/* Capstone Disassembly Engine */

/* By Giovanni Dante Grazioli, deroad <wargio@libero.it>, 2024 */

#ifdef CAPSTONE_HAS_MIPS

#include <stdio.h>

#include <string.h>

#include <capstone/capstone.h>

#include <capstone/mips.h>

#include "../../Mapping.h"

#include "../../MCDisassembler.h"

#include "../../cs_priv.h"

#include "../../cs_simple_types.h"

#include "MipsMapping.h"

#include "MipsLinkage.h"

#include "MipsDisassembler.h"

#define GET_REGINFO_ENUM

#define GET_REGINFO_MC_DESC

#include "MipsGenRegisterInfo.inc"

#define GET_INSTRINFO_ENUM

#include "MipsGenInstrInfo.inc"

void Mips_init_mri(MCRegisterInfo *MRI)

{

  MCRegisterInfo_InitMCRegisterInfo(MRI, MipsRegDesc, sizeof(MipsRegDesc),

            0, 0, MipsMCRegisterClasses,

            ARR_SIZE(MipsMCRegisterClasses), 0, 0,

            MipsRegDiffLists, 0,

            MipsSubRegIdxLists,

            ARR_SIZE(MipsSubRegIdxLists), 0);

}

const char *Mips_reg_name(csh handle, unsigned int reg)

{

  int syntax_opt = ((cs_struct *)(uintptr_t)handle)->syntax;

  return Mips_LLVM_getRegisterName(reg,

           syntax_opt & CS_OPT_SYNTAX_NOREGNAME);

}

void Mips_get_insn_id(cs_struct *h, cs_insn *insn, unsigned int id)

{

  // Not used by Mips. Information is set after disassembly.

}

static const char *const insn_name_maps[] = {

#include "MipsGenCSMappingInsnName.inc"

};

#ifndef CAPSTONE_DIET

static const name_map insn_alias_mnem_map[] = {

#include "MipsGenCSAliasMnemMap.inc"

  // The followings aliases are not generated by LLVM table gen.

  { MIPS_INS_ALIAS_B, "b" }, // beq

  { MIPS_INS_ALIAS_BEQZ, "beqz" }, // beq

  { MIPS_INS_ALIAS_BNEZ, "bnez" }, // bne

  { MIPS_INS_ALIAS_LI, "li" }, // addiu

  { MIPS_INS_ALIAS_END, NULL },

};

#endif

const char *Mips_insn_name(csh handle, unsigned int id)

{

#ifndef CAPSTONE_DIET

  if (id < MIPS_INS_ALIAS_END && id > MIPS_INS_ALIAS_BEGIN) {

    if (id - MIPS_INS_ALIAS_BEGIN >= ARR_SIZE(insn_alias_mnem_map))

      return NULL;

    return insn_alias_mnem_map[id - MIPS_INS_ALIAS_BEGIN - 1].name;

  }

  if (id >= MIPS_INS_ENDING)

    return NULL;

  if (id < ARR_SIZE(insn_name_maps))

    return insn_name_maps[id];

  // not found

  return NULL;

#else

  return NULL;

#endif

}

#ifndef CAPSTONE_DIET

static const name_map group_name_maps[] = {

  { MIPS_GRP_INVALID, NULL },

  { MIPS_GRP_JUMP, "jump" },

  { MIPS_GRP_CALL, "call" },

  { MIPS_GRP_RET, "return" },

  { MIPS_GRP_INT, "int" },

  { MIPS_GRP_IRET, "iret" },

  { MIPS_GRP_PRIVILEGE, "privilege" },

  { MIPS_GRP_BRANCH_RELATIVE, "branch_relative" },

// architecture-specific groups

#include "MipsGenCSFeatureName.inc"

};

#endif

const char *Mips_group_name(csh handle, unsigned int id)

{

#ifndef CAPSTONE_DIET

  return id2name(group_name_maps, ARR_SIZE(group_name_maps), id);

#else

  return NULL;

#endif

}

const insn_map mips_insns[] = {

#include "MipsGenCSMappingInsn.inc"

