH: RISCV_ASSERT_RV32 (cpu, "CSR: %s", name); /* All the rest are immutable. */ default: val = *reg; break; } TRACE_REGISTER (cpu, "wrote CSR %s = %#" PRIxTW, name, val); } static inline unsigned_word ashiftrt (unsigned_word val, unsigned_word shift) { uint32_t sign = (val & 0x80000000) ? ~(0xfffffffful >> shift) : 0; return (val >> shift) | sign; } static inline unsigned_word ashiftrt64 (unsigned_word val, unsigned_word shift) { uint64_t sign = (val & 0x8000000000000000ull) ? ~(0xffffffffffffffffull >> shift) : 0; return (val >> shift) | sign; } static sim_cia execute_i (SIM_CPU *cpu, unsigned_word iw, const struct riscv_opcode *op) { SIM_DESC sd = CPU_STATE (cpu); int rd = (iw >> OP_SH_RD) & OP_MASK_RD; int rs1 = (iw >> OP_SH_RS1) & OP_MASK_RS1; int rs2 = (iw >> OP_SH_RS2) & OP_MASK_RS2; const char *rd_name = riscv_gpr_names_abi[rd]; const char *rs1_name = riscv_gpr_names_abi[rs1]; const char *rs2_name = riscv_gpr_names_abi[rs2]; unsigned int csr = (iw >> OP_SH_CSR) & OP_MASK_CSR; unsigned_word i_imm = EXTRACT_ITYPE_IMM (iw); unsigned_word u_imm = EXTRACT_UTYPE_IMM ((uint64_t) iw); unsigned_word s_imm = EXTRACT_STYPE_IMM (iw); unsigned_word sb_imm = EXTRACT_BTYPE_IMM (iw); unsigned_word shamt_imm = ((iw >> OP_SH_SHAMT) & OP_MASK_SHAMT); unsigned_word tmp; sim_cia pc = cpu->pc + 4; TRACE_EXTRACT (cpu, "rd:%-2i:%-4s " "rs1:%-2i:%-4s %0*" PRIxTW " " "rs2:%-2i:%-4s %0*" PRIxTW " " "match:%#x mask:%#x", rd, rd_name, rs1, rs1_name, (int) sizeof (unsigned_word) * 2, cpu->regs[rs1], rs2, rs2_name, (int) sizeof (unsigned_word) * 2, cpu->regs[rs2], (unsigned) op->match, (unsigned) op->mask); switch (op->match) { case MATCH_ADD: TRACE_INSN (cpu, "add %s, %s, %s; // %s = %s + %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); store_rd (cpu, rd, cpu->regs[rs1] + cpu->regs[rs2]); break; case MATCH_ADDW: TRACE_INSN (cpu, "addw %s, %s, %s; // %s = %s + %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); store_rd (cpu, rd, EXTEND32 (cpu->regs[rs1] + cpu->regs[rs2])); break; case MATCH_ADDI: TRACE_INSN (cpu, "addi %s, %s, %#" PRIxTW "; // %s = %s + %#" PRIxTW, rd_name, rs1_name, i_imm, rd_name, rs1_name, i_imm); store_rd (cpu, rd, cpu->regs[rs1] + i_imm); break; case MATCH_ADDIW: TRACE_INSN (cpu, "addiw %s, %s, %#" PRIxTW "; // %s = %s + %#" PRIxTW, rd_name, rs1_name, i_imm, rd_name, rs1_name, i_imm); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); store_rd (cpu, rd, EXTEND32 (cpu->regs[rs1] + i_imm)); break; case MATCH_AND: TRACE_INSN (cpu, "and %s, %s, %s; // %s = %s & %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); store_rd (cpu, rd, cpu->regs[rs1] & cpu->regs[rs2]); break; case MATCH_ANDI: TRACE_INSN (cpu, "andi %s, %s, %" PRIiTW "; // %s = %s & %#" PRIxTW, rd_name, rs1_name, i_imm, rd_name, rs1_name, i_imm); store_rd (cpu, rd, cpu->regs[rs1] & i_imm); break; case MATCH_OR: TRACE_INSN (cpu, "or %s, %s, %s; // %s = %s | %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); store_rd (cpu, rd, cpu->regs[rs1] | cpu->regs[rs2]); break; case MATCH_ORI: TRACE_INSN (cpu, "ori %s, %s, %" PRIiTW "; // %s = %s | %#" PRIxTW, rd_name, rs1_name, i_imm, rd_name, rs1_name, i_imm); store_rd (cpu, rd, cpu->regs[rs1] | i_imm); break; case MATCH_XOR: TRACE_INSN (cpu, "xor %s, %s, %s; // %s = %s ^ %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); store_rd (cpu, rd, cpu->regs[rs1] ^ cpu->regs[rs2]); break; case MATCH_XORI: TRACE_INSN (cpu, "xori %s, %s, %" PRIiTW "; // %s = %s ^ %#" PRIxTW, rd_name, rs1_name, i_imm, rd_name, rs1_name, i_imm); store_rd (cpu, rd, cpu->regs[rs1] ^ i_imm); break; case MATCH_SUB: TRACE_INSN (cpu, "sub %s, %s, %s; // %s = %s - %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); store_rd (cpu, rd, cpu->regs[rs1] - cpu->regs[rs2]); break; case MATCH_SUBW: TRACE_INSN (cpu, "subw %s, %s, %s; // %s = %s - %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); store_rd (cpu, rd, EXTEND32 (cpu->regs[rs1] - cpu->regs[rs2])); break; case MATCH_LUI: TRACE_INSN (cpu, "lui %s, %#" PRIxTW ";", rd_name, u_imm); store_rd (cpu, rd, u_imm); break; case MATCH_SLL: TRACE_INSN (cpu, "sll %s, %s, %s; // %s = %s << %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); u_imm = RISCV_XLEN (cpu) == 32 ? 