[binutils.git] / gdb / ns32k-pinsn.c

/* Print 32000 instructions for GDB, the GNU debugger.
   Copyright (C) 1986,1988 Free Software Foundation, Inc.

This file is part of GDB.

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., 675 Mass Ave, Cambridge, MA 02139, USA.  */

#include <stdio.h>

#include "defs.h"
#include "param.h"
#include "symtab.h"
#include "ns32k-opcode.h"
#include "gdbcore.h"

/* 32000 instructions are never longer than this.  */
#define MAXLEN 62

/* Number of elements in the opcode table.  */
#define NOPCODES (sizeof notstrs / sizeof notstrs[0])

extern char *reg_names[];

#define NEXT_IS_ADDR	'|'

/*
 * extract "count" bits starting "offset" bits
 * into buffer
 */

int
bit_extract (buffer, offset, count)
     char *buffer;
     int offset;
     int count;
{
  int result;
  int mask;
  int bit;

  buffer += offset >> 3;
  offset &= 7;
  bit = 1;
  result = 0;
  while (count--) 
    {
      if ((*buffer & (1 << offset)))
	result |= bit;
      if (++offset == 8)
	{
	  offset = 0;
	  buffer++;
	}
      bit <<= 1;
    }
  return result;
}

float
fbit_extract (buffer, offset, count)
{
  union {
    int ival;
    float fval;
  } foo;

  foo.ival = bit_extract (buffer, offset, 32);
  return foo.fval;
}

double
dbit_extract (buffer, offset, count)
{
  union {
    struct {int low, high; } ival;
    double dval;
  } foo;

  foo.ival.low = bit_extract (buffer, offset, 32);
  foo.ival.high = bit_extract (buffer, offset+32, 32);
  return foo.dval;
}

sign_extend (value, bits)
{
  value = value & ((1 << bits) - 1);
  return (value & (1 << (bits-1))
	  ? value | (~((1 << bits) - 1))
	  : value);
}

flip_bytes (ptr, count)
     char *ptr;
     int count;
{
  char tmp;

  while (count > 0)
    {
      tmp = *ptr;
      ptr[0] = ptr[count-1];
      ptr[count-1] = tmp;
      ptr++;
      count -= 2;
    }
}
\f
/* Given a character C, does it represent a general addressing mode?  */
#define Is_gen(c) \
  ((c) == 'F' || (c) == 'L' || (c) == 'B' \
   || (c) == 'W' || (c) == 'D' || (c) == 'A')

/* Adressing modes.  */
#define Adrmod_index_byte 0x1c
#define Adrmod_index_word 0x1d
#define Adrmod_index_doubleword 0x1e
#define Adrmod_index_quadword 0x1f

/* Is MODE an indexed addressing mode?  */
#define Adrmod_is_index(mode) \
  (mode == Adrmod_index_byte \
   || mode == Adrmod_index_word \
   || mode == Adrmod_index_doubleword \
   || mode == Adrmod_index_quadword)

\f
/* Print the 32000 instruction at address MEMADDR in debugged memory,
   on STREAM.  Returns length of the instruction, in bytes.  */

int
print_insn (memaddr, stream)
     CORE_ADDR memaddr;
     FILE *stream;
{
  unsigned char buffer[MAXLEN];
  register int i;
  register unsigned char *p;
  register char *d;
  unsigned short first_word;
  int gen, disp;
  int ioffset;		/* bits into instruction */
  int aoffset;		/* bits into arguments */
  char arg_bufs[MAX_ARGS+1][ARG_LEN];
  int argnum;
  int maxarg;

  read_memory (memaddr, buffer, MAXLEN);

  first_word = *(unsigned short *) buffer;
  for (i = 0; i < NOPCODES; i++)
    if ((first_word & ((1 << notstrs[i].detail.obits) - 1))
	== notstrs[i].detail.code)
      break;