};

void Mips_reg_access(const cs_insn *insn, cs_regs regs_read,

         uint8_t *regs_read_count, cs_regs regs_write,

         uint8_t *regs_write_count)

{

  uint8_t i;

  uint8_t read_count, write_count;

  cs_mips *mips = &(insn->detail->mips);

  read_count = insn->detail->regs_read_count;

  write_count = insn->detail->regs_write_count;

  // implicit registers

  memcpy(regs_read, insn->detail->regs_read,

         read_count * sizeof(insn->detail->regs_read[0]));

  memcpy(regs_write, insn->detail->regs_write,

         write_count * sizeof(insn->detail->regs_write[0]));

  // explicit registers

  for (i = 0; i < mips->op_count; i++) {

    cs_mips_op *op = &(mips->operands[i]);

    switch ((int)op->type) {

    case MIPS_OP_REG:

      if ((op->access & CS_AC_READ) &&

          !arr_exist(regs_read, read_count, op->reg)) {

        regs_read[read_count] = (uint16_t)op->reg;

        read_count++;

      }

      if ((op->access & CS_AC_WRITE) &&

          !arr_exist(regs_write, write_count, op->reg)) {

        regs_write[write_count] = (uint16_t)op->reg;

        write_count++;

      }

      break;

    case MIPS_OP_MEM:

      // registers appeared in memory references always being read

      if ((op->mem.base != MIPS_REG_INVALID) &&

          !arr_exist(regs_read, read_count, op->mem.base)) {

        regs_read[read_count] = (uint16_t)op->mem.base;

        read_count++;

      }

      if ((insn->detail->writeback) &&

          (op->mem.base != MIPS_REG_INVALID) &&

          !arr_exist(regs_write, write_count, op->mem.base)) {

        regs_write[write_count] =

          (uint16_t)op->mem.base;

        write_count++;

      }

    default:

      break;

    }

  }

  *regs_read_count = read_count;

  *regs_write_count = write_count;

}

void Mips_set_instr_map_data(MCInst *MI)

{

  // Fixes for missing groups.

  if (MCInst_getOpcode(MI) == Mips_JR) {

    unsigned Reg = MCInst_getOpVal(MI, 0);

    switch (Reg) {

    case MIPS_REG_RA:

    case MIPS_REG_RA_64:

      add_group(MI, MIPS_GRP_RET);

      break;

    }

  }

  map_cs_id(MI, mips_insns, ARR_SIZE(mips_insns));

  map_implicit_reads(MI, mips_insns);

  map_implicit_writes(MI, mips_insns);

  map_groups(MI, mips_insns);

}

bool Mips_getInstruction(csh handle, const uint8_t *code, size_t code_len,

       MCInst *instr, uint16_t *size, uint64_t address,

       void *info)

{

  uint64_t size64;

  Mips_init_cs_detail(instr);

  instr->MRI = (MCRegisterInfo *)info;

  map_set_fill_detail_ops(instr, true);

  DecodeStatus Result = Mips_LLVM_getInstruction(instr, &size64, code,

                   code_len, address, info);

  *size = size64;

  if (Result != MCDisassembler_Fail) {

    Mips_set_instr_map_data(instr);

  }

  if (Result == MCDisassembler_SoftFail) {

    MCInst_setSoftFail(instr);

  }

  return Result != MCDisassembler_Fail;

}

void Mips_printer(MCInst *MI, SStream *O, void * /* MCRegisterInfo* */ info)

{

  MCRegisterInfo *MRI = (MCRegisterInfo *)info;

  MI->MRI = MRI;

  Mips_LLVM_printInst(MI, MI->address, O);

#ifndef CAPSTONE_DIET

  map_set_alias_id(MI, O, insn_alias_mnem_map,

       ARR_SIZE(insn_alias_mnem_map));

#endif

}

static void Mips_setup_op(cs_mips_op *op)

{

  memset(op, 0, sizeof(cs_mips_op));

  op->type = MIPS_OP_INVALID;

}

void Mips_init_cs_detail(MCInst *MI)

