opcodes/tic30-dis.c - binutils-gdb - Git at Google

 /* Disassembly routines for TMS320C30 architecture
    Copyright (C) 1998, 1999 Free Software Foundation, Inc.
    Contributed by Steven Haworth (steve@pm.cse.rmit.edu.au)

    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 <errno.h>
 #include <math.h>
 #include "sysdep.h"
 #include "dis-asm.h"
 #include "opcode/tic30.h"

 #define NORMAL_INSN   1
 #define PARALLEL_INSN 2

 /* Gets the type of instruction based on the top 2 or 3 bits of the
    instruction word. */
 #define GET_TYPE(insn) (insn & 0x80000000 ? insn & 0xC0000000 : insn & 0xE0000000)

 /* Instruction types. */
 #define TWO_OPERAND_1 0x00000000
 #define TWO_OPERAND_2 0x40000000
 #define THREE_OPERAND 0x20000000
 #define PAR_STORE     0xC0000000
 #define MUL_ADDS      0x80000000
 #define BRANCHES      0x60000000

 /* Specific instruction id bits. */
 #define NORMAL_IDEN    0x1F800000
 #define PAR_STORE_IDEN 0x3E000000
 #define MUL_ADD_IDEN   0x2C000000
 #define BR_IMM_IDEN    0x1F000000
 #define BR_COND_IDEN   0x1C3F0000

 /* Addressing modes. */
 #define AM_REGISTER 0x00000000
 #define AM_DIRECT   0x00200000
 #define AM_INDIRECT 0x00400000
 #define AM_IMM      0x00600000

 #define P_FIELD 0x03000000

 #define REG_AR0 0x08
 #define LDP_INSN 0x08700000

 /* TMS320C30 program counter for current instruction. */
 static unsigned int _pc;

 struct instruction
   {
     int type;
     template *tm;
     partemplate *ptm;
   };

 int get_tic30_instruction PARAMS ((unsigned long, struct instruction *));
 int print_two_operand
   PARAMS ((disassemble_info *, unsigned long, struct instruction *));
 int print_three_operand
   PARAMS ((disassemble_info *, unsigned long, struct instruction *));
 int print_par_insn
   PARAMS ((disassemble_info *, unsigned long, struct instruction *));
 int print_branch
   PARAMS ((disassemble_info *, unsigned long, struct instruction *));
 int get_indirect_operand PARAMS ((unsigned short, int, char *));
 int get_register_operand PARAMS ((unsigned char, char *));
 int cnvt_tmsfloat_ieee PARAMS ((unsigned long, int, float *));

 int
 print_insn_tic30 (pc, info)
      bfd_vma pc;
      disassemble_info *info;
 {
   unsigned long insn_word;
   struct instruction insn =
   {0, NULL, NULL};
   bfd_vma bufaddr = pc - info->buffer_vma;
   /* Obtain the current instruction word from the buffer. */
   insn_word = (*(info->buffer + bufaddr) << 24) | (*(info->buffer + bufaddr + 1) << 16) |
     (*(info->buffer + bufaddr + 2) << 8) | *(info->buffer + bufaddr + 3);
   _pc = pc / 4;
   /* Get the instruction refered to by the current instruction word
      and print it out based on its type. */
   if (!get_tic30_instruction (insn_word, &insn))
     return -1;
   switch (GET_TYPE (insn_word))
     {
     case TWO_OPERAND_1:
     case TWO_OPERAND_2:
       if (!print_two_operand (info, insn_word, &insn))
 	return -1;
       break;
     case THREE_OPERAND:
       if (!print_three_operand (info, insn_word, &insn))
 	return -1;
       break;
     case PAR_STORE:
     case MUL_ADDS:
       if (!print_par_insn (info, insn_word, &insn))
 	return -1;
       break;
     case BRANCHES:
       if (!print_branch (info, insn_word, &insn))
 	return -1;
       break;
     }
   return 4;
 }

 int
 get_tic30_instruction (insn_word, insn)
      unsigned long insn_word;
      struct instruction *insn;
 {
   switch (GET_TYPE (insn_word))
     {
     case TWO_OPERAND_1:
     case TWO_OPERAND_2:
     case THREE_OPERAND:
       insn->type = NORMAL_INSN;
       {
 	template *current_optab = (template *) tic30_optab;
 	for (; current_optab < tic30_optab_end; current_optab++)
 	  {
 	    if (GET_TYPE (current_optab->base_opcode) == GET_TYPE (insn_word))
 	      {
 		if (current_optab->operands == 0)
 		  {
 		    if (current_optab->base_opcode == insn_word)
 		      {
 			insn->tm = current_optab;
 			break;
 		      }
 		  }
 		else if ((current_optab->base_opcode & NORMAL_IDEN) == (insn_word & NORMAL_IDEN))
 		  {
 		    insn->tm = current_optab;
 		    break;
 		  }
 	      }
 	  }
       }
       break;
     case PAR_STORE:
       insn->type = PARALLEL_INSN;
       {
 	partemplate *current_optab = (partemplate *) tic30_paroptab;
 	for (; current_optab < tic30_paroptab_end; current_optab++)
 	  {
 	    if (GET_TYPE (current_optab->base_opcode) == GET_TYPE (insn_word))
 	      {
 		if ((current_optab->base_opcode & PAR_STORE_IDEN) == (insn_word & PAR_STORE_IDEN))
 		  {
 		    insn->ptm = current_optab;
 		    break;
 		  }
 	      }
 	  }
       }
       break;
     case MUL_ADDS:
       insn->type = PARALLEL_INSN;
       {
 	partemplate *current_optab = (partemplate *) tic30_paroptab;
 	for (; current_optab < tic30_paroptab_end; current_optab++)
 	  {
 	    if (GET_TYPE (current_optab->base_opcode) == GET_TYPE (insn_word))
 	      {
 		if ((current_optab->base_opcode & MUL_ADD_IDEN) == (insn_word & MUL_ADD_IDEN))
 		  {
 		    insn->ptm = current_optab;
 		    break;
 		  }
 	      }
 	  }
       }
       break;
     case BRANCHES:
       insn->type = NORMAL_INSN;
       {
 	template *current_optab = (template *) tic30_optab;
 	for (; current_optab < tic30_optab_end; current_optab++)
 	  {
 	    if (GET_TYPE (current_optab->base_opcode) == GET_TYPE (insn_word))
 	      {
 		if (current_optab->operand_types[0] & Imm24)
 		  {
 		    if ((current_optab->base_opcode & BR_IMM_IDEN) == (insn_word & BR_IMM_IDEN))
 		      {
 			insn->tm = current_optab;
 			break;
 		      }
 		  }
 		else if (current_optab->operands > 0)
 		  {
 		    if ((current_optab->base_opcode & BR_COND_IDEN) == (insn_word & BR_COND_IDEN))
 		      {
 			insn->tm = current_optab;
 			break;
 		      }
 		  }
 		else
 		  {
 		    if ((current_optab->base_opcode & (BR_COND_IDEN | 0x00800000)) == (insn_word & (BR_COND_IDEN | 0x00800000)))
 		      {
 			insn->tm = current_optab;
 			break;
 		      }
 		  }
 	      }
 	  }
       }
       break;
     default:
       return 0;
     }
   return 1;
 }

