* config/tc-mcore.c (mcore_pool_count): New function.

[binutils.git] / opcodes / tic4x-dis.c

/* Print instructions for the Texas TMS320C[34]X, for GDB and GNU Binutils.

   Copyright 2002 Free Software Foundation, Inc.

   Contributed by Michael P. Hayes (m.hayes@elec.canterbury.ac.nz)
   
   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 <math.h>
#include "libiberty.h"
#include "dis-asm.h"
#include "opcode/tic4x.h"

#define C4X_DEBUG 0

#define C4X_HASH_SIZE   11   /* 11 (bits) and above should give unique entries.  */
#define C4X_SPESOP_SIZE 8    /* Max 8. ops for special instructions */

typedef enum
  {
    IMMED_SINT,
    IMMED_SUINT,
    IMMED_SFLOAT,
    IMMED_INT,
    IMMED_UINT,
    IMMED_FLOAT
  }
immed_t;

typedef enum
  {
    INDIRECT_SHORT,
    INDIRECT_LONG,
    INDIRECT_C4X
  }
indirect_t;

static int c4x_version = 0;
static int c4x_dp = 0;

static int c4x_pc_offset
  PARAMS ((unsigned int));
static int c4x_print_char
  PARAMS ((struct disassemble_info *, char));
static int c4x_print_str
  PARAMS ((struct disassemble_info *, char *));
static int c4x_print_register
  PARAMS ((struct disassemble_info *, unsigned long));
static int c4x_print_addr
  PARAMS ((struct disassemble_info *, unsigned long));
static int c4x_print_relative
  PARAMS ((struct disassemble_info *, unsigned long, long, unsigned long));
void c4x_print_ftoa
  PARAMS ((unsigned int, FILE *, fprintf_ftype));
static int c4x_print_direct
  PARAMS ((struct disassemble_info *, unsigned long));
static int c4x_print_immed
  PARAMS ((struct disassemble_info *, immed_t, unsigned long));
static int c4x_print_cond
  PARAMS ((struct disassemble_info *, unsigned int));
static int c4x_print_indirect
  PARAMS ((struct disassemble_info *, indirect_t, unsigned long));
static int c4x_print_op
  PARAMS ((struct disassemble_info *, unsigned long, c4x_inst_t *, unsigned long));
static void c4x_hash_opcode_special
  PARAMS ((c4x_inst_t **, const c4x_inst_t *));
static void c4x_hash_opcode
  PARAMS ((c4x_inst_t **, c4x_inst_t **, const c4x_inst_t *, unsigned long));
static int c4x_disassemble
  PARAMS ((unsigned long, unsigned long, struct disassemble_info *));
int print_insn_tic4x
  PARAMS ((bfd_vma, struct disassemble_info *));


static int
c4x_pc_offset (op)
     unsigned int op;
{
  /* Determine the PC offset for a C[34]x instruction.
     This could be simplified using some boolean algebra
     but at the expense of readability.  */
  switch (op >> 24)
    {
    case 0x60:  /* br */
    case 0x62:  /* call  (C4x) */
    case 0x64:  /* rptb  (C4x) */
      return 1;
    case 0x61:  /* brd */
    case 0x63:  /* laj */
    case 0x65:  /* rptbd (C4x) */
      return 3;
    case 0x66:  /* swi */
    case 0x67:
      return 0;
    default:
      break;
    }
  
  switch ((op & 0xffe00000) >> 20)
    {
    case 0x6a0: /* bB */
    case 0x720: /* callB */
    case 0x740: /* trapB */
      return 1;
      
    case 0x6a2: /* bBd */
    case 0x6a6: /* bBat */
    case 0x6aa: /* bBaf */
    case 0x722: /* lajB */
    case 0x748: /* latB */
    case 0x798: /* rptbd */
      return 3;
      
    default:
      break;
    }
  
  switch ((op & 0xfe200000) >> 20)
    {
    case 0x6e0: /* dbB */
      return 1;
      
    case 0x6e2: /* dbBd */
      return 3;
      
