gcc/bc-emit.c - gcc - Git at Google

 /* Output bytecodes for GNU C-compiler.
    Copyright (C) 1993, 1994, 1996, 1997 Free Software Foundation, Inc.

 This file is part of GNU CC.

 GNU CC 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, or (at your option)
 any later version.

 GNU CC 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 GNU CC; see the file COPYING.  If not, write to
 the Free Software Foundation, 59 Temple Place - Suite 330,
 Boston, MA 02111-1307, USA.  */


 #include "config.h"
 #include <stdio.h>
 #ifdef __STDC__
 #include <stdarg.h>
 #else
 #include <varargs.h>
 #endif
 #include "machmode.h"
 #include "rtl.h"
 #include "real.h"
 #include "obstack.h"
 #include "bytecode.h"
 #ifdef __GNUC__
 #include "bytetypes.h"
 #endif
 #include "bc-emit.h"
 #include "bc-opcode.h"
 #include "bc-typecd.h"
 #include "bi-run.h"

 extern char *xmalloc (), *xrealloc ();

 extern struct obstack *rtl_obstack;

 /* Indexed by mode class, gives the narrowest mode for each class.  */

 extern enum machine_mode class_narrowest_mode[(int) MAX_MODE_CLASS];

 /* Commonly used modes.  */
 /* Mode whose width is BITS_PER_UNIT */
 extern enum machine_mode byte_mode;

 /* Mode whose width is BITS_PER_WORD */
 extern enum machine_mode word_mode;

 /* Vector indexed by opcode giving info about the args for each opcode.  */
 static struct arityvec arityvec[] = {
 #include "bc-arity.h"
 };

 /* How to print a symbol name for the assembler.  */

 static void
 prsym (file, s)
      FILE *file;
      char *s;
 {
   if (*s == '*')
     fprintf (file, "%s", s + 1);
   else

 #ifdef NAMES_HAVE_UNDERSCORES
     fprintf (file, "_%s", s);
 #else
     fprintf (file, "%s", s);
 #endif

 }

 /* Maintain a bucket hash table for symbol names.  */

 #define HASH_BITS 32
 #define HASH_SIZE 509

 static struct bc_sym *hashtab[HASH_SIZE];

 static unsigned int
 hash (name)
      char *name;
 {
   unsigned int hash = 0;

   while (*name)
     {
       hash = hash << 3 | hash >> HASH_BITS - 3;
       hash += *name++;
     }

   return hash % HASH_SIZE;
 }


 /* Look up the named symbol, creating it if it doesn't exist.  */

 struct bc_sym *
 sym_lookup (name)
      char *name;
 {
   int i;
   struct bc_sym *s;

   i = hash (name);
   for (s = hashtab[i]; s; s = s->next)
     if (!strcmp (s->name, name))
       return s;

   s = (struct bc_sym *) xmalloc (sizeof (struct bc_sym));
   s->name = xmalloc (strlen (name) + 1);
   strcpy (s->name, name);
   s->defined = s->global = s->common = 0;
   s->val = 0;
   s->next = hashtab[i];
   hashtab[i] = s;
   return s;
 }


 /* Write out .globl and common symbols to the named file.  */

 static void
 bc_sym_write (file)
      FILE *file;
 {
   int i;
   struct bc_sym *s;

   for (i = 0; i < HASH_SIZE; ++i)
     for (s = hashtab[i]; s; s = s->next)
       {
 	if (s->global)
 	  {
 	    fprintf (file, "\n\t.globl ");
 	    prsym (file, s->name);
 	    putc ('\n', file);
 	    if (s->common)
 	      {
 		fprintf (file, "\n\t.comm ");
 		prsym (file, s->name);
 		fprintf (file, ", %lu\n", s->val);
 	      }
 	  }
 	else if (s->common)
 	  {
 	    fprintf (file, "\n\t.lcomm ");
 	    prsym (file, s->name);
 	    fprintf (file, ", %lu\n", s->val);
 	  }
       }
 }


 /* Create and initialize a new segment.  */

 static struct bc_seg *
 seg_create ()
 {
   struct bc_seg *result;

   result = (struct bc_seg *) xmalloc (sizeof (struct bc_seg));
   result->alloc = 256;
   result->data = xmalloc (result->alloc);
   result->size = 0;
   result->syms = 0;
   result->relocs = 0;
   return result;
 }


 /* Advance the segment index to the next alignment boundary.  */

 static void
 seg_align (seg, log)
      struct bc_seg *seg;
      int log;
 {
   unsigned int oldsize = seg->size;

   seg->size = seg->size + (1 << log) - 1 & ~((1 << log) - 1);
   if (seg->size > seg->alloc)
     {
       while (seg->size > seg->alloc)
 	seg->alloc *= 2;
       seg->data = xrealloc (seg->data, seg->alloc);
     }
   bzero (seg->data + oldsize, seg->size - oldsize);
 }


