c_soft/cpu/riscv.c

#include "riscv.h"
#include "debug.h"
#include "print.h"
#include "stdio.h"
#include "stdlib.h"
#include "errno.h"
#include "string.h"

#include "../main.h"

#define device_write(riscv,addr,value) \
  for (int i = 0;i < riscv->device_num;i++) {\
    if (riscv->device_list[i] && riscv->device_list[i]->write) {\
      if(addr>=riscv->device_list[i]->addr && addr<riscv->device_list[i]->addr+riscv->device_list[i]->size) {\
        riscv->device_list[i]->write(addr, value);\
        return;\
      }\
    }\
  }

  #define device_read(riscv,addr,ret) \
  for (int i = 0;i < riscv->device_num;i++) {\
    if (riscv->device_list[i] && riscv->device_list[i]->read) {\
      if(addr>=riscv->device_list[i]->addr && addr<riscv->device_list[i]->addr+riscv->device_list[i]->size) {\
        ret=riscv->device_list[i]->read(addr);\
        return ret;\
      }\
    }\
  }

  int riscv_print(riscv_t* riscv) {
    printf("x0(zero):  %08x\n", riscv->zero);
    printf("x1(ra):    %08x\n", riscv->ra);
    printf("x2(sp):    %08x\n", riscv->sp);
    printf("x3(gp):    %08x\n", riscv->gp);
    printf("x4(tp):    %08x\n", riscv->tp);
    printf("x5(t0):    %08x\n", riscv->t0);
    printf("x6(t1):    %08x\n", riscv->t1);
    printf("x7(t2):    %08x\n", riscv->t2);
    printf("x8(s0|fp): %08x\n", riscv->fp);
    printf("x9(s1):    %08x\n", riscv->s1);
    printf("x10(a0):   %08x\n", riscv->a0);
    printf("x11(a1):   %08x\n", riscv->a1);
    printf("x12(a2):   %08x\n", riscv->a2);
    printf("x13(a3):   %08x\n", riscv->a3);
    printf("x14(a4):   %08x\n", riscv->a4);
    printf("x15(a5):   %08x\n", riscv->a5);
    printf("x16(a6):   %08x\n", riscv->a6);
    printf("x17(a7):   %08x\n", riscv->a7);
    printf("x18(s2):   %08x\n", riscv->s2);
    printf("x19(s3):   %08x\n", riscv->s3);
    printf("x20(s4):   %08x\n", riscv->s4);
    printf("x21(s5):   %08x\n", riscv->s5);
    printf("x22(s6):   %08x\n", riscv->s6);
    printf("x23(s7):   %08x\n", riscv->s7);
    printf("x24(s8):   %08x\n", riscv->s8);
    printf("x25(s9):   %08x\n", riscv->s9);
    printf("x26(s10):  %08x\n", riscv->s10);
    printf("x27(s11):  %08x\n", riscv->s11);
    printf("x28(t3):   %08x\n", riscv->t3);
    printf("x29(t4):   %08x\n", riscv->t4);
    printf("x30(t5):   %08x\n", riscv->t5);
    printf("x31(t6):   %08x\n", riscv->t6);
    return 0;
  }


void mem_w_write(riscv_t * riscv, uint32_t addr, uint32_t value) {
  if (addr & 0x3) {
    riscv->exc_code = 6;
    riscv->mtval = addr;
    return;
  }
  if (addr >= MEM_ADDR_BASE && addr < MEM_ADDR_BASE + MEM_SIZE) {
    mem_wr(addr) = value;
  } else {
    device_write(riscv, addr, value);
    riscv->exc_code = 7;
    riscv->mtval = addr;
  }
}


void mem_wh_write(riscv_t* riscv, uint32_t addr, uint16_t value) {
  if (addr & 0x1) {
    riscv->exc_code = 6;
    riscv->mtval = addr;
    return;
  }
  if (addr >= MEM_ADDR_BASE && addr < MEM_ADDR_BASE + MEM_SIZE) {
    mem_wrh(addr) = value;
  } else {
    device_write(riscv, addr, value);
    riscv->exc_code = 7;
    riscv->mtval = addr;
  }
}