 int
 print_two_operand (info, insn_word, insn)
      disassemble_info *info;
      unsigned long insn_word;
      struct instruction *insn;
 {
   char name[12];
   char operand[2][13] =
   {
     {0},
     {0}};
   float f_number;

   if (insn->tm == NULL)
     return 0;
   strcpy (name, insn->tm->name);
   if (insn->tm->opcode_modifier == AddressMode)
     {
       int src_op, dest_op;
       /* Determine whether instruction is a store or a normal instruction. */
       if ((insn->tm->operand_types[1] & (Direct | Indirect)) == (Direct | Indirect))
 	{
 	  src_op = 1;
 	  dest_op = 0;
 	}
       else
 	{
 	  src_op = 0;
 	  dest_op = 1;
 	}
       /* Get the destination register. */
       if (insn->tm->operands == 2)
 	get_register_operand ((insn_word & 0x001F0000) >> 16, operand[dest_op]);
       /* Get the source operand based on addressing mode. */
       switch (insn_word & AddressMode)
 	{
 	case AM_REGISTER:
 	  /* Check for the NOP instruction before getting the operand. */
 	  if ((insn->tm->operand_types[0] & NotReq) == 0)
 	    get_register_operand ((insn_word & 0x0000001F), operand[src_op]);
 	  break;
 	case AM_DIRECT:
 	  sprintf (operand[src_op], "@0x%lX", (insn_word & 0x0000FFFF));
 	  break;
 	case AM_INDIRECT:
 	  get_indirect_operand ((insn_word & 0x0000FFFF), 2, operand[src_op]);
 	  break;
 	case AM_IMM:
 	  /* Get the value of the immediate operand based on variable type. */
 	  switch (insn->tm->imm_arg_type)
 	    {
 	    case Imm_Float:
 	      cnvt_tmsfloat_ieee ((insn_word & 0x0000FFFF), 2, &f_number);
 	      sprintf (operand[src_op], "%2.2f", f_number);
 	      break;
 	    case Imm_SInt:
 	      sprintf (operand[src_op], "%d", (short) (insn_word & 0x0000FFFF));
 	      break;
 	    case Imm_UInt:
 	      sprintf (operand[src_op], "%lu", (insn_word & 0x0000FFFF));
 	      break;
 	    default:
 	      return 0;
 	    }
 	  /* Handle special case for LDP instruction. */
 	  if ((insn_word & 0xFFFFFF00) == LDP_INSN)
 	    {
 	      strcpy (name, "ldp");
 	      sprintf (operand[0], "0x%06lX", (insn_word & 0x000000FF) << 16);
 	      operand[1][0] = '\0';
 	    }
 	}
     }
   /* Handle case for stack and rotate instructions. */
   else if (insn->tm->operands == 1)
     {
       if (insn->tm->opcode_modifier == StackOp)
 	{
 	  get_register_operand ((insn_word & 0x001F0000) >> 16, operand[0]);
 	}
     }
   /* Output instruction to stream. */
   info->fprintf_func (info->stream, "   %s %s%c%s", name,
 		      operand[0][0] ? operand[0] : "",
 		      operand[1][0] ? ',' : ' ',
 		      operand[1][0] ? operand[1] : "");
   return 1;
 }

 int
 print_three_operand (info, insn_word, insn)
      disassemble_info *info;
      unsigned long insn_word;
      struct instruction *insn;
 {
   char operand[3][13] =
   {
     {0},
     {0},
     {0}};