 /* Append the given data to the given segment.  */

 static void
 seg_data (seg, data, size)
      struct bc_seg *seg;
      char *data;
      unsigned int size;
 {
   if (seg->size + size > seg->alloc)
     {
       while (seg->size + size > seg->alloc)
 	seg->alloc *= 2;
       seg->data = xrealloc (seg->data, seg->alloc);
     }

   bcopy (data, seg->data + seg->size, size);
   seg->size += size;
 }


 /* Append a zero-filled skip to the given segment.  */

 static void
 seg_skip (seg, size)
      struct bc_seg *seg;
      unsigned int size;
 {
   if (seg->size + size > seg->alloc)
     {
       while (seg->size + size > seg->alloc)
 	seg->alloc *= 2;
       seg->data = xrealloc (seg->data, seg->alloc);
     }

   memset (seg->data + seg->size, 0, size);
   seg->size += size;
 }


 /* Define the given name as the current offset in the given segment.  It
    is an error if the name is already defined.  Return 0 or 1 indicating
    failure or success respectively.  */

 static int
 seg_defsym (seg, name)
      struct bc_seg *seg;
      char *name;
 {
   struct bc_sym *sym;
   struct bc_segsym *segsym;

   sym = sym_lookup (name);
   if (sym->defined)
     return 0;

   sym->defined = 1;
   sym->val = seg->size;
   segsym = (struct bc_segsym *) xmalloc (sizeof (struct bc_segsym));
   segsym->sym = sym;
   segsym->next = seg->syms;
   seg->syms = segsym;
   return 1;
 }


 /* Generate in seg's data a reference to the given sym, adjusted by
    the given offset.  */

 static void
 seg_refsym (seg, name, offset)
      struct bc_seg *seg;
      char *name;
      int offset;
 {
   struct bc_sym *sym;
   struct bc_segreloc *segreloc;

   sym = sym_lookup (name);
   segreloc = (struct bc_segreloc *) xmalloc (sizeof (struct bc_segreloc));
   segreloc->offset = seg->size;
   segreloc->sym = sym;
   segreloc->next = seg->relocs;
   seg->relocs = segreloc;
   seg_data (seg, (char *) &offset, sizeof offset);
 }


 /* Concatenate the contents of given segments into the first argument.  */

 static void
 seg_concat (result, seg)
      struct bc_seg *result, *seg;
 {
   unsigned int fix;
   struct bc_segsym *segsym;
   struct bc_segreloc *segreloc;

   seg_align (result, MACHINE_SEG_ALIGN);
   fix = result->size;
   seg_data (result, seg->data, seg->size);
   free (seg->data);

   /* Go through the symbols and relocs of SEG, adjusting their offsets
      for their new location in RESULT.  */
   if (seg->syms)
     {
       segsym = seg->syms;
       do
 	segsym->sym->val += fix;
       while (segsym->next && (segsym = segsym->next));
       segsym->next = result->syms;
       result->syms = seg->syms;
     }
   if (seg->relocs)
     {
       segreloc = seg->relocs;
       do
 	segreloc->offset += fix;
       while (segreloc->next && (segreloc = segreloc->next));
       segreloc->next = result->relocs;
       result->relocs = seg->relocs;
     }

   free ((char *) seg);
 }

 /* Write a segment to a file.  */

 static void
 bc_seg_write (seg, file)
      struct bc_seg *seg;
      FILE *file;
 {
   struct bc_segsym *segsym, *nsegsym, *psegsym;
   struct bc_segreloc *segreloc, *nsegreloc, *psegreloc;
   int i, offset, flag;

   /* Reverse the list of symbols.  */
   for (psegsym = 0, segsym = seg->syms; segsym; segsym = nsegsym)
     {
       nsegsym = segsym->next;
       segsym->next = psegsym;
       psegsym = segsym;
     }
   seg->syms = psegsym;

   /* Reverse the list of relocs.  */
   for (psegreloc = 0, segreloc = seg->relocs; segreloc; segreloc = nsegreloc)
     {
       nsegreloc = segreloc->next;
       segreloc->next = psegreloc;
       psegreloc = segreloc;
     }
   seg->relocs = psegreloc;

   /* Output each byte of the segment.  */
   for (i = 0, segsym = seg->syms, segreloc = seg->relocs; i < seg->size; ++i)
     {
       while (segsym && segsym->sym->val == i)
 	{
 	  if (i % 8 != 0)
 	    putc ('\n', file);

 	  BC_WRITE_SEGSYM (segsym, file);
 	  segsym = segsym->next;
 	  flag = 1;
 	}
       if (segreloc && segreloc->offset == i)
 	{
 	  if (i % 8 != 0)
 	    putc ('\n', file);

 	  bcopy (seg->data + i, (char *) &offset, sizeof (int));
 	  i += sizeof (int) - 1;

 	  BC_WRITE_RELOC_ENTRY (segreloc, file, offset);
 	  segreloc = segreloc->next;
 	  flag = 1;
 	}
       else
 	{
 	  if (i % 8 == 0 || flag)
 	    BC_START_BYTECODE_LINE (file);

 	  BC_WRITE_BYTECODE (i % 8 == 0 || flag ? ' ' : ',',
 			     seg->data[i] & 0xFF,
 			     file);
 	  flag = 0;
 	  if (i % 8 == 7)
 	    putc ('\n', file);
 	}
     }

   /* Paranoia check--we should have visited all syms and relocs during
      the output pass.  */

   if (segsym || segreloc)
     abort ();
 }


 /* Text and data segments of the object file in making.  */
 static struct bc_seg *bc_text_seg;
 static struct bc_seg *bc_data_seg;

 /* Called before anything else in this module.  */

 void
 bc_initialize ()
 {
   int min_class_size[(int) MAX_MODE_CLASS];
   enum machine_mode mode;
   int i;

   bc_init_mode_to_code_map ();

   bc_text_seg = seg_create ();
   bc_data_seg = seg_create ();

   dconst0 = REAL_VALUE_ATOF ("0", DFmode);
   dconst1 = REAL_VALUE_ATOF ("1", DFmode);
   dconst2 = REAL_VALUE_ATOF ("2", DFmode);
   dconstm1 = REAL_VALUE_ATOF ("-1", DFmode);

