[deliverable/binutils-gdb.git] / opcodes / ia64-opc.c

/* ia64-opc.c -- Functions to access the compacted opcode table
   Copyright 1999, 2000, 2001, 2003, 2005, 2007, 2009 Free Software Foundation, Inc.
   Written by Bob Manson of Cygnus Solutions, <manson@cygnus.com>

   This file is part of the GNU opcodes library.

   This library is free software; you can redistribute it and/or modify
   it under the terms of the GNU General Public License as published by
   the Free Software Foundation; either version 3, or (at your option)
   any later version.

   It is distributed in the hope that it will be useful, but WITHOUT
   ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
   or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public
   License for more details.

   You should have received a copy of the GNU General Public License
   along with this file; see the file COPYING.  If not, write to the
   Free Software Foundation, 51 Franklin Street - Fifth Floor, Boston,
   MA 02110-1301, USA.  */

#include "ansidecl.h"
#include "sysdep.h"
#include "libiberty.h"
#include "ia64-asmtab.h"
#include "ia64-asmtab.c"

static void get_opc_prefix (const char **, char *);
static short int find_string_ent (const char *);
static short int find_main_ent (short int);
static short int find_completer (short int, short int, const char *);
static ia64_insn apply_completer (ia64_insn, int);
static int extract_op_bits (int, int, int);
static int extract_op (int, int *, unsigned int *);
static int opcode_verify (ia64_insn, int, enum ia64_insn_type);
static int locate_opcode_ent (ia64_insn, enum ia64_insn_type);
static struct ia64_opcode *make_ia64_opcode
  (ia64_insn, const char *, int, int);
static struct ia64_opcode *ia64_find_matching_opcode
  (const char *, short int);

const struct ia64_templ_desc ia64_templ_desc[16] =
  {
    { 0, { IA64_UNIT_M, IA64_UNIT_I, IA64_UNIT_I }, "MII" },	/* 0 */
    { 2, { IA64_UNIT_M, IA64_UNIT_I, IA64_UNIT_I }, "MII" },
    { 0, { IA64_UNIT_M, IA64_UNIT_L, IA64_UNIT_X }, "MLX" },
    { 0, { 0, },				    "-3-" },
    { 0, { IA64_UNIT_M, IA64_UNIT_M, IA64_UNIT_I }, "MMI" },	/* 4 */
    { 1, { IA64_UNIT_M, IA64_UNIT_M, IA64_UNIT_I }, "MMI" },
    { 0, { IA64_UNIT_M, IA64_UNIT_F, IA64_UNIT_I }, "MFI" },
    { 0, { IA64_UNIT_M, IA64_UNIT_M, IA64_UNIT_F }, "MMF" },
    { 0, { IA64_UNIT_M, IA64_UNIT_I, IA64_UNIT_B }, "MIB" },	/* 8 */
    { 0, { IA64_UNIT_M, IA64_UNIT_B, IA64_UNIT_B }, "MBB" },
    { 0, { 0, },				    "-a-" },
    { 0, { IA64_UNIT_B, IA64_UNIT_B, IA64_UNIT_B }, "BBB" },
    { 0, { IA64_UNIT_M, IA64_UNIT_M, IA64_UNIT_B }, "MMB" },	/* c */
    { 0, { 0, },				    "-d-" },
    { 0, { IA64_UNIT_M, IA64_UNIT_F, IA64_UNIT_B }, "MFB" },
    { 0, { 0, },				    "-f-" },
  };


/* Copy the prefix contained in *PTR (up to a '.' or a NUL) to DEST.
   PTR will be adjusted to point to the start of the next portion
   of the opcode, or at the NUL character. */

static void
get_opc_prefix (const char **ptr, char *dest)
{
  char *c = strchr (*ptr, '.');
  if (c != NULL)
    {
      memcpy (dest, *ptr, c - *ptr);
      dest[c - *ptr] = '\0';
      *ptr = c + 1;
    }
  else
    {
      int l = strlen (*ptr);
      memcpy (dest, *ptr, l);
      dest[l] = '\0';
      *ptr += l;
    }
}
\f
/* Find the index of the entry in the string table corresponding to
   STR; return -1 if one does not exist. */

static short
find_string_ent (const char *str)
{
  short start = 0;
  short end = sizeof (ia64_strings) / sizeof (const char *);
  short i = (start + end) / 2;

  if (strcmp (str, ia64_strings[end - 1]) > 0)
    {
      return -1;
    }
  while (start <= end)
    {
      int c = strcmp (str, ia64_strings[i]);
      if (c < 0)
	{
	  end = i - 1;
	}
      else if (c == 0)
	{
	  return i;
	}
      else
	{
	  start = i + 1;
	}
      i = (start + end) / 2;
    }
  return -1;
}
\f
/* Find the opcode in the main opcode table whose name is STRINGINDEX, or
   return -1 if one does not exist. */

static short
find_main_ent (short nameindex)
{
  short start = 0;
  short end = sizeof (main_table) / sizeof (struct ia64_main_table);
  short i = (start + end) / 2;

  if (nameindex < main_table[0].name_index
      || nameindex > main_table[end - 1].name_index)
    {
      return -1;
    }
  while (start <= end)
    {
      if (nameindex < main_table[i].name_index)
	{
	  end = i - 1;
	}
      else if (nameindex == main_table[i].name_index)
	{
	  while (i > 0 && main_table[i - 1].name_index == nameindex)
	    {
	      i--;
	    }
	  return i;
	}
      else
	{
	  start = i + 1;
	}
      i = (start + end) / 2;
    }
  return -1;
}
\f
/* Find the index of the entry in the completer table that is part of
   MAIN_ENT (starting from PREV_COMPLETER) that matches NAME, or
   return -1 if one does not exist. */

static short
find_completer (short main_ent, short prev_completer, const char *name)
{
  short name_index = find_string_ent (name);