void mem_wb_write(riscv_t* riscv, uint32_t addr, uint8_t value) {
  if (addr >= MEM_ADDR_BASE && addr < MEM_ADDR_BASE + MEM_SIZE) {
    mem_wrb(addr) = value;
  } else {
    device_write(riscv, addr, value);
    riscv->exc_code = 7;
    riscv->mtval = addr;
  }
}

uint32_t mem_w_read(riscv_t* riscv, uint32_t addr) {
  uint32_t ret = 0xaaaaaaaa;
  if (addr & 0x3) {
    riscv->exc_code = 4;
    riscv->mtval = addr;
    return ret;
  }
  if (addr >= MEM_ADDR_BASE && addr < MEM_ADDR_BASE + MEM_SIZE) {
    ret = mem_wr(addr);
  } else if (addr>=riscv->rom_addr_base && addr<riscv->rom_addr_base+riscv->rom_size){
    ret = rom_wr(addr);
  } else {
    device_read(riscv, addr, ret);
    riscv->exc_code = 5;
    riscv->mtval = addr;
  }
  return ret;
}


uint16_t mem_wh_read(riscv_t* riscv, uint32_t addr) {
  uint16_t ret = 0xaaaa;
  if (addr & 0x1) {
    riscv->exc_code = 4;
    riscv->mtval = addr;
    return ret;
  }
  if (addr >= MEM_ADDR_BASE && addr < MEM_ADDR_BASE + MEM_SIZE) {
    ret = mem_wrh(addr);
  } else if (addr>=riscv->rom_addr_base && addr<riscv->rom_addr_base+riscv->rom_size){
    ret = rom_wrh(addr);
  } else {
    device_read(riscv, addr, ret);
    riscv->exc_code = 5;
    riscv->mtval = addr;
  }
  return ret;
}

uint8_t mem_wb_read(riscv_t* riscv, uint32_t addr) {
  uint8_t ret = 0xaa;
  // printf("read addr=%08x\n", addr);
  if (addr >= MEM_ADDR_BASE && addr < MEM_ADDR_BASE + MEM_SIZE) {
    ret = mem_wrb(addr);
  } else if (addr>=riscv->rom_addr_base && addr<riscv->rom_addr_base+riscv->rom_size){
    ret = rom_wrb(addr);
  } else {
    device_read(riscv, addr, ret);
    riscv->exc_code = 5;
    riscv->mtval = addr;
  }
  return ret;
}


void ins_add(riscv_t* riscv, int rs2, int rs1, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] + riscv->reg[rs2];
}

void ins_addi(riscv_t* riscv, int rs1, int imm, int rd) {
  riscv->reg[rd] = (int)riscv->reg[rs1] + imm;
}

void ins_addiw(riscv_t* riscv, int rs1, int imm, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] + imm;
}

void ins_addw(riscv_t* riscv, int rs2, int rs1, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] + riscv->reg[rs2];
}

void ins_and(riscv_t* riscv, int rs2, int rs1, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] & riscv->reg[rs2];
}

void ins_andi(riscv_t* riscv, int rs1, int imm, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] & imm;
}

// 设置pc指针高位地址
void ins_auipc(riscv_t* riscv, int imm, int rd) {
  riscv->reg[rd] = riscv->pc + imm;
}

void ins_beq(riscv_t* riscv, int rs2, int rs1, int imm) {
  if (riscv->reg[rs1] == riscv->reg[rs2]) {
    riscv->pc += imm;
  }
}

void ins_bge(riscv_t* riscv, int rs2, int rs1, int imm) {
  if ((int)riscv->reg[rs1] >= (int)riscv->reg[rs2]) {
    riscv->pc += imm;
  }
}

void ins_bgeu(riscv_t* riscv, int rs2, int rs1, int imm) {
  if (riscv->reg[rs1] >= riscv->reg[rs2]) {
    riscv->pc += imm;
  }
}

void ins_blt(riscv_t* riscv, int rs2, int rs1, int imm) {
  if ((int)riscv->reg[rs1] < (int)riscv->reg[rs2]) {
    riscv->pc += imm;
  }
}

void ins_bltu(riscv_t* riscv, int rs2, int rs1, int imm) {
  if (riscv->reg[rs1] < riscv->reg[rs2]) {
    riscv->pc += imm;
  }
}

void ins_bne(riscv_t* riscv, int rs2, int rs1, int imm) {
  // printf("bne %d %d imm=%08x\n", rs2, rs1, imm);
  if (riscv->reg[rs1] != riscv->reg[rs2]) {
    riscv->pc += imm;
  }
}

