[pf3gnuchains/pf3gnuchains3x.git] / opcodes / i960-dis.c

/* Disassemble i80960 instructions.
   Copyright (C) 1990, 91, 93, 94, 95, 96, 1998 Free Software Foundation, Inc.

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, 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; see the file COPYING.  If not, write to the
Free Software Foundation, 59 Temple Place - Suite 330, Boston, MA
02111-1307, USA.  */

#include "sysdep.h"
#include "dis-asm.h"

static const char *const reg_names[] = {
/*  0 */        "pfp", "sp",  "rip", "r3",  "r4",  "r5",  "r6",  "r7", 
/*  8 */        "r8",  "r9",  "r10", "r11", "r12", "r13", "r14", "r15",
/* 16 */        "g0",  "g1",  "g2",  "g3",  "g4",  "g5",  "g6",  "g7", 
/* 24 */        "g8",  "g9",  "g10", "g11", "g12", "g13", "g14", "fp", 
/* 32 */        "pc",  "ac",  "ip",  "tc",  "fp0", "fp1", "fp2", "fp3" 
};


static FILE *stream;            /* Output goes here */
static struct disassemble_info *info;
static void print_addr();
static void ctrl();
static void cobr();
static void reg();
static int mem();
static void ea();
static void dstop();
static void regop();
static void invalid();
static int pinsn();
static void put_abs();


/* Print the i960 instruction at address 'memaddr' in debugged memory,
   on INFO->STREAM.  Returns length of the instruction, in bytes.  */

int
print_insn_i960 (memaddr, info_arg)
    bfd_vma memaddr;
    struct disassemble_info *info_arg;
{
  unsigned int word1, word2 = 0xdeadbeef;
  bfd_byte buffer[8];
  int status;

  info = info_arg;
  stream = info->stream;

  /* Read word1.  Only read word2 if the instruction
     needs it, to prevent reading past the end of a section.  */

  status = (*info->read_memory_func) (memaddr, (bfd_byte *) buffer, 4, info);
  if (status != 0)
    {
      (*info->memory_error_func) (status, memaddr, info);
      return -1;
    }

  word1 = bfd_getl32 (buffer);

  /* Divide instruction set into classes based on high 4 bits of opcode.  */
  switch ( (word1 >> 28) & 0xf )
    {
    default:
      break;
    case 0x8:
    case 0x9:
    case 0xa:
    case 0xb:
    case 0xc:
      /* Read word2.  */
      status = (*info->read_memory_func)
        (memaddr + 4, (bfd_byte *) (buffer + 4), 4, info);
      if (status != 0)
        {
          (*info->memory_error_func) (status, memaddr, info);
          return -1;
        }
      word2 = bfd_getl32 (buffer + 4);
      break;
    }

  return pinsn( memaddr, word1, word2 );
}
\f
#define IN_GDB

/*****************************************************************************
 *      All code below this point should be identical with that of
 *      the disassembler in gdmp960.

 A noble sentiment, but at least in cosmetic ways (info->fprintf_func), it
 just ain't so. -kingdon, 31 Mar 93
 *****************************************************************************/

struct tabent {
  char *name;
  short numops;
};

struct sparse_tabent {
  int opcode;
  char *name;
  short numops;
};

static int
pinsn( memaddr, word1, word2 )
    bfd_vma memaddr;
    unsigned long word1, word2;
{
        int instr_len;

        instr_len = 4;
        put_abs( word1, word2 );

        /* Divide instruction set into classes based on high 4 bits of opcode*/
        switch ( (word1 >> 28) & 0xf ){
        case 0x0:
        case 0x1:
                ctrl( memaddr, word1, word2 );
                break;
        case 0x2:
        case 0x3:
                cobr( memaddr, word1, word2 );
                break;
        case 0x5:
        case 0x6:
        case 0x7:
                reg( word1 );
                break;
        case 0x8:
        case 0x9:
        case 0xa:
        case 0xb:
        case 0xc:
                instr_len = mem( memaddr, word1, word2, 0 );
                break;
        default:
                /* invalid instruction, print as data word */ 
                invalid( word1 );
                break;
        }
        return instr_len;
}