  if (name_index < 0)
    {
      return -1;
    }

  if (prev_completer == -1)
    {
      prev_completer = main_table[main_ent].completers;
    }
  else
    {
      prev_completer = completer_table[prev_completer].subentries;
    }

  while (prev_completer != -1)
    {
      if (completer_table[prev_completer].name_index == name_index)
	{
	  return prev_completer;
	}
      prev_completer = completer_table[prev_completer].alternative;
    }
  return -1;
}
\f
/* Apply the completer referred to by COMPLETER_INDEX to OPCODE, and
   return the result. */

static ia64_insn
apply_completer (ia64_insn opcode, int completer_index)
{
  ia64_insn mask = completer_table[completer_index].mask;
  ia64_insn bits = completer_table[completer_index].bits;
  int shiftamt = (completer_table[completer_index].offset & 63);

  mask = mask << shiftamt;
  bits = bits << shiftamt;
  opcode = (opcode & ~mask) | bits;
  return opcode;
}
\f
/* Extract BITS number of bits starting from OP_POINTER + BITOFFSET in
   the dis_table array, and return its value.  (BITOFFSET is numbered
   starting from MSB to LSB, so a BITOFFSET of 0 indicates the MSB of the
   first byte in OP_POINTER.) */

static int
extract_op_bits (int op_pointer, int bitoffset, int bits)
{
  int res = 0;

  op_pointer += (bitoffset / 8);

  if (bitoffset % 8)
    {
      unsigned int op = dis_table[op_pointer++];
      int numb = 8 - (bitoffset % 8);
      int mask = (1 << numb) - 1;
      int bata = (bits < numb) ? bits : numb;
      int delta = numb - bata;

      res = (res << bata) | ((op & mask) >> delta);
      bitoffset += bata;
      bits -= bata;
    }
  while (bits >= 8)
    {
      res = (res << 8) | (dis_table[op_pointer++] & 255);
      bits -= 8;
    }
  if (bits > 0)
    {
      unsigned int op = (dis_table[op_pointer++] & 255);
      res = (res << bits) | (op >> (8 - bits));
    }
  return res;
}
\f
/* Examine the state machine entry at OP_POINTER in the dis_table
   array, and extract its values into OPVAL and OP.  The length of the
   state entry in bits is returned. */

static int
extract_op (int op_pointer, int *opval, unsigned int *op)
{
  int oplen = 5;

  *op = dis_table[op_pointer];

  if ((*op) & 0x40)
    {
      opval[0] = extract_op_bits (op_pointer, oplen, 5);
      oplen += 5;
    }
  switch ((*op) & 0x30)
    {
    case 0x10:
      {
	opval[1] = extract_op_bits (op_pointer, oplen, 8);
	oplen += 8;
	opval[1] += op_pointer;
	break;
      }
    case 0x20:
      {
	opval[1] = extract_op_bits (op_pointer, oplen, 16);
	if (! (opval[1] & 32768))
	  {
	    opval[1] += op_pointer;
	  }
	oplen += 16;
	break;
      }
    case 0x30:
      {
	oplen--;
	opval[2] = extract_op_bits (op_pointer, oplen, 12);
	oplen += 12;
	opval[2] |= 32768;
	break;
      }
    }
  if (((*op) & 0x08) && (((*op) & 0x30) != 0x30))
    {
      opval[2] = extract_op_bits (op_pointer, oplen, 16);
      oplen += 16;
      if (! (opval[2] & 32768))
	{
	  opval[2] += op_pointer;
	}
    }
  return oplen;
}
\f
/* Returns a non-zero value if the opcode in the main_table list at
   PLACE matches OPCODE and is of type TYPE. */

static int
opcode_verify (ia64_insn opcode, int place, enum ia64_insn_type type)
{
  if (main_table[place].opcode_type != type)
    {
      return 0;
    }
  if (main_table[place].flags
      & (IA64_OPCODE_F2_EQ_F3 | IA64_OPCODE_LEN_EQ_64MCNT))
    {
      const struct ia64_operand *o1, *o2;
      ia64_insn f2, f3;

      if (main_table[place].flags & IA64_OPCODE_F2_EQ_F3)
	{
	  o1 = elf64_ia64_operands + IA64_OPND_F2;
	  o2 = elf64_ia64_operands + IA64_OPND_F3;
	  (*o1->extract) (o1, opcode, &f2);
	  (*o2->extract) (o2, opcode, &f3);
	  if (f2 != f3)
	    return 0;
	}
      else
	{
	  ia64_insn len, count;

	  /* length must equal 64-count: */
	  o1 = elf64_ia64_operands + IA64_OPND_LEN6;
	  o2 = elf64_ia64_operands + main_table[place].operands[2];
	  (*o1->extract) (o1, opcode, &len);
	  (*o2->extract) (o2, opcode, &count);
	  if (len != 64 - count)
	    return 0;
	}
    }
  return 1;
}
\f
/* Find an instruction entry in the ia64_dis_names array that matches
   opcode OPCODE and is of type TYPE.  Returns either a positive index
   into the array, or a negative value if an entry for OPCODE could
   not be found.  Checks all matches and returns the one with the highest
   priority. */

static int
locate_opcode_ent (ia64_insn opcode, enum ia64_insn_type type)
{
  int currtest[41];
  int bitpos[41];
  int op_ptr[41];
  int currstatenum = 0;
  short found_disent = -1;
  short found_priority = -1;

  currtest[currstatenum] = 0;
  op_ptr[currstatenum] = 0;
  bitpos[currstatenum] = 40;

  while (1)
    {
      int op_pointer = op_ptr[currstatenum];
      unsigned int op;
      int currbitnum = bitpos[currstatenum];
      int oplen;
      int opval[3] = {0};
      int next_op;
      int currbit;

      oplen = extract_op (op_pointer, opval, &op);

      bitpos[currstatenum] = currbitnum;

      /* Skip opval[0] bits in the instruction. */
      if (op & 0x40)
	{
	  currbitnum -= opval[0];
	}

      /* The value of the current bit being tested. */
      currbit = opcode & (((ia64_insn) 1) << currbitnum) ? 1 : 0;
      next_op = -1;

      /* We always perform the tests specified in the current state in
	 a particular order, falling through to the next test if the
	 previous one failed. */
      switch (currtest[currstatenum])
	{
	case 0:
	  currtest[currstatenum]++;
	  if (currbit == 0 && (op & 0x80))
	    {
	      /* Check for a zero bit.  If this test solely checks for
		 a zero bit, we can check for up to 8 consecutive zero
		 bits (the number to check is specified by the lower 3
		 bits in the state code.)