// 读后清除
void ins_csrrc(riscv_t* riscv, int rs1, int rd, int csr) {
  uint32_t t = riscv->csrs[csr];
  riscv->csrs[csr] = riscv->csrs[csr] & ~riscv->reg[rs1];
  riscv->reg[rd] = t;
}

void ins_csrrs(riscv_t* riscv, int rs1, int rd, int csr) {
  uint32_t t = riscv->csrs[csr];
  riscv->csrs[csr] = riscv->csrs[csr] | riscv->reg[rs1];
  riscv->reg[rd] = t;
}

void ins_csrrw(riscv_t* riscv, int rs1, int rd, int csr) {
  uint32_t t = riscv->csrs[csr];
  riscv->csrs[csr] = riscv->reg[rs1];
  riscv->reg[rd] = t;
}

void ins_csrrci(riscv_t* riscv, int imm, int rd, int csr) {
  uint32_t t = riscv->csrs[csr];
  riscv->csrs[csr] = riscv->csrs[csr] & ~imm;
  riscv->reg[rd] = t;
}

void ins_csrrsi(riscv_t* riscv, int imm, int rd, int csr) {
  uint32_t t = riscv->csrs[csr];
  riscv->csrs[csr] = riscv->csrs[csr] | imm;
  riscv->reg[rd] = t;
}

void ins_csrrwi(riscv_t* riscv, int imm, int rd, int csr) {
  uint32_t t = riscv->csrs[csr];
  riscv->csrs[csr] = imm;
  riscv->reg[rd] = t;
}

void ins_ecall(riscv_t* riscv) {
  printf("ecall\n");
}

void ins_ebreak(riscv_t* riscv) {
  printf("ebreak\n");
}

void ins_jal(riscv_t* riscv, int imm, int rd) {
  riscv->reg[rd] = riscv->pc + 4;
  riscv->pc += imm;
}

void ins_jalr(riscv_t* riscv, int rs1, int imm, int rd) {
  uint32_t t;
  t = riscv->pc + 4;
  riscv->pc = (riscv->reg[rs1] + imm) & (~1);
  riscv->reg[rd] = t;
}

void ins_lb(riscv_t* riscv, int rs1, int imm, int rd) {
  uint32_t addr = riscv->reg[rs1] + imm;
  // printf("lb %08x,imm=%d\n",addr,imm);
  uint32_t r=mem_wb_read(riscv, addr);
  if(r&(0x80)){
    r|=0xffffff00;
  }
  riscv->reg[rd] = r;
}

void ins_lbu(riscv_t* riscv, int rs1, int imm, int rd) {
  uint32_t addr = riscv->reg[rs1] + imm;
  // printf("lbu %08x,imm=%d\n",addr,imm);
  riscv->reg[rd] = mem_wb_read(riscv, addr);
}

void ins_lh(riscv_t* riscv, int rs1, int imm, int rd) {
  uint32_t addr = riscv->reg[rs1] + imm;
  // printf("lh %08x,imm=%d\n",addr,imm);
  uint32_t r=mem_wh_read(riscv, addr);
  if(r&(0x8000)){
    r|=0xffff0000;
  }
  riscv->reg[rd] = r;
}

void ins_lhu(riscv_t* riscv, int rs1, int imm, int rd) {
  uint32_t addr = riscv->reg[rs1] + imm;
  // printf("lhu %08x,imm=%d\n",addr,imm);
  riscv->reg[rd] = mem_wh_read(riscv, addr);
}

void ins_lw(riscv_t* riscv, int rs1, int imm, int rd) {
  uint32_t addr = riscv->reg[rs1] + imm;
  // printf("lw %08x,imm=%d\n",addr,imm);
  riscv->reg[rd] = (int)mem_w_read(riscv, addr);
}