/****************************************/
/* CTRL format                          */
/****************************************/
static void
ctrl( memaddr, word1, word2 )
    bfd_vma memaddr;
    unsigned long word1, word2;
{
        int i;
        static const struct tabent ctrl_tab[] = {
          { NULL,               0, },   /* 0x00 */
          { NULL,               0, },   /* 0x01 */
          { NULL,               0, },   /* 0x02 */
          { NULL,               0, },   /* 0x03 */
          { NULL,               0, },   /* 0x04 */
          { NULL,               0, },   /* 0x05 */
          { NULL,               0, },   /* 0x06 */
          { NULL,               0, },   /* 0x07 */
          { "b",                1, },   /* 0x08 */
          { "call",             1, },   /* 0x09 */
          { "ret",              0, },   /* 0x0a */
          { "bal",              1, },   /* 0x0b */
          { NULL,               0, },   /* 0x0c */
          { NULL,               0, },   /* 0x0d */
          { NULL,               0, },   /* 0x0e */
          { NULL,               0, },   /* 0x0f */
          { "bno",              1, },   /* 0x10 */
          { "bg",               1, },   /* 0x11 */
          { "be",               1, },   /* 0x12 */
          { "bge",              1, },   /* 0x13 */
          { "bl",               1, },   /* 0x14 */
          { "bne",              1, },   /* 0x15 */
          { "ble",              1, },   /* 0x16 */
          { "bo",               1, },   /* 0x17 */
          { "faultno",          0, },   /* 0x18 */
          { "faultg",           0, },   /* 0x19 */
          { "faulte",           0, },   /* 0x1a */
          { "faultge",          0, },   /* 0x1b */
          { "faultl",           0, },   /* 0x1c */
          { "faultne",          0, },   /* 0x1d */
          { "faultle",          0, },   /* 0x1e */
          { "faulto",           0, },   /* 0x1f */
        };

        i = (word1 >> 24) & 0xff;
        if ( (ctrl_tab[i].name == NULL) || ((word1 & 1) != 0) ){
                invalid( word1 );
                return;
        }

        (*info->fprintf_func) ( stream, ctrl_tab[i].name );
        if ( word1 & 2 ){               /* Predicts branch not taken */
                (*info->fprintf_func) ( stream, ".f" );
        }

        if ( ctrl_tab[i].numops == 1 ){
                /* EXTRACT DISPLACEMENT AND CONVERT TO ADDRESS */
                word1 &= 0x00ffffff;
                if ( word1 & 0x00800000 ){              /* Sign bit is set */
                        word1 |= (-1 & ~0xffffff);      /* Sign extend */
                }
                (*info->fprintf_func)( stream, "\t" );
                print_addr( word1 + memaddr );
        }
}

/****************************************/
/* COBR format                          */
/****************************************/
static void
cobr( memaddr, word1, word2 )
    bfd_vma memaddr;
    unsigned long word1, word2;
{
        int src1;
        int src2;
        int i;

        static const struct tabent cobr_tab[] = {
          { "testno",   1, },   /* 0x20 */
          { "testg",    1, },   /* 0x21 */
          { "teste",    1, },   /* 0x22 */
          { "testge",   1, },   /* 0x23 */
          { "testl",    1, },   /* 0x24 */
          { "testne",   1, },   /* 0x25 */
          { "testle",   1, },   /* 0x26 */
          { "testo",    1, },   /* 0x27 */
          { NULL,       0, },   /* 0x28 */
          { NULL,       0, },   /* 0x29 */
          { NULL,       0, },   /* 0x2a */
          { NULL,       0, },   /* 0x2b */
          { NULL,       0, },   /* 0x2c */
          { NULL,       0, },   /* 0x2d */
          { NULL,       0, },   /* 0x2e */
          { NULL,       0, },   /* 0x2f */
          { "bbc",      3, },   /* 0x30 */
          { "cmpobg",   3, },   /* 0x31 */
          { "cmpobe",   3, },   /* 0x32 */
          { "cmpobge",  3, },   /* 0x33 */
          { "cmpobl",   3, },   /* 0x34 */
          { "cmpobne",  3, },   /* 0x35 */
          { "cmpoble",  3, },   /* 0x36 */
          { "bbs",      3, },   /* 0x37 */
          { "cmpibno",  3, },   /* 0x38 */
          { "cmpibg",   3, },   /* 0x39 */
          { "cmpibe",   3, },   /* 0x3a */
          { "cmpibge",  3, },   /* 0x3b */
          { "cmpibl",   3, },   /* 0x3c */
          { "cmpibne",  3, },   /* 0x3d */
          { "cmpible",  3, },   /* 0x3e */
          { "cmpibo",   3, },   /* 0x3f */
        };