		 If the state instruction matches, we go to the very
		 next state instruction; otherwise, try the next test. */

	      if ((op & 0xf8) == 0x80)
		{
		  int count = op & 0x7;
		  int x;

		  for (x = 0; x <= count; x++)
		    {
		      int i =
			opcode & (((ia64_insn) 1) << (currbitnum - x)) ? 1 : 0;
		      if (i)
			{
			  break;
			}
		    }
		  if (x > count)
		    {
		      next_op = op_pointer + ((oplen + 7) / 8);
		      currbitnum -= count;
		      break;
		    }
		}
	      else if (! currbit)
		{
		  next_op = op_pointer + ((oplen + 7) / 8);
		  break;
		}
	    }
	  /* FALLTHROUGH */
	case 1:
	  /* If the bit in the instruction is one, go to the state
	     instruction specified by opval[1]. */
	  currtest[currstatenum]++;
	  if (currbit && (op & 0x30) != 0 && ((op & 0x30) != 0x30))
	    {
	      next_op = opval[1];
	      break;
	    }
	  /* FALLTHROUGH */
	case 2:
	  /* Don't care.  Skip the current bit and go to the state
	     instruction specified by opval[2].

	     An encoding of 0x30 is special; this means that a 12-bit
	     offset into the ia64_dis_names[] array is specified.  */
	  currtest[currstatenum]++;
	  if ((op & 0x08) || ((op & 0x30) == 0x30))
	    {
	      next_op = opval[2];
	      break;
	    }
	}

      /* If bit 15 is set in the address of the next state, an offset
	 in the ia64_dis_names array was specified instead.  We then
	 check to see if an entry in the list of opcodes matches the
	 opcode we were given; if so, we have succeeded.  */

      if ((next_op >= 0) && (next_op & 32768))
	{
	  short disent = next_op & 32767;
          short priority = -1;

	  if (next_op > 65535)
	    {
	      abort ();
	    }

	  /* Run through the list of opcodes to check, trying to find
	     one that matches.  */
	  while (disent >= 0)
	    {
	      int place = ia64_dis_names[disent].insn_index;

              priority = ia64_dis_names[disent].priority;

	      if (opcode_verify (opcode, place, type)
                  && priority > found_priority)
		{
		  break;
		}
	      if (ia64_dis_names[disent].next_flag)
		{
		  disent++;
		}
	      else
		{
		  disent = -1;
		}
	    }

	  if (disent >= 0)
	    {
              found_disent = disent;
              found_priority = priority;
	    }
          /* Try the next test in this state, regardless of whether a match
             was found. */
          next_op = -2;
	}

      /* next_op == -1 is "back up to the previous state".
	 next_op == -2 is "stay in this state and try the next test".
	 Otherwise, transition to the state indicated by next_op. */

      if (next_op == -1)
	{
	  currstatenum--;
	  if (currstatenum < 0)
	    {
              return found_disent;
	    }
	}
      else if (next_op >= 0)
	{
	  currstatenum++;
	  bitpos[currstatenum] = currbitnum - 1;
	  op_ptr[currstatenum] = next_op;
	  currtest[currstatenum] = 0;
	}
    }
}
\f
/* Construct an ia64_opcode entry based on OPCODE, NAME and PLACE. */

static struct ia64_opcode *
make_ia64_opcode (ia64_insn opcode, const char *name, int place, int depind)
{
  struct ia64_opcode *res =
    (struct ia64_opcode *) xmalloc (sizeof (struct ia64_opcode));
  res->name = xstrdup (name);
  res->type = main_table[place].opcode_type;
  res->num_outputs = main_table[place].num_outputs;
  res->opcode = opcode;
  res->mask = main_table[place].mask;
  res->operands[0] = main_table[place].operands[0];
  res->operands[1] = main_table[place].operands[1];
  res->operands[2] = main_table[place].operands[2];
  res->operands[3] = main_table[place].operands[3];
  res->operands[4] = main_table[place].operands[4];
  res->flags = main_table[place].flags;
  res->ent_index = place;
  res->dependencies = &op_dependencies[depind];
  return res;
}
\f
/* Determine the ia64_opcode entry for the opcode specified by INSN
   and TYPE.  If a valid entry is not found, return NULL. */
struct ia64_opcode *
ia64_dis_opcode (ia64_insn insn, enum ia64_insn_type type)
{
  int disent = locate_opcode_ent (insn, type);

  if (disent < 0)
    {
      return NULL;
    }
  else
    {
      unsigned int cb = ia64_dis_names[disent].completer_index;
      static char name[128];
      int place = ia64_dis_names[disent].insn_index;
      int ci = main_table[place].completers;
      ia64_insn tinsn = main_table[place].opcode;

      strcpy (name, ia64_strings [main_table[place].name_index]);

      while (cb)
	{
	  if (cb & 1)
	    {
	      int cname = completer_table[ci].name_index;

	      tinsn = apply_completer (tinsn, ci);

