mon/src/mon_z80.cpp

/*
 *  mon_z80.cpp - Z80 disassembler
 *
 *  cxmon (C) 1997-2003 Christian Bauer, Marc Hellwig
 *
 *  This program 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 2 of the License, or
 *  (at your option) any later version.
 *
 *  This program 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., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA
 */

#include "sysdeps.h"

#include <stdarg.h>

#include "mon.h"
#include "mon_disass.h"


// Addressing modes
enum {
        A_IMPL,
        A_IMM8,         // xx
        A_IMM16,        // xxxx
        A_ABS8,         // (xx)
        A_ABS16,        // (xxxx)
        A_REL,          // relative
        A_A,            // a
        A_HL,           // hl or ix or iy
        A_SP,           // sp
        A_REG1,         // 8-bit register (bits 0..2 of opcode) or (hl)/(ix+d)/(iy+d)
        A_REG1X,        // 8-bit register (bits 0..2 of opcode) or (hl)/(ix+d)/(iy+d), don't substitute h or l on prefixes
        A_REG2,         // 8-bit register (bits 3..5 of opcode) or (hl)/(ix+d)/(iy+d)
        A_REG2X,        // 8-bit register (bits 3..5 of opcode) or (hl)/(ix+d)/(iy+d), don't substitute h or l on prefixes
        A_REG3,         // 16-bit register (bits 4..5 of opcode) bc/de/hl/sp
        A_REG4,         // 16-bit register (bits 4..5 of opcode) bc/de/hl/af
        A_COND,         // condition code (bits 3..5 of opcode)
        A_COND2,        // condition code (bits 3..4 of opcode)
        A_BIT,          // bit number (bits 3..5 of opcode)
        A_BIT_REG1,     // bit number (bits 3..5 of opcode) followed by 8-bit register (bits 0..2 of opcode)
        A_RST,          // restart
        A_BC_IND,       // (bc)
        A_DE_IND,       // (de)
        A_HL_IND,       // (hl) or (ix) or (iy)
        A_XY_IND,       // (ix+d) or (iy+d)
        A_SP_IND,       // (sp)
        A_DE_HL,        // de,hl
        A_AF_AF,        // af,af'
};

// Mnemonics
enum {
        M_ADC, M_ADD, M_AND, M_BIT, M_CALL, M_CCF, M_CP, M_CPD, M_CPDR, M_CPI,
        M_CPIR, M_CPL, M_DAA, M_DEC, M_DI, M_DJNZ, M_EI, M_EX, M_EXX, M_HALT,
        M_IM0, M_IM1, M_IM2, M_IN, M_INC, M_IND, M_INDR, M_INI, M_INIR, M_JP,
        M_JR, M_LD, M_LDD, M_LDDR, M_LDI, M_LDIR, M_NEG, M_NOP, M_OR, M_OTDR,
        M_OTIR, M_OUT, M_OUTD, M_OUTI, M_POP, M_PUSH, M_RES, M_RET, M_RETI,
        M_RETN, M_RL, M_RLA, M_RLC, M_RLCA, M_RLD, M_RR, M_RRA, M_RRC, M_RRCA,
        M_RRD, M_RST, M_SBC, M_SCF, M_SET, M_SL1, M_SLA, M_SRA, M_SRL, M_SUB,
        M_XOR,
        M_ILLEGAL,

        M_MAXIMUM
};

// Chars for each mnemonic
static const char mnem_1[] = "aaabccccccccddddeeehiiiiiiiiijjlllllnnoooooopprrrrrrrrrrrrrrrssssssssx?";
static const char mnem_2[] = "ddniacppppppaeijixxammmnnnnnnprdddddeorttuuuoueeeelllllrrrrrsbcellrruo ";
static const char mnem_3[] = "cddtlf ddiilac n  xl    cddii   ddiigp ditttpssttt accd accdtcft1aalbr ";
static const char mnem_4[] = "    l   r r    z   t012   r r    r r   rr di h  in   a    a            ";

// Mnemonic for each opcode
static const char mnemonic[256] = {
        M_NOP , M_LD , M_LD , M_INC    , M_INC , M_DEC    , M_LD  , M_RLCA,     // 00
        M_EX  , M_ADD, M_LD , M_DEC    , M_INC , M_DEC    , M_LD  , M_RRCA,
        M_DJNZ, M_LD , M_LD , M_INC    , M_INC , M_DEC    , M_LD  , M_RLA ,     // 10
        M_JR  , M_ADD, M_LD , M_DEC    , M_INC , M_DEC    , M_LD  , M_RRA ,
        M_JR  , M_LD , M_LD , M_INC    , M_INC , M_DEC    , M_LD  , M_DAA ,     // 20
        M_JR  , M_ADD, M_LD , M_DEC    , M_INC , M_DEC    , M_LD  , M_CPL ,
        M_JR  , M_LD , M_LD , M_INC    , M_INC , M_DEC    , M_LD  , M_SCF ,     // 30
        M_JR  , M_ADD, M_LD , M_DEC    , M_INC , M_DEC    , M_LD  , M_CCF ,
        M_LD  , M_LD , M_LD , M_LD     , M_LD  , M_LD     , M_LD  , M_LD  ,     // 40
        M_LD  , M_LD , M_LD , M_LD     , M_LD  , M_LD     , M_LD  , M_LD  ,
        M_LD  , M_LD , M_LD , M_LD     , M_LD  , M_LD     , M_LD  , M_LD  ,     // 50
        M_LD  , M_LD , M_LD , M_LD     , M_LD  , M_LD     , M_LD  , M_LD  ,
        M_LD  , M_LD , M_LD , M_LD     , M_LD  , M_LD     , M_LD  , M_LD  ,     // 60
        M_LD  , M_LD , M_LD , M_LD     , M_LD  , M_LD     , M_LD  , M_LD  ,
        M_LD  , M_LD , M_LD , M_LD     , M_LD  , M_LD     , M_HALT, M_LD  ,     // 70
        M_LD  , M_LD , M_LD , M_LD     , M_LD  , M_LD     , M_LD  , M_LD  ,
        M_ADD , M_ADD, M_ADD, M_ADD    , M_ADD , M_ADD    , M_ADD , M_ADD ,     // 80
        M_ADC , M_ADC, M_ADC, M_ADC    , M_ADC , M_ADC    , M_ADC , M_ADC ,
        M_SUB , M_SUB, M_SUB, M_SUB    , M_SUB , M_SUB    , M_SUB , M_SUB ,     // 90
        M_SBC , M_SBC, M_SBC, M_SBC    , M_SBC , M_SBC    , M_SBC , M_SBC ,
        M_AND , M_AND, M_AND, M_AND    , M_AND , M_AND    , M_AND , M_AND ,     // a0
        M_XOR , M_XOR, M_XOR, M_XOR    , M_XOR , M_XOR    , M_XOR , M_XOR ,
        M_OR  , M_OR , M_OR , M_OR     , M_OR  , M_OR     , M_OR  , M_OR  ,     // b0
        M_CP  , M_CP , M_CP , M_CP     , M_CP  , M_CP     , M_CP  , M_CP  ,
        M_RET , M_POP, M_JP , M_JP     , M_CALL, M_PUSH   , M_ADD , M_RST ,     // c0
        M_RET , M_RET, M_JP , M_ILLEGAL, M_CALL, M_CALL   , M_ADC , M_RST ,
        M_RET , M_POP, M_JP , M_OUT    , M_CALL, M_PUSH   , M_SUB , M_RST ,     // d0
        M_RET , M_EXX, M_JP , M_IN     , M_CALL, M_ILLEGAL, M_SBC , M_RST ,
        M_RET , M_POP, M_JP , M_EX     , M_CALL, M_PUSH   , M_AND , M_RST ,     // e0
        M_RET , M_JP , M_JP , M_EX     , M_CALL, M_ILLEGAL, M_XOR , M_RST ,
        M_RET , M_POP, M_JP , M_DI     , M_CALL, M_PUSH   , M_OR  , M_RST ,     // f0
        M_RET , M_LD , M_JP , M_EI     , M_CALL, M_ILLEGAL, M_CP  , M_RST
};