   if (insn->tm == NULL)
     return 0;
   switch (insn_word & AddressMode)
     {
     case AM_REGISTER:
       get_register_operand ((insn_word & 0x000000FF), operand[0]);
       get_register_operand ((insn_word & 0x0000FF00) >> 8, operand[1]);
       break;
     case AM_DIRECT:
       get_register_operand ((insn_word & 0x000000FF), operand[0]);
       get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1]);
       break;
     case AM_INDIRECT:
       get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0]);
       get_register_operand ((insn_word & 0x0000FF00) >> 8, operand[1]);
       break;
     case AM_IMM:
       get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0]);
       get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1]);
       break;
     default:
       return 0;
     }
   if (insn->tm->operands == 3)
     get_register_operand ((insn_word & 0x001F0000) >> 16, operand[2]);
   info->fprintf_func (info->stream, "   %s %s,%s%c%s", insn->tm->name,
 		      operand[0], operand[1],
 		      operand[2][0] ? ',' : ' ',
 		      operand[2][0] ? operand[2] : "");
   return 1;
 }

 int
 print_par_insn (info, insn_word, insn)
      disassemble_info *info;
      unsigned long insn_word;
      struct instruction *insn;
 {
   size_t i, len;
   char *name1, *name2;
   char operand[2][3][13] =
   {
     {
       {0},
       {0},
       {0}},
     {
       {0},
       {0},
       {0}}};

   if (insn->ptm == NULL)
     return 0;
   /* Parse out the names of each of the parallel instructions from the
      q_insn1_insn2 format. */
   name1 = (char *) strdup (insn->ptm->name + 2);
   name2 = "";
   len = strlen (name1);
   for (i = 0; i < len; i++)
     {
       if (name1[i] == '_')
 	{
 	  name2 = &name1[i + 1];
 	  name1[i] = '\0';
 	  break;
 	}
     }
   /* Get the operands of the instruction based on the operand order. */
   switch (insn->ptm->oporder)
     {
     case OO_4op1:
       get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0][0]);
       get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1][1]);
       get_register_operand ((insn_word >> 16) & 0x07, operand[1][0]);
       get_register_operand ((insn_word >> 22) & 0x07, operand[0][1]);
       break;
     case OO_4op2:
       get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0][0]);
       get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1][0]);
       get_register_operand ((insn_word >> 19) & 0x07, operand[1][1]);
       get_register_operand ((insn_word >> 22) & 0x07, operand[0][1]);
       break;
     case OO_4op3:
       get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0][1]);
       get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1][1]);
       get_register_operand ((insn_word >> 16) & 0x07, operand[1][0]);
       get_register_operand ((insn_word >> 22) & 0x07, operand[0][0]);
       break;
     case OO_5op1:
       get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0][0]);
       get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1][1]);
       get_register_operand ((insn_word >> 16) & 0x07, operand[1][0]);
       get_register_operand ((insn_word >> 19) & 0x07, operand[0][1]);
       get_register_operand ((insn_word >> 22) & 0x07, operand[0][2]);
       break;
     case OO_5op2:
       get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0][1]);
       get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1][1]);
       get_register_operand ((insn_word >> 16) & 0x07, operand[1][0]);
       get_register_operand ((insn_word >> 19) & 0x07, operand[0][0]);
       get_register_operand ((insn_word >> 22) & 0x07, operand[0][2]);
       break;
     case OO_PField:
       if (insn_word & 0x00800000)
 	get_register_operand (0x01, operand[0][2]);
       else
 	get_register_operand (0x00, operand[0][2]);
       if (insn_word & 0x00400000)
 	get_register_operand (0x03, operand[1][2]);
       else
 	get_register_operand (0x02, operand[1][2]);
       switch (insn_word & P_FIELD)
 	{
 	case 0x00000000:
 	  get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0][1]);
 	  get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[0][0]);
 	  get_register_operand ((insn_word >> 16) & 0x07, operand[1][1]);
 	  get_register_operand ((insn_word >> 19) & 0x07, operand[1][0]);
 	  break;
 	case 0x01000000:
 	  get_indirect_operand ((insn_word & 0x000000FF), 1, operand[1][0]);
 	  get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[0][0]);
 	  get_register_operand ((insn_word >> 16) & 0x07, operand[1][1]);
 	  get_register_operand ((insn_word >> 19) & 0x07, operand[0][1]);
 	  break;
 	case 0x02000000:
 	  get_indirect_operand ((insn_word & 0x000000FF), 1, operand[1][1]);
 	  get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1][0]);
 	  get_register_operand ((insn_word >> 16) & 0x07, operand[0][1]);
 	  get_register_operand ((insn_word >> 19) & 0x07, operand[0][0]);
 	  break;
 	case 0x03000000:
 	  get_indirect_operand ((insn_word & 0x000000FF), 1, operand[1][1]);
 	  get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[0][0]);
 	  get_register_operand ((insn_word >> 16) & 0x07, operand[1][0]);
 	  get_register_operand ((insn_word >> 19) & 0x07, operand[0][1]);
 	  break;
 	}
       break;
     default:
       return 0;
     }
   info->fprintf_func (info->stream, "   %s %s,%s%c%s", name1,
 		      operand[0][0], operand[0][1],
 		      operand[0][2][0] ? ',' : ' ',
 		      operand[0][2][0] ? operand[0][2] : "");
   info->fprintf_func (info->stream, "\n\t\t\t|| %s %s,%s%c%s", name2,
 		      operand[1][0], operand[1][1],
 		      operand[1][2][0] ? ',' : ' ',
 		      operand[1][2][0] ? operand[1][2] : "");
   free (name1);
   return 1;
 }

 int
 print_branch (info, insn_word, insn)
      disassemble_info *info;
      unsigned long insn_word;
      struct instruction *insn;
 {
   char operand[2][13] =
   {
     {0},
     {0}};
   unsigned long address;
   int print_label = 0;