   /* Find the narrowest mode for each class and compute the word and byte
      modes.  */

   for (i = 0; i < (int) MAX_MODE_CLASS; i++)
     min_class_size[i] = 1000;

   for (mode = VOIDmode; (int) mode < (int) MAX_MACHINE_MODE;
        mode = (enum machine_mode) ((int) mode + 1))
     {
       if (GET_MODE_SIZE (mode) < min_class_size[(int) GET_MODE_CLASS (mode)])
 	{
 	  class_narrowest_mode[(int) GET_MODE_CLASS (mode)] = mode;
 	  min_class_size[(int) GET_MODE_CLASS (mode)] = GET_MODE_SIZE (mode);
 	}
       if (GET_MODE_CLASS (mode) == MODE_INT
 	  && GET_MODE_BITSIZE (mode) == BITS_PER_UNIT)
 	byte_mode = mode;

       if (GET_MODE_CLASS (mode) == MODE_INT
 	  && GET_MODE_BITSIZE (mode) == BITS_PER_WORD)
 	word_mode = mode;
     }
 }


 /* External addresses referenced in a function.  Rather than trying to
    work relocatable address directly into bytecoded functions (which would
    require us to provide hairy location info and possibly obey alignment
    rules imposed by the architecture) we build an auxiliary table of
    pointer constants, and encode just offsets into this table into the
    actual bytecode.  */
 static struct bc_seg *ptrconsts;

 /* Trampoline code for the function entry.  */
 struct bc_seg *trampoline;

 /* Actual byte code of the function.  */
 struct bc_seg *bytecode;

 /* List of labels defined in the function.  */
 struct bc_label *labels;

 /* List of label references in the function.  */
 struct bc_labelref *labelrefs;


 /* Add symbol to pointer table.  Return offset into table where
    pointer was stored.  The offset usually goes into the bytecode
    stream as a constP literal.  */

 int
 bc_define_pointer (p)
      char *p;
 {
   int offset = ptrconsts->size;

   seg_refsym (ptrconsts, p, 0);
   return offset;
 }


 /* Begin a bytecoded function.  */

 int
 bc_begin_function (name)
     char *name;
 {
   ptrconsts = seg_create ();
   trampoline = seg_create ();
   bytecode = seg_create ();
   return seg_defsym (trampoline, name);
 }


 /* Force alignment in inline bytecode.  */

 void
 bc_align_bytecode (align)
     int align;
 {
   seg_align (bytecode, align);
 }


 /* Emit data inline into bytecode.  */

 void
 bc_emit_bytecode_const (data, size)
      char *data;
      unsigned int size;
 {
   if (bytecode)
     seg_data (bytecode, data, size);
 }


 /* Create a new "bytecode label", to have its value defined later.
    Bytecode labels have nothing to do with the object file symbol table,
    and are purely local to a given bytecoded function.  */

 struct bc_label *
 bc_get_bytecode_label ()
 {
   struct bc_label *result;

   result = (struct bc_label *) xmalloc (sizeof (struct bc_label));
   result->defined = 0;
   result->next = labels;
   result->uid = 0;
   labels = result;
   return result;
 }


 /* Define the given label with the current location counter.  */

 int
 bc_emit_bytecode_labeldef (label)
      struct bc_label *label;
 {
   extern int bc_new_uid ();

   if (!label || label->defined)
     return 0;

   label->offset = bytecode->size;
   label->defined = 1;
   label->uid = bc_new_uid ();

 #ifdef DEBUG_PRINT_CODE
   fprintf (stderr, "$%lx:\n", label);
 #endif

   return 1;
 }


 /* Generate a location-relative reference to the given bytecode label.
    It need not be defined yet; label references will be backpatched later.  */

 void
 bc_emit_bytecode_labelref (label)
      struct bc_label *label;
 {
   struct bc_labelref *labelref;
   static int zero;

   labelref = (struct bc_labelref *) xmalloc (sizeof (struct bc_labelref));
   labelref->label = label;
   labelref->offset = bytecode->size;
   labelref->next = labelrefs;
   labelrefs = labelref;

 #ifdef DEBUG_PRINT_CODE
   fprintf (stderr, " $%lx", label);
 #endif

   seg_data (bytecode, (char *) &zero, sizeof zero);
 }


 /* Emit a reference to an external address; generate the reference in the
    ptrconst area, and emit an offset in the bytecode.  */

 void
 bc_emit_code_labelref (name, offset)
      char *name;
      int offset;
 {
   int ptroff;

   ptroff = ptrconsts->size / sizeof (char *);
   seg_data (bytecode, (char *) &ptroff, sizeof ptroff);
   seg_refsym (ptrconsts, name, offset);

 #ifdef DEBUG_PRINT_CODE
   fprintf (stderr, " [external <%x> %s]", ptroff, name);
 #endif
 }


 /* Backpatch label references in the byte code, and concatenate the bytecode
    and pointer constant segments to the cumulative text for the object file.
    Return a label name for the pointer constants region.  */

 char *
 bc_end_function ()
 {
   int addr;
   struct bc_label *label, *next;
   struct bc_labelref *ref, *nextref;
   char ptrconsts_label[20];
   static int nlab;

   /* Backpatch bytecode label references.  */
   for (ref = labelrefs; ref; ref = ref->next)
     if (ref->label->defined)
       {
 	addr = ref->label->offset;
 	bcopy ((char *) &addr, bytecode->data + ref->offset, sizeof addr);
       }