    default:
      break;
    }
  
  return 0;
}

static int
c4x_print_char (info, ch)
     struct disassemble_info * info;
     char ch;
{
  if (info != NULL)
    (*info->fprintf_func) (info->stream, "%c", ch);
  return 1;
}

static int
c4x_print_str (info, str)
     struct disassemble_info *info;
     char *str;
{
  if (info != NULL)
    (*info->fprintf_func) (info->stream, "%s", str);
  return 1;
}

static int
c4x_print_register (info, regno)
     struct disassemble_info *info;
     unsigned long regno;
{
  static c4x_register_t **registertable = NULL;
  unsigned int i;
  
  if (registertable == NULL)
    {
      registertable = (c4x_register_t **)
        xmalloc (sizeof (c4x_register_t *) * REG_TABLE_SIZE);
      for (i = 0; i < c3x_num_registers; i++)
        registertable[c3x_registers[i].regno] = (void *)&c3x_registers[i];
      if (IS_CPU_C4X (c4x_version))
        {
          /* Add C4x additional registers, overwriting
             any C3x registers if necessary.  */
          for (i = 0; i < c4x_num_registers; i++)
            registertable[c4x_registers[i].regno] = (void *)&c4x_registers[i];
        }
    }
  if ((int) regno > (IS_CPU_C4X (c4x_version) ? C4X_REG_MAX : C3X_REG_MAX))
    return 0;
  if (info != NULL)
    (*info->fprintf_func) (info->stream, "%s", registertable[regno]->name);
  return 1;
}

static int
c4x_print_addr (info, addr)
     struct disassemble_info *info;
     unsigned long addr;
{
  if (info != NULL)
    (*info->print_address_func)(addr, info);
  return 1;
}

static int
c4x_print_relative (info, pc, offset, opcode)
     struct disassemble_info *info;
     unsigned long pc;
     long offset;
     unsigned long opcode;
{
  return c4x_print_addr (info, pc + offset + c4x_pc_offset (opcode));
}

static int
c4x_print_direct (info, arg)
     struct disassemble_info *info;
     unsigned long arg;
{
  if (info != NULL)
    {
      (*info->fprintf_func) (info->stream, "@");
      c4x_print_addr (info, arg + (c4x_dp << 16));
    }
  return 1;
}

/* FIXME: make the floating point stuff not rely on host
   floating point arithmetic.  */
void
c4x_print_ftoa (val, stream, pfunc)
     unsigned int val;
     FILE *stream;
     fprintf_ftype pfunc;
{
  int e;
  int s;
  int f;
  double num = 0.0;
  
  e = EXTRS (val, 31, 24);      /* exponent */
  if (e != -128)
    {
      s = EXTRU (val, 23, 23);  /* sign bit */
      f = EXTRU (val, 22, 0);   /* mantissa */
      if (s)
        f += -2 * (1 << 23);
      else
        f += (1 << 23);
      num = f / (double)(1 << 23);
      num = ldexp (num, e);
    }    
  (*pfunc)(stream, "%.9g", num);
}

static int
c4x_print_immed (info, type, arg)
     struct disassemble_info *info;
     immed_t type;
     unsigned long arg;
{
  int s;
  int f;
  int e;
  double num = 0.0;
  
  if (info == NULL)
    return 1;
  switch (type)
    {
    case IMMED_SINT:
    case IMMED_INT:
      (*info->fprintf_func) (info->stream, "%d", (long)arg);
      break;
      
    case IMMED_SUINT:
    case IMMED_UINT:
      (*info->fprintf_func) (info->stream, "%u", arg);
      break;
      
    case IMMED_SFLOAT:
      e = EXTRS (arg, 15, 12);
      if (e != -8)
        {
          s = EXTRU (arg, 11, 11);
          f = EXTRU (arg, 10, 0);
          if (s)
            f += -2 * (1 << 11);
          else
            f += (1 << 11);
          num = f / (double)(1 << 11);
          num = ldexp (num, e);
        }
      (*info->fprintf_func) (info->stream, "%f", num);
      break;
    case IMMED_FLOAT:
      e = EXTRS (arg, 31, 24);
      if (e != -128)
        {
          s = EXTRU (arg, 23, 23);
          f = EXTRU (arg, 22, 0);
          if (s)
            f += -2 * (1 << 23);
          else
            f += (1 << 23);
          num = f / (double)(1 << 23);
          num = ldexp (num, e);
        }
      (*info->fprintf_func) (info->stream, "%f", num);
      break;
    }
  return 1;
}