  /* Handle undefined instructions.  */
  if (i == NOPCODES)
    {
      fprintf (stream, "0%o", buffer[0]);
      return 1;
    }

  fprintf (stream, "%s", notstrs[i].name);

  ioffset = notstrs[i].detail.ibits;
  aoffset = notstrs[i].detail.ibits;
  d = notstrs[i].detail.args;

  if (*d)
    {
      /* Offset in bits of the first thing beyond each index byte.
	 Element 0 is for operand A and element 1 is for operand B.
	 The rest are irrelevant, but we put them here so we don't
	 index outside the array.  */
      int index_offset[MAX_ARGS];

      /* 0 for operand A, 1 for operand B, greater for other args.  */
      int whicharg = 0;
      
      fputc ('\t', stream);

      maxarg = 0;

      /* First we have to find and keep track of the index bytes,
	 if we are using scaled indexed addressing mode, since the index
	 bytes occur right after the basic instruction, not as part
	 of the addressing extension.  */
      if (Is_gen(d[1]))
	{
	  int addr_mode = bit_extract (buffer, ioffset - 5, 5);

	  if (Adrmod_is_index (addr_mode))
	    {
	      aoffset += 8;
	      index_offset[0] = aoffset;
	    }
	}
      if (d[2] && Is_gen(d[3]))
	{
	  int addr_mode = bit_extract (buffer, ioffset - 10, 5);

	  if (Adrmod_is_index (addr_mode))
	    {
	      aoffset += 8;
	      index_offset[1] = aoffset;
	    }
	}

      while (*d)
	{
	  argnum = *d - '1';
	  d++;
	  if (argnum > maxarg && argnum < MAX_ARGS)
	    maxarg = argnum;
	  ioffset = print_insn_arg (*d, ioffset, &aoffset, buffer,
				    memaddr, arg_bufs[argnum],
				    index_offset[whicharg]);
	  d++;
	  whicharg++;
	}
      for (argnum = 0; argnum <= maxarg; argnum++)
	{
	  CORE_ADDR addr;
	  char *ch, *index ();
	  for (ch = arg_bufs[argnum]; *ch;)
	    {
	      if (*ch == NEXT_IS_ADDR)
		{
		  ++ch;
		  addr = atoi (ch);
		  print_address (addr, stream);
		  while (*ch && *ch != NEXT_IS_ADDR)
		    ++ch;
		  if (*ch)
		    ++ch;
		}
	      else
		putc (*ch++, stream);
	    }
	  if (argnum < maxarg)
	    fprintf (stream, ", ");
	}
    }
  return aoffset / 8;
}

/* Print an instruction operand of category given by d.  IOFFSET is
   the bit position below which small (<1 byte) parts of the operand can
   be found (usually in the basic instruction, but for indexed
   addressing it can be in the index byte).  AOFFSETP is a pointer to the
   bit position of the addressing extension.  BUFFER contains the
   instruction.  ADDR is where BUFFER was read from.  Put the disassembled
   version of the operand in RESULT.  INDEX_OFFSET is the bit position
   of the index byte (it contains garbage if this operand is not a
   general operand using scaled indexed addressing mode).  */

print_insn_arg (d, ioffset, aoffsetp, buffer, addr, result, index_offset)
     char d;
     int ioffset, *aoffsetp;
     char *buffer;
     CORE_ADDR addr;
     char *result;
     int index_offset;
{
  int addr_mode;
  float Fvalue;
  double Lvalue;
  int Ivalue;
  int disp1, disp2;
  int index;