   /* Free the chains of labelrefs and labeldefs.  */
   for (ref = labelrefs; ref; ref = nextref)
     {
       nextref = ref->next;
       free ((char *) ref);
     }

   for (label = labels; label; label = next)
     {
       next = label->next;
       free ((char *) label);
     }

   seg_concat (trampoline, bytecode);
   seg_align (trampoline, MACHINE_SEG_ALIGN);
   sprintf (ptrconsts_label, "*LP%d", nlab++);
   seg_defsym (trampoline, ptrconsts_label);
   seg_concat (trampoline, ptrconsts);
   seg_concat (bc_text_seg, trampoline);

   labels = 0;
   labelrefs = 0;
   trampoline = 0;
   bytecode = 0;
   ptrconsts = 0;

   return sym_lookup (ptrconsts_label)->name;
 }

 /* Force alignment in const data.  */

 void
 bc_align_const (align)
      int align;
 {
   seg_align (bc_text_seg, align);
 }

 /* Emit const data.  */

 void
 bc_emit_const (data, size)
      char *data;
      unsigned int size;
 {
   seg_data (bc_text_seg, data, size);
 }

 /* Emit a zero-filled constant skip.  */

 void
 bc_emit_const_skip (size)
      unsigned int size;
 {
   seg_skip (bc_text_seg, size);
 }

 /* Emit a label definition in const data.  */

 int
 bc_emit_const_labeldef (name)
      char *name;
 {
   return seg_defsym (bc_text_seg, name);
 }

 /* Emit a label reference in const data.  */

 void
 bc_emit_const_labelref (name, offset)
      char *name;
      int offset;
 {
   seg_refsym (bc_text_seg, name, offset);
 }

 /* Force alignment in data.  */

 void
 bc_align_data (align)
      int align;
 {
   seg_align (bc_data_seg, align);
 }

 /* Emit data.  */

 void
 bc_emit_data (data, size)
      char *data;
      unsigned int size;
 {
   seg_data (bc_data_seg, data, size);
 }

 /* Emit a zero-filled data skip.  */

 void
 bc_emit_data_skip (size)
      unsigned int size;
 {
   seg_skip (bc_data_seg, size);
 }

 /* Emit label definition in data.  */

 int
 bc_emit_data_labeldef (name)
      char *name;
 {
   return seg_defsym (bc_data_seg, name);
 }

 /* Emit label reference in data.  */

 void
 bc_emit_data_labelref (name, offset)
      char *name;
      int offset;
 {
   seg_refsym (bc_data_seg, name, offset);
 }

 /* Emit a common block of the given name and size.  Note that
    when the .o file is actually written non-global "common"
    blocks will have to be turned into space in the data section.  */

 int
 bc_emit_common (name, size)
      char *name;
      unsigned int size;
 {
   struct bc_sym *sym;

   sym = sym_lookup (name);
   if (sym->defined)
     return 0;

   sym->defined = 1;
   sym->common = 1;
   sym->val = size;
   return 1;
 }

 /* Globalize the given label.  */

 void
 bc_globalize_label (name)
      char *name;
 {
   struct bc_sym *sym;

   sym = sym_lookup (name);
   sym->global = 1;
 }

 static enum { in_text, in_data } section = in_text;

 void
 bc_text ()
 {
   section = in_text;
 }

 void
 bc_data ()
 {
   section = in_data;
 }

 void
 bc_align (align)
      int align;
 {
   if (section == in_text)
     bc_align_const (align);
   else
     bc_align_data (align);
 }

 void
 bc_emit (data, size)
      char *data;
      unsigned int size;
 {
   if (section == in_text)
     bc_emit_const (data, size);
   else
     bc_emit_data (data, size);
 }

 void
 bc_emit_skip (size)
      unsigned int size;
 {
   if (section == in_text)
     bc_emit_const_skip (size);
   else
     bc_emit_data_skip (size);
 }

 int
 bc_emit_labeldef (name)
      char *name;
 {
   if (section == in_text)
     return bc_emit_const_labeldef (name);
   else
     return bc_emit_data_labeldef (name);
 }

 void
 bc_emit_labelref (name, offset)
      char *name;
      int offset;
 {
   if (section == in_text)
     bc_emit_const_labelref (name, offset);
   else
     bc_emit_data_labelref (name, offset);
 }

 void
 bc_write_file (file)
      FILE *file;
 {
   BC_WRITE_FILE (file);
 }


 /* Allocate a new bytecode rtx.
    If you supply a null BC_LABEL, we generate one.  */

 rtx
 bc_gen_rtx (label, offset, bc_label)
      char *label;
      int offset;
      struct bc_label *bc_label;
 {
   rtx r;

   if (bc_label == 0)
     bc_label = (struct bc_label *) xmalloc (sizeof (struct bc_label));

   r = gen_rtx (CODE_LABEL, VOIDmode, label, bc_label);
   bc_label->offset = offset;

   return r;
 }


 /* Print bytecode rtx */

 void
 bc_print_rtl (fp, r)
      FILE *fp;
      rtx r;
 {
 #if 0 /* This needs to get fixed to really work again.  */
   /* BC_WRITE_RTL has a definition
      that doesn't even make sense for this use.  */
   BC_WRITE_RTL (r, fp);
 #endif
 }


 /* Emit a bytecode, keeping a running tally of the stack depth.  */

 void
 bc_emit_bytecode (bytecode)
      enum bytecode_opcode bytecode;
 {
   char byte;
   static int prev_lineno = -1;

   byte = (char) bytecode;