{

  if (detail_is_set(MI)) {

    unsigned int i;

    memset(get_detail(MI), 0,

           offsetof(cs_detail, mips) + sizeof(cs_mips));

    for (i = 0; i < ARR_SIZE(Mips_get_detail(MI)->operands); i++)

      Mips_setup_op(&Mips_get_detail(MI)->operands[i]);

  }

}

static const map_insn_ops insn_operands[] = {

#include "MipsGenCSMappingInsnOp.inc"

};

static void Mips_set_detail_op_mem_reg(MCInst *MI, unsigned OpNum, mips_reg Reg)

{

  Mips_get_detail_op(MI, 0)->type = MIPS_OP_MEM;

  Mips_get_detail_op(MI, 0)->mem.base = Reg;

  Mips_get_detail_op(MI, 0)->access = map_get_op_access(MI, OpNum);

}

static void Mips_set_detail_op_mem_disp(MCInst *MI, unsigned OpNum, int64_t Imm)

{

  Mips_get_detail_op(MI, 0)->type = MIPS_OP_MEM;

  Mips_get_detail_op(MI, 0)->mem.disp = Imm;

  Mips_get_detail_op(MI, 0)->access = map_get_op_access(MI, OpNum);

}

static void Mips_set_detail_op_imm(MCInst *MI, unsigned OpNum, int64_t Imm)

{

  if (!detail_is_set(MI))

    return;

  if (doing_mem(MI)) {

    Mips_set_detail_op_mem_disp(MI, OpNum, Imm);

    return;

  }

  Mips_get_detail_op(MI, 0)->type = MIPS_OP_IMM;

  Mips_get_detail_op(MI, 0)->imm = Imm;

  Mips_get_detail_op(MI, 0)->access = map_get_op_access(MI, OpNum);

  Mips_inc_op_count(MI);

}

static void Mips_set_detail_op_uimm(MCInst *MI, unsigned OpNum, uint64_t Imm)

{

  if (!detail_is_set(MI))

    return;

  if (doing_mem(MI)) {

    Mips_set_detail_op_mem_disp(MI, OpNum, Imm);

    return;

  }

  Mips_get_detail_op(MI, 0)->type = MIPS_OP_IMM;

  Mips_get_detail_op(MI, 0)->uimm = Imm;

  Mips_get_detail_op(MI, 0)->is_unsigned = true;

  Mips_get_detail_op(MI, 0)->access = map_get_op_access(MI, OpNum);

  Mips_inc_op_count(MI);

}

static void Mips_set_detail_op_reg(MCInst *MI, unsigned OpNum, mips_reg Reg,

           bool is_reglist)

{

  if (!detail_is_set(MI))

    return;

  if (doing_mem(MI)) {

    Mips_set_detail_op_mem_reg(MI, OpNum, Reg);

    return;

  }

  CS_ASSERT(is_reglist ||

      (map_get_op_type(MI, OpNum) & ~CS_OP_MEM) == CS_OP_REG);

  Mips_get_detail_op(MI, 0)->type = MIPS_OP_REG;

  Mips_get_detail_op(MI, 0)->reg = Reg;

  Mips_get_detail_op(MI, 0)->is_reglist = is_reglist;

  Mips_get_detail_op(MI, 0)->access = map_get_op_access(MI, OpNum);

  Mips_inc_op_count(MI);

}

static void Mips_set_detail_op_operand(MCInst *MI, unsigned OpNum)

{

  cs_op_type op_type = map_get_op_type(MI, OpNum) & ~CS_OP_MEM;

  int64_t value = MCInst_getOpVal(MI, OpNum);

  if (op_type == CS_OP_IMM) {

    Mips_set_detail_op_imm(MI, OpNum, value);

  } else if (op_type == CS_OP_REG) {

    Mips_set_detail_op_reg(MI, OpNum, value, false);

  } else {

    // Register list which ends with a memory operand

    // Gives very large MCInst operand numbers but don't

    // have the respective Capstone type in the mapping table.