        i = ((word1 >> 24) & 0xff) - 0x20;
        if ( cobr_tab[i].name == NULL ){
                invalid( word1 );
                return;
        }

        (*info->fprintf_func) ( stream, cobr_tab[i].name );
        if ( word1 & 2 ){               /* Predicts branch not taken */
                (*info->fprintf_func) ( stream, ".f" );
        }
        (*info->fprintf_func)( stream, "\t" );

        src1 = (word1 >> 19) & 0x1f;
        src2 = (word1 >> 14) & 0x1f;

        if ( word1 & 0x02000 ){         /* M1 is 1 */
                (*info->fprintf_func)( stream, "%d", src1 );
        } else {                        /* M1 is 0 */
                (*info->fprintf_func)( stream, reg_names[src1] );
        }

        if ( cobr_tab[i].numops > 1 ){
                if ( word1 & 1 ){               /* S2 is 1 */
                        (*info->fprintf_func)( stream, ",sf%d,", src2 );
                } else {                        /* S1 is 0 */
                        (*info->fprintf_func)( stream, ",%s,", reg_names[src2] );
                }

                /* Extract displacement and convert to address
                 */
                word1 &= 0x00001ffc;
                if ( word1 & 0x00001000 ){      /* Negative displacement */
                        word1 |= (-1 & ~0x1fff);        /* Sign extend */
                }
                print_addr( memaddr + word1 );
        }
}

/****************************************/
/* MEM format                           */
/****************************************/
static int                              /* returns instruction length: 4 or 8 */
mem( memaddr, word1, word2, noprint )
    bfd_vma memaddr;
    unsigned long word1, word2;
    int noprint;                /* If TRUE, return instruction length, but
                                 * don't output any text.
                                 */
{
        int i, j;
        int len;
        int mode;
        int offset;
        const char *reg1, *reg2, *reg3;

        /* This lookup table is too sparse to make it worth typing in, but not
           so large as to make a sparse array necessary.  We create the table
           at runtime.  */

        /*
         * NOTE: In this table, the meaning of 'numops' is:
         *       1: single operand
         *       2: 2 operands, load instruction
         *      -2: 2 operands, store instruction
         */
        static struct tabent *mem_tab;
/* Opcodes of 0x8X, 9X, aX, bX, and cX must be in the table.  */
#define MEM_MIN 0x80
#define MEM_MAX 0xcf
#define MEM_SIZ ( * sizeof(struct tabent))

        static const struct sparse_tabent mem_init[] = {
          { 0x80,       "ldob",  2 },
          { 0x82,       "stob", -2 },
          { 0x84,       "bx",    1 },
          { 0x85,       "balx",  2 },
          { 0x86,       "callx", 1 },
          { 0x88,       "ldos",  2 },
          { 0x8a,       "stos", -2 },
          { 0x8c,       "lda",   2 },
          { 0x90,       "ld",    2 },
          { 0x92,       "st",   -2 },
          { 0x98,       "ldl",   2 },
          { 0x9a,       "stl",  -2 },
          { 0xa0,       "ldt",   2 },
          { 0xa2,       "stt",  -2 },
          { 0xac,       "dcinva", 1 },
          { 0xb0,       "ldq",   2 },
          { 0xb2,       "stq",  -2 },
          { 0xc0,       "ldib",  2 },
          { 0xc2,       "stib", -2 },
          { 0xc8,       "ldis",  2 },
          { 0xca,       "stis", -2 },
          { 0,          NULL,   0 }
        };
        static struct tabent mem_tab_buf[MEM_MAX - MEM_MIN + 1];

