//===-- SparcInstPrinter.cpp - Convert Sparc MCInst to assembly syntax --------===//

//

//                     The LLVM Compiler Infrastructure

//

// This file is distributed under the University of Illinois Open Source

// License. See LICENSE.TXT for details.

//

//===----------------------------------------------------------------------===//

//

// This class prints an Sparc MCInst to a .s file.

//

//===----------------------------------------------------------------------===//

/* Capstone Disassembly Engine */

/* By Nguyen Anh Quynh <aquynh@gmail.com>, 2013-2015 */

#ifdef CAPSTONE_HAS_SPARC

#ifdef _MSC_VER

#define _CRT_SECURE_NO_WARNINGS

#endif

#include <stdio.h>

#include <stdlib.h>

#include <string.h>

#include <limits.h>

#include "SparcInstPrinter.h"

#include "../../MCInst.h"

#include "../../utils.h"

#include "../../SStream.h"

#include "../../MCRegisterInfo.h"

#include "../../MathExtras.h"

#include "SparcMapping.h"

#include "Sparc.h"

static const char *getRegisterName(unsigned RegNo);

static void printInstruction(MCInst *MI, SStream *O, const MCRegisterInfo *MRI);

static void printMemOperand(MCInst *MI, int opNum, SStream *O, const char *Modifier);

static void printOperand(MCInst *MI, int opNum, SStream *O);

static void Sparc_add_hint(MCInst *MI, unsigned int hint)

{

  if (MI->csh->detail) {

    MI->flat_insn->detail->sparc.hint = hint;

  }

}

static void Sparc_add_reg(MCInst *MI, unsigned int reg)

{

  if (MI->csh->detail) {

    MI->flat_insn->detail->sparc.operands[MI->flat_insn->detail->sparc.op_count].type = SPARC_OP_REG;

    MI->flat_insn->detail->sparc.operands[MI->flat_insn->detail->sparc.op_count].reg = reg;

    MI->flat_insn->detail->sparc.op_count++;

  }

}

static void set_mem_access(MCInst *MI, bool status)

{

  if (MI->csh->detail != CS_OPT_ON)

    return;

  MI->csh->doing_mem = status;

  if (status) {

    MI->flat_insn->detail->sparc.operands[MI->flat_insn->detail->sparc.op_count].type = SPARC_OP_MEM;

    MI->flat_insn->detail->sparc.operands[MI->flat_insn->detail->sparc.op_count].mem.base = SPARC_REG_INVALID;

    MI->flat_insn->detail->sparc.operands[MI->flat_insn->detail->sparc.op_count].mem.disp = 0;

  } else {

    // done, create the next operand slot

    MI->flat_insn->detail->sparc.op_count++;

  }

}

void Sparc_post_printer(csh ud, cs_insn *insn, char *insn_asm, MCInst *mci)

{

  if (((cs_struct *)ud)->detail != CS_OPT_ON)

    return;

  // fix up some instructions

  if (insn->id == SPARC_INS_CASX) {

    // first op is actually a memop, not regop

    insn->detail->sparc.operands[0].type = SPARC_OP_MEM;

    insn->detail->sparc.operands[0].mem.base = (uint8_t)insn->detail->sparc.operands[0].reg;

    insn->detail->sparc.operands[0].mem.disp = 0;

  }

}

static void printRegName(SStream *OS, unsigned RegNo)

{

  SStream_concat0(OS, "%");

  SStream_concat0(OS, getRegisterName(RegNo));

}

#define GET_INSTRINFO_ENUM

#include "SparcGenInstrInfo.inc"

#define GET_REGINFO_ENUM

#include "SparcGenRegisterInfo.inc"

static bool printSparcAliasInstr(MCInst *MI, SStream *O)

{

  switch (MCInst_getOpcode(MI)) {

    default: return false;

    case SP_JMPLrr:

    case SP_JMPLri:

         if (MCInst_getNumOperands(MI) != 3)

           return false;

         if (!MCOperand_isReg(MCInst_getOperand(MI, 0)))

           return false;

         switch (MCOperand_getReg(MCInst_getOperand(MI, 0))) {

           default: return false;

           case SP_G0: // jmp $addr | ret | retl

                if (MCOperand_isImm(MCInst_getOperand(MI, 2)) &&

                  MCOperand_getImm(MCInst_getOperand(MI, 2)) == 8) {

                  switch(MCOperand_getReg(MCInst_getOperand(MI, 1))) {

                    default: break;

                    case SP_I7: SStream_concat0(O, "ret"); MCInst_setOpcodePub(MI, SPARC_INS_RET); return true;

                    case SP_O7: SStream_concat0(O, "retl"); MCInst_setOpcodePub(MI, SPARC_INS_RETL); return true;