   if (insn->tm == NULL)
     return 0;
   /* Get the operands for 24-bit immediate jumps. */
   if (insn->tm->operand_types[0] & Imm24)
     {
       address = insn_word & 0x00FFFFFF;
       sprintf (operand[0], "0x%lX", address);
       print_label = 1;
     }
   /* Get the operand for the trap instruction. */
   else if (insn->tm->operand_types[0] & IVector)
     {
       address = insn_word & 0x0000001F;
       sprintf (operand[0], "0x%lX", address);
     }
   else
     {
       address = insn_word & 0x0000FFFF;
       /* Get the operands for the DB instructions. */
       if (insn->tm->operands == 2)
 	{
 	  get_register_operand (((insn_word & 0x01C00000) >> 22) + REG_AR0, operand[0]);
 	  if (insn_word & PCRel)
 	    {
 	      sprintf (operand[1], "%d", (short) address);
 	      print_label = 1;
 	    }
 	  else
 	    get_register_operand (insn_word & 0x0000001F, operand[1]);
 	}
       /* Get the operands for the standard branches. */
       else if (insn->tm->operands == 1)
 	{
 	  if (insn_word & PCRel)
 	    {
 	      address = (short) address;
 	      sprintf (operand[0], "%ld", address);
 	      print_label = 1;
 	    }
 	  else
 	    get_register_operand (insn_word & 0x0000001F, operand[0]);
 	}
     }
   info->fprintf_func (info->stream, "   %s %s%c%s", insn->tm->name,
 		      operand[0][0] ? operand[0] : "",
 		      operand[1][0] ? ',' : ' ',
 		      operand[1][0] ? operand[1] : "");
   /* Print destination of branch in relation to current symbol. */
   if (print_label && info->symbols)
     {
       asymbol *sym = *info->symbols;

       if ((insn->tm->opcode_modifier == PCRel) && (insn_word & PCRel))
 	{
 	  address = (_pc + 1 + (short) address) - ((sym->section->vma + sym->value) / 4);
 	  /* Check for delayed instruction, if so adjust destination. */
 	  if (insn_word & 0x00200000)
 	    address += 2;
 	}
       else
 	{
 	  address -= ((sym->section->vma + sym->value) / 4);
 	}
       if (address == 0)
 	info->fprintf_func (info->stream, " <%s>", sym->name);
       else
 	info->fprintf_func (info->stream, " <%s %c %d>", sym->name,
 			    ((short) address < 0) ? '-' : '+',
 			    abs (address));
     }
   return 1;
 }

 int
 get_indirect_operand (fragment, size, buffer)
      unsigned short fragment;
      int size;
      char *buffer;
 {
   unsigned char mod;
   unsigned arnum;
   unsigned char disp;

   if (buffer == NULL)
     return 0;
   /* Determine which bits identify the sections of the indirect operand based on the
      size in bytes. */
   switch (size)
     {
     case 1:
       mod = (fragment & 0x00F8) >> 3;
       arnum = (fragment & 0x0007);
       disp = 0;
       break;
     case 2:
       mod = (fragment & 0xF800) >> 11;
       arnum = (fragment & 0x0700) >> 8;
       disp = (fragment & 0x00FF);
       break;
     default:
       return 0;
     }
   {
     const ind_addr_type *current_ind = tic30_indaddr_tab;
     for (; current_ind < tic30_indaddrtab_end; current_ind++)
       {
 	if (current_ind->modfield == mod)
 	  {
 	    if (current_ind->displacement == IMPLIED_DISP && size == 2)
 	      {
 		continue;
 	      }
 	    else
 	      {
 		size_t i, len;
 		int bufcnt;

 		len = strlen (current_ind->syntax);
 		for (i = 0, bufcnt = 0; i < len; i++, bufcnt++)
 		  {
 		    buffer[bufcnt] = current_ind->syntax[i];
 		    if (buffer[bufcnt - 1] == 'a' && buffer[bufcnt] == 'r')
 		      buffer[++bufcnt] = arnum + '0';
 		    if (buffer[bufcnt] == '(' && current_ind->displacement == DISP_REQUIRED)
 		      {
 			sprintf (&buffer[bufcnt + 1], "%u", disp);
 			bufcnt += strlen (&buffer[bufcnt + 1]);
 		      }
 		  }
 		buffer[bufcnt + 1] = '\0';
 		break;
 	      }
 	  }
       }
   }
   return 1;
 }

 int
 get_register_operand (fragment, buffer)
      unsigned char fragment;
      char *buffer;
 {
   const reg *current_reg = tic30_regtab;

   if (buffer == NULL)
     return 0;
   for (; current_reg < tic30_regtab_end; current_reg++)
     {
       if ((fragment & 0x1F) == current_reg->opcode)
 	{
 	  strcpy (buffer, current_reg->name);
 	  return 1;
 	}
     }
   return 0;
 }

 int
 cnvt_tmsfloat_ieee (tmsfloat, size, ieeefloat)
      unsigned long tmsfloat;
      int size;
      float *ieeefloat;
 {
   unsigned long exp, sign, mant;

   if (size == 2)
     {
       if ((tmsfloat & 0x0000F000) == 0x00008000)
 	tmsfloat = 0x80000000;
       else
 	{
 	  tmsfloat <<= 16;
 	  tmsfloat = (long) tmsfloat >> 4;
 	}
     }
   exp = tmsfloat & 0xFF000000;
   if (exp == 0x80000000)
     {
       *ieeefloat = 0.0;
       return 1;
     }
   exp += 0x7F000000;
   sign = (tmsfloat & 0x00800000) << 8;
   mant = tmsfloat & 0x007FFFFF;
   if (exp == 0xFF000000)
     {
       if (mant == 0)
 	*ieeefloat = ERANGE;
       if (sign == 0)
 	*ieeefloat = 1.0 / 0.0;
       else
 	*ieeefloat = -1.0 / 0.0;
       return 1;
     }
   exp >>= 1;
   if (sign)
     {
       mant = (~mant) & 0x007FFFFF;
       mant += 1;
       exp += mant & 0x00800000;
       exp &= 0x7F800000;
       mant &= 0x007FFFFF;
     }
   if (tmsfloat == 0x80000000)
     sign = mant = exp = 0;
   tmsfloat = sign | exp | mant;
   *ieeefloat = *((float *) &tmsfloat);
   return 1;
 }
	/* Disassembly routines for TMS320C30 architecture
	Copyright (C) 1998, 1999 Free Software Foundation, Inc.
	Contributed by Steven Haworth (steve@pm.cse.rmit.edu.au)

