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/* tc-mcore.c -- Assemble code for M*Core

   Copyright 1999, 2000, 2001, 2002, 2003, 2005, 2006, 2007

   Free Software Foundation, Inc.

   This file is part of GAS, the GNU Assembler.

   GAS 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.

   GAS 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 GAS; see the file COPYING.  If not, write to the Free

   Software Foundation, 51 Franklin Street - Fifth Floor, Boston, MA

   02110-1301, USA.  */

#include "as.h"

#include "subsegs.h"

#define DEFINE_TABLE

#include "../opcodes/mcore-opc.h"

#include "safe-ctype.h"

#ifdef OBJ_ELF

#include "elf/mcore.h"

#endif

#ifndef streq

#define streq(a,b) (strcmp (a, b) == 0)

#endif

/* Forward declarations for dumb compilers.  */

/* Several places in this file insert raw instructions into the

   object. They should use MCORE_INST_XXX macros to get the opcodes

   and then use these two macros to crack the MCORE_INST value into

   the appropriate byte values.  */

#define INST_BYTE0(x)  (target_big_endian ? (((x) >> 8) & 0xFF) : ((x) & 0xFF))

#define INST_BYTE1(x)  (target_big_endian ? ((x) & 0xFF) : (((x) >> 8) & 0xFF))

const char comment_chars[] = "#/";

const char line_separator_chars[] = ";";

const char line_comment_chars[] = "#/";

static int do_jsri2bsr = 0;      /* Change here from 1 by Cruess 19 August 97.  */

static int sifilter_mode = 0;

const char EXP_CHARS[] = "eE";

/* Chars that mean this number is a floating point constant

    As in 0f12.456

    or    0d1.2345e12  */

const char FLT_CHARS[] = "rRsSfFdDxXpP";

#define C(what,length) (((what) << 2) + (length))

#define GET_WHAT(x)    ((x >> 2))

/* These are the two types of relaxable instruction.  */

#define COND_JUMP  1

#define UNCD_JUMP  2

#define UNDEF_DISP      0

#define DISP12          1

#define DISP32          2

#define UNDEF_WORD_DISP 3

#define C12_LEN         2

#define C32_LEN        10       /* Allow for align.  */

#define U12_LEN         2

#define U32_LEN         8       /* Allow for align.  */

typedef enum

{

  M210,

  M340

}

cpu_type;

cpu_type cpu = M340;

/* Initialize the relax table.  */

const relax_typeS md_relax_table[] =

{

  {    0,     0, 0,          0 },

  {    0,     0, 0,          0 },

  {    0,     0, 0,          0 },

  {    0,     0, 0,          0 },

  /* COND_JUMP */

  {    0,     0, 0,          0 },                     /* UNDEF_DISP */

  { 2048, -2046, C12_LEN, C(COND_JUMP, DISP32) }, /* DISP12 */

  {    0,     0, C32_LEN, 0 },                       /* DISP32 */

  {    0,     0, C32_LEN, 0 },                       /* UNDEF_WORD_DISP */

  /* UNCD_JUMP */

  {    0,     0, 0,          0 },                     /* UNDEF_DISP */

  { 2048, -2046, U12_LEN, C(UNCD_JUMP, DISP32) }, /* DISP12 */

  {    0,     0, U32_LEN, 0 },                       /* DISP32 */

  {    0,     0, U32_LEN, 0 }                        /* UNDEF_WORD_DISP */

};

/* Literal pool data structures.  */

struct literal

{

  unsigned short  refcnt;

  unsigned char   ispcrel;

  unsigned char   unused;

  expressionS     e;

};

#define MAX_POOL_SIZE   (1024/4)

static struct literal litpool [MAX_POOL_SIZE];

static unsigned poolsize;

static unsigned poolnumber;

static unsigned long poolspan;

/* SPANPANIC: the point at which we get too scared and force a dump

   of the literal pool, and perhaps put a branch in place.

   Calculated as:

                 1024   span of lrw/jmpi/jsri insn (actually span+1)

                -2      possible alignment at the insn.

                -2      possible alignment to get the table aligned.

                -2      an inserted branch around the table.

             == 1018

   at 1018, we might be in trouble.

   -- so we have to be smaller than 1018 and since we deal with 2-byte

   instructions, the next good choice is 1016.