  switch (d)
    {
    case 'F':
    case 'L':
    case 'B':
    case 'W':
    case 'D':
    case 'A':
      addr_mode = bit_extract (buffer, ioffset-5, 5);
      ioffset -= 5;
      switch (addr_mode)
	{
	case 0x0: case 0x1: case 0x2: case 0x3:
	case 0x4: case 0x5: case 0x6: case 0x7:
	  switch (d)
	    {
	    case 'F':
	    case 'L':
	      sprintf (result, "f%d", addr_mode);
	      break;
	    default:
	      sprintf (result, "r%d", addr_mode);
	    }
	  break;
	case 0x8: case 0x9: case 0xa: case 0xb:
	case 0xc: case 0xd: case 0xe: case 0xf:
	  disp1 = get_displacement (buffer, aoffsetp);
	  sprintf (result, "%d(r%d)", disp1, addr_mode & 7);
	  break;
	case 0x10:
	case 0x11:
	case 0x12:
	  disp1 = get_displacement (buffer, aoffsetp);
	  disp2 = get_displacement (buffer, aoffsetp);
	  sprintf (result, "%d(%d(%s))", disp2, disp1,
		   addr_mode==0x10?"fp":addr_mode==0x11?"sp":"sb");
	  break;
	case 0x13:
	  sprintf (result, "reserved");
	  break;
	case 0x14:
	  switch (d)
	    {
	    case 'B':
	      Ivalue = bit_extract (buffer, *aoffsetp, 8);
	      Ivalue = sign_extend (Ivalue, 8);
	      *aoffsetp += 8;
	      sprintf (result, "$%d", Ivalue);
	      break;
	    case 'W':
	      Ivalue = bit_extract (buffer, *aoffsetp, 16);
	      flip_bytes (&Ivalue, 2);
	      *aoffsetp += 16;
	      Ivalue = sign_extend (Ivalue, 16);
	      sprintf (result, "$%d", Ivalue);
	      break;
	    case 'D':
	      Ivalue = bit_extract (buffer, *aoffsetp, 32);
	      flip_bytes (&Ivalue, 4);
	      *aoffsetp += 32;
	      sprintf (result, "$%d", Ivalue);
	      break;
	    case 'A':
	      Ivalue = bit_extract (buffer, *aoffsetp, 32);
	      flip_bytes (&Ivalue, 4);
	      *aoffsetp += 32;
	      sprintf (result, "$|%d|", Ivalue);
	      break;
	    case 'F':
	      Fvalue = fbit_extract (buffer, *aoffsetp, 32);
	      flip_bytes (&Fvalue, 4);
	      *aoffsetp += 32;
	      sprintf (result, "$%g", Fvalue);
	      break;
	    case 'L':
	      Lvalue = dbit_extract (buffer, *aoffsetp, 64);
	      flip_bytes (&Lvalue, 8);
	      *aoffsetp += 64;
	      sprintf (result, "$%g", Lvalue);
	      break;
	    }
	  break;
	case 0x15:
	  disp1 = get_displacement (buffer, aoffsetp);
	  sprintf (result, "@|%d|", disp1);
	  break;
	case 0x16:
	  disp1 = get_displacement (buffer, aoffsetp);
	  disp2 = get_displacement (buffer, aoffsetp);
	  sprintf (result, "EXT(%d) + %d", disp1, disp2);
	  break;
	case 0x17:
	  sprintf (result, "tos");
	  break;
	case 0x18:
	  disp1 = get_displacement (buffer, aoffsetp);
	  sprintf (result, "%d(fp)", disp1);
	  break;
	case 0x19:
	  disp1 = get_displacement (buffer, aoffsetp);
	  sprintf (result, "%d(sp)", disp1);
	  break;
	case 0x1a:
	  disp1 = get_displacement (buffer, aoffsetp);
	  sprintf (result, "%d(sb)", disp1);
	  break;
	case 0x1b:
	  disp1 = get_displacement (buffer, aoffsetp);
	  sprintf (result, "|%d|", addr + disp1);
	  break;
	case 0x1c:
	case 0x1d:
	case 0x1e:
	case 0x1f:
	  index = bit_extract (buffer, index_offset - 8, 3);
	  print_insn_arg (d, index_offset, aoffsetp, buffer, addr,
			  result, 0);
	  {
	    static char	*ind[] = {"b", "w", "d", "q"};
	    char *off;

	    off = result + strlen (result);
	    sprintf (off, "[r%d:%s]", index,
		     ind[addr_mode & 3]);
	  }
	  break;
	}
      break;
    case 'q':
      Ivalue = bit_extract (buffer, ioffset-4, 4);
      Ivalue = sign_extend (Ivalue, 4);
      sprintf (result, "%d", Ivalue);
      ioffset -= 4;
      break;
    case 'r':
      Ivalue = bit_extract (buffer, ioffset-3, 3);
      sprintf (result, "r%d", Ivalue&7);
      ioffset -= 3;
      break;
    case 'd':
      sprintf (result, "%d", get_displacement (buffer, aoffsetp));
      break;
    case 'p':
      sprintf (result, "%c%d%c", NEXT_IS_ADDR,
	       addr + get_displacement (buffer, aoffsetp),
	       NEXT_IS_ADDR);
      break;
    case 'i':
      Ivalue = bit_extract (buffer, *aoffsetp, 8);
      *aoffsetp += 8;
      sprintf (result, "0x%x", Ivalue);
      break;
    }
  return ioffset;
}