	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 <errno.h>
	#include <math.h>
	#include "sysdep.h"
	#include "dis-asm.h"
	#include "opcode/tic30.h"

	#define NORMAL_INSN 1
	#define PARALLEL_INSN 2

	/* Gets the type of instruction based on the top 2 or 3 bits of the
	instruction word. */
	#define GET_TYPE(insn) (insn & 0x80000000 ? insn & 0xC0000000 : insn & 0xE0000000)

	/* Instruction types. */
	#define TWO_OPERAND_1 0x00000000
	#define TWO_OPERAND_2 0x40000000
	#define THREE_OPERAND 0x20000000
	#define PAR_STORE 0xC0000000
	#define MUL_ADDS 0x80000000
	#define BRANCHES 0x60000000

	/* Specific instruction id bits. */
	#define NORMAL_IDEN 0x1F800000
	#define PAR_STORE_IDEN 0x3E000000
	#define MUL_ADD_IDEN 0x2C000000
	#define BR_IMM_IDEN 0x1F000000
	#define BR_COND_IDEN 0x1C3F0000

	/* Addressing modes. */
	#define AM_REGISTER 0x00000000
	#define AM_DIRECT 0x00200000
	#define AM_INDIRECT 0x00400000
	#define AM_IMM 0x00600000

	#define P_FIELD 0x03000000

	#define REG_AR0 0x08
	#define LDP_INSN 0x08700000

	/* TMS320C30 program counter for current instruction. */
	static unsigned int _pc;

	struct instruction
	{
	int type;
	template *tm;
	partemplate *ptm;
	};

	int get_tic30_instruction PARAMS ((unsigned long, struct instruction *));
	int print_two_operand
	PARAMS ((disassemble_info , unsigned long, struct instruction ));
	int print_three_operand
	PARAMS ((disassemble_info , unsigned long, struct instruction ));
	int print_par_insn
	PARAMS ((disassemble_info , unsigned long, struct instruction ));
	int print_branch
	PARAMS ((disassemble_info , unsigned long, struct instruction ));
	int get_indirect_operand PARAMS ((unsigned short, int, char *));
	int get_register_operand PARAMS ((unsigned char, char *));
	int cnvt_tmsfloat_ieee PARAMS ((unsigned long, int, float *));

	int
	print_insn_tic30 (pc, info)
	bfd_vma pc;
	disassemble_info *info;
	{
	unsigned long insn_word;
	struct instruction insn =
	{0, NULL, NULL};
	bfd_vma bufaddr = pc - info->buffer_vma;
	/* Obtain the current instruction word from the buffer. */
	insn_word = ((info->buffer + bufaddr) << 24) \| ((info->buffer + bufaddr + 1) << 16) \|
	((info->buffer + bufaddr + 2) << 8) \| (info->buffer + bufaddr + 3);
	_pc = pc / 4;
	/* Get the instruction refered to by the current instruction word
	and print it out based on its type. */
	if (!get_tic30_instruction (insn_word, &insn))
	return -1;
	switch (GET_TYPE (insn_word))
	{
	case TWO_OPERAND_1:
	case TWO_OPERAND_2:
	if (!print_two_operand (info, insn_word, &insn))
	return -1;
	break;
	case THREE_OPERAND:
	if (!print_three_operand (info, insn_word, &insn))
	return -1;
	break;
	case PAR_STORE:
	case MUL_ADDS:
	if (!print_par_insn (info, insn_word, &insn))
	return -1;
	break;
	case BRANCHES:
	if (!print_branch (info, insn_word, &insn))
	return -1;
	break;
	}
	return 4;
	}