   -- Note we have a test case that fails when we've got 1018 here.  */

#define SPANPANIC       (1016)          /* 1024 - 1 entry - 2 byte rounding.  */

#define SPANCLOSE       (900)

#define SPANEXIT        (600)

static symbolS * poolsym;               /* Label for current pool.  */

static char poolname[8];

static struct hash_control * opcode_hash_control;       /* Opcode mnemonics.  */

#define POOL_END_LABEL   ".LE"

#define POOL_START_LABEL ".LS"

static void

make_name (char * s, char * p, int n)

{

  static const char hex[] = "0123456789ABCDEF";

  s[0] = p[0];

  s[1] = p[1];

  s[2] = p[2];

  s[3] = hex[(n >> 12) & 0xF];

  s[4] = hex[(n >>  8) & 0xF];

  s[5] = hex[(n >>  4) & 0xF];

  s[6] = hex[(n)       & 0xF];

  s[7] = 0;

}

static void

dump_literals (int isforce)

{

  unsigned int i;

  struct literal * p;

  symbolS * brarsym = NULL;

  if (poolsize == 0)

    return;

  /* Must we branch around the literal table?  */

  if (isforce)

    {

      char * output;

      char brarname[8];

      make_name (brarname, POOL_END_LABEL, poolnumber);

      brarsym = symbol_make (brarname);

      symbol_table_insert (brarsym);

      output = frag_var (rs_machine_dependent,

                         md_relax_table[C (UNCD_JUMP, DISP32)].rlx_length,

                         md_relax_table[C (UNCD_JUMP, DISP12)].rlx_length,

                         C (UNCD_JUMP, 0), brarsym, 0, 0);

      output[0] = INST_BYTE0 (MCORE_INST_BR);    /* br .+xxx */

      output[1] = INST_BYTE1 (MCORE_INST_BR);

    }

  /* Make sure that the section is sufficiently aligned and that

     the literal table is aligned within it.  */

  record_alignment (now_seg, 2);

  frag_align (2, 0, 0);

  colon (S_GET_NAME (poolsym));

  for (i = 0, p = litpool; i < poolsize; i++, p++)

    emit_expr (& p->e, 4);

  if (brarsym != NULL)

    colon (S_GET_NAME (brarsym));

   poolsize = 0;

}

static void

mcore_s_literals (int ignore ATTRIBUTE_UNUSED)

{

  dump_literals (0);

  demand_empty_rest_of_line ();

}

/* Perform FUNC (ARG), and track number of bytes added to frag.  */

static void

mcore_pool_count (void (*func) (int), int arg)

{

  const fragS *curr_frag = frag_now;

  offsetT added = -frag_now_fix_octets ();

  (*func) (arg);

  while (curr_frag != frag_now)

    {

      added += curr_frag->fr_fix;

      curr_frag = curr_frag->fr_next;

    }

  added += frag_now_fix_octets ();

  poolspan += added;

}

static void

check_literals (int kind, int offset)

{

  poolspan += offset;

  /* SPANCLOSE and SPANEXIT are smaller numbers than SPANPANIC.

     SPANPANIC means that we must dump now.

     kind == 0 is any old instruction.

     kind  > 0 means we just had a control transfer instruction.

     kind == 1 means within a function

     kind == 2 means we just left a function

     The dump_literals (1) call inserts a branch around the table, so

     we first look to see if its a situation where we won't have to

     insert a branch (e.g., the previous instruction was an unconditional

     branch).

     SPANPANIC is the point where we must dump a single-entry pool.

     it accounts for alignments and an inserted branch.

     the 'poolsize*2' accounts for the scenario where we do:

       lrw r1,lit1; lrw r2,lit2; lrw r3,lit3

     Note that the 'lit2' reference is 2 bytes further along

     but the literal it references will be 4 bytes further along,

     so we must consider the poolsize into this equation.

     This is slightly over-cautious, but guarantees that we won't

     panic because a relocation is too distant.  */

  if (poolspan > SPANCLOSE && kind > 0)

    dump_literals (0);

  else if (poolspan > SPANEXIT && kind > 1)

    dump_literals (0);

  else if (poolspan >= (SPANPANIC - poolsize * 2))

    dump_literals (1);

}

static void

mcore_cons (int nbytes)

{

  if (now_seg == text_section)

    mcore_pool_count (cons, nbytes);

  else

    cons (nbytes);

  /* In theory we ought to call check_literals (2,0) here in case

     we need to dump the literal table.  We cannot do this however,

     as the directives that we are intercepting may be being used

     to build a switch table, and we must not interfere with its

     contents.  Instead we cross our fingers and pray...  */

}

static void

mcore_float_cons (int float_type)

{

  if (now_seg == text_section)

    mcore_pool_count (float_cons, float_type);

  else

    float_cons (float_type);

  /* See the comment in mcore_cons () about calling check_literals.