void ins_lwu(riscv_t* riscv, int rs1, int imm, int rd) {
  uint32_t addr = riscv->reg[rs1] + imm;
  // printf("lwu %08x,imm=%d\n",addr,imm);
  riscv->reg[rd] = mem_w_read(riscv, addr);
}

void ins_lui(riscv_t* riscv, int imm, int rd) {
  riscv->reg[rd] = imm;
}

void ins_mret(riscv_t* riscv) {
  riscv->pc = riscv->mepc;
  if (riscv->mstatus & MSTATUS_MPIE) {
    riscv->mstatus &= ~MSTATUS_MPIE;
    riscv->mstatus |= MSTATUS_MIE;
  } else {
    riscv->mstatus &= ~MSTATUS_MIE;
  }
  printf("mret: pc=%08x\n", riscv->pc);
}

void ins_or(riscv_t* riscv, int rs2, int rs1, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] | riscv->reg[rs2];
}

void ins_ori(riscv_t* riscv, int rs1, int imm, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] | imm;
}

void ins_sb(riscv_t* riscv, int rs2, int rs1, int imm) {
  uint32_t addr = riscv->reg[rs1] + imm;
  // printf("sb %08x,imm=%d\n",addr,imm);
  mem_wb_write(riscv, addr, riscv->reg[rs2]);
}

void ins_sh(riscv_t* riscv, int rs2, int rs1, int imm) {
  uint32_t addr = riscv->reg[rs1] + imm;
  // printf("sh %08x,imm=%d\n",addr,imm);
  mem_wh_write(riscv, addr, riscv->reg[rs2]);
}

void ins_sw(riscv_t* riscv, int rs2, int rs1, int imm) {
  uint32_t addr = riscv->reg[rs1] + imm;
  // printf("sw %08x,imm=%d\n",addr,imm);
  mem_w_write(riscv, addr, riscv->reg[rs2]);
}

void ins_sll(riscv_t* riscv, int rs2, int rs1, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] << riscv->reg[rs2];
}

void ins_slli(riscv_t* riscv, int rs1, int imm, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] << imm;
}

void ins_slliw(riscv_t* riscv, int rs1, int imm, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] << imm;
}

void ins_sllw(riscv_t* riscv, int rs2, int rs1, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] << riscv->reg[rs2];
}

void ins_slt(riscv_t* riscv, int rs2, int rs1, int rd) {
  riscv->reg[rd] = (int)riscv->reg[rs1] < (int)riscv->reg[rs2];
}

void ins_slti(riscv_t* riscv, int rs1, int imm, int rd) {
  riscv->reg[rd] = (int)riscv->reg[rs1] < imm;
}

void ins_sltiu(riscv_t* riscv, int rs1, int imm, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] < (uint32_t)imm;
}

void ins_sltu(riscv_t* riscv, int rs2, int rs1, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] < riscv->reg[rs2];
}

void ins_sra(riscv_t* riscv, int rs2, int rs1, int rd) {
  riscv->reg[rd] = (int)riscv->reg[rs1] >> riscv->reg[rs2];
}

void ins_srai(riscv_t* riscv, int rs1, int imm, int rd) {
  riscv->reg[rd] = (int)riscv->reg[rs1] >> imm;
}

void ins_sraiw(riscv_t* riscv, int rs1, int imm, int rd) {
  riscv->reg[rd] = (int)riscv->reg[rs1] >> imm;
}

void ins_sraw(riscv_t* riscv, int rs2, int rs1, int rd) {
  riscv->reg[rd] = (int)riscv->reg[rs1] >> riscv->reg[rs2];
}

void ins_srl(riscv_t* riscv, int rs2, int rs1, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] >> riscv->reg[rs2];
}

void ins_srli(riscv_t* riscv, int rs1, int imm, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] >> imm;
}

void ins_srliw(riscv_t* riscv, int rs1, int imm, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] >> imm;
}

void ins_srlw(riscv_t* riscv, int rs2, int rs1, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] >> riscv->reg[rs2];
}

void ins_sub(riscv_t* riscv, int rs2, int rs1, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] - riscv->reg[rs2];
}

void ins_subw(riscv_t* riscv, int rs2, int rs1, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] - riscv->reg[rs2];
}

void ins_wfi(riscv_t* riscv) {
  printf("wfi\n");
}

void ins_xor(riscv_t* riscv, int rs2, int rs1, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] ^ riscv->reg[rs2];
}

void ins_xori(riscv_t* riscv, int rs1, int imm, int rd) {
  riscv->reg[rd] = riscv->reg[rs1] ^ imm;
}