	int
	get_tic30_instruction (insn_word, insn)
	unsigned long insn_word;
	struct instruction *insn;
	{
	switch (GET_TYPE (insn_word))
	{
	case TWO_OPERAND_1:
	case TWO_OPERAND_2:
	case THREE_OPERAND:
	insn->type = NORMAL_INSN;
	{
	template current_optab = (template ) tic30_optab;
	for (; current_optab < tic30_optab_end; current_optab++)
	{
	if (GET_TYPE (current_optab->base_opcode) == GET_TYPE (insn_word))
	{
	if (current_optab->operands == 0)
	{
	if (current_optab->base_opcode == insn_word)
	{
	insn->tm = current_optab;
	break;
	}
	}
	else if ((current_optab->base_opcode & NORMAL_IDEN) == (insn_word & NORMAL_IDEN))
	{
	insn->tm = current_optab;
	break;
	}
	}
	}
	}
	break;
	case PAR_STORE:
	insn->type = PARALLEL_INSN;
	{
	partemplate current_optab = (partemplate ) tic30_paroptab;
	for (; current_optab < tic30_paroptab_end; current_optab++)
	{
	if (GET_TYPE (current_optab->base_opcode) == GET_TYPE (insn_word))
	{
	if ((current_optab->base_opcode & PAR_STORE_IDEN) == (insn_word & PAR_STORE_IDEN))
	{
	insn->ptm = current_optab;
	break;
	}
	}
	}
	}
	break;
	case MUL_ADDS:
	insn->type = PARALLEL_INSN;
	{
	partemplate current_optab = (partemplate ) tic30_paroptab;
	for (; current_optab < tic30_paroptab_end; current_optab++)
	{
	if (GET_TYPE (current_optab->base_opcode) == GET_TYPE (insn_word))
	{
	if ((current_optab->base_opcode & MUL_ADD_IDEN) == (insn_word & MUL_ADD_IDEN))
	{
	insn->ptm = current_optab;
	break;
	}
	}
	}
	}
	break;
	case BRANCHES:
	insn->type = NORMAL_INSN;
	{
	template current_optab = (template ) tic30_optab;
	for (; current_optab < tic30_optab_end; current_optab++)
	{
	if (GET_TYPE (current_optab->base_opcode) == GET_TYPE (insn_word))
	{
	if (current_optab->operand_types[0] & Imm24)
	{
	if ((current_optab->base_opcode & BR_IMM_IDEN) == (insn_word & BR_IMM_IDEN))
	{
	insn->tm = current_optab;
	break;
	}
	}
	else if (current_optab->operands > 0)
	{
	if ((current_optab->base_opcode & BR_COND_IDEN) == (insn_word & BR_COND_IDEN))
	{
	insn->tm = current_optab;
	break;
	}
	}
	else
	{
	if ((current_optab->base_opcode & (BR_COND_IDEN \| 0x00800000)) == (insn_word & (BR_COND_IDEN \| 0x00800000)))
	{
	insn->tm = current_optab;
	break;
	}
	}
	}
	}
	}
	break;
	default:
	return 0;
	}
	return 1;
	}

	int
	print_two_operand (info, insn_word, insn)
	disassemble_info *info;
	unsigned long insn_word;
	struct instruction *insn;
	{
	char name[12];
	char operand[2][13] =
	{
	{0},
	{0}};
	float f_number;

	if (insn->tm == NULL)
	return 0;
	strcpy (name, insn->tm->name);
	if (insn->tm->opcode_modifier == AddressMode)
	{
	int src_op, dest_op;
	/* Determine whether instruction is a store or a normal instruction. */
	if ((insn->tm->operand_types[1] & (Direct \| Indirect)) == (Direct \| Indirect))
	{
	src_op = 1;
	dest_op = 0;
	}
	else
	{
	src_op = 0;
	dest_op = 1;
	}
	/* Get the destination register. */
	if (insn->tm->operands == 2)
	get_register_operand ((insn_word & 0x001F0000) >> 16, operand[dest_op]);
	/* Get the source operand based on addressing mode. */
	switch (insn_word & AddressMode)
	{
	case AM_REGISTER:
	/* Check for the NOP instruction before getting the operand. */
	if ((insn->tm->operand_types[0] & NotReq) == 0)
	get_register_operand ((insn_word & 0x0000001F), operand[src_op]);
	break;
	case AM_DIRECT:
	sprintf (operand[src_op], "@0x%lX", (insn_word & 0x0000FFFF));
	break;
	case AM_INDIRECT:
	get_indirect_operand ((insn_word & 0x0000FFFF), 2, operand[src_op]);
	break;
	case AM_IMM:
	/* Get the value of the immediate operand based on variable type. */
	switch (insn->tm->imm_arg_type)
	{
	case Imm_Float:
	cnvt_tmsfloat_ieee ((insn_word & 0x0000FFFF), 2, &f_number);
	sprintf (operand[src_op], "%2.2f", f_number);
	break;
	case Imm_SInt:
	sprintf (operand[src_op], "%d", (short) (insn_word & 0x0000FFFF));
	break;
	case Imm_UInt:
	sprintf (operand[src_op], "%lu", (insn_word & 0x0000FFFF));
	break;
	default:
	return 0;
	}
	/* Handle special case for LDP instruction. */
	if ((insn_word & 0xFFFFFF00) == LDP_INSN)
	{
	strcpy (name, "ldp");
	sprintf (operand[0], "0x%06lX", (insn_word & 0x000000FF) << 16);
	operand[1][0] = '\0';
	}
	}
	}
	/* Handle case for stack and rotate instructions. */
	else if (insn->tm->operands == 1)
	{
	if (insn->tm->opcode_modifier == StackOp)
	{
	get_register_operand ((insn_word & 0x001F0000) >> 16, operand[0]);
	}
	}
	/* Output instruction to stream. */
	info->fprintf_func (info->stream, " %s %s%c%s", name,
	operand[0][0] ? operand[0] : "",
	operand[1][0] ? ',' : ' ',
	operand[1][0] ? operand[1] : "");
	return 1;
	}

	int
	print_three_operand (info, insn_word, insn)
	disassemble_info *info;
	unsigned long insn_word;
	struct instruction *insn;
	{
	char operand[3][13] =
	{
	{0},
	{0},
	{0}};

	if (insn->tm == NULL)
	return 0;
	switch (insn_word & AddressMode)
	{
	case AM_REGISTER:
	get_register_operand ((insn_word & 0x000000FF), operand[0]);
	get_register_operand ((insn_word & 0x0000FF00) >> 8, operand[1]);
	break;
	case AM_DIRECT:
	get_register_operand ((insn_word & 0x000000FF), operand[0]);
	get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1]);
	break;
	case AM_INDIRECT:
	get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0]);
	get_register_operand ((insn_word & 0x0000FF00) >> 8, operand[1]);
	break;
	case AM_IMM:
	get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0]);
	get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1]);
	break;
	default:
	return 0;
	}
	if (insn->tm->operands == 3)
	get_register_operand ((insn_word & 0x001F0000) >> 16, operand[2]);
	info->fprintf_func (info->stream, " %s %s,%s%c%s", insn->tm->name,
	operand[0], operand[1],
	operand[2][0] ? ',' : ' ',
	operand[2][0] ? operand[2] : "");
	return 1;
	}