// Source/destination addressing modes for each opcode
#define A(d,s) (((A_ ## d) << 8) | (A_ ## s))

static const short adr_mode[256] = {
        A(IMPL,IMPL)  , A(REG3,IMM16) , A(BC_IND,A)  , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) ,       // 00
        A(AF_AF,IMPL) , A(HL,REG3)    , A(A,BC_IND)  , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) ,
        A(REL,IMPL)   , A(REG3,IMM16) , A(DE_IND,A)  , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) ,       // 10
        A(REL,IMPL)   , A(HL,REG3)    , A(A,DE_IND)  , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) ,
        A(COND2,REL)  , A(REG3,IMM16) , A(ABS16,HL)  , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) ,       // 20
        A(COND2,REL)  , A(HL,REG3)    , A(HL,ABS16)  , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) ,
        A(COND2,REL)  , A(REG3,IMM16) , A(ABS16,A)   , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) ,       // 30
        A(COND2,REL)  , A(HL,REG3)    , A(A,ABS16)   , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) ,
        A(REG2,REG1)  , A(REG2,REG1)  , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2X,REG1), A(REG2,REG1) ,       // 40
        A(REG2,REG1)  , A(REG2,REG1)  , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2X,REG1), A(REG2,REG1) ,
        A(REG2,REG1)  , A(REG2,REG1)  , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2X,REG1), A(REG2,REG1) ,       // 50
        A(REG2,REG1)  , A(REG2,REG1)  , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2X,REG1), A(REG2,REG1) ,
        A(REG2,REG1)  , A(REG2,REG1)  , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2X,REG1), A(REG2,REG1) ,       // 60
        A(REG2,REG1)  , A(REG2,REG1)  , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2X,REG1), A(REG2,REG1) ,
        A(REG2,REG1X) , A(REG2,REG1X) , A(REG2,REG1X), A(REG2,REG1X), A(REG2,REG1X), A(REG2,REG1X), A(IMPL,IMPL) , A(REG2,REG1X),       // 70
        A(REG2,REG1)  , A(REG2,REG1)  , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2X,REG1), A(REG2,REG1) ,
        A(A,REG1)     , A(A,REG1)     , A(A,REG1)    , A(A,REG1)    , A(A,REG1)    , A(A,REG1)    , A(A,REG1)    , A(A,REG1)    ,       // 80
        A(A,REG1)     , A(A,REG1)     , A(A,REG1)    , A(A,REG1)    , A(A,REG1)    , A(A,REG1)    , A(A,REG1)    , A(A,REG1)    ,
        A(REG1,IMPL)  , A(REG1,IMPL)  , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) ,       // 90
        A(A,REG1)     , A(A,REG1)     , A(A,REG1)    , A(A,REG1)    , A(A,REG1)    , A(A,REG1)    , A(A,REG1)    , A(A,REG1)    ,
        A(REG1,IMPL)  , A(REG1,IMPL)  , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) ,       // a0
        A(REG1,IMPL)  , A(REG1,IMPL)  , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) ,
        A(REG1,IMPL)  , A(REG1,IMPL)  , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) ,       // b0
        A(REG1,IMPL)  , A(REG1,IMPL)  , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) ,
        A(COND,IMPL)  , A(REG4,IMPL)  , A(COND,IMM16), A(IMM16,IMPL), A(COND,IMM16), A(REG4,IMPL) , A(A,IMM8)    , A(RST,IMPL)  ,       // c0
        A(COND,IMPL)  , A(IMPL,IMPL)  , A(COND,IMM16), A(IMPL,IMPL) , A(COND,IMM16), A(IMM16,IMPL), A(A,IMM8)    , A(RST,IMPL)  ,
        A(COND,IMPL)  , A(REG4,IMPL)  , A(COND,IMM16), A(ABS8,A)    , A(COND,IMM16), A(REG4,IMPL) , A(IMM8,IMPL) , A(RST,IMPL)  ,       // d0
        A(COND,IMPL)  , A(IMPL,IMPL)  , A(COND,IMM16), A(A,ABS8)    , A(COND,IMM16), A(IMPL,IMPL) , A(A,IMM8)    , A(RST,IMPL)  ,
        A(COND,IMPL)  , A(REG4,IMPL)  , A(COND,IMM16), A(SP_IND,HL) , A(COND,IMM16), A(REG4,IMPL) , A(IMM8,IMPL) , A(RST,IMPL)  ,       // e0
        A(COND,IMPL)  , A(HL_IND,IMPL), A(COND,IMM16), A(DE_HL,IMPL), A(COND,IMM16), A(IMPL,IMPL) , A(IMM8,IMPL) , A(RST,IMPL)  ,
        A(COND,IMPL)  , A(REG4,IMPL)  , A(COND,IMM16), A(IMPL,IMPL) , A(COND,IMM16), A(REG4,IMPL) , A(IMM8,IMPL) , A(RST,IMPL)  ,       // f0
        A(COND,IMPL)  , A(SP,HL)      , A(COND,IMM16), A(IMPL,IMPL) , A(COND,IMM16), A(IMPL,IMPL) , A(IMM8,IMPL) , A(RST,IMPL)
};