// 解析指令
int riscv_decode(riscv_t* riscv, uint32_t ins) {
  int imm = 0;
  int rs1 = (ins >> 15) & 0x1f;
  int rs2 = (ins >> 20) & 0x1f;
  int rd = (ins >> 7) & 0x1f;
  int funct3 = (ins >> 12) & 0x7;
  int funct7 = (ins >> 25) & 0x7f;
  int opcode = ins & 0x7f;
  switch (opcode) {
    // U-type
  case opcode_lui:
    imm_u_type(ins, imm);
    ins_lui(riscv, imm, rd);
    break;
  case opcode_auipc:
    imm_u_type(ins, imm);
    ins_auipc(riscv, imm, rd);
    break;
    // J-type
  case opcode_jal:
    imm_j_type(ins, imm);
    ins_jal(riscv, imm, rd);
    break;
  case opcode_jalr:
    // I-type
    imm_i_type(ins, imm);
    ins_jalr(riscv, rs1, imm, rd);
    break;
  case opcode_beq:
    imm_b_type(ins, imm);
    switch(funct3) {
      case 0x0:
        ins_beq(riscv, rs2, rs1, imm);
        break;
      case 0x1:
        ins_bne(riscv, rs2, rs1, imm);
        break;
      case 0x4:
        ins_blt(riscv, rs2, rs1, imm);
        break;
      case 0x5:
        ins_bge(riscv, rs2, rs1, imm);
        break;
      case 0x6:
        ins_bltu(riscv, rs2, rs1, imm);
        break;
      case 0x7:
        ins_bgeu(riscv, rs2, rs1, imm);
        break;
      default:
        riscv->exc_code = 2;
        break;
    }
    break;
  case opcode_lb:
    imm_i_type(ins, imm);
    switch (funct3)
    {
    case 0x0:
      ins_lb(riscv, rs1, imm, rd);
      break;
    case 0x1:
      ins_lh(riscv, rs1, imm, rd);
      break;
    case 0x2:
      ins_lw(riscv, rs1, imm, rd);
      break;
    case 0x4:
      ins_lbu(riscv, rs1, imm, rd);
      break;
    case 0x5:
      ins_lhu(riscv, rs1, imm, rd);
      break;
    default:
      riscv->exc_code = 2;
      break;
    }
    break;
  case opcode_sb:
    imm_s_type(ins, imm);
    switch (funct3) {
      case 0x0:
        ins_sb(riscv, rs2, rs1, imm);
        break;
      case 0x1:
        ins_sh(riscv, rs2, rs1, imm);
        break;
      case 0x2:
        ins_sw(riscv, rs2, rs1, imm);
        break;
      default:
        riscv->exc_code = 2;
        break;
    }
    break;
  case opcode_addi:
    imm_i_type(ins,imm);
    switch (funct3)
    {
      case 0x0:
        ins_addi(riscv, rs1, imm, rd);
        break;
      case 0x2:
        ins_slti(riscv, rs1, imm, rd);
        break;
      case 0x3:
       ins_sltiu(riscv, rs1, imm, rd);
        break;
      case 0x4:
        ins_xori(riscv, rs1, imm, rd);
        break;
      case 0x6:
        ins_ori(riscv, rs1, imm, rd);
        break;
      case 0x7:
        ins_andi(riscv, rs1, imm, rd);
        break;
      case 0x1:
        imm = imm&0x1f;
        ins_slli(riscv, rs1, imm, rd);
        break;
      case 0x5:
        imm = imm&0x1f;
        if(funct7 == 0x20){
          ins_srai(riscv, rs1, imm, rd);
        }else{
          ins_srli(riscv, rs1, imm, rd);
        }
        break;
      default:
        riscv->exc_code = 2;
        break;
    }
    break;
  case opcode_add:
    switch (funct3)
    {
      case 0x0:
        if(funct7 == 0x20){
          ins_sub(riscv, rs2, rs1, rd);
        }else{
          ins_add(riscv, rs2, rs1, rd);
        }
        break;
      case 0x1:
        ins_sll(riscv, rs2, rs1, rd);
        break;
      case 0x2:
        ins_slt(riscv, rs2, rs1, rd);
        break;
      case 0x3:
        ins_sltu(riscv, rs2, rs1, rd);
        break;
      case 0x4:
        ins_xor(riscv, rs2, rs1, rd);
        break;
      case 0x5:
        if (funct7 == 0x20) {
          ins_sra(riscv, rs2, rs1, rd);
        }else{
          ins_srl(riscv, rs2, rs1, rd);
        }
        break;
      case 0x6:
        ins_or(riscv, rs2, rs1, rd);
        break;
      case 0x7:
        ins_and(riscv, rs2, rs1, rd);
        break;
      default:
        riscv->exc_code = 2;
        break;
    }
    break;
    case opcode_ecall:
    imm_csr(ins,imm);
    switch (funct3)
    {
    case 0x0:
      if (imm == 1) {
        ins_ebreak(riscv);
      } else if (imm == 0) {
        ins_ecall(riscv);
      } else if (ins == 0x30200073) {
        ins_mret(riscv);
      } else{
        riscv->exc_code = 2;
      }
      break;
    case 0x1:
      ins_csrrw(riscv, rs1, rd, imm);
      break;
    case 0x2:
      ins_csrrs(riscv, rs1, rd, imm);
      break;
    case 0x3:
      ins_csrrc(riscv, rs1, rd, imm);
      break;
    case 0x5:
      // rs1 保存的是zimm 值
      ins_csrrwi(riscv, rs1, rd, imm);
      break;
    case 0x6:
      ins_csrrsi(riscv, rs1, rd, imm);
      break;
    case 0x7:
      ins_csrrci(riscv, rs1, rd, imm);
      break;
    default:
      riscv->exc_code = 2;
      break;
    }
    break;
    default:
    riscv->exc_code = 2;
    break;
  }
  if (riscv->exc_code == 2) {
    riscv->mtval = ins;
  }
  return 0;
}