        if ( mem_tab == NULL ){
                mem_tab = mem_tab_buf;
                for ( i = 0; mem_init[i].opcode != 0; i++ ){
                        j = mem_init[i].opcode - MEM_MIN;
                        mem_tab[j].name = mem_init[i].name;
                        mem_tab[j].numops = mem_init[i].numops;
                }
        }

        i = ((word1 >> 24) & 0xff) - MEM_MIN;
        mode = (word1 >> 10) & 0xf;

        if ( (mem_tab[i].name != NULL)          /* Valid instruction */
        &&   ((mode == 5) || (mode >=12)) ){    /* With 32-bit displacement */
                len = 8;
        } else {
                len = 4;
        }

        if ( noprint ){
                return len;
        }

        if ( (mem_tab[i].name == NULL) || (mode == 6) ){
                invalid( word1 );
                return len;
        }

        (*info->fprintf_func)( stream, "%s\t", mem_tab[i].name );

        reg1 = reg_names[ (word1 >> 19) & 0x1f ];       /* MEMB only */
        reg2 = reg_names[ (word1 >> 14) & 0x1f ];
        reg3 = reg_names[ word1 & 0x1f ];               /* MEMB only */
        offset = word1 & 0xfff;                         /* MEMA only  */

        switch ( mem_tab[i].numops ){

        case 2: /* LOAD INSTRUCTION */
                if ( mode & 4 ){                        /* MEMB FORMAT */
                        ea( memaddr, mode, reg2, reg3, word1, word2 );
                        (*info->fprintf_func)( stream, ",%s", reg1 );
                } else {                                /* MEMA FORMAT */
                        (*info->fprintf_func)( stream, "0x%x", (unsigned) offset );
                        if (mode & 8) {
                                (*info->fprintf_func)( stream, "(%s)", reg2 );
                        }
                        (*info->fprintf_func)( stream, ",%s", reg1 );
                }
                break;

        case -2: /* STORE INSTRUCTION */
                if ( mode & 4 ){                        /* MEMB FORMAT */
                        (*info->fprintf_func)( stream, "%s,", reg1 );
                        ea( memaddr, mode, reg2, reg3, word1, word2 );
                } else {                                /* MEMA FORMAT */
                        (*info->fprintf_func)( stream, "%s,0x%x", reg1, (unsigned) offset );
                        if (mode & 8) {
                                (*info->fprintf_func)( stream, "(%s)", reg2 );
                        }
                }
                break;

        case 1: /* BX/CALLX INSTRUCTION */
                if ( mode & 4 ){                        /* MEMB FORMAT */
                        ea( memaddr, mode, reg2, reg3, word1, word2 );
                } else {                                /* MEMA FORMAT */
                        (*info->fprintf_func)( stream, "0x%x", (unsigned) offset );
                        if (mode & 8) {
                                (*info->fprintf_func)( stream, "(%s)", reg2 );
                        }
                }
                break;
        }

        return len;
}

/****************************************/
/* REG format                           */
/****************************************/
static void
reg( word1 )
    unsigned long word1;
{
        int i, j;
        int opcode;
        int fp;
        int m1, m2, m3;
        int s1, s2;
        int src, src2, dst;
        char *mnemp;

        /* This lookup table is too sparse to make it worth typing in, but not
           so large as to make a sparse array necessary.  We create the table
           at runtime.  */

        /*
         * NOTE: In this table, the meaning of 'numops' is:
         *       1: single operand, which is NOT a destination.
         *      -1: single operand, which IS a destination.
         *       2: 2 operands, the 2nd of which is NOT a destination.
         *      -2: 2 operands, the 2nd of which IS a destination.
         *       3: 3 operands
         *
         *      If an opcode mnemonic begins with "F", it is a floating-point
         *      opcode (the "F" is not printed).
         */