get_displacement (buffer, aoffsetp)
     char *buffer;
     int *aoffsetp;
{
  int Ivalue;

  Ivalue = bit_extract (buffer, *aoffsetp, 8);
  switch (Ivalue & 0xc0)
    {
    case 0x00:
    case 0x40:
      Ivalue = sign_extend (Ivalue, 7);
      *aoffsetp += 8;
      break;
    case 0x80:
      Ivalue = bit_extract (buffer, *aoffsetp, 16);
      flip_bytes (&Ivalue, 2);
      Ivalue = sign_extend (Ivalue, 14);
      *aoffsetp += 16;
      break;
    case 0xc0:
      Ivalue = bit_extract (buffer, *aoffsetp, 32);
      flip_bytes (&Ivalue, 4);
      Ivalue = sign_extend (Ivalue, 30);
      *aoffsetp += 32;
      break;
    }
  return Ivalue;
}
\f
/* Return the number of locals in the current frame given a pc
   pointing to the enter instruction.  This is used in the macro
   FRAME_FIND_SAVED_REGS.  */

ns32k_localcount (enter_pc)
     CORE_ADDR enter_pc;
{
  unsigned char localtype;
  int localcount;

  localtype = read_memory_integer (enter_pc+2, 1);
  if ((localtype & 0x80) == 0)
    localcount = localtype;
  else if ((localtype & 0xc0) == 0x80)
    localcount = (((localtype & 0x3f) << 8)
		  | (read_memory_integer (enter_pc+3, 1) & 0xff));
  else
    localcount = (((localtype & 0x3f) << 24)
		  | ((read_memory_integer (enter_pc+3, 1) & 0xff) << 16)
		  | ((read_memory_integer (enter_pc+4, 1) & 0xff) << 8 )
		  | (read_memory_integer (enter_pc+5, 1) & 0xff));
  return localcount;
}

/*
 * Get the address of the enter opcode for the function
 * containing PC, if there is an enter for the function,
 * and if the pc is between the enter and exit.
 * Returns positive address if pc is between enter/exit,
 * 1 if pc before enter or after exit, 0 otherwise.
 */

CORE_ADDR
ns32k_get_enter_addr (pc)
     CORE_ADDR pc;
{
  CORE_ADDR enter_addr;
  unsigned char op;

  if (ABOUT_TO_RETURN (pc))
    return 1;		/* after exit */

  enter_addr = get_pc_function_start (pc);

  if (pc == enter_addr) 
    return 1;		/* before enter */

  op = read_memory_integer (enter_addr, 1);