/*
 *  sprintf into a "stream"
 */

struct SFILE {
        char *buffer;
        char *current;
};

static int mon_sprintf(SFILE *f, const char *format, ...)
{
        int n;
        va_list args;
        va_start(args, format);
        vsprintf(f->current, format, args);
        f->current += n = strlen(f->current);
        va_end(args);
        return n;
}


/*
 *  Disassemble one instruction, return number of bytes
 */

static const char *reg_name[] = {"b", "c", "d", "e", "h", "l", "*", "a"};
static const char *reg_name_ix[] = {"b", "c", "d", "e", "hx", "lx", "*", "a"};  // undoc
static const char *reg_name_iy[] = {"b", "c", "d", "e", "hy", "ly", "*", "a"};  // undoc
static const char *reg_name_16[] = {"bc", "de", "hl", "sp"};
static const char *reg_name_16_2[] = {"bc", "de", "hl", "af"};
static const char *cond_name[] = {"nz", "z", "nc", "c", "po", "pe", "p", "m"};

static void operand(SFILE *f, char mode, uint32 &adr, uint8 op, bool ix, bool iy)
{
        switch (mode) {
                case A_IMPL:
                        break;

                case A_IMM8:
                        mon_sprintf(f, "$%02x", mon_read_byte(adr)); adr++;
                        break;

                case A_IMM16:
                        mon_sprintf(f, "$%04x", (mon_read_byte(adr + 1) << 8) | mon_read_byte(adr)); adr += 2;
                        break;

                case A_ABS8:
                        mon_sprintf(f, "($%02x)", mon_read_byte(adr)); adr++;
                        break;

                case A_ABS16:
                        mon_sprintf(f, "($%04x)", (mon_read_byte(adr + 1) << 8) | mon_read_byte(adr)); adr += 2;
                        break;

                case A_REL:
                        mon_sprintf(f, "$%04x", (adr + 2 + (int8)mon_read_byte(adr)) & 0xffff); adr++;
                        break;

                case A_A:
                        mon_sprintf(f, "a");
                        break;

                case A_HL:
                        mon_sprintf(f, ix ? "ix" : (iy ? "iy" : "hl"));
                        break;

                case A_SP:
                        mon_sprintf(f, "sp");
                        break;

                case A_REG1:
                case A_REG1X: {
                        int reg = op & 7;
                        if (reg == 6) {
                                if (ix || iy) {
                                        mon_sprintf(f, "(%s+$%02x)", ix ? "ix" : "iy", mon_read_byte(adr)); adr++;
                                } else
                                        mon_sprintf(f, "(hl)");
                        } else if (mode == A_REG1)
                                mon_sprintf(f, "%s", ix ? reg_name_ix[reg] : (iy ? reg_name_iy[reg] : reg_name[reg]));
                        else
                                mon_sprintf(f, "%s", reg_name[reg]);
                        break;
                }

                case A_REG2:
                case A_REG2X: {
                        int reg = (op >> 3) & 7;
                        if (reg == 6) {
                                if (ix || iy) {
                                        mon_sprintf(f, "(%s+$%02x)", ix ? "ix" : "iy", mon_read_byte(adr)); adr++;
                                } else
                                        mon_sprintf(f, "(hl)");
                        } else if (mode == A_REG2)
                                mon_sprintf(f, "%s", ix ? reg_name_ix[reg] : (iy ? reg_name_iy[reg] : reg_name[reg]));
                        else
                                mon_sprintf(f, "%s", reg_name[reg]);
                        break;
                }

                case A_REG3:
                        mon_sprintf(f, reg_name_16[(op >> 4) & 3]);
                        break;

                case A_REG4:
                        mon_sprintf(f, reg_name_16_2[(op >> 4) & 3]);
                        break;

                case A_COND:
                        mon_sprintf(f, cond_name[(op >> 3) & 7]);
                        break;

                case A_COND2:
                        mon_sprintf(f, cond_name[(op >> 3) & 3]);
                        break;

                case A_BIT:
                        mon_sprintf(f, "%d", (op >> 3) & 7);
                        break;

                case A_BIT_REG1: { // undoc
                        int reg = op & 7;
                        if (reg == 6)
                                mon_sprintf(f, "%d", (op >> 3) & 7);
                        else
                                mon_sprintf(f, "%d,%s", (op >> 3) & 7, reg_name[reg]);
                        break;
                }

                case A_RST:
                        mon_sprintf(f, "$%02x", op & 0x38);
                        break;

                case A_BC_IND:
                        mon_sprintf(f, "(bc)");
                        break;

                case A_DE_IND:
                        mon_sprintf(f, "(de)");
                        break;

                case A_HL_IND:
                        mon_sprintf(f, ix ? "(ix)" : (iy ? "(iy)" : "(hl)"));
                        break;

                case A_XY_IND: // undoc
                        mon_sprintf(f, "(%s+$%02x)", ix ? "ix" : "iy", mon_read_byte(adr)); adr++;
                        break;

                case A_SP_IND:
                        mon_sprintf(f, "(sp)");
                        break;

                case A_DE_HL:
                        mon_sprintf(f, "de,hl");
                        break;

                case A_AF_AF:
                        mon_sprintf(f, "af,af'");
                        break;
        }
}

static int print_instr(SFILE *f, char mnem, char dst_mode, char src_mode, uint32 adr, uint8 op, bool ix, bool iy)
{
        uint32 orig_adr = adr;

        // Print mnemonic
        mon_sprintf(f, "%c%c%c%c ", mnem_1[mnem], mnem_2[mnem], mnem_3[mnem], mnem_4[mnem]);

        // Print destination operand
        operand(f, dst_mode, adr, op, ix, iy);

        // Print source operand
        if (src_mode != A_IMPL)
                mon_sprintf(f, ",");
        operand(f, src_mode, adr, op, ix, iy);

        return adr - orig_adr;
}

static int disass_cb(SFILE *f, uint32 adr, bool ix, bool iy)
{
        int num;

        // Fetch opcode
        uint8 op;
        if (ix || iy) {
                op = mon_read_byte(adr + 1);
                num = 2;
        } else {
                op = mon_read_byte(adr);
                num = 1;
        }