        static struct tabent *reg_tab;
        static const struct sparse_tabent reg_init[] = {
#define REG_MIN 0x580
          { 0x580,      "notbit",       3 },
          { 0x581,      "and",          3 },
          { 0x582,      "andnot",       3 },
          { 0x583,      "setbit",       3 },
          { 0x584,      "notand",       3 },
          { 0x586,      "xor",          3 },
          { 0x587,      "or",           3 },
          { 0x588,      "nor",          3 },
          { 0x589,      "xnor",         3 },
          { 0x58a,      "not",          -2 },
          { 0x58b,      "ornot",        3 },
          { 0x58c,      "clrbit",       3 },
          { 0x58d,      "notor",        3 },
          { 0x58e,      "nand",         3 },
          { 0x58f,      "alterbit",     3 },
          { 0x590,      "addo",         3 },
          { 0x591,      "addi",         3 },
          { 0x592,      "subo",         3 },
          { 0x593,      "subi",         3 },
          { 0x594,      "cmpob",        2 },
          { 0x595,      "cmpib",        2 },
          { 0x596,      "cmpos",        2 },
          { 0x597,      "cmpis",        2 },
          { 0x598,      "shro",         3 },
          { 0x59a,      "shrdi",        3 },
          { 0x59b,      "shri",         3 },
          { 0x59c,      "shlo",         3 },
          { 0x59d,      "rotate",       3 },
          { 0x59e,      "shli",         3 },
          { 0x5a0,      "cmpo",         2 },
          { 0x5a1,      "cmpi",         2 },
          { 0x5a2,      "concmpo",      2 },
          { 0x5a3,      "concmpi",      2 },
          { 0x5a4,      "cmpinco",      3 },
          { 0x5a5,      "cmpinci",      3 },
          { 0x5a6,      "cmpdeco",      3 },
          { 0x5a7,      "cmpdeci",      3 },
          { 0x5ac,      "scanbyte",     2 },
          { 0x5ad,      "bswap",        -2 },
          { 0x5ae,      "chkbit",       2 },
          { 0x5b0,      "addc",         3 },
          { 0x5b2,      "subc",         3 },
          { 0x5b4,      "intdis",       0 },
          { 0x5b5,      "inten",        0 },
          { 0x5cc,      "mov",          -2 },
          { 0x5d8,      "eshro",        3 },
          { 0x5dc,      "movl",         -2 },
          { 0x5ec,      "movt",         -2 },
          { 0x5fc,      "movq",         -2 },
          { 0x600,      "synmov",       2 },
          { 0x601,      "synmovl",      2 },
          { 0x602,      "synmovq",      2 },
          { 0x603,      "cmpstr",       3 },
          { 0x604,      "movqstr",      3 },
          { 0x605,      "movstr",       3 },
          { 0x610,      "atmod",        3 },
          { 0x612,      "atadd",        3 },
          { 0x613,      "inspacc",      -2 },
          { 0x614,      "ldphy",        -2 },
          { 0x615,      "synld",        -2 },
          { 0x617,      "fill",         3 },
          { 0x630,      "sdma",         3 },
          { 0x631,      "udma",         0 },
          { 0x640,      "spanbit",      -2 },
          { 0x641,      "scanbit",      -2 },
          { 0x642,      "daddc",        3 },
          { 0x643,      "dsubc",        3 },
          { 0x644,      "dmovt",        -2 },
          { 0x645,      "modac",        3 },
          { 0x646,      "condrec",      -2 },
          { 0x650,      "modify",       3 },
          { 0x651,      "extract",      3 },
          { 0x654,      "modtc",        3 },
          { 0x655,      "modpc",        3 },
          { 0x656,      "receive",      -2 },
          { 0x658,      "intctl",       -2 },
          { 0x659,      "sysctl",       3 },
          { 0x65b,      "icctl",        3 },
          { 0x65c,      "dcctl",        3 },
          { 0x65d,      "halt",         0 },
          { 0x660,      "calls",        1 },
          { 0x662,      "send",         3 },
          { 0x663,      "sendserv",     1 },
          { 0x664,      "resumprcs",    1 },
          { 0x665,      "schedprcs",    1 },
          { 0x666,      "saveprcs",     0 },
          { 0x668,      "condwait",     1 },
          { 0x669,      "wait",         1 },
          { 0x66a,      "signal",       1 },
          { 0x66b,      "mark",         0 },
          { 0x66c,      "fmark",        0 },
          { 0x66d,      "flushreg",     0 },
          { 0x66f,      "syncf",        0 },
          { 0x670,      "emul",         3 },
          { 0x671,      "ediv",         3 },
          { 0x673,      "ldtime",       -1 },