                  }

                }

                SStream_concat0(O, "jmp\t");

                MCInst_setOpcodePub(MI, SPARC_INS_JMP);

                printMemOperand(MI, 1, O, NULL);

                return true;

           case SP_O7: // call $addr

                SStream_concat0(O, "call ");

                MCInst_setOpcodePub(MI, SPARC_INS_CALL);

                printMemOperand(MI, 1, O, NULL);

                return true;

         }

    case SP_V9FCMPS:

    case SP_V9FCMPD:

    case SP_V9FCMPQ:

    case SP_V9FCMPES:

    case SP_V9FCMPED:

    case SP_V9FCMPEQ:

         if (MI->csh->mode & CS_MODE_V9 || (MCInst_getNumOperands(MI) != 3) ||

             (!MCOperand_isReg(MCInst_getOperand(MI, 0))) ||

             (MCOperand_getReg(MCInst_getOperand(MI, 0)) != SP_FCC0))

             return false;

         // if V8, skip printing %fcc0.

         switch(MCInst_getOpcode(MI)) {

           default:

           case SP_V9FCMPS:  SStream_concat0(O, "fcmps\t"); MCInst_setOpcodePub(MI, SPARC_INS_FCMPS); break;

           case SP_V9FCMPD:  SStream_concat0(O, "fcmpd\t"); MCInst_setOpcodePub(MI, SPARC_INS_FCMPD); break;

           case SP_V9FCMPQ:  SStream_concat0(O, "fcmpq\t"); MCInst_setOpcodePub(MI, SPARC_INS_FCMPQ); break;

           case SP_V9FCMPES: SStream_concat0(O, "fcmpes\t"); MCInst_setOpcodePub(MI, SPARC_INS_FCMPES); break;

           case SP_V9FCMPED: SStream_concat0(O, "fcmped\t"); MCInst_setOpcodePub(MI, SPARC_INS_FCMPED); break;

           case SP_V9FCMPEQ: SStream_concat0(O, "fcmpeq\t"); MCInst_setOpcodePub(MI, SPARC_INS_FCMPEQ); break;

         }

         printOperand(MI, 1, O);

         SStream_concat0(O, ", ");

         printOperand(MI, 2, O);

         return true;

  }

}

static void printOperand(MCInst *MI, int opNum, SStream *O)

{

  int64_t Imm;

  unsigned reg;

  MCOperand *MO = MCInst_getOperand(MI, opNum);

  if (MCOperand_isReg(MO)) {

    reg = MCOperand_getReg(MO);

    printRegName(O, reg);

    reg = Sparc_map_register(reg);

    if (MI->csh->detail) {

      if (MI->csh->doing_mem) {

        if (MI->flat_insn->detail->sparc.operands[MI->flat_insn->detail->sparc.op_count].mem.base)

          MI->flat_insn->detail->sparc.operands[MI->flat_insn->detail->sparc.op_count].mem.index = (uint8_t)reg;

        else

          MI->flat_insn->detail->sparc.operands[MI->flat_insn->detail->sparc.op_count].mem.base = (uint8_t)reg;

      } else {

        MI->flat_insn->detail->sparc.operands[MI->flat_insn->detail->sparc.op_count].type = SPARC_OP_REG;

        MI->flat_insn->detail->sparc.operands[MI->flat_insn->detail->sparc.op_count].reg = reg;

        MI->flat_insn->detail->sparc.op_count++;

      }

    }

    return;

  }

  if (MCOperand_isImm(MO)) {

    Imm = (int)MCOperand_getImm(MO);

    // Conditional branches displacements needs to be signextended to be

    // able to jump backwards.