        // Decode mnemonic and addressing modes
        char mnem = M_ILLEGAL, dst_mode = A_IMPL, src_mode = A_IMPL;
        switch (op & 0xc0) {
                case 0x00:
                        dst_mode = A_REG1X;
                        if ((ix || iy) && ((op & 7) != 6))
                                src_mode = A_XY_IND;
                        switch ((op >> 3) & 7) {
                                case 0: mnem = M_RLC; break;
                                case 1: mnem = M_RRC; break;
                                case 2: mnem = M_RL; break;
                                case 3: mnem = M_RR; break;
                                case 4: mnem = M_SLA; break;
                                case 5: mnem = M_SRA; break;
                                case 6: mnem = M_SL1; break;
                                case 7: mnem = M_SRL; break;
                        }
                        break;
                case 0x40:
                        mnem = M_BIT; dst_mode = A_BIT;
                        if (ix || iy)
                                src_mode = A_XY_IND;
                        else
                                src_mode = A_REG1;
                        break;
                case 0x80:
                        mnem = M_RES;
                        if (ix || iy) {
                                dst_mode = A_BIT_REG1;
                                src_mode = A_XY_IND;
                        } else {
                                dst_mode = A_BIT;
                                src_mode = A_REG1;
                        }
                        break;
                case 0xc0:
                        mnem = M_SET;
                        if (ix || iy) {
                                dst_mode = A_BIT_REG1;
                                src_mode = A_XY_IND;
                        } else {
                                dst_mode = A_BIT;
                                src_mode = A_REG1;
                        }
                        break;
        }

        // Print instruction
        print_instr(f, mnem, dst_mode, src_mode, adr, op, ix, iy);
        return num;
}

static int disass_ed(SFILE *f, uint32 adr)
{
        // Fetch opcode
        uint8 op = mon_read_byte(adr);

        // Decode mnemonic and addressing modes
        char mnem, dst_mode = A_IMPL, src_mode = A_IMPL;
        switch (op) {
                case 0x40:
                case 0x48:
                case 0x50:
                case 0x58:
                case 0x60:
                case 0x68:
                case 0x78:
                        mon_sprintf(f, "in  %s,(c)", reg_name[(op >> 3) & 7]);
                        return 1;
                case 0x70:
                        mon_sprintf(f, "in  (c)");
                        return 1;

                case 0x41:
                case 0x49:
                case 0x51:
                case 0x59:
                case 0x61:
                case 0x69:
                case 0x79:
                        mon_sprintf(f, "out (c),%s", reg_name[(op >> 3) & 7]);
                        return 1;
                case 0x71:      // undoc
                        mon_sprintf(f, "out (c),0");
                        return 1;

                case 0x42:
                case 0x52:
                case 0x62:
                case 0x72:
                        mnem = M_SBC; dst_mode = A_HL; src_mode = A_REG3;
                        break;

                case 0x43:
                case 0x53:
                case 0x63:
                case 0x73:
                        mnem = M_LD; dst_mode = A_ABS16; src_mode = A_REG3;
                        break;

                case 0x4a:
                case 0x5a:
                case 0x6a:
                case 0x7a:
                        mnem = M_ADC; dst_mode = A_HL; src_mode = A_REG3;
                        break;

                case 0x4b:
                case 0x5b:
                case 0x6b:
                case 0x7b:
                        mnem = M_LD; dst_mode = A_REG3; src_mode = A_ABS16;
                        break;

                case 0x44:
                case 0x4c:      // undoc
                case 0x54:      // undoc
                case 0x5c:      // undoc
                case 0x64:      // undoc
                case 0x6c:      // undoc
                case 0x74:      // undoc
                case 0x7c:      // undoc
                        mnem = M_NEG;
                        break;

                case 0x45:
                case 0x55:      // undoc
                case 0x5d:      // undoc
                case 0x65:      // undoc
                case 0x6d:      // undoc
                case 0x75:      // undoc
                case 0x7d:      // undoc
                        mnem = M_RETN;
                        break;
                case 0x4d: mnem = M_RETI; break;

                case 0x46:
                case 0x4e:      // undoc
                case 0x66:      // undoc
                case 0x6e:      // undoc
                        mnem = M_IM0;
                        break;
                case 0x56:
                case 0x76:      // undoc
                        mnem = M_IM1;
                        break;
                case 0x5e:
                case 0x7e:      // undoc
                        mnem = M_IM2;
                        break;

                case 0x47:
                        mon_sprintf(f, "ld  i,a");
                        return 1;
                case 0x4f:
                        mon_sprintf(f, "ld  r,a");
                        return 1;
                case 0x57:
                        mon_sprintf(f, "ld  a,i");
                        return 1;
                case 0x5f:
                        mon_sprintf(f, "ld  a,r");
                        return 1;

                case 0x67: mnem = M_RRD; break;
                case 0x6f: mnem = M_RLD; break;

                case 0xa0: mnem = M_LDI; break;
                case 0xa1: mnem = M_CPI; break;
                case 0xa2: mnem = M_INI; break;
                case 0xa3: mnem = M_OUTI; break;
                case 0xa8: mnem = M_LDD; break;
                case 0xa9: mnem = M_CPD; break;
                case 0xaa: mnem = M_IND; break;
                case 0xab: mnem = M_OUTD; break;
                case 0xb0: mnem = M_LDIR; break;
                case 0xb1: mnem = M_CPIR; break;
                case 0xb2: mnem = M_INIR; break;
                case 0xb3: mnem = M_OTIR; break;
                case 0xb8: mnem = M_LDDR; break;
                case 0xb9: mnem = M_CPDR; break;
                case 0xba: mnem = M_INDR; break;
                case 0xbb: mnem = M_OTDR; break;

                default:
                        mnem = M_NOP;
                        break;
        }

        // Print instruction
        return print_instr(f, mnem, dst_mode, src_mode, adr + 1, op, false, false) + 1;
}

static int disass(SFILE *f, uint32 adr, bool ix, bool iy)
{
        uint8 op = mon_read_byte(adr);
        if (op == 0xcb)
                return disass_cb(f, adr + 1, ix, iy) + 1;
        else
                return print_instr(f, mnemonic[op], adr_mode[op] >> 8, adr_mode[op] & 0xff, adr + 1, op, ix, iy) + 1;
}

int disass_z80(FILE *f, uint32 adr)
{
        int num;
        char buf[64];
        SFILE sfile = {buf, buf};

        switch (mon_read_byte(adr)) {
                case 0xdd:      // ix prefix
                        num = disass(&sfile, adr + 1, true, false) + 1;
                        break;
                case 0xed:
                        num = disass_ed(&sfile, adr + 1) + 1;
                        break;
                case 0xfd:      // iy prefix
                        num = disass(&sfile, adr + 1, false, true) + 1;
                        break;
                default:
                        num = disass(&sfile, adr, false, false);
                        break;
        }

        for (int i=0; i<4; i++) {
                if (num > i)
                        fprintf(f, "%02x ", mon_read_byte(adr + i));
                else
                        fprintf(f, "   ");
        }