    if (MCOperand_isImm(MCInst_getOperand(MI, OpNum))) {

      Mips_get_detail_op(MI, 0)->type = MIPS_OP_MEM;

      Mips_get_detail_op(MI, 0)->mem.disp = value;

    } else if (MCOperand_isReg(MCInst_getOperand(MI, OpNum))) {

      Mips_get_detail_op(MI, 0)->mem.base = value;

    } else {

      printf("Operand type %d not handled!\n", op_type);

    }

  }

}

static void Mips_set_detail_op_jump(MCInst *MI, unsigned OpNum)

{

  cs_op_type op_type = map_get_op_type(MI, OpNum) & ~CS_OP_MEM;

  if (op_type == CS_OP_IMM) {

    uint64_t Base = MI->address & ~0x0fffffffull;

    uint64_t Target = Base | (uint64_t)MCInst_getOpVal(MI, OpNum);

    Mips_set_detail_op_uimm(MI, OpNum, Target);

  } else if (op_type == CS_OP_REG) {

    Mips_set_detail_op_reg(MI, OpNum, MCInst_getOpVal(MI, OpNum),

               false);

  } else

    printf("Operand type %d not handled!\n", op_type);

}

static void Mips_set_detail_op_branch(MCInst *MI, unsigned OpNum)

{

  cs_op_type op_type = map_get_op_type(MI, OpNum) & ~CS_OP_MEM;

  if (op_type == CS_OP_IMM) {

    uint64_t Target = MI->address + MCInst_getOpVal(MI, OpNum);

    Mips_set_detail_op_uimm(MI, OpNum, Target);

  } else if (op_type == CS_OP_REG) {

    Mips_set_detail_op_reg(MI, OpNum, MCInst_getOpVal(MI, OpNum),

               false);

  } else

    printf("Operand type %d not handled!\n", op_type);

}

static void Mips_set_detail_op_unsigned(MCInst *MI, unsigned OpNum)

{

  Mips_set_detail_op_uimm(MI, OpNum, MCInst_getOpVal(MI, OpNum));

}

static void Mips_set_detail_op_unsigned_offset(MCInst *MI, unsigned OpNum,

                 unsigned Bits, uint64_t Offset)

{

  uint64_t Imm = MCInst_getOpVal(MI, OpNum);

  Imm -= Offset;

  Imm &= (((uint64_t)1) << Bits) - 1;

  Imm += Offset;

  Mips_set_detail_op_uimm(MI, OpNum, Imm);

}

static void Mips_set_detail_op_mem_nanomips(MCInst *MI, unsigned OpNum)

{

  CS_ASSERT(doing_mem(MI));

  MCOperand *Op = MCInst_getOperand(MI, OpNum);

  Mips_get_detail_op(MI, 0)->type = MIPS_OP_MEM;

  // Base is a register, but nanoMips uses the Imm value as register.

  Mips_get_detail_op(MI, 0)->mem.base = MCOperand_getImm(Op);

  Mips_get_detail_op(MI, 0)->access = map_get_op_access(MI, OpNum);

}

static void Mips_set_detail_op_reglist(MCInst *MI, unsigned OpNum,

               bool isNanoMips)

{

  if (isNanoMips) {

    for (unsigned i = OpNum; i < MCInst_getNumOperands(MI); i++) {

      Mips_set_detail_op_reg(MI, i, MCInst_getOpVal(MI, i),

                 true);

    }

    return;

  }

  // -2 because register List is always first operand of instruction

  // and it is always followed by memory operand (base + offset).

  for (unsigned i = OpNum, e = MCInst_getNumOperands(MI) - 2; i != e;

       ++i) {

    Mips_set_detail_op_reg(MI, i, MCInst_getOpVal(MI, i), true);

  }

}

static void Mips_set_detail_op_unsigned_address(MCInst *MI, unsigned OpNum)

{

  uint64_t Target = MI->address + (uint64_t)MCInst_getOpVal(MI, OpNum);

  Mips_set_detail_op_imm(MI, OpNum, Target);

}

void Mips_add_cs_detail_0(MCInst *MI, mips_op_group op_group, size_t OpNum)