 #ifdef BCDEBUG_PRINT_CODE
   if (lineno != prev_lineno)
     {
       fprintf (stderr, "<line %d>\n", lineno);
       prev_lineno = lineno;
     }

   fputs (opcode_name[(unsigned int) bytecode], stderr);
 #endif

   /* Due to errors we are often requested to output bytecodes that
      will cause an interpreter stack undeflow when executed.  Instead of
      dumping core on such occasions, we omit the bytecode.  Erroneous code
      should not be executed, regardless.  This makes life much easier, since
      we don't have to deceive ourselves about the known stack depth.  */

   bc_emit_bytecode_const (&byte, 1);

   if ((stack_depth -= arityvec[(int) bytecode].ninputs) >= 0)
     {
       if ((stack_depth += arityvec[(int) bytecode].noutputs) > max_stack_depth)
 	max_stack_depth = stack_depth;
     }

 #ifdef VALIDATE_STACK_FOR_BC
   VALIDATE_STACK_FOR_BC ();
 #endif
 }


 #ifdef BCDEBUG_PRINT_CODE
 #define PRLIT(TYPE, PTR)  fprintf (stderr, " [%x]", *(TYPE *) PTR)
 #else
 #define PRLIT(X,Y)
 #endif

 /* Emit a complete bytecode instruction, expecting the correct number
    of literal values in the call.  First argument is the instruction, the
    remaining arguments are literals of size HOST_WIDE_INT or smaller.  */

 void
 bc_emit_instruction VPROTO((enum bytecode_opcode opcode, ...))
 {
 #ifndef __STDC__
   enum bytecode_opcode opcode;
 #endif
   va_list arguments;
   int nliteral, instruction;

   VA_START (arguments, opcode);

 #ifndef __STDC__
   opcode = va_arg (arguments, enum bytecode_opcode);
 #endif

   /* Emit instruction bytecode */
   bc_emit_bytecode (opcode);
   instruction = (int) opcode;

   /* Loop literals and emit as bytecode constants */
   for (nliteral = 0; nliteral < arityvec[instruction].nliterals; nliteral++)
     {
       switch (arityvec[instruction].literals[nliteral])
 	{
 /* This conditional is a kludge, but it's necessary
    because TYPE might be long long.  */
 #ifdef __GNUC__
 	  /* Expand definitions into case statements */
 #define DEFTYPECODE(CODE, NAME, MODE, TYPE)				\
 	case CODE:							\
 	  {								\
 	    TYPE temp = va_arg (arguments, TYPE); 			\
 	    bc_emit_bytecode_const ((void *) &temp, sizeof temp); 	\
 	    PRLIT (TYPE, &temp); }					\
 	  break;

 #include "bc-typecd.def"

 #undef DEFTYPECODE
 #endif /* __GNUC__ */

 	default:
 	  abort ();
 	}
     }

   va_end (arguments);

 #ifdef BCDEBUG_PRINT_CODE
   fputc ('\n', stderr);
 #endif
 }

 /* Emit the machine-code interface trampoline at the beginning of a byte
    coded function.  The argument is a label name of the interpreter
    bytecode callinfo structure; the return value is a label name for
    the beginning of the actual bytecode.  */

 char *
 bc_emit_trampoline (callinfo)
      char *callinfo;
 {
   char mylab[20];
   static int n;

   sprintf (mylab, "*LB%d", n++);

   BC_EMIT_TRAMPOLINE (trampoline, callinfo);

   seg_defsym (bytecode, mylab);
   return sym_lookup (mylab)->name;
 }
	/* Output bytecodes for GNU C-compiler.
	Copyright (C) 1993, 1994, 1996, 1997 Free Software Foundation, Inc.

	This file is part of GNU CC.

	GNU CC 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, or (at your option)
	any later version.

	GNU CC 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 GNU CC; see the file COPYING. If not, write to
	the Free Software Foundation, 59 Temple Place - Suite 330,
	Boston, MA 02111-1307, USA. */


	#include "config.h"
	#include <stdio.h>
	#ifdef __STDC__
	#include <stdarg.h>
	#else
	#include <varargs.h>
	#endif
	#include "machmode.h"
	#include "rtl.h"
	#include "real.h"
	#include "obstack.h"
	#include "bytecode.h"
	#ifdef __GNUC__
	#include "bytetypes.h"
	#endif
	#include "bc-emit.h"
	#include "bc-opcode.h"
	#include "bc-typecd.h"
	#include "bi-run.h"

	extern char xmalloc (), xrealloc ();

	extern struct obstack *rtl_obstack;

	/* Indexed by mode class, gives the narrowest mode for each class. */

	extern enum machine_mode class_narrowest_mode[(int) MAX_MODE_CLASS];

	/* Commonly used modes. */
	/* Mode whose width is BITS_PER_UNIT */
	extern enum machine_mode byte_mode;

	/* Mode whose width is BITS_PER_WORD */
	extern enum machine_mode word_mode;

	/* Vector indexed by opcode giving info about the args for each opcode. */
	static struct arityvec arityvec[] = {
	#include "bc-arity.h"
	};

	/* How to print a symbol name for the assembler. */

	static void
	prsym (file, s)
	FILE *file;
	char *s;
	{
	if (s == '')
	fprintf (file, "%s", s + 1);
	else

	#ifdef NAMES_HAVE_UNDERSCORES
	fprintf (file, "_%s", s);
	#else
	fprintf (file, "%s", s);
	#endif