  if (op != 0x82)
    return 0;		/* function has no enter/exit */

  return enter_addr;	/* pc is between enter and exit */
}
Commit	Line	Data
dd3b648e RP	1	/* Print 32000 instructions for GDB, the GNU debugger.
	2	Copyright (C) 1986,1988 Free Software Foundation, Inc.
	3
609756e2 JG	4	This file is part of GDB.
	5
	6	This program is free software; you can redistribute it and/or modify
	7	it under the terms of the GNU General Public License as published by
	8	the Free Software Foundation; either version 2 of the License, or
	9	(at your option) any later version.
	10
	11	This program is distributed in the hope that it will be useful,
	12	but WITHOUT ANY WARRANTY; without even the implied warranty of
	13	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	14	GNU General Public License for more details.
	15
	16	You should have received a copy of the GNU General Public License
	17	along with this program; if not, write to the Free Software
	18	Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */
dd3b648e RP	19
	20	#include <stdio.h>
	21
	22	#include "defs.h"
	23	#include "param.h"
	24	#include "symtab.h"
	25	#include "ns32k-opcode.h"
	26	#include "gdbcore.h"
	27
	28	/* 32000 instructions are never longer than this. */
	29	#define MAXLEN 62
	30
	31	/* Number of elements in the opcode table. */
	32	#define NOPCODES (sizeof notstrs / sizeof notstrs[0])
	33
	34	extern char *reg_names[];
	35
	36	#define NEXT_IS_ADDR '\|'
	37
	38	/*
	39	* extract "count" bits starting "offset" bits
	40	* into buffer
	41	*/
	42
	43	int
	44	bit_extract (buffer, offset, count)
	45	char *buffer;
	46	int offset;
	47	int count;
	48	{
	49	int result;
	50	int mask;
	51	int bit;
	52
	53	buffer += offset >> 3;
	54	offset &= 7;
	55	bit = 1;
	56	result = 0;
	57	while (count--)
	58	{
	59	if ((*buffer & (1 << offset)))
	60	result \|= bit;
	61	if (++offset == 8)
	62	{
	63	offset = 0;
	64	buffer++;
	65	}
	66	bit <<= 1;
	67	}
	68	return result;
	69	}
	70
	71	float
	72	fbit_extract (buffer, offset, count)
	73	{
	74	union {
	75	int ival;
	76	float fval;
	77	} foo;
	78
	79	foo.ival = bit_extract (buffer, offset, 32);
	80	return foo.fval;
	81	}
	82
83	double
84	dbit_extract (buffer, offset, count)
85	{
86	union {
87	struct {int low, high; } ival;
88	double dval;
89	} foo;
90
91	foo.ival.low = bit_extract (buffer, offset, 32);
92	foo.ival.high = bit_extract (buffer, offset+32, 32);
93	return foo.dval;
94	}
95
96	sign_extend (value, bits)
97	{
98	value = value & ((1 << bits) - 1);
99	return (value & (1 << (bits-1))
100	? value \| (~((1 << bits) - 1))
101	: value);
102	}
103
104	flip_bytes (ptr, count)
105	char *ptr;
106	int count;
107	{
108	char tmp;
109
110	while (count > 0)
111	{
112	tmp = *ptr;
113	ptr[0] = ptr[count-1];
114	ptr[count-1] = tmp;
115	ptr++;
116	count -= 2;
117	}
118	}
119	\f
120	/* Given a character C, does it represent a general addressing mode? */
121	#define Is_gen(c) \
122	((c) == 'F' \|\| (c) == 'L' \|\| (c) == 'B' \
123	\|\| (c) == 'W' \|\| (c) == 'D' \|\| (c) == 'A')
124
125	/* Adressing modes. */
126	#define Adrmod_index_byte 0x1c
127	#define Adrmod_index_word 0x1d
128	#define Adrmod_index_doubleword 0x1e
129	#define Adrmod_index_quadword 0x1f
130
131	/* Is MODE an indexed addressing mode? */
132	#define Adrmod_is_index(mode) \
133	(mode == Adrmod_index_byte \
134	\|\| mode == Adrmod_index_word \