        fprintf(f, "\t%s\n", buf);
        return num;
}
Revision:	1.5
Committed:	2003-09-27T20:33:06Z (20 years, 7 months ago) by cebix
Branch:	MAIN
Changes since 1.4:	+1 -1 lines
Log Message:	2002 -> 2003
#	User	Rev	Content
1	cebix	1.1	/*
2			* mon_z80.cpp - Z80 disassembler
3			*
4	cebix	1.5	* cxmon (C) 1997-2003 Christian Bauer, Marc Hellwig
5	cebix	1.1	*
6			* This program is free software; you can redistribute it and/or modify
7			* it under the terms of the GNU General Public License as published by
8			* the Free Software Foundation; either version 2 of the License, or
9			* (at your option) any later version.
10			*
11			* This program is distributed in the hope that it will be useful,
12			* but WITHOUT ANY WARRANTY; without even the implied warranty of
13			* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14			* GNU General Public License for more details.
15			*
16			* You should have received a copy of the GNU General Public License
17			* along with this program; if not, write to the Free Software
18			* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
19			*/
20
21			#include "sysdeps.h"
22
23			#include <stdarg.h>
24
25			#include "mon.h"
26			#include "mon_disass.h"
27
28
29			// Addressing modes
30			enum {
31			A_IMPL,
32			A_IMM8, // xx
33			A_IMM16, // xxxx
34			A_ABS8, // (xx)
35			A_ABS16, // (xxxx)
36			A_REL, // relative
37			A_A, // a
38			A_HL, // hl or ix or iy
39			A_SP, // sp
40			A_REG1, // 8-bit register (bits 0..2 of opcode) or (hl)/(ix+d)/(iy+d)
41			A_REG1X, // 8-bit register (bits 0..2 of opcode) or (hl)/(ix+d)/(iy+d), don't substitute h or l on prefixes
42			A_REG2, // 8-bit register (bits 3..5 of opcode) or (hl)/(ix+d)/(iy+d)
43			A_REG2X, // 8-bit register (bits 3..5 of opcode) or (hl)/(ix+d)/(iy+d), don't substitute h or l on prefixes
44			A_REG3, // 16-bit register (bits 4..5 of opcode) bc/de/hl/sp
45			A_REG4, // 16-bit register (bits 4..5 of opcode) bc/de/hl/af
46			A_COND, // condition code (bits 3..5 of opcode)
47			A_COND2, // condition code (bits 3..4 of opcode)
48			A_BIT, // bit number (bits 3..5 of opcode)
49	cebix	1.4	A_BIT_REG1, // bit number (bits 3..5 of opcode) followed by 8-bit register (bits 0..2 of opcode)
50	cebix	1.1	A_RST, // restart
51			A_BC_IND, // (bc)
52			A_DE_IND, // (de)
53			A_HL_IND, // (hl) or (ix) or (iy)
54	cebix	1.4	A_XY_IND, // (ix+d) or (iy+d)
55	cebix	1.1	A_SP_IND, // (sp)
56			A_DE_HL, // de,hl
57			A_AF_AF, // af,af'
58			};
59
60			// Mnemonics
61			enum {
62			M_ADC, M_ADD, M_AND, M_BIT, M_CALL, M_CCF, M_CP, M_CPD, M_CPDR, M_CPI,
63			M_CPIR, M_CPL, M_DAA, M_DEC, M_DI, M_DJNZ, M_EI, M_EX, M_EXX, M_HALT,
64			M_IM0, M_IM1, M_IM2, M_IN, M_INC, M_IND, M_INDR, M_INI, M_INIR, M_JP,
65			M_JR, M_LD, M_LDD, M_LDDR, M_LDI, M_LDIR, M_NEG, M_NOP, M_OR, M_OTDR,
66			M_OTIR, M_OUT, M_OUTD, M_OUTI, M_POP, M_PUSH, M_RES, M_RET, M_RETI,
67			M_RETN, M_RL, M_RLA, M_RLC, M_RLCA, M_RLD, M_RR, M_RRA, M_RRC, M_RRCA,
68			M_RRD, M_RST, M_SBC, M_SCF, M_SET, M_SL1, M_SLA, M_SRA, M_SRL, M_SUB,
69			M_XOR,
70			M_ILLEGAL,
71
72			M_MAXIMUM
73			};
74
75			// Chars for each mnemonic
76			static const char mnem_1[] = "aaabccccccccddddeeehiiiiiiiiijjlllllnnoooooopprrrrrrrrrrrrrrrssssssssx?";
77			static const char mnem_2[] = "ddniacppppppaeijixxammmnnnnnnprdddddeorttuuuoueeeelllllrrrrrsbcellrruo ";
78			static const char mnem_3[] = "cddtlf ddiilac n xl cddii ddiigp ditttpssttt accd accdtcft1aalbr ";
79			static const char mnem_4[] = " l r r z t012 r r r r rr di h in a a ";
80
81			// Mnemonic for each opcode
82			static const char mnemonic[256] = {
83			M_NOP , M_LD , M_LD , M_INC , M_INC , M_DEC , M_LD , M_RLCA, // 00
84			M_EX , M_ADD, M_LD , M_DEC , M_INC , M_DEC , M_LD , M_RRCA,
85			M_DJNZ, M_LD , M_LD , M_INC , M_INC , M_DEC , M_LD , M_RLA , // 10
86			M_JR , M_ADD, M_LD , M_DEC , M_INC , M_DEC , M_LD , M_RRA ,
87			M_JR , M_LD , M_LD , M_INC , M_INC , M_DEC , M_LD , M_DAA , // 20
88			M_JR , M_ADD, M_LD , M_DEC , M_INC , M_DEC , M_LD , M_CPL ,
89			M_JR , M_LD , M_LD , M_INC , M_INC , M_DEC , M_LD , M_SCF , // 30
90			M_JR , M_ADD, M_LD , M_DEC , M_INC , M_DEC , M_LD , M_CCF ,
91			M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , // 40
92			M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , M_LD ,
93			M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , // 50
94			M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , M_LD ,
95			M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , // 60
96			M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , M_LD ,
97			M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , M_HALT, M_LD , // 70
98			M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , M_LD , M_LD ,
99			M_ADD , M_ADD, M_ADD, M_ADD , M_ADD , M_ADD , M_ADD , M_ADD , // 80
100			M_ADC , M_ADC, M_ADC, M_ADC , M_ADC , M_ADC , M_ADC , M_ADC ,
101			M_SUB , M_SUB, M_SUB, M_SUB , M_SUB , M_SUB , M_SUB , M_SUB , // 90
102			M_SBC , M_SBC, M_SBC, M_SBC , M_SBC , M_SBC , M_SBC , M_SBC ,
103			M_AND , M_AND, M_AND, M_AND , M_AND , M_AND , M_AND , M_AND , // a0