static int
c4x_print_cond (info, cond)
     struct disassemble_info *info;
     unsigned int cond;
{
  static c4x_cond_t **condtable = NULL;
  unsigned int i;
  
  if (condtable == NULL)
    {
      condtable = (c4x_cond_t **)xmalloc (sizeof (c4x_cond_t *) * 32);
      for (i = 0; i < num_conds; i++)
        condtable[c4x_conds[i].cond] = (void *)&c4x_conds[i];
    }
  if (cond > 31 || condtable[cond] == NULL)
    return 0;
  if (info != NULL)
    (*info->fprintf_func) (info->stream, "%s", condtable[cond]->name);
  return 1;
}

static int
c4x_print_indirect (info, type, arg)
     struct disassemble_info *info;
     indirect_t type;
     unsigned long arg;
{
  unsigned int aregno;
  unsigned int modn;
  unsigned int disp;
  char *a;

  aregno = 0;
  modn = 0;
  disp = 1;
  switch(type)
    {
    case INDIRECT_C4X:          /* *+ARn(disp) */
      disp = EXTRU (arg, 7, 3);
      aregno = EXTRU (arg, 2, 0) + REG_AR0;
      modn = 0;
      break;
    case INDIRECT_SHORT:
      disp = 1;
      aregno = EXTRU (arg, 2, 0) + REG_AR0;
      modn = EXTRU (arg, 7, 3);
      break;
    case INDIRECT_LONG:
      disp = EXTRU (arg, 7, 0);
      aregno = EXTRU (arg, 10, 8) + REG_AR0;
      modn = EXTRU (arg, 15, 11);
      if (modn > 7 && disp != 0)
        return 0;
      break;
    default:
      abort ();
    }
  if (modn > C3X_MODN_MAX)
    return 0;
  a = c4x_indirects[modn].name;
  while (*a)
    {
      switch (*a)
        {
        case 'a':
          c4x_print_register (info, aregno);
          break;
        case 'd':
          c4x_print_immed (info, IMMED_UINT, disp);
          break;
        case 'y':
          c4x_print_str (info, "ir0");
          break;
        case 'z':
          c4x_print_str (info, "ir1");
          break;
        default:
          c4x_print_char (info, *a);
          break;
        }
      a++;
    }
  return 1;
}

static int
c4x_print_op (info, instruction, p, pc)
     struct disassemble_info *info;
     unsigned long instruction;
     c4x_inst_t *p;
     unsigned long pc;
{
  int val;
  char *s;
  char *parallel = NULL;

  /* Print instruction name.  */
  s = p->name;
  while (*s && parallel == NULL)
    {
      switch (*s)
        {
        case 'B':
          if (! c4x_print_cond (info, EXTRU (instruction, 20, 16)))
            return 0;
          break;
        case 'C':
          if (! c4x_print_cond (info, EXTRU (instruction, 27, 23)))
            return 0;
          break;
        case '_':
          parallel = s + 1;     /* Skip past `_' in name */
          break;
        default:
          c4x_print_char (info, *s);
          break;
        }
      s++;
    }
  