135	\|\| mode == Adrmod_index_doubleword \
136	\|\| mode == Adrmod_index_quadword)
137
138	\f
139	/* Print the 32000 instruction at address MEMADDR in debugged memory,
140	on STREAM. Returns length of the instruction, in bytes. */
141
142	int
143	print_insn (memaddr, stream)
144	CORE_ADDR memaddr;
145	FILE *stream;
146	{
147	unsigned char buffer[MAXLEN];
148	register int i;
149	register unsigned char *p;
150	register char *d;
151	unsigned short first_word;
152	int gen, disp;
153	int ioffset; /* bits into instruction */
154	int aoffset; /* bits into arguments */
155	char arg_bufs[MAX_ARGS+1][ARG_LEN];
156	int argnum;
157	int maxarg;
158
159	read_memory (memaddr, buffer, MAXLEN);
160
161	first_word = (unsigned short ) buffer;
162	for (i = 0; i < NOPCODES; i++)
163	if ((first_word & ((1 << notstrs[i].detail.obits) - 1))
164	== notstrs[i].detail.code)
165	break;
166
167	/* Handle undefined instructions. */
168	if (i == NOPCODES)
169	{
170	fprintf (stream, "0%o", buffer[0]);
171	return 1;
172	}
173
174	fprintf (stream, "%s", notstrs[i].name);
175
176	ioffset = notstrs[i].detail.ibits;
177	aoffset = notstrs[i].detail.ibits;
178	d = notstrs[i].detail.args;
179
180	if (*d)
181	{
182	/* Offset in bits of the first thing beyond each index byte.
183	Element 0 is for operand A and element 1 is for operand B.
184	The rest are irrelevant, but we put them here so we don't
185	index outside the array. */
186	int index_offset[MAX_ARGS];
187
188	/* 0 for operand A, 1 for operand B, greater for other args. */
189	int whicharg = 0;
190
191	fputc ('\t', stream);
192
193	maxarg = 0;
194
195	/* First we have to find and keep track of the index bytes,
196	if we are using scaled indexed addressing mode, since the index
197	bytes occur right after the basic instruction, not as part
198	of the addressing extension. */
199	if (Is_gen(d[1]))
200	{
201	int addr_mode = bit_extract (buffer, ioffset - 5, 5);
202
203	if (Adrmod_is_index (addr_mode))
204	{
205	aoffset += 8;
206	index_offset[0] = aoffset;
207	}
208	}
209	if (d[2] && Is_gen(d[3]))
210	{
211	int addr_mode = bit_extract (buffer, ioffset - 10, 5);
212
213	if (Adrmod_is_index (addr_mode))
214	{
215	aoffset += 8;
216	index_offset[1] = aoffset;
217	}
218	}
219
220	while (*d)
221	{
222	argnum = *d - '1';
223	d++;
224	if (argnum > maxarg && argnum < MAX_ARGS)
225	maxarg = argnum;
226	ioffset = print_insn_arg (*d, ioffset, &aoffset, buffer,
227	memaddr, arg_bufs[argnum],
228	index_offset[whicharg]);
229	d++;
230	whicharg++;
231	}
232	for (argnum = 0; argnum <= maxarg; argnum++)
233	{
234	CORE_ADDR addr;
235	char ch, index ();
236	for (ch = arg_bufs[argnum]; *ch;)
237	{
238	if (*ch == NEXT_IS_ADDR)
239	{
240	++ch;
241	addr = atoi (ch);
242	print_address (addr, stream);
243	while (ch && ch != NEXT_IS_ADDR)
244	++ch;
245	if (*ch)
246	++ch;
247	}
248	else
249	putc (*ch++, stream);
250	}
251	if (argnum < maxarg)
252	fprintf (stream, ", ");
253	}
254	}
255	return aoffset / 8;
256	}
257
258	/* Print an instruction operand of category given by d. IOFFSET is
259	the bit position below which small (<1 byte) parts of the operand can
260	be found (usually in the basic instruction, but for indexed
261	addressing it can be in the index byte). AOFFSETP is a pointer to the
262	bit position of the addressing extension. BUFFER contains the
263	instruction. ADDR is where BUFFER was read from. Put the disassembled