0x1f : 0x3f; store_rd (cpu, rd, cpu->regs[rs1] << (cpu->regs[rs2] & u_imm)); break; case MATCH_SLLW: TRACE_INSN (cpu, "sllw %s, %s, %s; // %s = %s << %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); store_rd (cpu, rd, EXTEND32 ( (uint32_t) cpu->regs[rs1] << (cpu->regs[rs2] & 0x1f))); break; case MATCH_SLLI: TRACE_INSN (cpu, "slli %s, %s, %" PRIiTW "; // %s = %s << %#" PRIxTW, rd_name, rs1_name, shamt_imm, rd_name, rs1_name, shamt_imm); if (RISCV_XLEN (cpu) == 32 && shamt_imm > 0x1f) sim_engine_halt (sd, cpu, NULL, cpu->pc, sim_signalled, SIM_SIGILL); store_rd (cpu, rd, cpu->regs[rs1] << shamt_imm); break; case MATCH_SLLIW: TRACE_INSN (cpu, "slliw %s, %s, %" PRIiTW "; // %s = %s << %#" PRIxTW, rd_name, rs1_name, shamt_imm, rd_name, rs1_name, shamt_imm); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); store_rd (cpu, rd, EXTEND32 ((uint32_t) cpu->regs[rs1] << shamt_imm)); break; case MATCH_SRL: TRACE_INSN (cpu, "srl %s, %s, %s; // %s = %s >> %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); u_imm = RISCV_XLEN (cpu) == 32 ? 0x1f : 0x3f; store_rd (cpu, rd, cpu->regs[rs1] >> (cpu->regs[rs2] & u_imm)); break; case MATCH_SRLW: TRACE_INSN (cpu, "srlw %s, %s, %s; // %s = %s >> %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); store_rd (cpu, rd, EXTEND32 ( (uint32_t) cpu->regs[rs1] >> (cpu->regs[rs2] & 0x1f))); break; case MATCH_SRLI: TRACE_INSN (cpu, "srli %s, %s, %" PRIiTW "; // %s = %s >> %#" PRIxTW, rd_name, rs1_name, shamt_imm, rd_name, rs1_name, shamt_imm); if (RISCV_XLEN (cpu) == 32 && shamt_imm > 0x1f) sim_engine_halt (sd, cpu, NULL, cpu->pc, sim_signalled, SIM_SIGILL); store_rd (cpu, rd, cpu->regs[rs1] >> shamt_imm); break; case MATCH_SRLIW: TRACE_INSN (cpu, "srliw %s, %s, %" PRIiTW "; // %s = %s >> %#" PRIxTW, rd_name, rs1_name, shamt_imm, rd_name, rs1_name, shamt_imm); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); store_rd (cpu, rd, EXTEND32 ((uint32_t) cpu->regs[rs1] >> shamt_imm)); break; case MATCH_SRA: TRACE_INSN (cpu, "sra %s, %s, %s; // %s = %s >>> %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); if (RISCV_XLEN (cpu) == 32) tmp = ashiftrt (cpu->regs[rs1], cpu->regs[rs2] & 0x1f); else tmp = ashiftrt64 (cpu->regs[rs1], cpu->regs[rs2] & 0x3f); store_rd (cpu, rd, tmp); break; case MATCH_SRAW: TRACE_INSN (cpu, "sraw %s, %s, %s; // %s = %s >>> %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); store_rd (cpu, rd, EXTEND32 ( ashiftrt ((int32_t) cpu->regs[rs1], cpu->regs[rs2] & 0x1f))); break; case MATCH_SRAI: TRACE_INSN (cpu, "srai %s, %s, %" PRIiTW "; // %s = %s >>> %#" PRIxTW, rd_name, rs1_name, shamt_imm, rd_name, rs1_name, shamt_imm); if (RISCV_XLEN (cpu) == 32) { if (shamt_imm > 0x1f) sim_engine_halt (sd, cpu, NULL, cpu->pc, sim_signalled, SIM_SIGILL); tmp = ashiftrt (cpu->regs[rs1], shamt_imm); } else tmp = ashiftrt64 (cpu->regs[rs1], shamt_imm); store_rd (cpu, rd, tmp); break; case MATCH_SRAIW: TRACE_INSN (cpu, "sraiw %s, %s, %" PRIiTW "; // %s = %s >>> %#" PRIxTW, rd_name, rs1_name, shamt_imm, rd_name, rs1_name, shamt_imm); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); store_rd (cpu, rd, EXTEND32 ( ashiftrt ((int32_t) cpu->regs[rs1], shamt_imm))); break; case MATCH_SLT: TRACE_INSN (cpu, "slt"); store_rd (cpu, rd, !!((signed_word) cpu->regs[rs1] < (signed_word) cpu->regs[rs2])); break; case MATCH_SLTU: TRACE_INSN (cpu, "sltu"); store_rd (cpu, rd, !!((unsigned_word) cpu->regs[rs1] < (unsigned_word) cpu->regs[rs2])); break; case MATCH_SLTI: TRACE_INSN (cpu, "slti"); store_rd (cpu, rd, !!