// 注册外设
int riscv_register_device(riscv_t* riscv, const device_t* device) {
  if (riscv->device_num >= DEVICE_MAX_NUM) {
    printf("riscv register device failed, device num out of range\n");
    return -1;
  }
  // printf("device: base_addr=%08x, size=%08x\n", device->addr, device->size);
  riscv->device_list[riscv->device_num] = device;
  riscv->device_num++;
  return 0;
}


int riscv_init(riscv_t* riscv, uint32_t* rom, uint32_t rom_addr_base, uint32_t rom_size) {
  riscv->rom = rom;
  riscv->rom_size = rom_size;
  riscv->rom_addr_base = rom_addr_base;
  riscv->pc = riscv->rom_addr_base;
  return 0;
}

// 进入中断 is_interrupt=1 进入中断 is_interrupt=0 进入异常
// irq_num 中断号
int riscv_enter_trap(riscv_t* riscv, int is_interrupt, int irq_num) {
  riscv->mepc = riscv->pc;
  riscv->mcause = (is_interrupt << 31) | irq_num;
  riscv->pc = riscv->mtvec;
  // 禁用全局中断
  if (riscv->mstatus & MSTATUS_MIE) {
    riscv->mstatus &= ~MSTATUS_MIE;
    riscv->mstatus |= MSTATUS_MPIE;
  } else {
    riscv->mstatus &= ~MSTATUS_MPIE;
  }
  return 0;
}