264	version of the operand in RESULT. INDEX_OFFSET is the bit position
265	of the index byte (it contains garbage if this operand is not a
266	general operand using scaled indexed addressing mode). */
267
268	print_insn_arg (d, ioffset, aoffsetp, buffer, addr, result, index_offset)
269	char d;
270	int ioffset, *aoffsetp;
271	char *buffer;
272	CORE_ADDR addr;
273	char *result;
274	int index_offset;
275	{
276	int addr_mode;
277	float Fvalue;
278	double Lvalue;
279	int Ivalue;
280	int disp1, disp2;
281	int index;
282
283	switch (d)
284	{
285	case 'F':
286	case 'L':
287	case 'B':
288	case 'W':
289	case 'D':
290	case 'A':
291	addr_mode = bit_extract (buffer, ioffset-5, 5);
292	ioffset -= 5;
293	switch (addr_mode)
294	{
295	case 0x0: case 0x1: case 0x2: case 0x3:
296	case 0x4: case 0x5: case 0x6: case 0x7:
297	switch (d)
298	{
299	case 'F':
300	case 'L':
301	sprintf (result, "f%d", addr_mode);
302	break;
303	default:
304	sprintf (result, "r%d", addr_mode);
305	}
306	break;
307	case 0x8: case 0x9: case 0xa: case 0xb:
308	case 0xc: case 0xd: case 0xe: case 0xf:
309	disp1 = get_displacement (buffer, aoffsetp);
310	sprintf (result, "%d(r%d)", disp1, addr_mode & 7);
311	break;
312	case 0x10:
313	case 0x11:
314	case 0x12:
315	disp1 = get_displacement (buffer, aoffsetp);
316	disp2 = get_displacement (buffer, aoffsetp);
317	sprintf (result, "%d(%d(%s))", disp2, disp1,
318	addr_mode==0x10?"fp":addr_mode==0x11?"sp":"sb");
319	break;
320	case 0x13:
321	sprintf (result, "reserved");
322	break;
323	case 0x14:
324	switch (d)
325	{
326	case 'B':
327	Ivalue = bit_extract (buffer, *aoffsetp, 8);
328	Ivalue = sign_extend (Ivalue, 8);
329	*aoffsetp += 8;
330	sprintf (result, "$%d", Ivalue);
331	break;
332	case 'W':
333	Ivalue = bit_extract (buffer, *aoffsetp, 16);
334	flip_bytes (&Ivalue, 2);
335	*aoffsetp += 16;
336	Ivalue = sign_extend (Ivalue, 16);
337	sprintf (result, "$%d", Ivalue);
338	break;
339	case 'D':
340	Ivalue = bit_extract (buffer, *aoffsetp, 32);
341	flip_bytes (&Ivalue, 4);
342	*aoffsetp += 32;
343	sprintf (result, "$%d", Ivalue);
344	break;
345	case 'A':
346	Ivalue = bit_extract (buffer, *aoffsetp, 32);
347	flip_bytes (&Ivalue, 4);
348	*aoffsetp += 32;
349	sprintf (result, "$\|%d\|", Ivalue);
350	break;
351	case 'F':
352	Fvalue = fbit_extract (buffer, *aoffsetp, 32);
353	flip_bytes (&Fvalue, 4);
354	*aoffsetp += 32;
355	sprintf (result, "$%g", Fvalue);
356	break;
357	case 'L':
358	Lvalue = dbit_extract (buffer, *aoffsetp, 64);
359	flip_bytes (&Lvalue, 8);
360	*aoffsetp += 64;
361	sprintf (result, "$%g", Lvalue);
362	break;
363	}
364	break;
365	case 0x15:
366	disp1 = get_displacement (buffer, aoffsetp);
367	sprintf (result, "@\|%d\|", disp1);
368	break;
369	case 0x16:
370	disp1 = get_displacement (buffer, aoffsetp);
371	disp2 = get_displacement (buffer, aoffsetp);
372	sprintf (result, "EXT(%d) + %d", disp1, disp2);
373	break;
374	case 0x17:
375	sprintf (result, "tos");
376	break;
377	case 0x18:
378	disp1 = get_displacement (buffer, aoffsetp);
379	sprintf (result, "%d(fp)", disp1);
380	break;
381	case 0x19:
382	disp1 = get_displacement (buffer, aoffsetp);
383	sprintf (result, "%d(sp)", disp1);
384	break;
385	case 0x1a:
386	disp1 = get_displacement (buffer, aoffsetp);
387	sprintf (result, "%d(sb)", disp1);
388	break;
389	case 0x1b:
390	disp1 = get_displacement (buffer, aoffsetp);