	}

	/* Maintain a bucket hash table for symbol names. */

	#define HASH_BITS 32
	#define HASH_SIZE 509

	static struct bc_sym *hashtab[HASH_SIZE];

	static unsigned int
	hash (name)
	char *name;
	{
	unsigned int hash = 0;

	while (*name)
	{
	hash = hash << 3 \| hash >> HASH_BITS - 3;
	hash += *name++;
	}

	return hash % HASH_SIZE;
	}


	/* Look up the named symbol, creating it if it doesn't exist. */

	struct bc_sym *
	sym_lookup (name)
	char *name;
	{
	int i;
	struct bc_sym *s;

	i = hash (name);
	for (s = hashtab[i]; s; s = s->next)
	if (!strcmp (s->name, name))
	return s;

	s = (struct bc_sym *) xmalloc (sizeof (struct bc_sym));
	s->name = xmalloc (strlen (name) + 1);
	strcpy (s->name, name);
	s->defined = s->global = s->common = 0;
	s->val = 0;
	s->next = hashtab[i];
	hashtab[i] = s;
	return s;
	}


	/* Write out .globl and common symbols to the named file. */

	static void
	bc_sym_write (file)
	FILE *file;
	{
	int i;
	struct bc_sym *s;

	for (i = 0; i < HASH_SIZE; ++i)
	for (s = hashtab[i]; s; s = s->next)
	{
	if (s->global)
	{
	fprintf (file, "\n\t.globl ");
	prsym (file, s->name);
	putc ('\n', file);
	if (s->common)
	{
	fprintf (file, "\n\t.comm ");
	prsym (file, s->name);
	fprintf (file, ", %lu\n", s->val);
	}
	}
	else if (s->common)
	{
	fprintf (file, "\n\t.lcomm ");
	prsym (file, s->name);
	fprintf (file, ", %lu\n", s->val);
	}
	}
	}




	/* Create and initialize a new segment. */

	static struct bc_seg *
	seg_create ()
	{
	struct bc_seg *result;

	result = (struct bc_seg *) xmalloc (sizeof (struct bc_seg));
	result->alloc = 256;
	result->data = xmalloc (result->alloc);
	result->size = 0;
	result->syms = 0;
	result->relocs = 0;
	return result;
	}


	/* Advance the segment index to the next alignment boundary. */

	static void
	seg_align (seg, log)
	struct bc_seg *seg;
	int log;
	{
	unsigned int oldsize = seg->size;

	seg->size = seg->size + (1 << log) - 1 & ~((1 << log) - 1);
	if (seg->size > seg->alloc)
	{
	while (seg->size > seg->alloc)
	seg->alloc *= 2;
	seg->data = xrealloc (seg->data, seg->alloc);
	}
	bzero (seg->data + oldsize, seg->size - oldsize);
	}


	/* Append the given data to the given segment. */

	static void
	seg_data (seg, data, size)
	struct bc_seg *seg;
	char *data;
	unsigned int size;
	{
	if (seg->size + size > seg->alloc)
	{
	while (seg->size + size > seg->alloc)
	seg->alloc *= 2;
	seg->data = xrealloc (seg->data, seg->alloc);
	}

	bcopy (data, seg->data + seg->size, size);
	seg->size += size;
	}


	/* Append a zero-filled skip to the given segment. */

	static void
	seg_skip (seg, size)
	struct bc_seg *seg;
	unsigned int size;
	{
	if (seg->size + size > seg->alloc)
	{
	while (seg->size + size > seg->alloc)
	seg->alloc *= 2;
	seg->data = xrealloc (seg->data, seg->alloc);
	}

	memset (seg->data + seg->size, 0, size);
	seg->size += size;
	}


	/* Define the given name as the current offset in the given segment. It
	is an error if the name is already defined. Return 0 or 1 indicating
	failure or success respectively. */

	static int
	seg_defsym (seg, name)
	struct bc_seg *seg;
	char *name;
	{
	struct bc_sym *sym;
	struct bc_segsym *segsym;

	sym = sym_lookup (name);
	if (sym->defined)
	return 0;

	sym->defined = 1;
	sym->val = seg->size;
	segsym = (struct bc_segsym *) xmalloc (sizeof (struct bc_segsym));
	segsym->sym = sym;
	segsym->next = seg->syms;
	seg->syms = segsym;
	return 1;
	}


	/* Generate in seg's data a reference to the given sym, adjusted by
	the given offset. */

	static void
	seg_refsym (seg, name, offset)
	struct bc_seg *seg;
	char *name;
	int offset;
	{
	struct bc_sym *sym;
	struct bc_segreloc *segreloc;

	sym = sym_lookup (name);
	segreloc = (struct bc_segreloc *) xmalloc (sizeof (struct bc_segreloc));
	segreloc->offset = seg->size;
	segreloc->sym = sym;
	segreloc->next = seg->relocs;
	seg->relocs = segreloc;
	seg_data (seg, (char *) &offset, sizeof offset);
	}


	/* Concatenate the contents of given segments into the first argument. */

	static void
	seg_concat (result, seg)
	struct bc_seg result, seg;
	{
	unsigned int fix;
	struct bc_segsym *segsym;
	struct bc_segreloc *segreloc;

	seg_align (result, MACHINE_SEG_ALIGN);
	fix = result->size;
	seg_data (result, seg->data, seg->size);
	free (seg->data);