          { 0x674,      "Fcvtir",       -2 },
          { 0x675,      "Fcvtilr",      -2 },
          { 0x676,      "Fscalerl",     3 },
          { 0x677,      "Fscaler",      3 },
          { 0x680,      "Fatanr",       3 },
          { 0x681,      "Flogepr",      3 },
          { 0x682,      "Flogr",        3 },
          { 0x683,      "Fremr",        3 },
          { 0x684,      "Fcmpor",       2 },
          { 0x685,      "Fcmpr",        2 },
          { 0x688,      "Fsqrtr",       -2 },
          { 0x689,      "Fexpr",        -2 },
          { 0x68a,      "Flogbnr",      -2 },
          { 0x68b,      "Froundr",      -2 },
          { 0x68c,      "Fsinr",        -2 },
          { 0x68d,      "Fcosr",        -2 },
          { 0x68e,      "Ftanr",        -2 },
          { 0x68f,      "Fclassr",      1 },
          { 0x690,      "Fatanrl",      3 },
          { 0x691,      "Flogeprl",     3 },
          { 0x692,      "Flogrl",       3 },
          { 0x693,      "Fremrl",       3 },
          { 0x694,      "Fcmporl",      2 },
          { 0x695,      "Fcmprl",       2 },
          { 0x698,      "Fsqrtrl",      -2 },
          { 0x699,      "Fexprl",       -2 },
          { 0x69a,      "Flogbnrl",     -2 },
          { 0x69b,      "Froundrl",     -2 },
          { 0x69c,      "Fsinrl",       -2 },
          { 0x69d,      "Fcosrl",       -2 },
          { 0x69e,      "Ftanrl",       -2 },
          { 0x69f,      "Fclassrl",     1 },
          { 0x6c0,      "Fcvtri",       -2 },
          { 0x6c1,      "Fcvtril",      -2 },
          { 0x6c2,      "Fcvtzri",      -2 },
          { 0x6c3,      "Fcvtzril",     -2 },
          { 0x6c9,      "Fmovr",        -2 },
          { 0x6d9,      "Fmovrl",       -2 },
          { 0x6e1,      "Fmovre",       -2 },
          { 0x6e2,      "Fcpysre",      3 },
          { 0x6e3,      "Fcpyrsre",     3 },
          { 0x701,      "mulo",         3 },
          { 0x708,      "remo",         3 },
          { 0x70b,      "divo",         3 },
          { 0x741,      "muli",         3 },
          { 0x748,      "remi",         3 },
          { 0x749,      "modi",         3 },
          { 0x74b,      "divi",         3 },
          { 0x780,      "addono",       3 },
          { 0x781,      "addino",       3 },
          { 0x782,      "subono",       3 },
          { 0x783,      "subino",       3 },
          { 0x784,      "selno",        3 },
          { 0x78b,      "Fdivr",        3 },
          { 0x78c,      "Fmulr",        3 },
          { 0x78d,      "Fsubr",        3 },
          { 0x78f,      "Faddr",        3 },
          { 0x790,      "addog",        3 },
          { 0x791,      "addig",        3 },
          { 0x792,      "subog",        3 },
          { 0x793,      "subig",        3 },
          { 0x794,      "selg",         3 },
          { 0x79b,      "Fdivrl",       3 },
          { 0x79c,      "Fmulrl",       3 },
          { 0x79d,      "Fsubrl",       3 },
          { 0x79f,      "Faddrl",       3 },
          { 0x7a0,      "addoe",        3 },
          { 0x7a1,      "addie",        3 },
          { 0x7a2,      "suboe",        3 },
          { 0x7a3,      "subie",        3 },
          { 0x7a4,      "sele",         3 },
          { 0x7b0,      "addoge",       3 },
          { 0x7b1,      "addige",       3 },
          { 0x7b2,      "suboge",       3 },
          { 0x7b3,      "subige",       3 },
          { 0x7b4,      "selge",        3 },
          { 0x7c0,      "addol",        3 },
          { 0x7c1,      "addil",        3 },
          { 0x7c2,      "subol",        3 },
          { 0x7c3,      "subil",        3 },
          { 0x7c4,      "sell",         3 },
          { 0x7d0,      "addone",       3 },
          { 0x7d1,      "addine",       3 },
          { 0x7d2,      "subone",       3 },
          { 0x7d3,      "subine",       3 },
          { 0x7d4,      "selne",        3 },
          { 0x7e0,      "addole",       3 },
          { 0x7e1,      "addile",       3 },
          { 0x7e2,      "subole",       3 },
          { 0x7e3,      "subile",       3 },
          { 0x7e4,      "selle",        3 },
          { 0x7f0,      "addoo",        3 },
          { 0x7f1,      "addio",        3 },
          { 0x7f2,      "suboo",        3 },
          { 0x7f3,      "subio",        3 },
          { 0x7f4,      "selo",         3 },
#define REG_MAX 0x7f4
          { 0,          NULL,           0 }
        };
        static struct tabent reg_tab_buf[REG_MAX - REG_MIN + 1];