	      if (ia64_strings[cname][0] != '\0')
		{
		  strcat (name, ".");
		  strcat (name, ia64_strings[cname]);
		}
	      if (cb != 1)
		{
		  ci = completer_table[ci].subentries;
		}
	    }
	  else
	    {
	      ci = completer_table[ci].alternative;
	    }
	  if (ci < 0)
	    {
	      abort ();
	    }
	  cb = cb >> 1;
	}
      if (tinsn != (insn & main_table[place].mask))
	{
	  abort ();
	}
      return make_ia64_opcode (insn, name, place,
                               completer_table[ci].dependencies);
    }
}
\f
/* Search the main_opcode table starting from PLACE for an opcode that
   matches NAME.  Return NULL if one is not found. */

static struct ia64_opcode *
ia64_find_matching_opcode (const char *name, short place)
{
  char op[129];
  const char *suffix;
  short name_index;

  if (strlen (name) > 128)
    {
      return NULL;
    }
  suffix = name;
  get_opc_prefix (&suffix, op);
  name_index = find_string_ent (op);
  if (name_index < 0)
    {
      return NULL;
    }

  while (main_table[place].name_index == name_index)
    {
      const char *curr_suffix = suffix;
      ia64_insn curr_insn = main_table[place].opcode;
      short completer = -1;

      do {
	if (suffix[0] == '\0')
	  {
	    completer = find_completer (place, completer, suffix);
	  }
	else
	  {
	    get_opc_prefix (&curr_suffix, op);
	    completer = find_completer (place, completer, op);
	  }
	if (completer != -1)
	  {
	    curr_insn = apply_completer (curr_insn, completer);
	  }
      } while (completer != -1 && curr_suffix[0] != '\0');

      if (completer != -1 && curr_suffix[0] == '\0'
	  && completer_table[completer].terminal_completer)
	{
          int depind = completer_table[completer].dependencies;
	  return make_ia64_opcode (curr_insn, name, place, depind);
	}
      else
	{
	  place++;
	}
    }
  return NULL;
}
\f
/* Find the next opcode after PREV_ENT that matches PREV_ENT, or return NULL
   if one does not exist.

   It is the caller's responsibility to invoke ia64_free_opcode () to
   release any resources used by the returned entry. */

struct ia64_opcode *
ia64_find_next_opcode (struct ia64_opcode *prev_ent)
{
  return ia64_find_matching_opcode (prev_ent->name,
				    prev_ent->ent_index + 1);
}

/* Find the first opcode that matches NAME, or return NULL if it does
   not exist.

   It is the caller's responsibility to invoke ia64_free_opcode () to
   release any resources used by the returned entry. */

struct ia64_opcode *
ia64_find_opcode (const char *name)
{
  char op[129];
  const char *suffix;
  short place;
  short name_index;

  if (strlen (name) > 128)
    {
      return NULL;
    }
  suffix = name;
  get_opc_prefix (&suffix, op);
  name_index = find_string_ent (op);
  if (name_index < 0)
    {
      return NULL;
    }

  place = find_main_ent (name_index);

  if (place < 0)
    {
      return NULL;
    }
  return ia64_find_matching_opcode (name, place);
}

/* Free any resources used by ENT. */
void
ia64_free_opcode (struct ia64_opcode *ent)
{
  free ((void *)ent->name);
  free (ent);
}

const struct ia64_dependency *
ia64_find_dependency (int dep_index)
{
  dep_index = DEP(dep_index);

  if (dep_index < 0
      || dep_index >= (int) ARRAY_SIZE (dependencies))
    return NULL;