104			M_XOR , M_XOR, M_XOR, M_XOR , M_XOR , M_XOR , M_XOR , M_XOR ,
105			M_OR , M_OR , M_OR , M_OR , M_OR , M_OR , M_OR , M_OR , // b0
106			M_CP , M_CP , M_CP , M_CP , M_CP , M_CP , M_CP , M_CP ,
107			M_RET , M_POP, M_JP , M_JP , M_CALL, M_PUSH , M_ADD , M_RST , // c0
108			M_RET , M_RET, M_JP , M_ILLEGAL, M_CALL, M_CALL , M_ADC , M_RST ,
109			M_RET , M_POP, M_JP , M_OUT , M_CALL, M_PUSH , M_SUB , M_RST , // d0
110			M_RET , M_EXX, M_JP , M_IN , M_CALL, M_ILLEGAL, M_SBC , M_RST ,
111			M_RET , M_POP, M_JP , M_EX , M_CALL, M_PUSH , M_AND , M_RST , // e0
112			M_RET , M_JP , M_JP , M_EX , M_CALL, M_ILLEGAL, M_XOR , M_RST ,
113			M_RET , M_POP, M_JP , M_DI , M_CALL, M_PUSH , M_OR , M_RST , // f0
114			M_RET , M_LD , M_JP , M_EI , M_CALL, M_ILLEGAL, M_CP , M_RST
115			};
116
117			// Source/destination addressing modes for each opcode
118			#define A(d,s) (((A_ ## d) << 8) \| (A_ ## s))
119
120			static const short adr_mode[256] = {
121			A(IMPL,IMPL) , A(REG3,IMM16) , A(BC_IND,A) , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) , // 00
122			A(AF_AF,IMPL) , A(HL,REG3) , A(A,BC_IND) , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) ,
123			A(REL,IMPL) , A(REG3,IMM16) , A(DE_IND,A) , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) , // 10
124			A(REL,IMPL) , A(HL,REG3) , A(A,DE_IND) , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) ,
125			A(COND2,REL) , A(REG3,IMM16) , A(ABS16,HL) , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) , // 20
126			A(COND2,REL) , A(HL,REG3) , A(HL,ABS16) , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) ,
127			A(COND2,REL) , A(REG3,IMM16) , A(ABS16,A) , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) , // 30
128			A(COND2,REL) , A(HL,REG3) , A(A,ABS16) , A(REG3,IMPL) , A(REG2,IMPL) , A(REG2,IMPL) , A(REG2,IMM8) , A(IMPL,IMPL) ,
129			A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2X,REG1), A(REG2,REG1) , // 40
130			A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2X,REG1), A(REG2,REG1) ,
131			A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2X,REG1), A(REG2,REG1) , // 50
132			A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2X,REG1), A(REG2,REG1) ,
133			A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2X,REG1), A(REG2,REG1) , // 60
134			A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2X,REG1), A(REG2,REG1) ,
135			A(REG2,REG1X) , A(REG2,REG1X) , A(REG2,REG1X), A(REG2,REG1X), A(REG2,REG1X), A(REG2,REG1X), A(IMPL,IMPL) , A(REG2,REG1X), // 70
136			A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2,REG1) , A(REG2X,REG1), A(REG2,REG1) ,
137			A(A,REG1) , A(A,REG1) , A(A,REG1) , A(A,REG1) , A(A,REG1) , A(A,REG1) , A(A,REG1) , A(A,REG1) , // 80
138			A(A,REG1) , A(A,REG1) , A(A,REG1) , A(A,REG1) , A(A,REG1) , A(A,REG1) , A(A,REG1) , A(A,REG1) ,
139			A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , // 90
140			A(A,REG1) , A(A,REG1) , A(A,REG1) , A(A,REG1) , A(A,REG1) , A(A,REG1) , A(A,REG1) , A(A,REG1) ,
141			A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , // a0
142			A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) ,
143			A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , // b0
144			A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) , A(REG1,IMPL) ,
145			A(COND,IMPL) , A(REG4,IMPL) , A(COND,IMM16), A(IMM16,IMPL), A(COND,IMM16), A(REG4,IMPL) , A(A,IMM8) , A(RST,IMPL) , // c0
146			A(COND,IMPL) , A(IMPL,IMPL) , A(COND,IMM16), A(IMPL,IMPL) , A(COND,IMM16), A(IMM16,IMPL), A(A,IMM8) , A(RST,IMPL) ,
147			A(COND,IMPL) , A(REG4,IMPL) , A(COND,IMM16), A(ABS8,A) , A(COND,IMM16), A(REG4,IMPL) , A(IMM8,IMPL) , A(RST,IMPL) , // d0
148			A(COND,IMPL) , A(IMPL,IMPL) , A(COND,IMM16), A(A,ABS8) , A(COND,IMM16), A(IMPL,IMPL) , A(A,IMM8) , A(RST,IMPL) ,
149			A(COND,IMPL) , A(REG4,IMPL) , A(COND,IMM16), A(SP_IND,HL) , A(COND,IMM16), A(REG4,IMPL) , A(IMM8,IMPL) , A(RST,IMPL) , // e0
150			A(COND,IMPL) , A(HL_IND,IMPL), A(COND,IMM16), A(DE_HL,IMPL), A(COND,IMM16), A(IMPL,IMPL) , A(IMM8,IMPL) , A(RST,IMPL) ,
151			A(COND,IMPL) , A(REG4,IMPL) , A(COND,IMM16), A(IMPL,IMPL) , A(COND,IMM16), A(REG4,IMPL) , A(IMM8,IMPL) , A(RST,IMPL) , // f0
152			A(COND,IMPL) , A(SP,HL) , A(COND,IMM16), A(IMPL,IMPL) , A(COND,IMM16), A(IMPL,IMPL) , A(IMM8,IMPL) , A(RST,IMPL)
153			};
154
155
156			/*
157			* sprintf into a "stream"
158			*/
159
160			struct SFILE {
161			char *buffer;
162			char *current;
163			};
164
165			static int mon_sprintf(SFILE f, const char format, ...)
166			{
167			int n;
168			va_list args;
169			va_start(args, format);
170			vsprintf(f->current, format, args);
171			f->current += n = strlen(f->current);
172			va_end(args);
173			return n;
174			}
175
176
177			/*
178			* Disassemble one instruction, return number of bytes
179			*/
180
181			static const char reg_name[] = {"b", "c", "d", "e", "h", "l", "", "a"};
182			static const char reg_name_ix[] = {"b", "c", "d", "e", "hx", "lx", "", "a"}; // undoc
183			static const char reg_name_iy[] = {"b", "c", "d", "e", "hy", "ly", "", "a"}; // undoc