        if ( reg_tab == NULL ){
                reg_tab = reg_tab_buf;
                for ( i = 0; reg_init[i].opcode != 0; i++ ){
                        j = reg_init[i].opcode - REG_MIN;
                        reg_tab[j].name = reg_init[i].name;
                        reg_tab[j].numops = reg_init[i].numops;
                }
        }

        opcode = ((word1 >> 20) & 0xff0) | ((word1 >> 7) & 0xf);
        i = opcode - REG_MIN;

        if ( (opcode<REG_MIN) || (opcode>REG_MAX) || (reg_tab[i].name==NULL) ){
                invalid( word1 );
                return;
        }

        mnemp = reg_tab[i].name;
        if ( *mnemp == 'F' ){
                fp = 1;
                mnemp++;
        } else {
                fp = 0;
        }

        (*info->fprintf_func)( stream, mnemp );

        s1   = (word1 >> 5)  & 1;
        s2   = (word1 >> 6)  & 1;
        m1   = (word1 >> 11) & 1;
        m2   = (word1 >> 12) & 1;
        m3   = (word1 >> 13) & 1;
        src  =  word1        & 0x1f;
        src2 = (word1 >> 14) & 0x1f;
        dst  = (word1 >> 19) & 0x1f;

        if  ( reg_tab[i].numops != 0 ){
                (*info->fprintf_func)( stream, "\t" );

                switch ( reg_tab[i].numops ){
                case 1:
                        regop( m1, s1, src, fp );
                        break;
                case -1:
                        dstop( m3, dst, fp );
                        break;
                case 2:
                        regop( m1, s1, src, fp );
                        (*info->fprintf_func)( stream, "," );
                        regop( m2, s2, src2, fp );
                        break;
                case -2:
                        regop( m1, s1, src, fp );
                        (*info->fprintf_func)( stream, "," );
                        dstop( m3, dst, fp );
                        break;
                case 3:
                        regop( m1, s1, src, fp );
                        (*info->fprintf_func)( stream, "," );
                        regop( m2, s2, src2, fp );
                        (*info->fprintf_func)( stream, "," );
                        dstop( m3, dst, fp );
                        break;
                }
        }
}


/*
 * Print out effective address for memb instructions.
 */
static void
ea( memaddr, mode, reg2, reg3, word1, word2 )
     bfd_vma memaddr;
     int mode;
     char *reg2, *reg3;
     int word1;
     unsigned int word2;
{
        int scale;
        static const int scale_tab[] = { 1, 2, 4, 8, 16 };

        scale = (word1 >> 7) & 0x07;
        if ( (scale > 4) || (((word1 >> 5) & 0x03) != 0) ){
                invalid( word1 );
                return;
        }
        scale = scale_tab[scale];