  /* Print arguments.  */
  s = p->args;
  if (*s)
    c4x_print_char (info, ' ');

  while (*s)
    {
      switch (*s)
        {
        case '*': /* indirect 0--15 */
          if (! c4x_print_indirect (info, INDIRECT_LONG,
                                    EXTRU (instruction, 15, 0)))
            return 0;
          break;

        case '#': /* only used for ldp, ldpk */
          c4x_print_immed (info, IMMED_UINT, EXTRU (instruction, 15, 0));
          break;

        case '@': /* direct 0--15 */
          c4x_print_direct (info, EXTRU (instruction, 15, 0));
          break;

        case 'A': /* address register 24--22 */
          if (! c4x_print_register (info, EXTRU (instruction, 24, 22) +
                                    REG_AR0))
            return 0;
          break;

        case 'B': /* 24-bit unsigned int immediate br(d)/call/rptb
                     address 0--23.  */
          if (IS_CPU_C4X (c4x_version))
            c4x_print_relative (info, pc, EXTRS (instruction, 23, 0),
                                p->opcode);
          else
            c4x_print_addr (info, EXTRU (instruction, 23, 0));
          break;

        case 'C': /* indirect (short C4x) 0--7 */
          if (! IS_CPU_C4X (c4x_version))
            return 0;
          if (! c4x_print_indirect (info, INDIRECT_C4X,
                                    EXTRU (instruction, 7, 0)))
            return 0;
          break;

        case 'D':
          /* Cockup if get here...  */
          break;

        case 'E': /* register 0--7 */
        case 'e':
          if (! c4x_print_register (info, EXTRU (instruction, 7, 0)))
            return 0;
          break;

        case 'F': /* 16-bit float immediate 0--15 */
          c4x_print_immed (info, IMMED_SFLOAT,
                           EXTRU (instruction, 15, 0));
          break;

        case 'i': /* Extended indirect 0--7 */
          if ( EXTRU (instruction, 7, 5) == 7 )
            {
              if( !c4x_print_register (info, EXTRU (instruction, 4, 0)) )
                return 0;
              break;
            }
          /* Fallthrough */

        case 'I': /* indirect (short) 0--7 */
          if (! c4x_print_indirect (info, INDIRECT_SHORT,
                                    EXTRU (instruction, 7, 0)))
            return 0;
          break;

        case 'j': /* Extended indirect 8--15 */
          if ( EXTRU (instruction, 15, 13) == 7 )
            {
              if( !c4x_print_register (info, EXTRU (instruction, 12, 8)) )
                return 0;
              break;
            }

        case 'J': /* indirect (short) 8--15 */
          if (! c4x_print_indirect (info, INDIRECT_SHORT,
                                    EXTRU (instruction, 15, 8)))
            return 0;
          break;

        case 'G': /* register 8--15 */
        case 'g':
          if (! c4x_print_register (info, EXTRU (instruction, 15, 8)))
            return 0;
          break;

        case 'H': /* register 16--18 */
          if (! c4x_print_register (info, EXTRU (instruction, 18, 16)))
            return 0;
          break;

        case 'K': /* register 19--21 */
          if (! c4x_print_register (info, EXTRU (instruction, 21, 19)))
            return 0;
          break;

        case 'L': /* register 22--24 */
          if (! c4x_print_register (info, EXTRU (instruction, 24, 22)))
            return 0;
          break;

        case 'M': /* register 22--22 */
          c4x_print_register (info, EXTRU (instruction, 22, 22) + REG_R2);
          break;

        case 'N': /* register 23--23 */
          c4x_print_register (info, EXTRU (instruction, 23, 23) + REG_R0);
          break;

        case 'O': /* indirect (short C4x) 8--15 */
          if (! IS_CPU_C4X (c4x_version))
            return 0;
          if (! c4x_print_indirect (info, INDIRECT_C4X,
                                    EXTRU (instruction, 15, 8)))
            return 0;
          break;

        case 'P': /* displacement 0--15 (used by Bcond and BcondD) */
          c4x_print_relative (info, pc, EXTRS (instruction, 15, 0),
                              p->opcode);
          break;

        case 'Q': /* register 0--15 */
        case 'q':
          if (! c4x_print_register (info, EXTRU (instruction, 15, 0)))
            return 0;
          break;

        case 'R': /* register 16--20 */
        case 'r':
          if (! c4x_print_register (info, EXTRU (instruction, 20, 16)))
            return 0;
          break;

        case 'S': /* 16-bit signed immediate 0--15 */
          c4x_print_immed (info, IMMED_SINT,
                           EXTRS (instruction, 15, 0));
          break;