  return &dependencies[dep_index];
}
Commit	Line	Data
800eeca4	1	/* ia64-opc.c -- Functions to access the compacted opcode table
91d6fa6a	2	Copyright 1999, 2000, 2001, 2003, 2005, 2007, 2009 Free Software Foundation, Inc.
800eeca4 JW	3	Written by Bob Manson of Cygnus Solutions, <manson@cygnus.com>
800eeca4 JW	4
9b201bb5	5	This file is part of the GNU opcodes library.
800eeca4	6
9b201bb5 NC	7	This library is free software; you can redistribute it and/or modify
	8	it under the terms of the GNU General Public License as published by
	9	the Free Software Foundation; either version 3, or (at your option)
	10	any later version.
800eeca4	11
9b201bb5 NC	12	It is distributed in the hope that it will be useful, but WITHOUT
	13	ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
	14	or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public
	15	License for more details.
800eeca4 JW	16
	17	You should have received a copy of the GNU General Public License
	18	along with this file; see the file COPYING. If not, write to the
9b201bb5 NC	19	Free Software Foundation, 51 Franklin Street - Fifth Floor, Boston,
9b201bb5 NC	20	MA 02110-1301, USA. */
800eeca4 JW	21
800eeca4 JW	22	#include "ansidecl.h"
800eeca4	23	#include "sysdep.h"
10b076a2	24	#include "libiberty.h"
800eeca4 JW	25	#include "ia64-asmtab.h"
	26	#include "ia64-asmtab.c"
	27
26ca5450 AJ	28	static void get_opc_prefix (const char *, char );
	29	static short int find_string_ent (const char *);
	30	static short int find_main_ent (short int);
	31	static short int find_completer (short int, short int, const char *);
	32	static ia64_insn apply_completer (ia64_insn, int);
	33	static int extract_op_bits (int, int, int);
	34	static int extract_op (int, int , unsigned int );
	35	static int opcode_verify (ia64_insn, int, enum ia64_insn_type);
	36	static int locate_opcode_ent (ia64_insn, enum ia64_insn_type);
279a96ca	37	static struct ia64_opcode *make_ia64_opcode
26ca5450	38	(ia64_insn, const char *, int, int);
279a96ca	39	static struct ia64_opcode *ia64_find_matching_opcode
26ca5450	40	(const char *, short int);
279a96ca	41
800eeca4 JW	42	const struct ia64_templ_desc ia64_templ_desc[16] =
	43	{
	44	{ 0, { IA64_UNIT_M, IA64_UNIT_I, IA64_UNIT_I }, "MII" }, /* 0 */
	45	{ 2, { IA64_UNIT_M, IA64_UNIT_I, IA64_UNIT_I }, "MII" },
	46	{ 0, { IA64_UNIT_M, IA64_UNIT_L, IA64_UNIT_X }, "MLX" },
	47	{ 0, { 0, }, "-3-" },
	48	{ 0, { IA64_UNIT_M, IA64_UNIT_M, IA64_UNIT_I }, "MMI" }, /* 4 */
	49	{ 1, { IA64_UNIT_M, IA64_UNIT_M, IA64_UNIT_I }, "MMI" },
	50	{ 0, { IA64_UNIT_M, IA64_UNIT_F, IA64_UNIT_I }, "MFI" },
	51	{ 0, { IA64_UNIT_M, IA64_UNIT_M, IA64_UNIT_F }, "MMF" },
	52	{ 0, { IA64_UNIT_M, IA64_UNIT_I, IA64_UNIT_B }, "MIB" }, /* 8 */
	53	{ 0, { IA64_UNIT_M, IA64_UNIT_B, IA64_UNIT_B }, "MBB" },
	54	{ 0, { 0, }, "-a-" },
	55	{ 0, { IA64_UNIT_B, IA64_UNIT_B, IA64_UNIT_B }, "BBB" },
	56	{ 0, { IA64_UNIT_M, IA64_UNIT_M, IA64_UNIT_B }, "MMB" }, /* c */
	57	{ 0, { 0, }, "-d-" },
	58	{ 0, { IA64_UNIT_M, IA64_UNIT_F, IA64_UNIT_B }, "MFB" },
	59	{ 0, { 0, }, "-f-" },
	60	};
	61
	62
	63	/* Copy the prefix contained in *PTR (up to a '.' or a NUL) to DEST.
	64	PTR will be adjusted to point to the start of the next portion
	65	of the opcode, or at the NUL character. */
	66
	67	static void
26ca5450	68	get_opc_prefix (const char *ptr, char dest)
800eeca4 JW	69	{
	70	char c = strchr (ptr, '.');
	71	if (c != NULL)
	72	{
	73	memcpy (dest, ptr, c - ptr);
	74	dest[c - *ptr] = '\0';
	75	*ptr = c + 1;
	76	}
	77	else
	78	{
	79	int l = strlen (*ptr);
	80	memcpy (dest, *ptr, l);
	81	dest[l] = '\0';
	82	*ptr += l;
	83	}
	84	}
	85	\f
	86	/* Find the index of the entry in the string table corresponding to
	87	STR; return -1 if one does not exist. */
	88
	89	static short
26ca5450	90	find_string_ent (const char *str)
800eeca4 JW	91	{
	92	short start = 0;
	93	short end = sizeof (ia64_strings) / sizeof (const char *);
	94	short i = (start + end) / 2;
	95
	96	if (strcmp (str, ia64_strings[end - 1]) > 0)
	97	{
	98	return -1;
	99	}
	100	while (start <= end)
	101	{
	102	int c = strcmp (str, ia64_strings[i]);
	103	if (c < 0)
	104	{
	105	end = i - 1;
	106	}
	107	else if (c == 0)
	108	{
	109	return i;
	110	}
	111	else
	112	{
	113	start = i + 1;
	114	}
	115	i = (start + end) / 2;
	116	}
	117	return -1;
	118	}
	119	\f
	120	/* Find the opcode in the main opcode table whose name is STRINGINDEX, or
	121	return -1 if one does not exist. */
	122
	123	static short
26ca5450	124	find_main_ent (short nameindex)
800eeca4 JW	125	{
	126	short start = 0;
	127	short end = sizeof (main_table) / sizeof (struct ia64_main_table);
	128	short i = (start + end) / 2;
	129
	130	if (nameindex < main_table[0].name_index
	131	\|\| nameindex > main_table[end - 1].name_index)
	132	{
	133	return -1;
	134	}
	135	while (start <= end)
	136	{
	137	if (nameindex < main_table[i].name_index)
	138	{
	139	end = i - 1;
	140	}
	141	else if (nameindex == main_table[i].name_index)
	142	{
	143	while (i > 0 && main_table[i - 1].name_index == nameindex)
	144	{
	145	i--;
	146	}
	147	return i;
	148	}
	149	else
	150	{
	151	start = i + 1;
	152	}
	153	i = (start + end) / 2;
	154	}
	155	return -1;
	156	}