{

  if (!detail_is_set(MI) || !map_fill_detail_ops(MI))

    return;

  switch (op_group) {

  default:

    printf("Operand group %d not handled!\n", op_group);

    return;

  case Mips_OP_GROUP_MemOperand:

    // this is only used by nanoMips.

    return Mips_set_detail_op_mem_nanomips(MI, OpNum);

  case Mips_OP_GROUP_BranchOperand:

    return Mips_set_detail_op_branch(MI, OpNum);

  case Mips_OP_GROUP_JumpOperand:

    return Mips_set_detail_op_jump(MI, OpNum);

  case Mips_OP_GROUP_Operand:

    return Mips_set_detail_op_operand(MI, OpNum);

  case Mips_OP_GROUP_UImm_1_0:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 1, 0);

  case Mips_OP_GROUP_UImm_2_0:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 2, 0);

  case Mips_OP_GROUP_UImm_3_0:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 3, 0);

  case Mips_OP_GROUP_UImm_32_0:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 32, 0);

  case Mips_OP_GROUP_UImm_16_0:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 16, 0);

  case Mips_OP_GROUP_UImm_8_0:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 8, 0);

  case Mips_OP_GROUP_UImm_5_0:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 5, 0);

  case Mips_OP_GROUP_UImm_6_0:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 6, 0);

  case Mips_OP_GROUP_UImm_4_0:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 4, 0);

  case Mips_OP_GROUP_UImm_7_0:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 7, 0);

  case Mips_OP_GROUP_UImm_10_0:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 10, 0);

  case Mips_OP_GROUP_UImm_6_1:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 6, 1);

  case Mips_OP_GROUP_UImm_5_1:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 5, 1);

  case Mips_OP_GROUP_UImm_5_33:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 5, 33);

  case Mips_OP_GROUP_UImm_5_32:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 5, 32);

  case Mips_OP_GROUP_UImm_6_2:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 6, 2);

  case Mips_OP_GROUP_UImm_2_1:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 2, 1);

  case Mips_OP_GROUP_UImm_0_0:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 0, 0);

  case Mips_OP_GROUP_UImm_26_0:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 26, 0);

  case Mips_OP_GROUP_UImm_12_0:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 12, 0);

  case Mips_OP_GROUP_UImm_20_0:

    return Mips_set_detail_op_unsigned_offset(MI, OpNum, 20, 0);

  case Mips_OP_GROUP_RegisterList:

    return Mips_set_detail_op_reglist(MI, OpNum, false);

  case Mips_OP_GROUP_NanoMipsRegisterList:

    return Mips_set_detail_op_reglist(MI, OpNum, true);

  case Mips_OP_GROUP_PCRel:

    /* fall-thru */

  case Mips_OP_GROUP_Hi20PCRel:

    return Mips_set_detail_op_unsigned_address(MI, OpNum);

  case Mips_OP_GROUP_Hi20:

    return Mips_set_detail_op_unsigned(MI, OpNum);

  }

}

void Mips_set_mem_access(MCInst *MI, bool status)

{

  if (!detail_is_set(MI))

    return;

  set_doing_mem(MI, status);

  if (status) {

    if (Mips_get_detail(MI)->op_count > 0 &&

        Mips_get_detail_op(MI, -1)->type == MIPS_OP_MEM &&

        Mips_get_detail_op(MI, -1)->mem.disp == 0) {

      // Previous memory operand not done yet. Select it.

      Mips_dec_op_count(MI);

      return;

    }

    // Init a new one.

    Mips_get_detail_op(MI, 0)->type = MIPS_OP_MEM;

    Mips_get_detail_op(MI, 0)->mem.base = MIPS_REG_INVALID;

    Mips_get_detail_op(MI, 0)->mem.disp = 0;

#ifndef CAPSTONE_DIET

    uint8_t access =

      map_get_op_access(MI, Mips_get_detail(MI)->op_count);

    Mips_get_detail_op(MI, 0)->access = access;

#endif

  } else {

    // done, select the next operand slot

    Mips_inc_op_count(MI);

  }

}

#endif