        case 'T': /* 5-bit signed immediate 16--20  (C4x stik) */
          if (! IS_CPU_C4X (c4x_version))
            return 0;
          if (! c4x_print_immed (info, IMMED_SUINT,
                                 EXTRU (instruction, 20, 16)))
            return 0;
          break;

        case 'U': /* 16-bit unsigned int immediate 0--15 */
          c4x_print_immed (info, IMMED_SUINT, EXTRU (instruction, 15, 0));
          break;

        case 'V': /* 5/9-bit unsigned vector 0--4/8 */
          c4x_print_immed (info, IMMED_SUINT,
                           IS_CPU_C4X (c4x_version) ? 
                           EXTRU (instruction, 8, 0) :
                           EXTRU (instruction, 4, 0) & ~0x20);
          break;

        case 'W': /* 8-bit signed immediate 0--7 */
          if (! IS_CPU_C4X (c4x_version))
            return 0;
          c4x_print_immed (info, IMMED_SINT, EXTRS (instruction, 7, 0));
          break;

        case 'X': /* expansion register 4--0 */
          val = EXTRU (instruction, 4, 0) + REG_IVTP;
          if (val < REG_IVTP || val > REG_TVTP)
            return 0;
          if (! c4x_print_register (info, val))
            return 0;
          break;

        case 'Y': /* address register 16--20 */
          val = EXTRU (instruction, 20, 16);
          if (val < REG_AR0 || val > REG_SP)
            return 0;
          if (! c4x_print_register (info, val))
            return 0;
          break;

        case 'Z': /* expansion register 16--20 */
          val = EXTRU (instruction, 20, 16) + REG_IVTP;
          if (val < REG_IVTP || val > REG_TVTP)
            return 0;
          if (! c4x_print_register (info, val))
            return 0;
          break;

        case '|':               /* Parallel instruction */
          c4x_print_str (info, " || ");
          c4x_print_str (info, parallel);
          c4x_print_char (info, ' ');
          break;

        case ';':
          c4x_print_char (info, ',');
          break;

        default:
          c4x_print_char (info, *s);
          break;
        }
      s++;
    }
  return 1;
}

static void
c4x_hash_opcode_special (optable_special, inst)
     c4x_inst_t **optable_special;
     const c4x_inst_t *inst;
{
  int i;

  for( i=0; i<C4X_SPESOP_SIZE; i++ )
    if( optable_special[i] != NULL
        && optable_special[i]->opcode == inst->opcode )
      {
        /* Collision (we have it already) - overwrite */
        optable_special[i] = (void *)inst;
        return;
      }

  for( i=0; i<C4X_SPESOP_SIZE; i++ )
    if( optable_special[i] == NULL )
      {
        /* Add the new opcode */
        optable_special[i] = (void *)inst;
        return;
      }

  /* This should never occur. This happens if the number of special
     instructions exceeds C4X_SPESOP_SIZE. Please increase the variable
     of this variable */
#if C4X_DEBUG
  printf("optable_special[] is full, please increase C4X_SPESOP_SIZE!\n");
#endif
}

static void
c4x_hash_opcode (optable, optable_special, inst, c4x_oplevel)
     c4x_inst_t **optable;
     c4x_inst_t **optable_special;
     const c4x_inst_t *inst;
     const unsigned long c4x_oplevel;
{
  int j;
  int opcode = inst->opcode >> (32 - C4X_HASH_SIZE);
  int opmask = inst->opmask >> (32 - C4X_HASH_SIZE);
  
  /* Use a C4X_HASH_SIZE bit index as a hash index.  We should
     have unique entries so there's no point having a linked list
     for each entry? */
  for (j = opcode; j < opmask; j++)
    if ( (j & opmask) == opcode
         && inst->oplevel & c4x_oplevel )
      {
#if C4X_DEBUG
        /* We should only have collisions for synonyms like
           ldp for ldi.  */
        if (optable[j] != NULL)
          printf("Collision at index %d, %s and %s\n",
                 j, optable[j]->name, inst->name);
#endif
        /* Catch those ops that collide with others already inside the
           hash, and have a opmask greater than the one we use in the
           hash. Store them in a special-list, that will handle full
           32-bit INSN, not only the first 11-bit (or so). */
        if ( optable[j] != NULL
             && inst->opmask & ~(opmask << (32 - C4X_HASH_SIZE)) )
          {
            /* Add the instruction already on the list */
            c4x_hash_opcode_special(optable_special, optable[j]);