     It is unlikely that a switch table will be constructed using

     floating point values, but it is still likely that an indexed

     table of floating point constants is being created by these

     directives, so again we must not interfere with their placement.  */

}

static void

mcore_stringer (int append_zero)

{

  if (now_seg == text_section)

    mcore_pool_count (stringer, append_zero);

  else

    stringer (append_zero);

  /* We call check_literals here in case a large number of strings are

     being placed into the text section with a sequence of stringer

     directives.  In theory we could be upsetting something if these

     strings are actually in an indexed table instead of referenced by

     individual labels.  Let us hope that that never happens.  */

  check_literals (2, 0);

}

static void

mcore_fill (int unused)

{

  if (now_seg == text_section)

    mcore_pool_count (s_fill, unused);

  else

    s_fill (unused);

  check_literals (2, 0);

}

/* Handle the section changing pseudo-ops.  These call through to the

   normal implementations, but they dump the literal pool first.  */

static void

mcore_s_text (int ignore)

{

  dump_literals (0);

#ifdef OBJ_ELF

  obj_elf_text (ignore);

#else

  s_text (ignore);

#endif

}

static void

mcore_s_data (int ignore)

{

  dump_literals (0);

#ifdef OBJ_ELF

  obj_elf_data (ignore);

#else

  s_data (ignore);

#endif

}

static void

mcore_s_section (int ignore)

{

  /* Scan forwards to find the name of the section.  If the section

     being switched to is ".line" then this is a DWARF1 debug section

     which is arbitrarily placed inside generated code.  In this case

     do not dump the literal pool because it is a) inefficient and

     b) would require the generation of extra code to jump around the

     pool.  */

  char * ilp = input_line_pointer;

  while (*ilp != 0 && ISSPACE (*ilp))

    ++ ilp;

  if (strncmp (ilp, ".line", 5) == 0

      && (ISSPACE (ilp[5]) || *ilp == '\n' || *ilp == '\r'))

    ;

  else

    dump_literals (0);

#ifdef OBJ_ELF

  obj_elf_section (ignore);

#endif

#ifdef OBJ_COFF

  obj_coff_section (ignore);

#endif

}

static void

mcore_s_bss (int needs_align)

{

  dump_literals (0);

  s_lcomm_bytes (needs_align);

}

#ifdef OBJ_ELF

static void

mcore_s_comm (int needs_align)

{

  dump_literals (0);

  obj_elf_common (needs_align);

}

#endif

/* This table describes all the machine specific pseudo-ops the assembler

   has to support.  The fields are:

     Pseudo-op name without dot

     Function to call to execute this pseudo-op

     Integer arg to pass to the function.   */

const pseudo_typeS md_pseudo_table[] =

{

  { "export",   s_globl,          0 },

  { "import",   s_ignore,         0 },

  { "literals", mcore_s_literals, 0 },

  { "page",     listing_eject,    0 },

  /* The following are to intercept the placement of data into the text

     section (eg addresses for a switch table), so that the space they

     occupy can be taken into account when deciding whether or not to

     dump the current literal pool.

     XXX - currently we do not cope with the .space and .dcb.d directives.  */

  { "ascii",    mcore_stringer,       8 + 0 },

  { "asciz",    mcore_stringer,       8 + 1 },

  { "byte",     mcore_cons,           1 },

  { "dc",       mcore_cons,           2 },

  { "dc.b",     mcore_cons,           1 },

  { "dc.d",     mcore_float_cons,    'd'},

  { "dc.l",     mcore_cons,           4 },

  { "dc.s",     mcore_float_cons,    'f'},

  { "dc.w",     mcore_cons,           2 },

  { "dc.x",     mcore_float_cons,    'x'},

  { "double",   mcore_float_cons,    'd'},

  { "float",    mcore_float_cons,    'f'},

  { "hword",    mcore_cons,           2 },

  { "int",      mcore_cons,           4 },

  { "long",     mcore_cons,           4 },

  { "octa",     mcore_cons,          16 },

  { "quad",     mcore_cons,           8 },

  { "short",    mcore_cons,           2 },

  { "single",   mcore_float_cons,    'f'},

  { "string",   mcore_stringer,       8 + 1 },

  { "word",     mcore_cons,           2 },

  { "fill",     mcore_fill,           0 },

  /* Allow for the effect of section changes.  */

  { "text",      mcore_s_text,    0 },

  { "data",      mcore_s_data,    0 },

  { "bss",       mcore_s_bss,     1 },

#ifdef OBJ_ELF

  { "comm",      mcore_s_comm,    0 },

#endif

  { "section",   mcore_s_section, 0 },

  { "section.s", mcore_s_section, 0 },

  { "sect",      mcore_s_section, 0 },

  { "sect.s",    mcore_s_section, 0 },

  { 0,          0,                0 }

};