391	sprintf (result, "\|%d\|", addr + disp1);
392	break;
393	case 0x1c:
394	case 0x1d:
395	case 0x1e:
396	case 0x1f:
397	index = bit_extract (buffer, index_offset - 8, 3);
398	print_insn_arg (d, index_offset, aoffsetp, buffer, addr,
399	result, 0);
400	{
401	static char *ind[] = {"b", "w", "d", "q"};
402	char *off;
403
404	off = result + strlen (result);
405	sprintf (off, "[r%d:%s]", index,
406	ind[addr_mode & 3]);
407	}
408	break;
409	}
410	break;
411	case 'q':
412	Ivalue = bit_extract (buffer, ioffset-4, 4);
413	Ivalue = sign_extend (Ivalue, 4);
414	sprintf (result, "%d", Ivalue);
415	ioffset -= 4;
416	break;
417	case 'r':
418	Ivalue = bit_extract (buffer, ioffset-3, 3);
419	sprintf (result, "r%d", Ivalue&7);
420	ioffset -= 3;
421	break;
422	case 'd':
423	sprintf (result, "%d", get_displacement (buffer, aoffsetp));
424	break;
425	case 'p':
426	sprintf (result, "%c%d%c", NEXT_IS_ADDR,
427	addr + get_displacement (buffer, aoffsetp),
428	NEXT_IS_ADDR);
429	break;
430	case 'i':
431	Ivalue = bit_extract (buffer, *aoffsetp, 8);
432	*aoffsetp += 8;
433	sprintf (result, "0x%x", Ivalue);
434	break;
435	}
436	return ioffset;
437	}
438
439	get_displacement (buffer, aoffsetp)
440	char *buffer;
441	int *aoffsetp;
442	{
443	int Ivalue;
444
445	Ivalue = bit_extract (buffer, *aoffsetp, 8);
446	switch (Ivalue & 0xc0)
447	{
448	case 0x00:
449	case 0x40:
450	Ivalue = sign_extend (Ivalue, 7);
451	*aoffsetp += 8;
452	break;
453	case 0x80:
454	Ivalue = bit_extract (buffer, *aoffsetp, 16);
455	flip_bytes (&Ivalue, 2);
456	Ivalue = sign_extend (Ivalue, 14);
457	*aoffsetp += 16;
458	break;
459	case 0xc0:
460	Ivalue = bit_extract (buffer, *aoffsetp, 32);
461	flip_bytes (&Ivalue, 4);
462	Ivalue = sign_extend (Ivalue, 30);
463	*aoffsetp += 32;
464	break;
465	}
466	return Ivalue;
467	}
468	\f
469	/* Return the number of locals in the current frame given a pc
470	pointing to the enter instruction. This is used in the macro
471	FRAME_FIND_SAVED_REGS. */
472
473	ns32k_localcount (enter_pc)
474	CORE_ADDR enter_pc;
475	{
476	unsigned char localtype;
477	int localcount;
478
479	localtype = read_memory_integer (enter_pc+2, 1);
480	if ((localtype & 0x80) == 0)
481	localcount = localtype;
482	else if ((localtype & 0xc0) == 0x80)
483	localcount = (((localtype & 0x3f) << 8)
484	\| (read_memory_integer (enter_pc+3, 1) & 0xff));
485	else
486	localcount = (((localtype & 0x3f) << 24)
487	\| ((read_memory_integer (enter_pc+3, 1) & 0xff) << 16)
488	\| ((read_memory_integer (enter_pc+4, 1) & 0xff) << 8 )
489	\| (read_memory_integer (enter_pc+5, 1) & 0xff));
490	return localcount;
491	}
492
493	/*
494	* Get the address of the enter opcode for the function
495	* containing PC, if there is an enter for the function,
496	* and if the pc is between the enter and exit.
497	* Returns positive address if pc is between enter/exit,
498	* 1 if pc before enter or after exit, 0 otherwise.
499	*/
500
501	CORE_ADDR
502	ns32k_get_enter_addr (pc)
503	CORE_ADDR pc;
504	{
505	CORE_ADDR enter_addr;
506	unsigned char op;
507
508	if (ABOUT_TO_RETURN (pc))
509	return 1; /* after exit */
510
511	enter_addr = get_pc_function_start (pc);
512
513	if (pc == enter_addr)
514	return 1; /* before enter */
515
516	op = read_memory_integer (enter_addr, 1);
517
518	if (op != 0x82)
519	return 0; /* function has no enter/exit */
520
521	return enter_addr; /* pc is between enter and exit */
522	}