	int
	print_par_insn (info, insn_word, insn)
	disassemble_info *info;
	unsigned long insn_word;
	struct instruction *insn;
	{
	size_t i, len;
	char name1, name2;
	char operand[2][3][13] =
	{
	{
	{0},
	{0},
	{0}},
	{
	{0},
	{0},
	{0}}};

	if (insn->ptm == NULL)
	return 0;
	/* Parse out the names of each of the parallel instructions from the
	q_insn1_insn2 format. */
	name1 = (char *) strdup (insn->ptm->name + 2);
	name2 = "";
	len = strlen (name1);
	for (i = 0; i < len; i++)
	{
	if (name1[i] == '_')
	{
	name2 = &name1[i + 1];
	name1[i] = '\0';
	break;
	}
	}
	/* Get the operands of the instruction based on the operand order. */
	switch (insn->ptm->oporder)
	{
	case OO_4op1:
	get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0][0]);
	get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1][1]);
	get_register_operand ((insn_word >> 16) & 0x07, operand[1][0]);
	get_register_operand ((insn_word >> 22) & 0x07, operand[0][1]);
	break;
	case OO_4op2:
	get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0][0]);
	get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1][0]);
	get_register_operand ((insn_word >> 19) & 0x07, operand[1][1]);
	get_register_operand ((insn_word >> 22) & 0x07, operand[0][1]);
	break;
	case OO_4op3:
	get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0][1]);
	get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1][1]);
	get_register_operand ((insn_word >> 16) & 0x07, operand[1][0]);
	get_register_operand ((insn_word >> 22) & 0x07, operand[0][0]);
	break;
	case OO_5op1:
	get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0][0]);
	get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1][1]);
	get_register_operand ((insn_word >> 16) & 0x07, operand[1][0]);
	get_register_operand ((insn_word >> 19) & 0x07, operand[0][1]);
	get_register_operand ((insn_word >> 22) & 0x07, operand[0][2]);
	break;
	case OO_5op2:
	get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0][1]);
	get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1][1]);
	get_register_operand ((insn_word >> 16) & 0x07, operand[1][0]);
	get_register_operand ((insn_word >> 19) & 0x07, operand[0][0]);
	get_register_operand ((insn_word >> 22) & 0x07, operand[0][2]);
	break;
	case OO_PField:
	if (insn_word & 0x00800000)
	get_register_operand (0x01, operand[0][2]);
	else
	get_register_operand (0x00, operand[0][2]);
	if (insn_word & 0x00400000)
	get_register_operand (0x03, operand[1][2]);
	else
	get_register_operand (0x02, operand[1][2]);
	switch (insn_word & P_FIELD)
	{
	case 0x00000000:
	get_indirect_operand ((insn_word & 0x000000FF), 1, operand[0][1]);
	get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[0][0]);
	get_register_operand ((insn_word >> 16) & 0x07, operand[1][1]);
	get_register_operand ((insn_word >> 19) & 0x07, operand[1][0]);
	break;
	case 0x01000000:
	get_indirect_operand ((insn_word & 0x000000FF), 1, operand[1][0]);
	get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[0][0]);
	get_register_operand ((insn_word >> 16) & 0x07, operand[1][1]);
	get_register_operand ((insn_word >> 19) & 0x07, operand[0][1]);
	break;
	case 0x02000000:
	get_indirect_operand ((insn_word & 0x000000FF), 1, operand[1][1]);
	get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[1][0]);
	get_register_operand ((insn_word >> 16) & 0x07, operand[0][1]);
	get_register_operand ((insn_word >> 19) & 0x07, operand[0][0]);
	break;
	case 0x03000000:
	get_indirect_operand ((insn_word & 0x000000FF), 1, operand[1][1]);
	get_indirect_operand ((insn_word & 0x0000FF00) >> 8, 1, operand[0][0]);
	get_register_operand ((insn_word >> 16) & 0x07, operand[1][0]);
	get_register_operand ((insn_word >> 19) & 0x07, operand[0][1]);
	break;
	}
	break;
	default:
	return 0;
	}
	info->fprintf_func (info->stream, " %s %s,%s%c%s", name1,
	operand[0][0], operand[0][1],
	operand[0][2][0] ? ',' : ' ',
	operand[0][2][0] ? operand[0][2] : "");
	info->fprintf_func (info->stream, "\n\t\t\t\|\| %s %s,%s%c%s", name2,
	operand[1][0], operand[1][1],
	operand[1][2][0] ? ',' : ' ',
	operand[1][2][0] ? operand[1][2] : "");
	free (name1);
	return 1;
	}

	int
	print_branch (info, insn_word, insn)
	disassemble_info *info;
	unsigned long insn_word;
	struct instruction *insn;
	{
	char operand[2][13] =
	{
	{0},
	{0}};
	unsigned long address;
	int print_label = 0;