    //

    // Displacements are measured as the number of instructions forward or

    // backward, so they need to be multiplied by 4

    switch (MI->Opcode) {

      case SP_CALL:

        // Imm = SignExtend32(Imm, 30);

        Imm += MI->address;

        break;

      // Branch on integer condition with prediction (BPcc)

      // Branch on floating point condition with prediction (FBPfcc)

      case SP_BPICC:

      case SP_BPICCA:

      case SP_BPICCANT:

      case SP_BPICCNT:

      case SP_BPXCC:

      case SP_BPXCCA:

      case SP_BPXCCANT:

      case SP_BPXCCNT:

      case SP_BPFCC:

      case SP_BPFCCA:

      case SP_BPFCCANT:

      case SP_BPFCCNT:

        Imm = SignExtend32(Imm, 19);

        Imm = MI->address + Imm * 4;

        break;

      // Branch on integer condition (Bicc)

      // Branch on floating point condition (FBfcc)

      case SP_BA:

      case SP_BCOND:

      case SP_BCONDA:

      case SP_FBCOND:

      case SP_FBCONDA:

        Imm = SignExtend32(Imm, 22);

        Imm = MI->address + Imm * 4;

        break;

      // Branch on integer register with prediction (BPr)

      case SP_BPGEZapn:

      case SP_BPGEZapt:

      case SP_BPGEZnapn:

      case SP_BPGEZnapt:

      case SP_BPGZapn:

      case SP_BPGZapt:

      case SP_BPGZnapn:

      case SP_BPGZnapt:

      case SP_BPLEZapn:

      case SP_BPLEZapt:

      case SP_BPLEZnapn:

      case SP_BPLEZnapt:

      case SP_BPLZapn:

      case SP_BPLZapt:

      case SP_BPLZnapn:

      case SP_BPLZnapt:

      case SP_BPNZapn:

      case SP_BPNZapt:

      case SP_BPNZnapn:

      case SP_BPNZnapt:

      case SP_BPZapn:

      case SP_BPZapt:

      case SP_BPZnapn:

      case SP_BPZnapt:

        Imm = SignExtend32(Imm, 16);

        Imm = MI->address + Imm * 4;

        break;

    }

    printInt64(O, Imm);

    if (MI->csh->detail) {

      if (MI->csh->doing_mem) {

        MI->flat_insn->detail->sparc.operands[MI->flat_insn->detail->sparc.op_count].mem.disp = Imm;

      } else {

        MI->flat_insn->detail->sparc.operands[MI->flat_insn->detail->sparc.op_count].type = SPARC_OP_IMM;

        MI->flat_insn->detail->sparc.operands[MI->flat_insn->detail->sparc.op_count].imm = Imm;

        MI->flat_insn->detail->sparc.op_count++;

      }

    }

  }

  return;

}

static void printMemOperand(MCInst *MI, int opNum, SStream *O, const char *Modifier)

{

  MCOperand *MO;

  set_mem_access(MI, true);

  printOperand(MI, opNum, O);

  // If this is an ADD operand, emit it like normal operands.

  if (Modifier && !strcmp(Modifier, "arith")) {

    SStream_concat0(O, ", ");

    printOperand(MI, opNum + 1, O);

    set_mem_access(MI, false);

    return;

  }

  MO = MCInst_getOperand(MI, opNum + 1);

  if (MCOperand_isReg(MO) && (MCOperand_getReg(MO) == SP_G0)) {

    set_mem_access(MI, false);

    return;   // don't print "+%g0"

  }

  if (MCOperand_isImm(MO) && (MCOperand_getImm(MO) == 0)) {

    set_mem_access(MI, false);

    return;   // don't print "+0"

  }

  SStream_concat0(O, "+");  // qq

  printOperand(MI, opNum + 1, O);

  set_mem_access(MI, false);

}

static void printCCOperand(MCInst *MI, int opNum, SStream *O)

{

  int CC = (int)MCOperand_getImm(MCInst_getOperand(MI, opNum)) + 256;

  switch (MCInst_getOpcode(MI)) {

    default: break;

    case SP_FBCOND:

    case SP_FBCONDA:

    case SP_BPFCC:

    case SP_BPFCCA:

    case SP_BPFCCNT:

    case SP_BPFCCANT:

    case SP_MOVFCCrr:  case SP_V9MOVFCCrr:

    case SP_MOVFCCri:  case SP_V9MOVFCCri:

    case SP_FMOVS_FCC: case SP_V9FMOVS_FCC:

    case SP_FMOVD_FCC: case SP_V9FMOVD_FCC:

    case SP_FMOVQ_FCC: case SP_V9FMOVQ_FCC:

         // Make sure CC is a fp conditional flag.