184			static const char *reg_name_16[] = {"bc", "de", "hl", "sp"};
185			static const char *reg_name_16_2[] = {"bc", "de", "hl", "af"};
186			static const char *cond_name[] = {"nz", "z", "nc", "c", "po", "pe", "p", "m"};
187
188			static void operand(SFILE *f, char mode, uint32 &adr, uint8 op, bool ix, bool iy)
189			{
190			switch (mode) {
191			case A_IMPL:
192			break;
193
194			case A_IMM8:
195			mon_sprintf(f, "$%02x", mon_read_byte(adr)); adr++;
196			break;
197
198			case A_IMM16:
199			mon_sprintf(f, "$%04x", (mon_read_byte(adr + 1) << 8) \| mon_read_byte(adr)); adr += 2;
200			break;
201
202			case A_ABS8:
203			mon_sprintf(f, "($%02x)", mon_read_byte(adr)); adr++;
204			break;
205
206			case A_ABS16:
207			mon_sprintf(f, "($%04x)", (mon_read_byte(adr + 1) << 8) \| mon_read_byte(adr)); adr += 2;
208			break;
209
210			case A_REL:
211			mon_sprintf(f, "$%04x", (adr + 2 + (int8)mon_read_byte(adr)) & 0xffff); adr++;
212			break;
213
214			case A_A:
215			mon_sprintf(f, "a");
216			break;
217
218			case A_HL:
219			mon_sprintf(f, ix ? "ix" : (iy ? "iy" : "hl"));
220			break;
221
222			case A_SP:
223			mon_sprintf(f, "sp");
224			break;
225
226			case A_REG1:
227			case A_REG1X: {
228			int reg = op & 7;
229			if (reg == 6) {
230			if (ix \|\| iy) {
231			mon_sprintf(f, "(%s+$%02x)", ix ? "ix" : "iy", mon_read_byte(adr)); adr++;
232			} else
233			mon_sprintf(f, "(hl)");
234			} else if (mode == A_REG1)
235			mon_sprintf(f, "%s", ix ? reg_name_ix[reg] : (iy ? reg_name_iy[reg] : reg_name[reg]));
236			else
237			mon_sprintf(f, "%s", reg_name[reg]);
238			break;
239			}
240
241			case A_REG2:
242			case A_REG2X: {
243			int reg = (op >> 3) & 7;
244			if (reg == 6) {
245			if (ix \|\| iy) {
246			mon_sprintf(f, "(%s+$%02x)", ix ? "ix" : "iy", mon_read_byte(adr)); adr++;
247			} else
248			mon_sprintf(f, "(hl)");
249			} else if (mode == A_REG2)
250			mon_sprintf(f, "%s", ix ? reg_name_ix[reg] : (iy ? reg_name_iy[reg] : reg_name[reg]));
251			else
252			mon_sprintf(f, "%s", reg_name[reg]);
253			break;
254			}
255
256			case A_REG3:
257			mon_sprintf(f, reg_name_16[(op >> 4) & 3]);
258			break;
259
260			case A_REG4:
261			mon_sprintf(f, reg_name_16_2[(op >> 4) & 3]);
262			break;
263
264			case A_COND:
265			mon_sprintf(f, cond_name[(op >> 3) & 7]);
266			break;
267
268			case A_COND2:
269			mon_sprintf(f, cond_name[(op >> 3) & 3]);
270			break;
271
272			case A_BIT:
273			mon_sprintf(f, "%d", (op >> 3) & 7);
274			break;
275
276	cebix	1.4	case A_BIT_REG1: { // undoc
277			int reg = op & 7;
278			if (reg == 6)
279			mon_sprintf(f, "%d", (op >> 3) & 7);
280			else
281			mon_sprintf(f, "%d,%s", (op >> 3) & 7, reg_name[reg]);
282			break;
283			}
284
285	cebix	1.1	case A_RST:
286			mon_sprintf(f, "$%02x", op & 0x38);
287			break;
288
289			case A_BC_IND:
290			mon_sprintf(f, "(bc)");
291			break;
292
293			case A_DE_IND:
294			mon_sprintf(f, "(de)");
295			break;
296
297			case A_HL_IND:
298			mon_sprintf(f, ix ? "(ix)" : (iy ? "(iy)" : "(hl)"));
299			break;
300
301	cebix	1.4	case A_XY_IND: // undoc
302			mon_sprintf(f, "(%s+$%02x)", ix ? "ix" : "iy", mon_read_byte(adr)); adr++;
303			break;
304
305	cebix	1.1	case A_SP_IND:
306			mon_sprintf(f, "(sp)");
307			break;
308
309			case A_DE_HL:
310			mon_sprintf(f, "de,hl");
311			break;
312
313			case A_AF_AF:
314			mon_sprintf(f, "af,af'");
315			break;
316			}
317			}
318
319			static int print_instr(SFILE *f, char mnem, char dst_mode, char src_mode, uint32 adr, uint8 op, bool ix, bool iy)
320			{
321			uint32 orig_adr = adr;
322
323			// Print mnemonic
324			mon_sprintf(f, "%c%c%c%c ", mnem_1[mnem], mnem_2[mnem], mnem_3[mnem], mnem_4[mnem]);
325
326			// Print destination operand
327			operand(f, dst_mode, adr, op, ix, iy);
328
329			// Print source operand
330			if (src_mode != A_IMPL)
331			mon_sprintf(f, ",");
332			operand(f, src_mode, adr, op, ix, iy);
333
334			return adr - orig_adr;
335			}
336
337			static int disass_cb(SFILE *f, uint32 adr, bool ix, bool iy)
338			{
339			int num;
340
341			// Fetch opcode
342			uint8 op;
343			if (ix \|\| iy) {
344			op = mon_read_byte(adr + 1);
345			num = 2;
346			} else {
347			op = mon_read_byte(adr);
348			num = 1;
349			}
350
351			// Decode mnemonic and addressing modes
352	cebix	1.2	char mnem = M_ILLEGAL, dst_mode = A_IMPL, src_mode = A_IMPL;
353	cebix	1.1	switch (op & 0xc0) {
354			case 0x00:
355	cebix	1.4	dst_mode = A_REG1X;
356			if ((ix \|\| iy) && ((op & 7) != 6))
357			src_mode = A_XY_IND;
358	cebix	1.1	switch ((op >> 3) & 7) {
359			case 0: mnem = M_RLC; break;
360			case 1: mnem = M_RRC; break;
361			case 2: mnem = M_RL; break;
362			case 3: mnem = M_RR; break;
363			case 4: mnem = M_SLA; break;
364			case 5: mnem = M_SRA; break;
365			case 6: mnem = M_SL1; break;
366			case 7: mnem = M_SRL; break;
367			}
368			break;
369			case 0x40:
370	cebix	1.4	mnem = M_BIT; dst_mode = A_BIT;
371			if (ix \|\| iy)
372			src_mode = A_XY_IND;
373			else
374			src_mode = A_REG1;
375	cebix	1.1	break;