((signed_word) cpu->regs[rs1] < (signed_word) i_imm)); break; case MATCH_SLTIU: TRACE_INSN (cpu, "sltiu"); store_rd (cpu, rd, !!((unsigned_word) cpu->regs[rs1] < (unsigned_word) i_imm)); break; case MATCH_AUIPC: TRACE_INSN (cpu, "auipc %s, %" PRIiTW "; // %s = pc + %" PRIiTW, rd_name, u_imm, rd_name, u_imm); store_rd (cpu, rd, cpu->pc + u_imm); break; case MATCH_BEQ: TRACE_INSN (cpu, "beq %s, %s, %#" PRIxTW "; " "// if (%s == %s) goto %#" PRIxTW, rs1_name, rs2_name, sb_imm, rs1_name, rs2_name, sb_imm); if (cpu->regs[rs1] == cpu->regs[rs2]) { pc = cpu->pc + sb_imm; TRACE_BRANCH (cpu, "to %#" PRIxTW, pc); } break; case MATCH_BLT: TRACE_INSN (cpu, "blt %s, %s, %#" PRIxTW "; " "// if (%s < %s) goto %#" PRIxTW, rs1_name, rs2_name, sb_imm, rs1_name, rs2_name, sb_imm); if ((signed_word) cpu->regs[rs1] < (signed_word) cpu->regs[rs2]) { pc = cpu->pc + sb_imm; TRACE_BRANCH (cpu, "to %#" PRIxTW, pc); } break; case MATCH_BLTU: TRACE_INSN (cpu, "bltu %s, %s, %#" PRIxTW "; " "// if (%s < %s) goto %#" PRIxTW, rs1_name, rs2_name, sb_imm, rs1_name, rs2_name, sb_imm); if ((unsigned_word) cpu->regs[rs1] < (unsigned_word) cpu->regs[rs2]) { pc = cpu->pc + sb_imm; TRACE_BRANCH (cpu, "to %#" PRIxTW, pc); } break; case MATCH_BGE: TRACE_INSN (cpu, "bge %s, %s, %#" PRIxTW "; " "// if (%s >= %s) goto %#" PRIxTW, rs1_name, rs2_name, sb_imm, rs1_name, rs2_name, sb_imm); if ((signed_word) cpu->regs[rs1] >= (signed_word) cpu->regs[rs2]) { pc = cpu->pc + sb_imm; TRACE_BRANCH (cpu, "to %#" PRIxTW, pc); } break; case MATCH_BGEU: TRACE_INSN (cpu, "bgeu %s, %s, %#" PRIxTW "; " "// if (%s >= %s) goto %#" PRIxTW, rs1_name, rs2_name, sb_imm, rs1_name, rs2_name, sb_imm); if ((unsigned_word) cpu->regs[rs1] >= (unsigned_word) cpu->regs[rs2]) { pc = cpu->pc + sb_imm; TRACE_BRANCH (cpu, "to %#" PRIxTW, pc); } break; case MATCH_BNE: TRACE_INSN (cpu, "bne %s, %s, %#" PRIxTW "; " "// if (%s != %s) goto %#" PRIxTW, rs1_name, rs2_name, sb_imm, rs1_name, rs2_name, sb_imm); if (cpu->regs[rs1] != cpu->regs[rs2]) { pc = cpu->pc + sb_imm; TRACE_BRANCH (cpu, "to %#" PRIxTW, pc); } break; case MATCH_JAL: TRACE_INSN (cpu, "jal %s, %" PRIiTW ";", rd_name, EXTRACT_JTYPE_IMM (iw)); store_rd (cpu, rd, cpu->pc + 4); pc = cpu->pc + EXTRACT_JTYPE_IMM (iw); TRACE_BRANCH (cpu, "to %#" PRIxTW, pc); break; case MATCH_JALR: TRACE_INSN (cpu, "jalr %s, %s, %" PRIiTW ";", rd_name, rs1_name, i_imm); store_rd (cpu, rd, cpu->pc + 4); pc = cpu->regs[rs1] + i_imm; TRACE_BRANCH (cpu, "to %#" PRIxTW, pc); break; case MATCH_LD: TRACE_INSN (cpu, "ld %s, %" PRIiTW "(%s);", rd_name, i_imm, rs1_name); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); store_rd (cpu, rd, sim_core_read_unaligned_8 (cpu, cpu->pc, read_map, cpu->regs[rs1] + i_imm)); break; case MATCH_LW: TRACE_INSN (cpu, "lw %s, %" PRIiTW "(%s);", rd_name, i_imm, rs1_name); store_rd (cpu, rd, EXTEND32 ( sim_core_read_unaligned_4 (cpu, cpu->pc, read_map, cpu->regs[rs1] + i_imm))); break; case MATCH_LWU: TRACE_INSN (cpu, "lwu %s, %" PRIiTW "(%s);", rd_name, i_imm, rs1_name); store_rd (cpu, rd, sim_core_read_unaligned_4 (cpu, cpu->pc, read_map, cpu->regs[rs1] + i_imm)); break; case MATCH_LH: TRACE_INSN (cpu, "lh %s, %" PRIiTW "(%s);", rd_name, i_imm, rs1_name); store_rd (cpu, rd, EXTEND16 ( sim_core_read_unaligned_2 (cpu, cpu->pc, read_map, cpu->regs[rs1] + i_imm))); break; case MATCH_LHU: TRACE_INSN (cpu, "lbu %s, %" PRIiTW "(%s);", rd_name, i_imm, rs1_name); store_rd (cpu, rd, sim_core_read_unaligned_2 (cpu, cpu->pc, read_map, cpu->regs[rs1] + i_imm)); break; case MATCH_LB: TRACE_INSN (cpu, "lb %s, %" PRIiTW "(%s);", rd_name, i_imm, rs1_name); store_rd (cpu, rd, EXTEND8 ( sim_core_read_unaligned_1 (cpu, cpu->pc, read_map, cpu->regs[rs1] + i_imm))); break; case MATCH_LBU: TRACE_INSN (cpu, "lbu %s, %" PRIiTW "(%s);", rd_name, i_imm, rs1_name); store_rd (cpu, rd, sim_core_read_unaligned_1 (cpu, cpu->pc, read_map, cpu->regs[rs1] + i_imm)); break; case MATCH_SD: TRACE_INSN (cpu, "sd %s, %" PRIiTW "(%s);", rs2_name, s_imm, rs1_name); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); sim_core_write_unaligned_8 (cpu, cpu->pc, write_map, cpu->regs[rs1] + s_imm, cpu->regs[rs2]); break; case MATCH_SW: TRACE_INSN (cpu, "sw %s, %" PRIiTW "(%s);", rs2_name, s_imm, rs1_name); sim_core_write_unaligned_4 (cpu, cpu->pc, write_map, cpu->regs[rs1] + s_imm, cpu->regs[rs2]); break; case MATCH_SH: TRACE_INSN (cpu, "sh %s, %" PRIiTW "(%s);", rs2_name, s_imm, rs1_name); sim_core_write_unaligned_2 (cpu, cpu->pc, write_map, cpu->regs[rs1] + s_imm, cpu->regs[rs2]); break; case MATCH_SB: TRACE_INSN (cpu, "sb %s, %" PRIiTW "(%s);", rs2_name, s_imm, rs1_name); sim_core_write_unaligned_1 (cpu, cpu->pc, write_map, cpu->regs[rs1] + s_imm, cpu->regs[rs2]); break; case MATCH_CSRRC: TRACE_INSN (cpu, "csrrc"); switch (csr) { #define DECLARE_CSR(name, num, ...) \ case num: \ store_rd (cpu, rd, fetch_csr (cpu, #name, num, &cpu->csr.name)); \ store_csr (cpu, #name, num, &cpu->csr.name, \ cpu->csr.name & !cpu->regs[rs1]); \ break; #include "opcode/riscv-opc.h" #undef DECLARE_CSR } break; case MATCH_CSRRS: TRACE_INSN (cpu, "csrrs"); switch (csr) { #define DECLARE_CSR(name, num, ...) \ case num: \ store_rd (cpu, rd, fetch_csr (cpu, #name, num, &cpu->csr.name)); \ store_csr (cpu, #name, num, &cpu->csr.name, \ cpu->csr.name | cpu->regs[rs1]); \ break; #include "opcode/riscv-opc.h" #undef DECLARE_CSR } break; case MATCH_CSRRW: TRACE_INSN (cpu, "csrrw"); switch (csr) { #define DECLARE_CSR(name, num, ...) \ case num: \ store_rd (cpu, rd, fetch_csr (cpu, #name, num, &cpu->csr.name)); \ store_csr (cpu, #name, num, &cpu->csr.name, cpu->regs[rs1]); \ break; #include "opcode/riscv-opc.h" #undef DECLARE_CSR } break; case MATCH_RDCYCLE: TRACE_INSN (cpu, "rdcycle %s;", rd_name); store_rd (cpu, rd, fetch_csr (cpu, "cycle", CSR_CYCLE, &cpu->csr.cycle)); break; case MATCH_RDCYCLEH: TRACE_INSN (cpu, "rdcycleh %s;", rd_name); RISCV_ASSERT_RV32 (cpu, "insn: %s", op->name); store_rd (cpu, rd, fetch_csr (cpu, "cycleh", CSR_CYCLEH, &cpu->csr.cycleh)); break; case MATCH_RDINSTRET: TRACE_INSN (cpu, "rdinstret %s;", rd_name); store_rd (cpu, rd, fetch_csr (cpu, "instret", CSR_INSTRET, &cpu->csr.instret)); break; case MATCH_RDINSTRETH: TRACE_INSN (cpu, "rdinstreth %s;", rd_name); RISCV_ASSERT_RV32 (cpu, "insn: %s", op->name); store_rd (cpu, rd, fetch_csr (cpu, "instreth", CSR_INSTRETH, &cpu->csr.instreth)); break; case MATCH_RDTIME: TRACE_INSN (cpu, "rdtime %s;", rd_name); store_rd (cpu, rd, fetch_csr (cpu, "time", CSR_TIME, &cpu->csr.time)); break; case MATCH_RDTIMEH: TRACE_INSN (cpu, "rdtimeh %s;", rd_name); RISCV_ASSERT_RV32 (cpu, "insn: %s", op->name); store_rd (cpu, rd, fetch_csr (cpu, "timeh", CSR_TIMEH, &cpu->csr.timeh)); break; case MATCH_FENCE: TRACE_INSN (cpu, "fence;"); break; case MATCH_FENCE_I: TRACE_INSN (cpu, "fence.i;"); break; case MATCH_EBREAK: TRACE_INSN (cpu, "ebreak;"); /* GDB expects us to step over EBREAK. */ sim_engine_halt (sd, cpu, NULL, cpu->pc + 4, sim_stopped, SIM_SIGTRAP); break; case MATCH_ECALL: TRACE_INSN (cpu, "ecall;"); cpu->a0 = sim_syscall (cpu, cpu->a7, cpu->a0, cpu->a1, cpu->a2, cpu->a3); break; default: TRACE_INSN (cpu, "UNHANDLED INSN: %s", op->name); sim_engine_halt (sd, cpu, NULL, cpu->pc, sim_signalled, SIM_SIGILL); } return pc; } static uint64_t mulhu (uint64_t a, uint64_t b) { #ifdef HAVE___INT128 return ((__int128)a * b) >> 64; #else uint64_t t; uint32_t y1, y2, y3; uint64_t a0 = (uint32_t)a, a1 = a >> 32; uint64_t b0 = (uint32_t)b, b1 = b >> 32; t = a1*b0 + ((a0*b0) >> 32); y1 = t; y2 = t >> 32; t = a0*b1 + y1; y1 = t; t = a1*b1 + y2 + (t >> 32); y2 = t; y3 = t >> 32; return ((uint64_t)y3 << 32) | y2; #endif } static uint64_t mulh (int64_t a, int64_t b) { int