/* Disassembler code for Renesas RL78. Copyright (C) 2011-2016 Free Software Foundation, Inc. Contributed by Red Hat. Written by DJ Delorie. This file is part of the GNU opcodes library. This library 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, or (at your option) any later version. It 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, write to the Free Software Foundation, Inc., 51 Franklin Street - Fifth Floor, Boston, MA 02110-1301, USA. */ #include "sysdep.h" #include #include "bfd.h" #include "elf-bfd.h" #include "dis-asm.h" #include "opcode/rl78.h" #include "elf/rl78.h" #define DEBUG_SEMANTICS 0 typedef struct { bfd_vma pc; disassemble_info * dis; } RL78_Data; static int rl78_get_byte (void * vdata) { bfd_byte buf[1]; RL78_Data *rl78_data = (RL78_Data *) vdata; rl78_data->dis->read_memory_func (rl78_data->pc, buf, 1, rl78_data->dis); rl78_data->pc ++; return buf[0]; } static char const * register_names[] = { "", "x", "a", "c", "b", "e", "d", "l", "h", "ax", "bc", "de", "hl", "sp", "psw", "cs", "es", "pmc", "mem" }; static char const * condition_names[] = { "t", "f", "c", "nc", "h", "nh", "z", "nz" }; static int indirect_type (int t) { switch (t) { case RL78_Operand_Indirect: case RL78_Operand_BitIndirect: case RL78_Operand_PostInc: case RL78_Operand_PreDec: return 1; default: return 0; } } static int print_insn_rl78_common (bfd_vma addr, disassemble_info * dis, RL78_Dis_Isa isa) { int rv; RL78_Data rl78_data; RL78_Opcode_Decoded opcode; const char * s; #if DEBUG_SEMANTICS static char buf[200]; #endif rl78_data.pc = addr; rl78_data.dis = dis; rv = rl78_decode_opcode (addr, &opcode, rl78_get_byte, &rl78_data, isa); dis->bytes_per_line = 10; #define PR (dis->fprintf_func) #define PS (dis->stream) #define PC(c) PR (PS, "%c", c) s = opcode.syntax; #if DEBUG_SEMANTICS switch (opcode.id) { case RLO_unknown: s = "uknown"; break; case RLO_add: s = "add: %e0%0 += %e1%1"; break; case RLO_addc: s = "addc: %e0%0 += %e1%1 + CY"; break; case RLO_and: s = "and: %e0%0 &= %e1%1"; break; case RLO_branch: s = "branch: pc = %e0%0"; break; case RLO_branch_cond: s = "branch_cond: pc = %e0%0 if %c1 / %e1%1"; break; case RLO_branch_cond_clear: s = "branch_cond_clear: pc = %e0%0 if %c1 / %e1%1, %e1%1 = 0"; break; case RLO_call: s = "call: pc = %e1%0"; break; case RLO_cmp: s = "cmp: %e0%0 - %e1%1"; break; case RLO_mov: s = "mov: %e0%0 = %e1%1"; break; case RLO_or: s = "or: %e0%0 |= %e1%1"; break; case RLO_rol: s = "rol: %e0%0 <<= %e1%1"; break; case RLO_rolc: s = "rol: %e0%0 <<= %e1%1,CY"; break; case RLO_ror: s = "ror: %e0%0 >>= %e1%1"; break; case RLO_rorc: s = "ror: %e0%0 >>= %e1%1,CY"; break; case RLO_sar: s = "sar: %e0%0 >>= %e1%1 signed"; break; case RLO_sel: s = "sel: rb = %1"; break; case RLO_shr: s = "shr: %e0%0 >>= %e1%1 unsigned"; break; case RLO_shl: s = "shl: %e0%0 <<= %e1%1"; break; case RLO_skip: s = "skip: if %c1"; break; case RLO_sub: s = "sub: %e0%0 -= %e1%1"; break; case RLO_subc: s = "subc: %e0%0 -= %e1%1 - CY"; break; case RLO_xch: s = "xch: %e0%0 <-> %e1%1"; break; case RLO_xor: s = "xor: %e0%0 ^= %e1%1"; break; } sprintf(buf, "%s%%W%%f\t\033[32m%s\033[0m", s, opcode.syntax); s = buf; #endif for (; *s; s++) { if (*s != '%') { PC (*s); } else { RL78_Opcode_Operand * oper; int do_hex = 0; int do_addr = 0; int do_es = 0; int do_sfr = 0; int do_cond = 0; int do_bang = 0; while (1) { s ++; switch (*s) { case 'x': do_hex = 1; break; case '!': do_bang = 1; break; case 'e': do_es = 1; break; case 'a': do_addr = 1; break; case 's': do_sfr = 1; break; case 'c': do_cond = 1; break; default: goto no_more_modifiers; } } no_more_modifiers:; switch (*s) { case '%': PC ('%'); break; #if DEBUG_SEMANTICS case 'W': if (opcode.size == RL78_Word) PR (PS, " \033[33mW\033[0m"); break; case 'f': if (opcode.flags) { char *comma = ""; PR (PS, " \033[35m"); if (opcode.flags & RL78_PSW_Z) { PR (PS, "Z"); comma = ","; } if (opcode.flags & RL78_PSW_AC) { PR (PS, "%sAC", comma); comma = ","; } if (opcode.flags & RL78_PSW_CY) { PR (PS, "%sCY", comma); comma = ","; } PR (PS, "\033[0m"); } break; #endif case '0': case '1': oper = *s == '0' ? &opcode.op[0] : &opcode.op[1]; if (do_es) { if (oper->use_es && indirect_type (oper->type)) PR (PS, "es:"); } if (do_bang) PC ('!'); if (do_cond) { PR (PS, "%s", condition_names[oper->condition]); break; } switch (oper->type) { case RL78_Operand_Immediate: if (do_addr) dis->print_address_func (oper->addend, dis); else if (do_hex || oper->addend > 999 || oper->addend < -999) PR (PS, "%#x", oper->addend); else PR (PS, "%d", oper->addend); break; case RL78_Operand_Register: PR (PS, "%s", register_names[oper->reg]); break; case RL78_Operand_Bit: PR (PS, "%s.%d", register_names[oper->reg], oper->bit_number); break; case RL78_Operand_Indirect: case RL78_Operand_BitIndirect: switch (oper->reg) { case RL78_Reg_None: if (oper->addend == 0xffffa && do_sfr && opcode.size == RL78_Byte) PR (PS, "psw"); else if (oper->addend == 0xffff8 && do_sfr && opcode.size == RL78_Word) PR (PS, "sp"); else if (oper->addend == 0xffff8 && do_sfr && opcode.size == RL78_Byte) PR (PS, "spl"); else if (oper->addend == 0xffff9 && do_sfr && opcode.size == RL78_Byte) PR (PS, "sph"); else if (oper->addend == 0xffffc && do_sfr && opcode.size == RL78_Byte) PR (PS, "cs"); else if (oper->addend == 0xffffd && do_sfr && opcode.size == RL78_Byte) PR (PS, "es"); else if (oper->addend == 0xffffe && do_sfr && opcode.size == RL78_Byte) PR (PS, "pmc"); else if (oper->addend == 0xfffff && do_sfr && opcode.size == RL78_Byte) PR (PS, "mem"); else if (oper->addend >= 0xffe20) PR (PS, "%#x", oper->addend); else { int faddr = oper->addend; if (do_es && ! oper->use_es) faddr += 0xf0000; dis->print_address_func (faddr, dis); } break; case RL78_Reg_B: case RL78_Reg_C: case RL78_Reg_BC: PR (PS, "%d[%s]", oper->addend, register_names[oper->reg]); break; default: PR (PS, "[%s", register_names[oper->reg]); if (oper->reg2 != RL78_Reg_None) PR (PS, "+%s", register_names[oper->reg2]); if (oper->addend || do_addr) PR (PS, "+%d", oper->addend); PC (']'); break; } if (oper->type == RL78_Operand_BitIndirect) PR (PS, ".%d", oper->bit_number); break; #if DEBUG_SEMANTICS /* Shouldn't happen - push and pop don't print [SP] directly. But we *do* use them for semantic debugging. */ case RL78_Operand_PostInc: PR (PS, "[%s++]", register_names[oper->reg]); break; case RL78_Operand_PreDec: PR (PS, "[--%s]", register_names[oper->reg]); break; #endif default: /* If we ever print this, that means the programmer tried to print an operand with a type we don't expect. Print the line and operand number from rl78-decode.opc for them. */ PR (PS, "???%d.%d", opcode.lineno, *s - '0'); break; } } } } #if DEBUG_SEMANTICS PR (PS, "\t\033[34m(line %d)\033[0m", opcode.lineno); #endif return rv; } int print_insn_rl78 (bfd_vma addr, disassemble_info * dis) { return print_insn_rl78_common (addr, dis, RL78_ISA_DEFAULT); } int print_insn_rl78_g10 (bfd_vma addr, disassemble_info * dis) { return print_insn_rl78_common (addr, dis, RL78_ISA_G10); } int print_insn_rl78_g13 (bfd_vma addr, disassemble_info * dis) { return print_insn_rl78_common (addr, dis, RL78_ISA_G13); } int print_insn_rl78_g14 (bfd_vma addr, disassemble_info * dis) { return print_insn_rl78_common (addr, dis, RL78_ISA_G14); } disassembler_ftype rl78_get_disassembler (bfd *abfd) { int cpu = abfd->tdata.elf_obj_data->elf_header->e_flags & E_FLAG_RL78_CPU_MASK; switch (cpu) { case E_FLAG_RL78_G10: return print_insn_rl78_g10; case E_FLAG_RL78_G13: return print_insn_rl78_g13; case E_FLAG_RL78_G14: return print_insn_rl78_g14; default: return print_insn_rl78; } }