        switch (mode) {
        case 4:                                         /* (reg) */
                (*info->fprintf_func)( stream, "(%s)", reg2 );
                break;
        case 5:                                         /* displ+8(ip) */
                print_addr( word2+8+memaddr );
                break;
        case 7:                                         /* (reg)[index*scale] */
                if (scale == 1) {
                        (*info->fprintf_func)( stream, "(%s)[%s]", reg2, reg3 );
                } else {
                        (*info->fprintf_func)( stream, "(%s)[%s*%d]",reg2,reg3,scale);
                }
                break;
        case 12:                                        /* displacement */
                print_addr( (bfd_vma)word2 );
                break;
        case 13:                                        /* displ(reg) */
                print_addr( (bfd_vma)word2 );
                (*info->fprintf_func)( stream, "(%s)", reg2 );
                break;
        case 14:                                        /* displ[index*scale] */
                print_addr( (bfd_vma)word2 );
                if (scale == 1) {
                        (*info->fprintf_func)( stream, "[%s]", reg3 );
                } else {
                        (*info->fprintf_func)( stream, "[%s*%d]", reg3, scale );
                }
                break;
        case 15:                                /* displ(reg)[index*scale] */
                print_addr( (bfd_vma)word2 );
                if (scale == 1) {
                        (*info->fprintf_func)( stream, "(%s)[%s]", reg2, reg3 );
                } else {
                        (*info->fprintf_func)( stream, "(%s)[%s*%d]",reg2,reg3,scale );
                }
                break;
        default:
                invalid( word1 );
                return;
        }
}


/************************************************/
/* Register Instruction Operand                 */
/************************************************/
static void
regop( mode, spec, reg, fp )
    int mode, spec, reg, fp;
{
        if ( fp ){                              /* FLOATING POINT INSTRUCTION */
                if ( mode == 1 ){                       /* FP operand */
                        switch ( reg ){
                        case 0:  (*info->fprintf_func)( stream, "fp0" );
                          break;
                        case 1:  (*info->fprintf_func)( stream, "fp1" );
                          break;
                        case 2:  (*info->fprintf_func)( stream, "fp2" );
                          break;
                        case 3:  (*info->fprintf_func)( stream, "fp3" );
                          break;
                        case 16: (*info->fprintf_func)( stream, "0f0.0" );
                          break;
                        case 22: (*info->fprintf_func)( stream, "0f1.0" );
                          break;
                        default: (*info->fprintf_func)( stream, "?" );
                          break;
                        }
                } else {                                /* Non-FP register */
                        (*info->fprintf_func)( stream, reg_names[reg] );
                }
        } else {                                /* NOT FLOATING POINT */
                if ( mode == 1 ){                       /* Literal */
                        (*info->fprintf_func)( stream, "%d", reg );
                } else {                                /* Register */
                        if ( spec == 0 ){
                                (*info->fprintf_func)( stream, reg_names[reg] );
                        } else {
                                (*info->fprintf_func)( stream, "sf%d", reg );
                        }
                }
        }
}

/************************************************/
/* Register Instruction Destination Operand     */
/************************************************/
static void
dstop( mode, reg, fp )
    int mode, reg, fp;
{
        /* 'dst' operand can't be a literal. On non-FP instructions,  register
         * mode is assumed and "m3" acts as if were "s3";  on FP-instructions,
         * sf registers are not allowed so m3 acts normally.
         */
         if ( fp ){
                regop( mode, 0, reg, fp );
         } else {
                regop( 0, mode, reg, fp );
         }
}


static void
invalid( word1 )
    int word1;
{
        (*info->fprintf_func)( stream, ".word\t0x%08x", (unsigned) word1 );
}       

static void
print_addr(a)
bfd_vma a;
{
  (*info->print_address_func) (a, info);
}

static void
put_abs( word1, word2 )
    unsigned long word1, word2;
{
#ifdef IN_GDB
        return;
#else
        int len;

        switch ( (word1 >> 28) & 0xf ){
        case 0x8:
        case 0x9:
        case 0xa:
        case 0xb:
        case 0xc:
                /* MEM format instruction */
                len = mem( 0, word1, word2, 1 );
                break;
        default:
                len = 4;
                break;
        }

        if ( len == 8 ){
                (*info->fprintf_func)( stream, "%08x %08x\t", word1, word2 );
        } else {
                (*info->fprintf_func)( stream, "%08x         \t", word1 );
        }
;

#endif
}