negate = (a < 0) != (b < 0); uint64_t res = mulhu (a < 0 ? -a : a, b < 0 ? -b : b); return negate ? ~res + (a * b == 0) : res; } static uint64_t mulhsu (int64_t a, uint64_t b) { int negate = a < 0; uint64_t res = mulhu (a < 0 ? -a : a, b); return negate ? ~res + (a * b == 0) : res; } static sim_cia execute_m (SIM_CPU *cpu, unsigned_word iw, const struct riscv_opcode *op) { SIM_DESC sd = CPU_STATE (cpu); int rd = (iw >> OP_SH_RD) & OP_MASK_RD; int rs1 = (iw >> OP_SH_RS1) & OP_MASK_RS1; int rs2 = (iw >> OP_SH_RS2) & OP_MASK_RS2; const char *rd_name = riscv_gpr_names_abi[rd]; const char *rs1_name = riscv_gpr_names_abi[rs1]; const char *rs2_name = riscv_gpr_names_abi[rs2]; unsigned_word tmp, dividend_max; sim_cia pc = cpu->pc + 4; dividend_max = -((unsigned_word) 1 << (WITH_TARGET_WORD_BITSIZE - 1)); switch (op->match) { case MATCH_DIV: TRACE_INSN (cpu, "div %s, %s, %s; // %s = %s / %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); if (cpu->regs[rs1] == dividend_max && cpu->regs[rs2] == -1) tmp = dividend_max; else if (cpu->regs[rs2]) tmp = (signed_word) cpu->regs[rs1] / (signed_word) cpu->regs[rs2]; else tmp = -1; store_rd (cpu, rd, tmp); break; case MATCH_DIVW: TRACE_INSN (cpu, "divw %s, %s, %s; // %s = %s / %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); if (EXTEND32 (cpu->regs[rs2]) == -1) tmp = 1 << 31; else if (EXTEND32 (cpu->regs[rs2])) tmp = EXTEND32 (cpu->regs[rs1]) / EXTEND32 (cpu->regs[rs2]); else tmp = -1; store_rd (cpu, rd, EXTEND32 (tmp)); break; case MATCH_DIVU: TRACE_INSN (cpu, "divu %s, %s, %s; // %s = %s / %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); if (cpu->regs[rs2]) store_rd (cpu, rd, (unsigned_word) cpu->regs[rs1] / (unsigned_word) cpu->regs[rs2]); else store_rd (cpu, rd, -1); break; case MATCH_DIVUW: TRACE_INSN (cpu, "divuw %s, %s, %s; // %s = %s / %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); if ((uint32_t) cpu->regs[rs2]) tmp = (uint32_t) cpu->regs[rs1] / (uint32_t) cpu->regs[rs2]; else tmp = -1; store_rd (cpu, rd, EXTEND32 (tmp)); break; case MATCH_MUL: TRACE_INSN (cpu, "mul %s, %s, %s; // %s = %s * %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); store_rd (cpu, rd, cpu->regs[rs1] * cpu->regs[rs2]); break; case MATCH_MULW: TRACE_INSN (cpu, "mulw %s, %s, %s; // %s = %s * %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); store_rd (cpu, rd, EXTEND32 ((int32_t) cpu->regs[rs1] * (int32_t) cpu->regs[rs2])); break; case MATCH_MULH: TRACE_INSN (cpu, "mulh %s, %s, %s; // %s = %s * %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); if (RISCV_XLEN (cpu) == 32) store_rd (cpu, rd, ((int64_t)(signed_word) cpu->regs[rs1] * (int64_t)(signed_word) cpu->regs[rs2]) >> 32); else store_rd (cpu, rd, mulh (cpu->regs[rs1], cpu->regs[rs2])); break; case MATCH_MULHU: TRACE_INSN (cpu, "mulhu %s, %s, %s; // %s = %s * %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); if (RISCV_XLEN (cpu) == 32) store_rd (cpu, rd, ((uint64_t)cpu->regs[rs1] * (uint64_t)cpu->regs[rs2]) >> 32); else store_rd (cpu, rd, mulhu (cpu->regs[rs1], cpu->regs[rs2])); break; case MATCH_MULHSU: TRACE_INSN (cpu, "mulhsu %s, %s, %s; // %s = %s * %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); if (RISCV_XLEN (cpu) == 32) store_rd (cpu, rd, ((int64_t)(signed_word) cpu->regs[rs1] * (uint64_t)cpu->regs[rs2]) >> 32); else store_rd (cpu, rd, mulhsu (cpu->regs[rs1], cpu->regs[rs2])); break; case MATCH_REM: TRACE_INSN (cpu, "rem %s, %s, %s; // %s = %s %% %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); if (cpu->regs[rs1] == dividend_max && cpu->regs[rs2] == -1) tmp = 0; else if (cpu->regs[rs2]) tmp = (signed_word) cpu->regs[rs1] % (signed_word) cpu->regs[rs2]; else tmp = cpu->regs[rs1]; store_rd (cpu, rd, tmp); break; case MATCH_REMW: TRACE_INSN (cpu, "remw %s, %s, %s; // %s = %s %% %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); if (EXTEND32 (cpu->regs[rs2]) == -1) tmp = 0; else if (EXTEND32 (cpu->regs[rs2])) tmp = EXTEND32 (cpu->regs[rs1]) % EXTEND32 (cpu->regs[rs2]); else tmp = cpu->regs[rs1]; store_rd (cpu, rd, EXTEND32 (tmp)); break; case MATCH_REMU: TRACE_INSN (cpu, "remu %s, %s, %s; // %s = %s %% %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); if (cpu->regs[rs2]) store_rd (cpu, rd, cpu->regs[rs1] % cpu->regs[rs2]); else store_rd (cpu, rd, cpu->regs[rs1]); break; case MATCH_REMUW: TRACE_INSN (cpu, "remuw %s, %s, %s; // %s = %s %% %s", rd_name, rs1_name, rs2_name, rd_name, rs1_name, rs2_name); RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); if ((uint32_t) cpu->regs[rs2]) tmp = (uint32_t) cpu->regs[rs1] % (uint32_t) cpu->regs[rs2]; else tmp = cpu->regs[rs1]; store_rd (cpu, rd, EXTEND32 (tmp)); break; default: TRACE_INSN (cpu, "UNHANDLED INSN: %s", op->name); sim_engine_halt (sd, cpu, NULL, cpu->pc, sim_signalled, SIM_SIGILL); } return pc; } static sim_cia execute_a (SIM_CPU *cpu, unsigned_word iw, const struct riscv_opcode *op) { SIM_DESC sd = CPU_STATE (cpu); struct riscv_sim_state *state = RISCV_SIM_STATE (sd); int rd = (iw >> OP_SH_RD) & OP_MASK_RD; int rs1 = (iw >> OP_SH_RS1) & OP_MASK_RS1; int rs2 = (iw >> OP_SH_RS2) & OP_MASK_RS2; const char *rd_name = riscv_gpr_names_abi[rd]; const char *rs1_name = riscv_gpr_names_abi[rs1]; const char *rs2_name = riscv_gpr_names_abi[rs2]; struct atomic_mem_reserved_list *amo_prev, *amo_curr; unsigned_word tmp; sim_cia pc = cpu->pc + 4; /* Handle these two load/store operations specifically. */ switch (op->match) { case MATCH_LR_W: TRACE_INSN (cpu, "%s %s, (%s);", op->name, rd_name, rs1_name); store_rd (cpu, rd, sim_core_read_unaligned_4 (cpu, cpu->pc, read_map, cpu->regs[rs1])); /* Walk the reservation list to find an existing match. */ amo_curr = state->amo_reserved_list; while (amo_curr) { if (amo_curr->addr == cpu->regs[rs1]) goto done; amo_curr = amo_curr->next; } /* No reservation exists, so add one. */ amo_curr = xmalloc (sizeof (*amo_curr)); amo_curr->addr = cpu->regs[rs1]; amo_curr->next = state->amo_reserved_list; state->amo_reserved_list = amo_curr; goto done; case MATCH_SC_W: TRACE_INSN (cpu, "%s %s, %s, (%s);", op->name, rd_name, rs2_name, rs1_name); /* Walk the reservation list to find a match. */ amo_curr = amo_prev = state->amo_reserved_list; while (amo_curr) { if (amo_curr->addr == cpu->regs[rs1]) { /* We found a reservation, so operate it. */ sim_core_write_unaligned_4 (cpu, cpu->pc, write_map, cpu->regs[rs1], cpu->regs[rs2]); store_rd (cpu, rd, 0); if (amo_curr == state->amo_reserved_list) state->amo_reserved_list = amo_curr->next; else amo_prev->next = amo_curr->next; free (amo_curr); goto done; } amo_prev = amo_curr; amo_curr = amo_curr->next; } /* If we're still here, then no reservation exists, so mark as failed. */ store_rd (cpu, rd, 1); goto done; } /* Handle the rest of the atomic insns with common code paths. */ TRACE_INSN (cpu, "%s %s, %s, (%s);", op->name, rd_name, rs2_name, rs1_name); if (op->xlen_requirement == 64) tmp = sim_core_read_unaligned_8 (cpu, cpu->pc, read_map, cpu->regs[rs1]); else tmp = EXTEND32 (sim_core_read_unaligned_4 (cpu, cpu->pc, read_map, cpu->regs[rs1])); store_rd (cpu, rd, tmp); switch (op->match) { case MATCH_AMOADD_D: case MATCH_AMOADD_W: tmp = cpu->regs[rd] + cpu->regs[rs2]; break; case MATCH_AMOAND_D: case MATCH_AMOAND_W: tmp = cpu->regs[rd] & cpu->regs[rs2]; break; case MATCH_AMOMAX_D: case MATCH_AMOMAX_W: tmp = max ((signed_word) cpu->regs[rd], (signed_word) cpu->regs[rs2]); break; case MATCH_AMOMAXU_D: case MATCH_AMOMAXU_W: tmp = max ((unsigned_word) cpu->regs[rd], (unsigned_word) cpu->regs[rs2]); break; case MATCH_AMOMIN_D: case MATCH_AMOMIN_W: tmp = min ((signed_word) cpu->regs[rd], (signed_word) cpu->regs[rs2]); break; case MATCH_AMOMINU_D: case MATCH_AMOMINU_W: tmp = min ((unsigned_word) cpu->regs[rd], (unsigned_word) cpu->regs[rs2]); break; case MATCH_AMOOR_D: case MATCH_AMOOR_W: tmp = cpu->regs[rd] | cpu->regs[rs2]; break; case MATCH_AMOSWAP_D: case MATCH_AMOSWAP_W: tmp = cpu->regs[rs2]; break; case MATCH_AMOXOR_D: case MATCH_AMOXOR_W: tmp = cpu->regs[rd] ^ cpu->regs[rs2]; break; default: TRACE_INSN (cpu, "UNHANDLED INSN: %s", op->name); sim_engine_halt (sd, cpu, NULL, cpu->pc, sim_signalled, SIM_SIGILL); } if (op->xlen_requirement == 64) sim_core_write_unaligned_8 (cpu, cpu->pc, write_map, cpu->regs[rs1], tmp); else sim_core_write_unaligned_4 (cpu, cpu->pc, write_map, cpu->regs[rs1], tmp); done: return pc; } static sim_cia execute_one (SIM_CPU *cpu, unsigned_word iw, const struct riscv_opcode *op) { SIM_DESC sd = CPU_STATE (cpu); if (op->xlen_requirement == 32) RISCV_ASSERT_RV32 (cpu, "insn: %s", op->name); else if (op->xlen_requirement == 64) RISCV_ASSERT_RV64 (cpu, "insn: %s", op->name); switch (op->insn_class) { case INSN_CLASS_A: return execute_a (cpu, iw, op); case INSN_CLASS_I: return execute_i (cpu, iw, op); case INSN_CLASS_M: return execute_m (cpu, iw, op); default: TRACE_INSN (cpu, "UNHANDLED EXTENSION: %d", op->insn_class); sim_engine_halt (sd, cpu, NULL, cpu->pc, sim_signalled, SIM_SIGILL); } return cpu->pc + riscv_insn_length (iw); } /* Decode & execute a single instruction. */ void step_once (SIM_CPU *cpu) { SIM_DESC sd = CPU_STATE (cpu); unsigned_word iw; unsigned int len; sim_cia pc = cpu->pc; const struct riscv_opcode *op; int xlen = RISCV_XLEN (cpu); if (TRACE_ANY_P (cpu)) trace_prefix (sd, cpu, NULL_CIA, pc, TRACE_LINENUM_P (cpu), NULL, 0, " "); /* Use a space for gcc warnings. */ iw = sim_core_read_aligned_2 (cpu, pc, exec_map, pc); /* Reject non-32-bit opcodes first. */ len = riscv_insn_length (iw); if (len != 4) { sim_io_printf (sd, "sim: bad insn len %#x @ %#" PRIxTA ": %#" PRIxTW "\n", len, pc, iw); sim_engine_halt (sd, cpu, NULL, pc, sim_signalled, SIM_SIGILL); } iw |= ((unsigned_word) sim_core_read_aligned_2 ( cpu, pc, exec_map, pc + 2) << 16); TRACE_CORE (cpu, "0x%08" PRIxTW, iw); op = riscv_hash[OP_HASH_IDX (iw)]; if (!op) sim_engine_halt (sd, cpu, NULL, pc, sim_signalled, SIM_SIGILL); /* NB: Same loop logic as riscv_disassemble_insn. */ for (; op->name; op++) { /* Does the opcode match? */ if (! op->match_func (op, iw)) continue; /* Is this a pseudo-instruction and may we print it as such? */ if (op->pinfo & INSN_ALIAS) continue; /* Is this instruction restricted to a certain value of XLEN? */ if (op->xlen_requirement != 0 && op->xlen_requirement != xlen) continue; /* It's a match. */ pc = execute_one (cpu, iw, op); break; } /* TODO: Handle overflow into high 32 bits. */ /* TODO: Try to use a common counter and only update on demand (reads). */ ++cpu->csr.cycle; ++cpu->csr.instret; cpu->pc = pc; } /* Return the program counter for this cpu. */ static sim_cia pc_get (sim_cpu *cpu) { return cpu->pc; } /* Set the program counter for this cpu to the new pc value. */ static void pc_set (sim_cpu *cpu, sim_cia pc) { cpu->pc = pc; } static int reg_fetch (sim_cpu *cpu, int rn, unsigned char *buf, int len) { if (len <= 0 || len > sizeof (unsigned_word)) return -1; switch (rn) { case SIM_RISCV_ZERO_REGNUM: memset (buf, 0, len); return len; case SIM_RISCV_RA_REGNUM ... SIM_RISCV_T6_REGNUM: memcpy (buf, &cpu->regs[rn], len); return len; case SIM_RISCV_FIRST_FP_REGNUM ... SIM_RISCV_LAST_FP_REGNUM: memcpy (buf, &cpu->fpregs[rn - SIM_RISCV_FIRST_FP_REGNUM], len); return len; case SIM_RISCV_PC_REGNUM: memcpy (buf, &cpu->pc, len); return len; #define DECLARE_CSR(name, num, ...) \ case SIM_RISCV_ ## num ## _REGNUM: \ memcpy (buf, &cpu->csr.name, len); \ return len; #include "opcode/riscv-opc.h" #undef DECLARE_CSR default: return -1; } } static int reg_store (sim_cpu *cpu, int rn, unsigned char *buf, int len) { if (len <= 0 || len > sizeof (unsigned_word)) return -1; switch (rn) { case SIM_RISCV_ZERO_REGNUM: /* Ignore writes. */ return len; case SIM_RISCV_RA_REGNUM ... SIM_RISCV_T6_REGNUM: memcpy (&cpu->regs[rn], buf, len); return len; case SIM_RISCV_FIRST_FP_REGNUM ... SIM_RISCV_LAST_FP_REGNUM: memcpy (&cpu->fpregs[rn - SIM_RISCV_FIRST_FP_REGNUM], buf, len); return len; case SIM_RISCV_PC_REGNUM: memcpy (&cpu->pc, buf, len); return len; #define DECLARE_CSR(name, num, ...) \ case SIM_RISCV_ ## num ## _REGNUM: \ memcpy (&cpu->csr.name, buf, len); \ return len; #include "opcode/riscv-opc.h" #undef DECLARE_CSR default: return -1; } } /* Initialize the state for a single cpu. Usuaully this involves clearing all registers back to their reset state. Should also hook up the fetch/store helper functions too. */ void initialize_cpu (SIM_DESC sd, SIM_CPU *cpu, int mhartid) { const char *extensions; int i; memset (cpu->regs, 0, sizeof (cpu->regs)); CPU_PC_FETCH (cpu) = pc_get; CPU_PC_STORE (cpu) = pc_set; CPU_REG_FETCH (cpu) = reg_fetch; CPU_REG_STORE (cpu) = reg_store; if (!riscv_hash[0]) { const struct riscv_opcode *op; for (op = riscv_opcodes; op->name; op++) if (!riscv_hash[OP_HASH_IDX (op->match)]) riscv_hash[OP_HASH_IDX (op->match)] = op; } cpu->csr.misa = 0; /* RV32 sets this field to 0, and we don't really support RV128 yet. */ if (RISCV_XLEN (cpu) == 64) cpu->csr.misa |= (uint64_t)2 << 62; /* Skip the leading "rv" prefix and the two numbers. */ extensions = MODEL_NAME (CPU_MODEL (cpu)) + 4; for (i = 0; i < 26; ++i) { char ext = 'A' + i; if (ext == 'X') continue; else if (strchr (extensions, ext) != NULL) { if (ext == 'G') cpu->csr.misa |= 0x1129; /* G = IMAFD. */ else cpu->csr.misa |= (1 << i); } } cpu->csr.mimpid = 0x8000; cpu->csr.mhartid = mhartid; } /* Some utils don't like having a NULL environ. */ static const char * const simple_env[] = { "HOME=/", "PATH=/bin", NULL }; /* Count the number of arguments in an argv. */ static int count_argv (const char * const *argv) { int i; if (!argv) return -1; for (i = 0; argv[i] != NULL; ++i) continue; return i; } void initialize_env (SIM_DESC sd, const char * const *argv, const char * const *env) { SIM_CPU *cpu = STATE_CPU (sd, 0); int i; int argc, argv_flat; int envc, env_flat; address_word sp, sp_flat; unsigned char null[8] = { 0, 0, 0, 0, 0, 0, 0, 0, }; /* Figure out how many bytes the argv strings take up. */ argc = count_argv (argv); if (argc == -1) argc = 0; argv_flat = argc; /* NUL bytes. */ for (i = 0; i < argc; ++i) argv_flat += strlen (argv[i]); /* Figure out how many bytes the environ strings take up. */ if (!env) env = simple_env; envc = count_argv (env); env_flat = envc; /* NUL bytes. */ for (i = 0; i < envc; ++i) env_flat += strlen (env[i]); /* Make space for the strings themselves. */ sp_flat = (DEFAULT_MEM_SIZE - argv_flat - env_flat) & -sizeof (address_word); /* Then the pointers to the strings. */ sp = sp_flat - ((argc + 1 + envc + 1) * sizeof (address_word)); /* Then the argc. */ sp -= sizeof (unsigned_word); /* Set up the regs the libgloss crt0 expects. */ cpu->a0 = argc; cpu->sp = sp; /* First push the argc value. */ sim_write (sd, sp, (void *)&argc, sizeof (unsigned_word)); sp += sizeof (unsigned_word); /* Then the actual argv strings so we know where to point argv[]. */ for (i = 0; i < argc; ++i) { unsigned len = strlen (argv[i]) + 1; sim_write (sd, sp_flat, (void *)argv[i], len); sim_write (sd, sp, (void *)&sp_flat, sizeof (address_word)); sp_flat += len; sp += sizeof (address_word); } sim_write (sd, sp, null, sizeof (address_word)); sp += sizeof (address_word); /* Then the actual env strings so we know where to point env[]. */ for (i = 0; i < envc; ++i) { unsigned len = strlen (env[i]) + 1; sim_write (sd, sp_flat, (void *)env[i], len); sim_write (sd, sp, (void *)&sp_flat, sizeof (address_word)); sp_flat += len; sp += sizeof (address_word); } }