/* This function is called once, at assembler startup time.  This should

   set up all the tables, etc that the MD part of the assembler needs.  */

void

md_begin (void)

{

  const mcore_opcode_info * opcode;

  char * prev_name = "";

  opcode_hash_control = hash_new ();

  /* Insert unique names into hash table.  */

  for (opcode = mcore_table; opcode->name; opcode ++)

    {

      if (! streq (prev_name, opcode->name))

        {

          prev_name = opcode->name;

          hash_insert (opcode_hash_control, opcode->name, (char *) opcode);

        }

    }

}

/* Get a log2(val).  */

static int

mylog2 (unsigned int val)

{

  int log = -1;

  while (val != 0)

      {

        log ++;

        val >>= 1;

      }

  return log;

}

/* Try to parse a reg name.  */

static char *

parse_reg (char * s, unsigned * reg)

{

  /* Strip leading whitespace.  */

  while (ISSPACE (* s))

    ++ s;

  if (TOLOWER (s[0]) == 'r')

    {

      if (s[1] == '1' && s[2] >= '0' && s[2] <= '5')

        {

          *reg = 10 + s[2] - '0';

          return s + 3;

        }

      if (s[1] >= '0' && s[1] <= '9')

        {

          *reg = s[1] - '0';

          return s + 2;

        }

    }

  else if (   TOLOWER (s[0]) == 's'

           && TOLOWER (s[1]) == 'p'

           && ! ISALNUM (s[2]))

    {

      * reg = 0;

      return s + 2;

    }

  as_bad (_("register expected, but saw '%.6s'"), s);

  return s;

}

static struct Cregs

{

  char * name;

  unsigned int crnum;

}

cregs[] =

{

  { "psr",       0},

  { "vbr",       1},

  { "epsr",      2},

  { "fpsr",      3},

  { "epc",       4},

  { "fpc",       5},

  { "ss0",       6},

  { "ss1",       7},

  { "ss2",       8},

  { "ss3",       9},

  { "ss4",      10},

  { "gcr",      11},

  { "gsr",      12},

  { "",          0}

};

static char *

parse_creg (char * s, unsigned * reg)

{

  int i;

  /* Strip leading whitespace.  */

  while (ISSPACE (* s))

    ++s;

  if ((TOLOWER (s[0]) == 'c' && TOLOWER (s[1]) == 'r'))

    {

      if (s[2] == '3' && s[3] >= '0' && s[3] <= '1')

        {

          *reg = 30 + s[3] - '0';

          return s + 4;

        }

      if (s[2] == '2' && s[3] >= '0' && s[3] <= '9')

        {

          *reg = 20 + s[3] - '0';

          return s + 4;

        }

      if (s[2] == '1' && s[3] >= '0' && s[3] <= '9')

        {

          *reg = 10 + s[3] - '0';

          return s + 4;

        }

      if (s[2] >= '0' && s[2] <= '9')

        {

          *reg = s[2] - '0';

          return s + 3;

        }

    }

  /* Look at alternate creg names before giving error.  */

  for (i = 0; cregs[i].name[0] != '\0'; i++)

    {

      char buf [10];

      int  length;

      int  j;

      length = strlen (cregs[i].name);

      for (j = 0; j < length; j++)

        buf[j] = TOLOWER (s[j]);

      if (strncmp (cregs[i].name, buf, length) == 0)

        {

          *reg = cregs[i].crnum;

          return s + length;

        }

    }

  as_bad (_("control register expected, but saw '%.6s'"), s);

  return s;

}

static char *

parse_psrmod (char * s, unsigned * reg)

{

  int  i;

  char buf[10];

  static struct psrmods

  {

    char *       name;

    unsigned int value;

  }

  psrmods[] =

  {

    { "ie", 1 },

    { "fe", 2 },

    { "ee", 4 },

    { "af", 8 } /* Really 0 and non-combinable.  */

  };

  for (i = 0; i < 2; i++)

    buf[i] = TOLOWER (s[i]);

  for (i = sizeof (psrmods) / sizeof (psrmods[0]); i--;)

    {

      if (! strncmp (psrmods[i].name, buf, 2))

        {

          * reg = psrmods[i].value;

          return s + 2;

        }

    }

  as_bad (_("bad/missing psr specifier"));

  * reg = 0;

  return s;

}

static char *

parse_exp (char * s, expressionS * e)

{

  char * save;

  char * new;

  /* Skip whitespace.  */

  while (ISSPACE (* s))

    ++ s;

  save = input_line_pointer;

  input_line_pointer = s;

  expression (e);

  if (e->X_op == O_absent)

    as_bad (_("missing operand"));

  new = input_line_pointer;

  input_line_pointer = save;

  return new;

}