	/* Go through the symbols and relocs of SEG, adjusting their offsets
	for their new location in RESULT. */
	if (seg->syms)
	{
	segsym = seg->syms;
	do
	segsym->sym->val += fix;
	while (segsym->next && (segsym = segsym->next));
	segsym->next = result->syms;
	result->syms = seg->syms;
	}
	if (seg->relocs)
	{
	segreloc = seg->relocs;
	do
	segreloc->offset += fix;
	while (segreloc->next && (segreloc = segreloc->next));
	segreloc->next = result->relocs;
	result->relocs = seg->relocs;
	}

	free ((char *) seg);
	}

	/* Write a segment to a file. */

	static void
	bc_seg_write (seg, file)
	struct bc_seg *seg;
	FILE *file;
	{
	struct bc_segsym segsym, nsegsym, *psegsym;
	struct bc_segreloc segreloc, nsegreloc, *psegreloc;
	int i, offset, flag;

	/* Reverse the list of symbols. */
	for (psegsym = 0, segsym = seg->syms; segsym; segsym = nsegsym)
	{
	nsegsym = segsym->next;
	segsym->next = psegsym;
	psegsym = segsym;
	}
	seg->syms = psegsym;

	/* Reverse the list of relocs. */
	for (psegreloc = 0, segreloc = seg->relocs; segreloc; segreloc = nsegreloc)
	{
	nsegreloc = segreloc->next;
	segreloc->next = psegreloc;
	psegreloc = segreloc;
	}
	seg->relocs = psegreloc;

	/* Output each byte of the segment. */
	for (i = 0, segsym = seg->syms, segreloc = seg->relocs; i < seg->size; ++i)
	{
	while (segsym && segsym->sym->val == i)
	{
	if (i % 8 != 0)
	putc ('\n', file);

	BC_WRITE_SEGSYM (segsym, file);
	segsym = segsym->next;
	flag = 1;
	}
	if (segreloc && segreloc->offset == i)
	{
	if (i % 8 != 0)
	putc ('\n', file);

	bcopy (seg->data + i, (char *) &offset, sizeof (int));
	i += sizeof (int) - 1;

	BC_WRITE_RELOC_ENTRY (segreloc, file, offset);
	segreloc = segreloc->next;
	flag = 1;
	}
	else
	{
	if (i % 8 == 0 \|\| flag)
	BC_START_BYTECODE_LINE (file);

	BC_WRITE_BYTECODE (i % 8 == 0 \|\| flag ? ' ' : ',',
	seg->data[i] & 0xFF,
	file);
	flag = 0;
	if (i % 8 == 7)
	putc ('\n', file);
	}
	}

	/* Paranoia check--we should have visited all syms and relocs during
	the output pass. */

	if (segsym \|\| segreloc)
	abort ();
	}



	/* Text and data segments of the object file in making. */
	static struct bc_seg *bc_text_seg;
	static struct bc_seg *bc_data_seg;

	/* Called before anything else in this module. */

	void
	bc_initialize ()
	{
	int min_class_size[(int) MAX_MODE_CLASS];
	enum machine_mode mode;
	int i;

	bc_init_mode_to_code_map ();

	bc_text_seg = seg_create ();
	bc_data_seg = seg_create ();

	dconst0 = REAL_VALUE_ATOF ("0", DFmode);
	dconst1 = REAL_VALUE_ATOF ("1", DFmode);
	dconst2 = REAL_VALUE_ATOF ("2", DFmode);
	dconstm1 = REAL_VALUE_ATOF ("-1", DFmode);

	/* Find the narrowest mode for each class and compute the word and byte
	modes. */

	for (i = 0; i < (int) MAX_MODE_CLASS; i++)
	min_class_size[i] = 1000;

	for (mode = VOIDmode; (int) mode < (int) MAX_MACHINE_MODE;
	mode = (enum machine_mode) ((int) mode + 1))
	{
	if (GET_MODE_SIZE (mode) < min_class_size[(int) GET_MODE_CLASS (mode)])
	{
	class_narrowest_mode[(int) GET_MODE_CLASS (mode)] = mode;
	min_class_size[(int) GET_MODE_CLASS (mode)] = GET_MODE_SIZE (mode);
	}
	if (GET_MODE_CLASS (mode) == MODE_INT
	&& GET_MODE_BITSIZE (mode) == BITS_PER_UNIT)
	byte_mode = mode;

	if (GET_MODE_CLASS (mode) == MODE_INT
	&& GET_MODE_BITSIZE (mode) == BITS_PER_WORD)
	word_mode = mode;
	}
	}


	/* External addresses referenced in a function. Rather than trying to
	work relocatable address directly into bytecoded functions (which would
	require us to provide hairy location info and possibly obey alignment
	rules imposed by the architecture) we build an auxiliary table of
	pointer constants, and encode just offsets into this table into the
	actual bytecode. */
	static struct bc_seg *ptrconsts;

	/* Trampoline code for the function entry. */
	struct bc_seg *trampoline;

	/* Actual byte code of the function. */
	struct bc_seg *bytecode;

	/* List of labels defined in the function. */
	struct bc_label *labels;

	/* List of label references in the function. */
	struct bc_labelref *labelrefs;


	/* Add symbol to pointer table. Return offset into table where
	pointer was stored. The offset usually goes into the bytecode
	stream as a constP literal. */

	int
	bc_define_pointer (p)
	char *p;
	{
	int offset = ptrconsts->size;

	seg_refsym (ptrconsts, p, 0);
	return offset;
	}


	/* Begin a bytecoded function. */

	int
	bc_begin_function (name)
	char *name;
	{
	ptrconsts = seg_create ();
	trampoline = seg_create ();
	bytecode = seg_create ();
	return seg_defsym (trampoline, name);
	}