	157	\f
	158	/* Find the index of the entry in the completer table that is part of
	159	MAIN_ENT (starting from PREV_COMPLETER) that matches NAME, or
	160	return -1 if one does not exist. */
	161
279a96ca	162	static short
26ca5450	163	find_completer (short main_ent, short prev_completer, const char *name)
800eeca4 JW	164	{
	165	short name_index = find_string_ent (name);
	166
	167	if (name_index < 0)
	168	{
	169	return -1;
	170	}
	171
	172	if (prev_completer == -1)
	173	{
	174	prev_completer = main_table[main_ent].completers;
	175	}
	176	else
	177	{
	178	prev_completer = completer_table[prev_completer].subentries;
	179	}
	180
	181	while (prev_completer != -1)
	182	{
	183	if (completer_table[prev_completer].name_index == name_index)
	184	{
	185	return prev_completer;
	186	}
	187	prev_completer = completer_table[prev_completer].alternative;
	188	}
	189	return -1;
	190	}
	191	\f
	192	/* Apply the completer referred to by COMPLETER_INDEX to OPCODE, and
	193	return the result. */
	194
	195	static ia64_insn
26ca5450	196	apply_completer (ia64_insn opcode, int completer_index)
800eeca4 JW	197	{
	198	ia64_insn mask = completer_table[completer_index].mask;
	199	ia64_insn bits = completer_table[completer_index].bits;
	200	int shiftamt = (completer_table[completer_index].offset & 63);
	201
	202	mask = mask << shiftamt;
	203	bits = bits << shiftamt;
	204	opcode = (opcode & ~mask) \| bits;
	205	return opcode;
	206	}
	207	\f
	208	/* Extract BITS number of bits starting from OP_POINTER + BITOFFSET in
	209	the dis_table array, and return its value. (BITOFFSET is numbered
	210	starting from MSB to LSB, so a BITOFFSET of 0 indicates the MSB of the
	211	first byte in OP_POINTER.) */
	212
	213	static int
26ca5450	214	extract_op_bits (int op_pointer, int bitoffset, int bits)
800eeca4 JW	215	{
	216	int res = 0;
	217
	218	op_pointer += (bitoffset / 8);
	219
	220	if (bitoffset % 8)
	221	{
	222	unsigned int op = dis_table[op_pointer++];
	223	int numb = 8 - (bitoffset % 8);
	224	int mask = (1 << numb) - 1;
	225	int bata = (bits < numb) ? bits : numb;
	226	int delta = numb - bata;
	227
	228	res = (res << bata) \| ((op & mask) >> delta);
	229	bitoffset += bata;
	230	bits -= bata;
	231	}
	232	while (bits >= 8)
	233	{
	234	res = (res << 8) \| (dis_table[op_pointer++] & 255);
	235	bits -= 8;
	236	}
	237	if (bits > 0)
	238	{
	239	unsigned int op = (dis_table[op_pointer++] & 255);
	240	res = (res << bits) \| (op >> (8 - bits));
	241	}
	242	return res;
	243	}
	244	\f
	245	/* Examine the state machine entry at OP_POINTER in the dis_table
	246	array, and extract its values into OPVAL and OP. The length of the
	247	state entry in bits is returned. */
	248
	249	static int
26ca5450	250	extract_op (int op_pointer, int opval, unsigned int op)
800eeca4 JW	251	{
	252	int oplen = 5;
	253
	254	*op = dis_table[op_pointer];
	255
	256	if ((*op) & 0x40)
	257	{
	258	opval[0] = extract_op_bits (op_pointer, oplen, 5);
	259	oplen += 5;
	260	}
	261	switch ((*op) & 0x30)
	262	{
	263	case 0x10:
	264	{
	265	opval[1] = extract_op_bits (op_pointer, oplen, 8);
	266	oplen += 8;
	267	opval[1] += op_pointer;
	268	break;
	269	}
	270	case 0x20:
	271	{
	272	opval[1] = extract_op_bits (op_pointer, oplen, 16);
	273	if (! (opval[1] & 32768))
	274	{
	275	opval[1] += op_pointer;
	276	}
	277	oplen += 16;
	278	break;
	279	}
	280	case 0x30:
	281	{
	282	oplen--;
	283	opval[2] = extract_op_bits (op_pointer, oplen, 12);
	284	oplen += 12;
	285	opval[2] \|= 32768;
	286	break;
	287	}
	288	}
	289	if (((op) & 0x08) && (((op) & 0x30) != 0x30))
	290	{
	291	opval[2] = extract_op_bits (op_pointer, oplen, 16);
	292	oplen += 16;
	293	if (! (opval[2] & 32768))
	294	{
	295	opval[2] += op_pointer;
	296	}
	297	}
	298	return oplen;
	299	}
	300	\f
	301	/* Returns a non-zero value if the opcode in the main_table list at
	302	PLACE matches OPCODE and is of type TYPE. */
	303
	304	static int
26ca5450	305	opcode_verify (ia64_insn opcode, int place, enum ia64_insn_type type)
800eeca4 JW	306	{
	307	if (main_table[place].opcode_type != type)
	308	{
	309	return 0;
	310	}
279a96ca	311	if (main_table[place].flags
800eeca4 JW	312	& (IA64_OPCODE_F2_EQ_F3 \| IA64_OPCODE_LEN_EQ_64MCNT))
	313	{
	314	const struct ia64_operand o1, o2;
	315	ia64_insn f2, f3;
	316
	317	if (main_table[place].flags & IA64_OPCODE_F2_EQ_F3)
	318	{
	319	o1 = elf64_ia64_operands + IA64_OPND_F2;
	320	o2 = elf64_ia64_operands + IA64_OPND_F3;
	321	(*o1->extract) (o1, opcode, &f2);
	322	(*o2->extract) (o2, opcode, &f3);
	323	if (f2 != f3)
	324	return 0;
	325	}
	326	else
	327	{
	328	ia64_insn len, count;
	329
	330	/* length must equal 64-count: */
	331	o1 = elf64_ia64_operands + IA64_OPND_LEN6;
	332	o2 = elf64_ia64_operands + main_table[place].operands[2];
	333	(*o1->extract) (o1, opcode, &len);
	334	(*o2->extract) (o2, opcode, &count);
	335	if (len != 64 - count)
	336	return 0;
	337	}
	338	}
	339	return 1;
	340	}
	341	\f
	342	/* Find an instruction entry in the ia64_dis_names array that matches
	343	opcode OPCODE and is of type TYPE. Returns either a positive index
	344	into the array, or a negative value if an entry for OPCODE could