// 检测是否产生了中断
int riscv_irq_check(riscv_t* riscv) {
  uint32_t tmp;
  int irq_num = 0;
  tmp = riscv->mip & (MIP_MSIP | MIP_MTIP | MIP_MEIP);
  if (tmp) {
    if (riscv->mstatus & MSTATUS_MIE) {
      if ((riscv->mie & MIP_MSIP) && (tmp & MIP_MSIP)) {
        irq_num = 3;
      } else if ((riscv->mie & MIP_MTIP) && (tmp & MIP_MTIP)) {
        irq_num = 7;
      } else if ((riscv->mie & MIP_MEIP) && (tmp & MIP_MEIP)) {
        irq_num = 11;
      }
      riscv->mtval = 0;
      riscv_enter_trap(riscv, 1, irq_num);
      if (irq_num>0) {
        riscv->mip &= ~(1 << irq_num);
        irq_num = 0;
      }
    }
  }
  return 0;
}

int riscv_run(riscv_t* riscv) {
  int ret = 0;
  uint32_t pc;
  while (1) {
    if (riscv->pc == 0) {
      break;
    }
    if (riscv->pc >= riscv->rom_addr_base + riscv->rom_size || riscv->pc < riscv->rom_addr_base) {
      // 指令访问失败
      riscv->mtval = riscv->pc;
      printf("riscv run out of rom pc=%08x\n",riscv->pc);
      riscv_enter_trap(riscv, 0, 1);
      printf("riscv run out of rom pc=%08x\n",riscv->pc);
    }
    if (riscv->pc & 0x3) {
      // 指令地址未对齐
      riscv->mtval = riscv->pc;
      riscv_enter_trap(riscv, 0, 0);
    }
    uint32_t instr = riscv->rom[(riscv->pc - riscv->rom_addr_base) >> 2];
    // printf("pc: %08x instr: %08x\n", riscv->pc, instr);
    pc = riscv->pc;
    ret = riscv_decode(riscv, instr);
    riscv->zero = 0;
    // 如果指令修改了pc，则以修改后的为准，如果pc未被修改，则继续执行下一条指令
    if (riscv->pc == pc) {
      riscv->pc += 4;
    }
    if (riscv->exc_code > 0) {
      riscv_enter_trap(riscv, 0, riscv->exc_code);
      riscv->exc_code = 0;
    }
    riscv_irq_check(riscv);
    // riscv_print(riscv);
    if(ret){
      break;
    }
    if (riscv->mscratch == 0xffffffff) {
      printf("proactively terminate\n");
      break;
    }
  }
  printf("riscv run end\n");
  return 0;
}



long get_file_size(FILE *stream)
{
	long file_size = -1;
	long cur_offset = ftell(stream);	// 获取当前偏移位置
	if (cur_offset == -1) {
		printf("ftell failed :%s\n", strerror(errno));
		return -1;
	}
	if (fseek(stream, 0, SEEK_END) != 0) {	// 移动文件指针到文件末尾
		printf("fseek failed: %s\n", strerror(errno));
		return -1;
	}
	file_size = ftell(stream);	// 获取此时偏移值，即文件大小
	if (file_size == -1) {
		printf("ftell failed :%s\n", strerror(errno));
	}
	if (fseek(stream, cur_offset, SEEK_SET) != 0) {	// 将文件指针恢复初始位置
		printf("fseek failed: %s\n", strerror(errno));
		return -1;
	}
	return file_size;
}



riscv_t riscv = { 0 };


int thread_fun(void* t)
{
  int argc;
  char** argv;
  argc = get_argv(&argv);

  char *bin_name="riscv.bin";
  if(argc>1){
    bin_name=argv[1];
  }

  printf("riscv start\n");
  FILE *file=fopen(bin_name, "rb" );
  if(file==NULL)
  {
    printf("open file %s error\n",bin_name);
    return -1;
  }
  riscv.rom_size = get_file_size(file);
  printf("rom size: %d\n", riscv.rom_size);
  riscv.rom = calloc((riscv.rom_size + 3) / 4, 4);
  fread(riscv.rom, 1, riscv.rom_size, file);
  fclose(file);

  riscv_register_device(&riscv, print_dev());
  riscv_init(&riscv, riscv.rom, 0x80000000, riscv.rom_size);
  riscv_run(&riscv);

  return 0;
}