	if (insn->tm == NULL)
	return 0;
	/* Get the operands for 24-bit immediate jumps. */
	if (insn->tm->operand_types[0] & Imm24)
	{
	address = insn_word & 0x00FFFFFF;
	sprintf (operand[0], "0x%lX", address);
	print_label = 1;
	}
	/* Get the operand for the trap instruction. */
	else if (insn->tm->operand_types[0] & IVector)
	{
	address = insn_word & 0x0000001F;
	sprintf (operand[0], "0x%lX", address);
	}
	else
	{
	address = insn_word & 0x0000FFFF;
	/* Get the operands for the DB instructions. */
	if (insn->tm->operands == 2)
	{
	get_register_operand (((insn_word & 0x01C00000) >> 22) + REG_AR0, operand[0]);
	if (insn_word & PCRel)
	{
	sprintf (operand[1], "%d", (short) address);
	print_label = 1;
	}
	else
	get_register_operand (insn_word & 0x0000001F, operand[1]);
	}
	/* Get the operands for the standard branches. */
	else if (insn->tm->operands == 1)
	{
	if (insn_word & PCRel)
	{
	address = (short) address;
	sprintf (operand[0], "%ld", address);
	print_label = 1;
	}
	else
	get_register_operand (insn_word & 0x0000001F, operand[0]);
	}
	}
	info->fprintf_func (info->stream, " %s %s%c%s", insn->tm->name,
	operand[0][0] ? operand[0] : "",
	operand[1][0] ? ',' : ' ',
	operand[1][0] ? operand[1] : "");
	/* Print destination of branch in relation to current symbol. */
	if (print_label && info->symbols)
	{
	asymbol sym = info->symbols;

	if ((insn->tm->opcode_modifier == PCRel) && (insn_word & PCRel))
	{
	address = (_pc + 1 + (short) address) - ((sym->section->vma + sym->value) / 4);
	/* Check for delayed instruction, if so adjust destination. */
	if (insn_word & 0x00200000)
	address += 2;
	}
	else
	{
	address -= ((sym->section->vma + sym->value) / 4);
	}
	if (address == 0)
	info->fprintf_func (info->stream, " <%s>", sym->name);
	else
	info->fprintf_func (info->stream, " <%s %c %d>", sym->name,
	((short) address < 0) ? '-' : '+',
	abs (address));
	}
	return 1;
	}

	int
	get_indirect_operand (fragment, size, buffer)
	unsigned short fragment;
	int size;
	char *buffer;
	{
	unsigned char mod;
	unsigned arnum;
	unsigned char disp;

	if (buffer == NULL)
	return 0;
	/* Determine which bits identify the sections of the indirect operand based on the
	size in bytes. */
	switch (size)
	{
	case 1:
	mod = (fragment & 0x00F8) >> 3;
	arnum = (fragment & 0x0007);
	disp = 0;
	break;
	case 2:
	mod = (fragment & 0xF800) >> 11;
	arnum = (fragment & 0x0700) >> 8;
	disp = (fragment & 0x00FF);
	break;
	default:
	return 0;
	}
	{
	const ind_addr_type *current_ind = tic30_indaddr_tab;
	for (; current_ind < tic30_indaddrtab_end; current_ind++)
	{
	if (current_ind->modfield == mod)
	{
	if (current_ind->displacement == IMPLIED_DISP && size == 2)
	{
	continue;
	}
	else
	{
	size_t i, len;
	int bufcnt;

	len = strlen (current_ind->syntax);
	for (i = 0, bufcnt = 0; i < len; i++, bufcnt++)
	{
	buffer[bufcnt] = current_ind->syntax[i];
	if (buffer[bufcnt - 1] == 'a' && buffer[bufcnt] == 'r')
	buffer[++bufcnt] = arnum + '0';
	if (buffer[bufcnt] == '(' && current_ind->displacement == DISP_REQUIRED)
	{
	sprintf (&buffer[bufcnt + 1], "%u", disp);
	bufcnt += strlen (&buffer[bufcnt + 1]);
	}
	}
	buffer[bufcnt + 1] = '\0';
	break;
	}
	}
	}
	}
	return 1;
	}

	int
	get_register_operand (fragment, buffer)
	unsigned char fragment;
	char *buffer;
	{
	const reg *current_reg = tic30_regtab;

	if (buffer == NULL)
	return 0;
	for (; current_reg < tic30_regtab_end; current_reg++)
	{
	if ((fragment & 0x1F) == current_reg->opcode)
	{
	strcpy (buffer, current_reg->name);
	return 1;
	}
	}
	return 0;
	}

	int
	cnvt_tmsfloat_ieee (tmsfloat, size, ieeefloat)
	unsigned long tmsfloat;
	int size;
	float *ieeefloat;
	{
	unsigned long exp, sign, mant;

	if (size == 2)
	{
	if ((tmsfloat & 0x0000F000) == 0x00008000)
	tmsfloat = 0x80000000;
	else
	{
	tmsfloat <<= 16;
	tmsfloat = (long) tmsfloat >> 4;
	}
	}
	exp = tmsfloat & 0xFF000000;
	if (exp == 0x80000000)
	{
	*ieeefloat = 0.0;
	return 1;
	}
	exp += 0x7F000000;
	sign = (tmsfloat & 0x00800000) << 8;
	mant = tmsfloat & 0x007FFFFF;
	if (exp == 0xFF000000)
	{
	if (mant == 0)
	*ieeefloat = ERANGE;
	if (sign == 0)
	*ieeefloat = 1.0 / 0.0;
	else
	*ieeefloat = -1.0 / 0.0;
	return 1;
	}
	exp >>= 1;
	if (sign)
	{
	mant = (~mant) & 0x007FFFFF;
	mant += 1;
	exp += mant & 0x00800000;
	exp &= 0x7F800000;
	mant &= 0x007FFFFF;
	}
	if (tmsfloat == 0x80000000)
	sign = mant = exp = 0;
	tmsfloat = sign \| exp \| mant;
	ieeefloat = ((float *) &tmsfloat);
	return 1;
	}