aa170a07 TW	345	not be found. Checks all matches and returns the one with the highest
aa170a07 TW	346	priority. */
800eeca4 JW	347
800eeca4 JW	348	static int
26ca5450	349	locate_opcode_ent (ia64_insn opcode, enum ia64_insn_type type)
800eeca4 JW	350	{
	351	int currtest[41];
	352	int bitpos[41];
	353	int op_ptr[41];
	354	int currstatenum = 0;
aa170a07 TW	355	short found_disent = -1;
aa170a07 TW	356	short found_priority = -1;
800eeca4 JW	357
	358	currtest[currstatenum] = 0;
	359	op_ptr[currstatenum] = 0;
	360	bitpos[currstatenum] = 40;
	361
	362	while (1)
	363	{
	364	int op_pointer = op_ptr[currstatenum];
	365	unsigned int op;
	366	int currbitnum = bitpos[currstatenum];
	367	int oplen;
33b71eeb	368	int opval[3] = {0};
800eeca4 JW	369	int next_op;
	370	int currbit;
	371
	372	oplen = extract_op (op_pointer, opval, &op);
	373
	374	bitpos[currstatenum] = currbitnum;
	375
	376	/* Skip opval[0] bits in the instruction. */
	377	if (op & 0x40)
	378	{
	379	currbitnum -= opval[0];
	380	}
	381
	382	/* The value of the current bit being tested. */
	383	currbit = opcode & (((ia64_insn) 1) << currbitnum) ? 1 : 0;
	384	next_op = -1;
	385
	386	/* We always perform the tests specified in the current state in
	387	a particular order, falling through to the next test if the
	388	previous one failed. */
	389	switch (currtest[currstatenum])
	390	{
	391	case 0:
	392	currtest[currstatenum]++;
	393	if (currbit == 0 && (op & 0x80))
	394	{
	395	/* Check for a zero bit. If this test solely checks for
	396	a zero bit, we can check for up to 8 consecutive zero
	397	bits (the number to check is specified by the lower 3
	398	bits in the state code.)
	399
	400	If the state instruction matches, we go to the very
	401	next state instruction; otherwise, try the next test. */
	402
	403	if ((op & 0xf8) == 0x80)
	404	{
	405	int count = op & 0x7;
	406	int x;
	407
	408	for (x = 0; x <= count; x++)
	409	{
	410	int i =
	411	opcode & (((ia64_insn) 1) << (currbitnum - x)) ? 1 : 0;
	412	if (i)
	413	{
	414	break;
	415	}
	416	}
	417	if (x > count)
	418	{
	419	next_op = op_pointer + ((oplen + 7) / 8);
	420	currbitnum -= count;
	421	break;
	422	}
	423	}
	424	else if (! currbit)
	425	{
	426	next_op = op_pointer + ((oplen + 7) / 8);
	427	break;
	428	}
	429	}
	430	/* FALLTHROUGH */
	431	case 1:
	432	/* If the bit in the instruction is one, go to the state
433	instruction specified by opval[1]. */
434	currtest[currstatenum]++;
435	if (currbit && (op & 0x30) != 0 && ((op & 0x30) != 0x30))
436	{
437	next_op = opval[1];
438	break;
439	}
440	/* FALLTHROUGH */
441	case 2:
442	/* Don't care. Skip the current bit and go to the state
443	instruction specified by opval[2].
444
445	An encoding of 0x30 is special; this means that a 12-bit
446	offset into the ia64_dis_names[] array is specified. */
447	currtest[currstatenum]++;
448	if ((op & 0x08) \|\| ((op & 0x30) == 0x30))
449	{
450	next_op = opval[2];
451	break;
452	}
453	}
454
455	/* If bit 15 is set in the address of the next state, an offset
456	in the ia64_dis_names array was specified instead. We then
457	check to see if an entry in the list of opcodes matches the
458	opcode we were given; if so, we have succeeded. */
459
460	if ((next_op >= 0) && (next_op & 32768))
461	{
462	short disent = next_op & 32767;
aa170a07	463	short priority = -1;
800eeca4 JW	464
	465	if (next_op > 65535)
	466	{
	467	abort ();
	468	}
	469
	470	/* Run through the list of opcodes to check, trying to find
	471	one that matches. */
	472	while (disent >= 0)
	473	{
	474	int place = ia64_dis_names[disent].insn_index;
	475
aa170a07 TW	476	priority = ia64_dis_names[disent].priority;
aa170a07 TW	477
279a96ca	478	if (opcode_verify (opcode, place, type)
aa170a07	479	&& priority > found_priority)
800eeca4 JW	480	{
	481	break;
	482	}
	483	if (ia64_dis_names[disent].next_flag)
	484	{
	485	disent++;
	486	}
	487	else
	488	{
	489	disent = -1;
	490	}
	491	}
	492
	493	if (disent >= 0)
	494	{
aa170a07 TW	495	found_disent = disent;
aa170a07 TW	496	found_priority = priority;
800eeca4	497	}
aa170a07 TW	498	/* Try the next test in this state, regardless of whether a match
	499	was found. */
	500	next_op = -2;
800eeca4 JW	501	}
	502
	503	/* next_op == -1 is "back up to the previous state".
	504	next_op == -2 is "stay in this state and try the next test".
	505	Otherwise, transition to the state indicated by next_op. */
	506
	507	if (next_op == -1)
	508	{
	509	currstatenum--;
	510	if (currstatenum < 0)
	511	{
aa170a07	512	return found_disent;
800eeca4 JW	513	}
	514	}
	515	else if (next_op >= 0)
	516	{
	517	currstatenum++;
	518	bitpos[currstatenum] = currbitnum - 1;
	519	op_ptr[currstatenum] = next_op;
	520	currtest[currstatenum] = 0;
	521	}
	522	}
	523	}
	524	\f
	525	/* Construct an ia64_opcode entry based on OPCODE, NAME and PLACE. */
	526
	527	static struct ia64_opcode *
26ca5450	528	make_ia64_opcode (ia64_insn opcode, const char *name, int place, int depind)
800eeca4 JW	529	{
	530	struct ia64_opcode *res =
	531	(struct ia64_opcode *) xmalloc (sizeof (struct ia64_opcode));
	532	res->name = xstrdup (name);
	533	res->type = main_table[place].opcode_type;
	534	res->num_outputs = main_table[place].num_outputs;
	535	res->opcode = opcode;
