//===-- XCoreInstPrinter.cpp - Convert XCore 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 XCore MCInst to a .s file.
//
//===----------------------------------------------------------------------===//
/* Capstone Disassembly Engine */
/* By Nguyen Anh Quynh <aquynh@gmail.com>, 2013-2014 */
#ifdef CAPSTONE_HAS_XCORE
#if defined (WIN32) || defined (WIN64) || defined (_WIN32) || defined (_WIN64)
#pragma warning(disable : 4996) // disable MSVC's warning on strcpy()
#pragma warning(disable : 28719) // disable MSVC's warning on strcpy()
#endif
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <platform.h>
#include "XCoreInstPrinter.h"
#include "../../MCInst.h"
#include "../../utils.h"
#include "../../SStream.h"
#include "../../MCRegisterInfo.h"
#include "../../MathExtras.h"
#include "XCoreMapping.h"
static char *getRegisterName(unsigned RegNo);
void XCore_post_printer(csh ud, cs_insn *insn, char *insn_asm, MCInst *mci)
{
/*
if (((cs_struct *)ud)->detail != CS_OPT_ON)
return;
*/
}
// stw sed, sp[3]
void XCore_insn_extract(MCInst *MI, const char *code)
{
int id;
char *p, *p2;
char tmp[128];
strcpy(tmp, code); // safe because code is way shorter than 128 bytes
// find the first space
p = strchr(tmp, ' ');
if (p) {
p++;
// find the next ','
p2 = strchr(p, ',');
if (p2) {
*p2 = '\0';
id = XCore_reg_id(p);
if (id) {
// register
if (MI->csh->detail) {
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].type = XCORE_OP_REG;
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].reg = id;
MI->flat_insn->detail->xcore.op_count++;
}
}
// next should be register, or memory?
// skip space
p2++;
while(*p2 && *p2 == ' ')
p2++;
if (*p2) {
// find '['
p = p2;
while(*p && *p != '[')
p++;
if (*p) {
// this is '['
*p = '\0';
id = XCore_reg_id(p2);
if (id) {
// base register
if (MI->csh->detail) {
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].type = XCORE_OP_MEM;
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.base = (uint8_t)id;
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.index = XCORE_REG_INVALID;
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.disp = 0;
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.direct = 1;
}
p++;
p2 = p;
// until ']'
while(*p && *p != ']')
p++;
if (*p) {
*p = '\0';
// p2 is either index, or disp
id = XCore_reg_id(p2);
if (id) {
// index register
if (MI->csh->detail) {
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.index = (uint8_t)id;
}
} else {
// a number means disp
if (MI->csh->detail) {
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.disp = atoi(p2);
}
}
}
if (MI->csh->detail) {
MI->flat_insn->detail->xcore.op_count++;
}
}
} else {
// a register?
id = XCore_reg_id(p2);
if (id) {
// register
if (MI->csh->detail) {
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].type = XCORE_OP_REG;
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].reg = id;
MI->flat_insn->detail->xcore.op_count++;
}
}
}
}
} else {
id = XCore_reg_id(p);
if (id) {
// register
if (MI->csh->detail) {
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].type = XCORE_OP_REG;
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].reg = id;
MI->flat_insn->detail->xcore.op_count++;
}
}
}
}
}
static void set_mem_access(MCInst *MI, bool status, int reg)
{
if (MI->csh->detail != CS_OPT_ON)
return;
MI->csh->doing_mem = status;
if (status) {
if (reg != 0xffff && reg != -0xffff) {
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].type = XCORE_OP_MEM;
if (reg) {
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.base = (uint8_t)reg;
} else {
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.base = XCORE_REG_INVALID;
}
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.index = XCORE_REG_INVALID;
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.disp = 0;
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.direct = 1;
} else {
// the last op should be the memory base
MI->flat_insn->detail->xcore.op_count--;
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].type = XCORE_OP_MEM;
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.base = (uint8_t)MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].reg;
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.index = XCORE_REG_INVALID;
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.disp = 0;
if (reg > 0)
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.direct = 1;
else
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.direct = -1;
}
} else {
if (reg) {
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.index = (uint8_t)reg;
// done, create the next operand slot
MI->flat_insn->detail->xcore.op_count++;
}
}
}
static void _printOperand(MCInst *MI, MCOperand *MO, SStream *O)
{
if (MCOperand_isReg(MO)) {
unsigned reg;
reg = MCOperand_getReg(MO);
SStream_concat0(O, getRegisterName(reg));
if (MI->csh->detail) {
if (MI->csh->doing_mem) {
if (MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.base == ARM_REG_INVALID)
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.base = (uint8_t)reg;
else
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.index = (uint8_t)reg;
} else {
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].type = XCORE_OP_REG;
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].reg = reg;
MI->flat_insn->detail->xcore.op_count++;
}
}
} else if (MCOperand_isImm(MO)) {
int32_t Imm = (int32_t)MCOperand_getImm(MO);
if (Imm >= 0) {
if (Imm > HEX_THRESHOLD)
SStream_concat(O, "0x%x", Imm);
else
SStream_concat(O, "%u", Imm);
} else {
if (Imm < -HEX_THRESHOLD)
SStream_concat(O, "-0x%x", -Imm);
else
SStream_concat(O, "-%u", -Imm);
}
if (MI->csh->detail) {
if (MI->csh->doing_mem) {
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].mem.disp = Imm;
} else {
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].type = XCORE_OP_IMM;
MI->flat_insn->detail->xcore.operands[MI->flat_insn->detail->xcore.op_count].imm = Imm;
MI->flat_insn->detail->xcore.op_count++;
}
}
}
}
static void printOperand(MCInst *MI, int OpNum, SStream *O)
{
if (OpNum >= MI->size)
return;
_printOperand(MI, MCInst_getOperand(MI, OpNum), O);
}
static void printInlineJT(MCInst *MI, int OpNum, SStream *O)
{
}
static void printInlineJT32(MCInst *MI, int OpNum, SStream *O)
{
}
#define PRINT_ALIAS_INSTR
#include "XCoreGenAsmWriter.inc"
void XCore_printInst(MCInst *MI, SStream *O, void *Info)
{
printInstruction(MI, O, Info);
set_mem_access(MI, false, 0);
}
#endif