            /* Add the new instruction */
            c4x_hash_opcode_special(optable_special, inst);
          }

        optable[j] = (void *)inst;
      }
}

/* Disassemble the instruction in 'instruction'.
   'pc' should be the address of this instruction, it will
   be used to print the target address if this is a relative jump or call
   the disassembled instruction is written to 'info'.
   The function returns the length of this instruction in words.  */

static int
c4x_disassemble (pc, instruction, info)
     unsigned long pc;
     unsigned long instruction;
     struct disassemble_info *info;
{
  static c4x_inst_t **optable = NULL;
  static c4x_inst_t **optable_special = NULL;
  c4x_inst_t *p;
  int i;
  unsigned long c4x_oplevel;
  
  c4x_version = info->mach;

  c4x_oplevel  = (IS_CPU_C4X (c4x_version)) ? OP_C4X : 0;
  c4x_oplevel |= OP_C3X|OP_LPWR|OP_IDLE2|OP_ENH;
  
  if (optable == NULL)
    {
      optable = (c4x_inst_t **)
        xcalloc (sizeof (c4x_inst_t *), (1 << C4X_HASH_SIZE));

      optable_special = (c4x_inst_t **)
        xcalloc (sizeof (c4x_inst_t *), C4X_SPESOP_SIZE );

      /* Install opcodes in reverse order so that preferred
         forms overwrite synonyms.  */
      for (i = c4x_num_insts - 1; i >= 0; i--)
        c4x_hash_opcode (optable, optable_special, &c4x_insts[i], c4x_oplevel);

      /* We now need to remove the insn that are special from the
         "normal" optable, to make the disasm search this extra list
         for them.
      */
      for (i=0; i<C4X_SPESOP_SIZE; i++)
        if ( optable_special[i] != NULL )
          optable[optable_special[i]->opcode >> (32 - C4X_HASH_SIZE)] = NULL;
    }
  
  /* See if we can pick up any loading of the DP register...  */
  if ((instruction >> 16) == 0x5070 || (instruction >> 16) == 0x1f70)
    c4x_dp = EXTRU (instruction, 15, 0);

  p = optable[instruction >> (32 - C4X_HASH_SIZE)];
  if ( p != NULL )
    {
      if ( ((instruction & p->opmask) == p->opcode)
           && c4x_print_op (NULL, instruction, p, pc) )
        c4x_print_op (info, instruction, p, pc);
      else
        (*info->fprintf_func) (info->stream, "%08x", instruction);
    }
  else
    {
      for (i = 0; i<C4X_SPESOP_SIZE; i++)
        if (optable_special[i] != NULL
            && optable_special[i]->opcode == instruction )
          {
            (*info->fprintf_func)(info->stream, "%s", optable_special[i]->name);
            break;
          }
      if (i==C4X_SPESOP_SIZE)
        (*info->fprintf_func) (info->stream, "%08x", instruction);
    }

  /* Return size of insn in words.  */
  return 1;     
}

/* The entry point from objdump and gdb.  */
int
print_insn_tic4x (memaddr, info)
     bfd_vma memaddr;
     struct disassemble_info *info;
{
  int status;
  unsigned long pc;
  unsigned long op;
  bfd_byte buffer[4];
  
  status = (*info->read_memory_func) (memaddr, buffer, 4, info);
  if (status != 0)
    {
      (*info->memory_error_func) (status, memaddr, info);
      return -1;
    }
  
  pc = memaddr;
  op = bfd_getl32 (buffer);
  info->bytes_per_line = 4;
  info->bytes_per_chunk = 4;
  info->octets_per_byte = 4;
  info->display_endian = BFD_ENDIAN_LITTLE;
  return c4x_disassemble (pc, op, info) * 4;
}