	536	res->mask = main_table[place].mask;
	537	res->operands[0] = main_table[place].operands[0];
	538	res->operands[1] = main_table[place].operands[1];
	539	res->operands[2] = main_table[place].operands[2];
	540	res->operands[3] = main_table[place].operands[3];
	541	res->operands[4] = main_table[place].operands[4];
	542	res->flags = main_table[place].flags;
	543	res->ent_index = place;
	544	res->dependencies = &op_dependencies[depind];
	545	return res;
	546	}
	547	\f
	548	/* Determine the ia64_opcode entry for the opcode specified by INSN
	549	and TYPE. If a valid entry is not found, return NULL. */
	550	struct ia64_opcode *
26ca5450	551	ia64_dis_opcode (ia64_insn insn, enum ia64_insn_type type)
800eeca4 JW	552	{
	553	int disent = locate_opcode_ent (insn, type);
	554
	555	if (disent < 0)
	556	{
	557	return NULL;
	558	}
	559	else
	560	{
	561	unsigned int cb = ia64_dis_names[disent].completer_index;
	562	static char name[128];
	563	int place = ia64_dis_names[disent].insn_index;
	564	int ci = main_table[place].completers;
	565	ia64_insn tinsn = main_table[place].opcode;
	566
	567	strcpy (name, ia64_strings [main_table[place].name_index]);
	568
	569	while (cb)
	570	{
	571	if (cb & 1)
	572	{
	573	int cname = completer_table[ci].name_index;
	574
	575	tinsn = apply_completer (tinsn, ci);
	576
	577	if (ia64_strings[cname][0] != '\0')
	578	{
	579	strcat (name, ".");
	580	strcat (name, ia64_strings[cname]);
	581	}
	582	if (cb != 1)
	583	{
	584	ci = completer_table[ci].subentries;
	585	}
	586	}
	587	else
	588	{
	589	ci = completer_table[ci].alternative;
	590	}
	591	if (ci < 0)
	592	{
	593	abort ();
	594	}
	595	cb = cb >> 1;
	596	}
	597	if (tinsn != (insn & main_table[place].mask))
	598	{
	599	abort ();
	600	}
279a96ca	601	return make_ia64_opcode (insn, name, place,
800eeca4 JW	602	completer_table[ci].dependencies);
	603	}
	604	}
	605	\f
	606	/* Search the main_opcode table starting from PLACE for an opcode that
	607	matches NAME. Return NULL if one is not found. */
	608
	609	static struct ia64_opcode *
26ca5450	610	ia64_find_matching_opcode (const char *name, short place)
800eeca4 JW	611	{
	612	char op[129];
	613	const char *suffix;
	614	short name_index;
	615
	616	if (strlen (name) > 128)
	617	{
	618	return NULL;
	619	}
	620	suffix = name;
	621	get_opc_prefix (&suffix, op);
	622	name_index = find_string_ent (op);
	623	if (name_index < 0)
	624	{
	625	return NULL;
	626	}
	627
	628	while (main_table[place].name_index == name_index)
	629	{
	630	const char *curr_suffix = suffix;
	631	ia64_insn curr_insn = main_table[place].opcode;
	632	short completer = -1;
	633
	634	do {
279a96ca	635	if (suffix[0] == '\0')
800eeca4 JW	636	{
	637	completer = find_completer (place, completer, suffix);
	638	}
	639	else
	640	{
	641	get_opc_prefix (&curr_suffix, op);
	642	completer = find_completer (place, completer, op);
	643	}
	644	if (completer != -1)
	645	{
	646	curr_insn = apply_completer (curr_insn, completer);
	647	}
	648	} while (completer != -1 && curr_suffix[0] != '\0');
	649
	650	if (completer != -1 && curr_suffix[0] == '\0'
	651	&& completer_table[completer].terminal_completer)
	652	{
	653	int depind = completer_table[completer].dependencies;
	654	return make_ia64_opcode (curr_insn, name, place, depind);
	655	}
	656	else
	657	{
	658	place++;
	659	}
	660	}
	661	return NULL;
	662	}
	663	\f
	664	/* Find the next opcode after PREV_ENT that matches PREV_ENT, or return NULL
	665	if one does not exist.
	666
	667	It is the caller's responsibility to invoke ia64_free_opcode () to
	668	release any resources used by the returned entry. */
	669
	670	struct ia64_opcode *
26ca5450	671	ia64_find_next_opcode (struct ia64_opcode *prev_ent)
800eeca4 JW	672	{
	673	return ia64_find_matching_opcode (prev_ent->name,
	674	prev_ent->ent_index + 1);
	675	}
	676
	677	/* Find the first opcode that matches NAME, or return NULL if it does
	678	not exist.
	679
	680	It is the caller's responsibility to invoke ia64_free_opcode () to
	681	release any resources used by the returned entry. */
	682
	683	struct ia64_opcode *
26ca5450	684	ia64_find_opcode (const char *name)
800eeca4 JW	685	{
	686	char op[129];
	687	const char *suffix;
	688	short place;
	689	short name_index;
	690
	691	if (strlen (name) > 128)
	692	{
	693	return NULL;
	694	}
	695	suffix = name;
	696	get_opc_prefix (&suffix, op);
	697	name_index = find_string_ent (op);
	698	if (name_index < 0)
	699	{
	700	return NULL;
	701	}
	702
	703	place = find_main_ent (name_index);
	704
	705	if (place < 0)
	706	{
	707	return NULL;
	708	}
	709	return ia64_find_matching_opcode (name, place);
	710	}
	711
	712	/* Free any resources used by ENT. */
	713	void
26ca5450	714	ia64_free_opcode (struct ia64_opcode *ent)
800eeca4 JW	715	{
	716	free ((void *)ent->name);
	717	free (ent);
	718	}
	719
	720	const struct ia64_dependency *
91d6fa6a	721	ia64_find_dependency (int dep_index)
800eeca4	722	{
91d6fa6a	723	dep_index = DEP(dep_index);
800eeca4	724
91d6fa6a NC	725	if (dep_index < 0
91d6fa6a NC	726	\|\| dep_index >= (int) ARRAY_SIZE (dependencies))
800eeca4 JW	727	return NULL;
800eeca4 JW	728
91d6fa6a	729	return &dependencies[dep_index];
800eeca4	730	}