376			case 0x80:
377	cebix	1.4	mnem = M_RES;
378			if (ix \|\| iy) {
379			dst_mode = A_BIT_REG1;
380			src_mode = A_XY_IND;
381			} else {
382			dst_mode = A_BIT;
383			src_mode = A_REG1;
384			}
385	cebix	1.1	break;
386			case 0xc0:
387	cebix	1.4	mnem = M_SET;
388			if (ix \|\| iy) {
389			dst_mode = A_BIT_REG1;
390			src_mode = A_XY_IND;
391			} else {
392			dst_mode = A_BIT;
393			src_mode = A_REG1;
394			}
395	cebix	1.1	break;
396			}
397
398			// Print instruction
399			print_instr(f, mnem, dst_mode, src_mode, adr, op, ix, iy);
400			return num;
401			}
402
403			static int disass_ed(SFILE *f, uint32 adr)
404			{
405			// Fetch opcode
406			uint8 op = mon_read_byte(adr);
407
408			// Decode mnemonic and addressing modes
409			char mnem, dst_mode = A_IMPL, src_mode = A_IMPL;
410			switch (op) {
411			case 0x40:
412			case 0x48:
413			case 0x50:
414			case 0x58:
415			case 0x60:
416			case 0x68:
417			case 0x78:
418	cebix	1.4	mon_sprintf(f, "in %s,(c)", reg_name[(op >> 3) & 7]);
419	cebix	1.1	return 1;
420			case 0x70:
421	cebix	1.4	mon_sprintf(f, "in (c)");
422	cebix	1.1	return 1;
423
424			case 0x41:
425			case 0x49:
426			case 0x51:
427			case 0x59:
428			case 0x61:
429			case 0x69:
430			case 0x79:
431	cebix	1.4	mon_sprintf(f, "out (c),%s", reg_name[(op >> 3) & 7]);
432	cebix	1.1	return 1;
433			case 0x71: // undoc
434	cebix	1.4	mon_sprintf(f, "out (c),0");
435	cebix	1.1	return 1;
436
437			case 0x42:
438			case 0x52:
439			case 0x62:
440			case 0x72:
441			mnem = M_SBC; dst_mode = A_HL; src_mode = A_REG3;
442			break;
443
444			case 0x43:
445			case 0x53:
446			case 0x63:
447			case 0x73:
448			mnem = M_LD; dst_mode = A_ABS16; src_mode = A_REG3;
449			break;
450
451			case 0x4a:
452			case 0x5a:
453			case 0x6a:
454			case 0x7a:
455			mnem = M_ADC; dst_mode = A_HL; src_mode = A_REG3;
456			break;
457
458			case 0x4b:
459			case 0x5b:
460			case 0x6b:
461			case 0x7b:
462			mnem = M_LD; dst_mode = A_REG3; src_mode = A_ABS16;
463			break;
464
465			case 0x44:
466			case 0x4c: // undoc
467			case 0x54: // undoc
468			case 0x5c: // undoc
469			case 0x64: // undoc
470			case 0x6c: // undoc
471			case 0x74: // undoc
472			case 0x7c: // undoc
473			mnem = M_NEG;
474			break;
475
476			case 0x45:
477			case 0x55: // undoc
478			case 0x5d: // undoc
479			case 0x65: // undoc
480			case 0x6d: // undoc
481			case 0x75: // undoc
482			case 0x7d: // undoc
483			mnem = M_RETN;
484			break;
485			case 0x4d: mnem = M_RETI; break;
486
487			case 0x46:
488			case 0x4e: // undoc
489			case 0x66: // undoc
490			case 0x6e: // undoc
491			mnem = M_IM0;
492			break;
493			case 0x56:
494			case 0x76: // undoc
495			mnem = M_IM1;
496			break;
497			case 0x5e:
498			case 0x7e: // undoc
499			mnem = M_IM2;
500			break;
501
502			case 0x47:
503	cebix	1.4	mon_sprintf(f, "ld i,a");
504	cebix	1.1	return 1;
505			case 0x4f:
506	cebix	1.4	mon_sprintf(f, "ld r,a");
507	cebix	1.1	return 1;
508			case 0x57:
509	cebix	1.4	mon_sprintf(f, "ld a,i");
510	cebix	1.1	return 1;
511			case 0x5f:
512	cebix	1.4	mon_sprintf(f, "ld a,r");
513	cebix	1.1	return 1;
514
515			case 0x67: mnem = M_RRD; break;
516			case 0x6f: mnem = M_RLD; break;
517
518			case 0xa0: mnem = M_LDI; break;
519			case 0xa1: mnem = M_CPI; break;
520			case 0xa2: mnem = M_INI; break;
521			case 0xa3: mnem = M_OUTI; break;
522			case 0xa8: mnem = M_LDD; break;
523			case 0xa9: mnem = M_CPD; break;
524			case 0xaa: mnem = M_IND; break;
525			case 0xab: mnem = M_OUTD; break;
526			case 0xb0: mnem = M_LDIR; break;
527			case 0xb1: mnem = M_CPIR; break;
528			case 0xb2: mnem = M_INIR; break;
529			case 0xb3: mnem = M_OTIR; break;
530			case 0xb8: mnem = M_LDDR; break;
531			case 0xb9: mnem = M_CPDR; break;
532			case 0xba: mnem = M_INDR; break;
533			case 0xbb: mnem = M_OTDR; break;
534
535			default:
536	cebix	1.4	mnem = M_NOP;
537	cebix	1.1	break;
538			}
539
540			// Print instruction
541			return print_instr(f, mnem, dst_mode, src_mode, adr + 1, op, false, false) + 1;
542			}
543
544			static int disass(SFILE *f, uint32 adr, bool ix, bool iy)
545			{
546			uint8 op = mon_read_byte(adr);
547			if (op == 0xcb)
548			return disass_cb(f, adr + 1, ix, iy) + 1;
549			else
550			return print_instr(f, mnemonic[op], adr_mode[op] >> 8, adr_mode[op] & 0xff, adr + 1, op, ix, iy) + 1;
551			}
552
553			int disass_z80(FILE *f, uint32 adr)
554			{
555			int num;
556			char buf[64];
557			SFILE sfile = {buf, buf};
558
559			switch (mon_read_byte(adr)) {
560			case 0xdd: // ix prefix
561			num = disass(&sfile, adr + 1, true, false) + 1;
562			break;
563			case 0xed:
564			num = disass_ed(&sfile, adr + 1) + 1;
565			break;
566			case 0xfd: // iy prefix
567			num = disass(&sfile, adr + 1, false, true) + 1;
568			break;
569			default:
570			num = disass(&sfile, adr, false, false);
571			break;
572			}
573
574			for (int i=0; i<4; i++) {
575			if (num > i)
576			fprintf(f, "%02x ", mon_read_byte(adr + i));
577			else
578			fprintf(f, " ");
579			}
580
581			fprintf(f, "\t%s\n", buf);
582			return num;
583			}