         CC = (CC < 16+256) ? (CC + 16) : CC;

         break;

  }

  SStream_concat0(O, SPARCCondCodeToString((sparc_cc)CC));

  if (MI->csh->detail)

    MI->flat_insn->detail->sparc.cc = (sparc_cc)CC;

}

static bool printGetPCX(MCInst *MI, unsigned opNum, SStream *O)

{

  return true;

}

#define PRINT_ALIAS_INSTR

#include "SparcGenAsmWriter.inc"

void Sparc_printInst(MCInst *MI, SStream *O, void *Info)

{

  char *mnem, *p;

  char instr[64]; // Sparc has no instruction this long

  mnem = printAliasInstr(MI, O, Info);

  if (mnem) {

    // fixup instruction id due to the change in alias instruction

    unsigned cpy_len = sizeof(instr) - 1 < strlen(mnem) ? sizeof(instr) - 1 : strlen(mnem);

    memcpy(instr, mnem, cpy_len);

    instr[cpy_len] = '\0';

    // does this contains hint with a coma?

    p = strchr(instr, ',');

    if (p)

      *p = '\0'; // now instr only has instruction mnemonic

    MCInst_setOpcodePub(MI, Sparc_map_insn(instr));

    switch(MCInst_getOpcode(MI)) {

      case SP_BCOND:

      case SP_BCONDA:

      case SP_BPICCANT:

      case SP_BPICCNT:

      case SP_BPXCCANT:

      case SP_BPXCCNT:

      case SP_TXCCri:

      case SP_TXCCrr:

        if (MI->csh->detail) {

          // skip 'b', 't'

          MI->flat_insn->detail->sparc.cc = Sparc_map_ICC(instr + 1);

          MI->flat_insn->detail->sparc.hint = Sparc_map_hint(mnem);

        }

        break;

      case SP_BPFCCANT:

      case SP_BPFCCNT:

        if (MI->csh->detail) {

          // skip 'fb'

          MI->flat_insn->detail->sparc.cc = Sparc_map_FCC(instr + 2);

          MI->flat_insn->detail->sparc.hint = Sparc_map_hint(mnem);

        }

        break;

      case SP_FMOVD_ICC:

      case SP_FMOVD_XCC:

      case SP_FMOVQ_ICC:

      case SP_FMOVQ_XCC:

      case SP_FMOVS_ICC:

      case SP_FMOVS_XCC:

        if (MI->csh->detail) {

          // skip 'fmovd', 'fmovq', 'fmovs'

          MI->flat_insn->detail->sparc.cc = Sparc_map_ICC(instr + 5);

          MI->flat_insn->detail->sparc.hint = Sparc_map_hint(mnem);

        }

        break;

      case SP_MOVICCri:

      case SP_MOVICCrr:

      case SP_MOVXCCri:

      case SP_MOVXCCrr:

        if (MI->csh->detail) {

          // skip 'mov'

          MI->flat_insn->detail->sparc.cc = Sparc_map_ICC(instr + 3);

          MI->flat_insn->detail->sparc.hint = Sparc_map_hint(mnem);

        }

        break;

      case SP_V9FMOVD_FCC:

      case SP_V9FMOVQ_FCC:

      case SP_V9FMOVS_FCC:

        if (MI->csh->detail) {

          // skip 'fmovd', 'fmovq', 'fmovs'

          MI->flat_insn->detail->sparc.cc = Sparc_map_FCC(instr + 5);

          MI->flat_insn->detail->sparc.hint = Sparc_map_hint(mnem);

        }

        break;

      case SP_V9MOVFCCri:

      case SP_V9MOVFCCrr:

        if (MI->csh->detail) {

          // skip 'mov'

          MI->flat_insn->detail->sparc.cc = Sparc_map_FCC(instr + 3);

          MI->flat_insn->detail->sparc.hint = Sparc_map_hint(mnem);

        }

        break;

      default:

        break;

    }

    cs_mem_free(mnem);

  } else {

    if (!printSparcAliasInstr(MI, O))

      printInstruction(MI, O, NULL);

  }

}

void Sparc_addReg(MCInst *MI, int reg)

{

  if (MI->csh->detail) {

    MI->flat_insn->detail->sparc.operands[MI->flat_insn->detail->sparc.op_count].type = SPARC_OP_REG;

    MI->flat_insn->detail->sparc.operands[MI->flat_insn->detail->sparc.op_count].reg = reg;

    MI->flat_insn->detail->sparc.op_count++;

  }

}

#endif