	/* Force alignment in inline bytecode. */

	void
	bc_align_bytecode (align)
	int align;
	{
	seg_align (bytecode, align);
	}


	/* Emit data inline into bytecode. */

	void
	bc_emit_bytecode_const (data, size)
	char *data;
	unsigned int size;
	{
	if (bytecode)
	seg_data (bytecode, data, size);
	}


	/* Create a new "bytecode label", to have its value defined later.
	Bytecode labels have nothing to do with the object file symbol table,
	and are purely local to a given bytecoded function. */

	struct bc_label *
	bc_get_bytecode_label ()
	{
	struct bc_label *result;

	result = (struct bc_label *) xmalloc (sizeof (struct bc_label));
	result->defined = 0;
	result->next = labels;
	result->uid = 0;
	labels = result;
	return result;
	}


	/* Define the given label with the current location counter. */

	int
	bc_emit_bytecode_labeldef (label)
	struct bc_label *label;
	{
	extern int bc_new_uid ();

	if (!label \|\| label->defined)
	return 0;

	label->offset = bytecode->size;
	label->defined = 1;
	label->uid = bc_new_uid ();

	#ifdef DEBUG_PRINT_CODE
	fprintf (stderr, "$%lx:\n", label);
	#endif

	return 1;
	}


	/* Generate a location-relative reference to the given bytecode label.
	It need not be defined yet; label references will be backpatched later. */

	void
	bc_emit_bytecode_labelref (label)
	struct bc_label *label;
	{
	struct bc_labelref *labelref;
	static int zero;

	labelref = (struct bc_labelref *) xmalloc (sizeof (struct bc_labelref));
	labelref->label = label;
	labelref->offset = bytecode->size;
	labelref->next = labelrefs;
	labelrefs = labelref;

	#ifdef DEBUG_PRINT_CODE
	fprintf (stderr, " $%lx", label);
	#endif

	seg_data (bytecode, (char *) &zero, sizeof zero);
	}


	/* Emit a reference to an external address; generate the reference in the
	ptrconst area, and emit an offset in the bytecode. */

	void
	bc_emit_code_labelref (name, offset)
	char *name;
	int offset;
	{
	int ptroff;

	ptroff = ptrconsts->size / sizeof (char *);
	seg_data (bytecode, (char *) &ptroff, sizeof ptroff);
	seg_refsym (ptrconsts, name, offset);

	#ifdef DEBUG_PRINT_CODE
	fprintf (stderr, " [external <%x> %s]", ptroff, name);
	#endif
	}


	/* Backpatch label references in the byte code, and concatenate the bytecode
	and pointer constant segments to the cumulative text for the object file.
	Return a label name for the pointer constants region. */

	char *
	bc_end_function ()
	{
	int addr;
	struct bc_label label, next;
	struct bc_labelref ref, nextref;
	char ptrconsts_label[20];
	static int nlab;

	/* Backpatch bytecode label references. */
	for (ref = labelrefs; ref; ref = ref->next)
	if (ref->label->defined)
	{
	addr = ref->label->offset;
	bcopy ((char *) &addr, bytecode->data + ref->offset, sizeof addr);
	}

	/* Free the chains of labelrefs and labeldefs. */
	for (ref = labelrefs; ref; ref = nextref)
	{
	nextref = ref->next;
	free ((char *) ref);
	}

	for (label = labels; label; label = next)
	{
	next = label->next;
	free ((char *) label);
	}

	seg_concat (trampoline, bytecode);
	seg_align (trampoline, MACHINE_SEG_ALIGN);
	sprintf (ptrconsts_label, "*LP%d", nlab++);
	seg_defsym (trampoline, ptrconsts_label);
	seg_concat (trampoline, ptrconsts);
	seg_concat (bc_text_seg, trampoline);

	labels = 0;
	labelrefs = 0;
	trampoline = 0;
	bytecode = 0;
	ptrconsts = 0;

	return sym_lookup (ptrconsts_label)->name;
	}

	/* Force alignment in const data. */

	void
	bc_align_const (align)
	int align;
	{
	seg_align (bc_text_seg, align);
	}

	/* Emit const data. */

	void
	bc_emit_const (data, size)
	char *data;
	unsigned int size;
	{
	seg_data (bc_text_seg, data, size);
	}

	/* Emit a zero-filled constant skip. */

	void
	bc_emit_const_skip (size)
	unsigned int size;
	{
	seg_skip (bc_text_seg, size);
	}

	/* Emit a label definition in const data. */

	int
	bc_emit_const_labeldef (name)
	char *name;
	{
	return seg_defsym (bc_text_seg, name);
	}

	/* Emit a label reference in const data. */

	void
	bc_emit_const_labelref (name, offset)
	char *name;
	int offset;
	{
	seg_refsym (bc_text_seg, name, offset);
	}

	/* Force alignment in data. */

	void
	bc_align_data (align)
	int align;
	{
	seg_align (bc_data_seg, align);
	}

	/* Emit data. */

	void
	bc_emit_data (data, size)
	char *data;
	unsigned int size;
	{
	seg_data (bc_data_seg, data, size);
	}

	/* Emit a zero-filled data skip. */

	void
	bc_emit_data_skip (size)
	unsigned int size;
	{
	seg_skip (bc_data_seg, size);
	}

	/* Emit label definition in data. */

	int
	bc_emit_data_labeldef (name)
	char *name;
	{
	return seg_defsym (bc_data_seg, name);
	}

	/* Emit label reference in data. */

	void
	bc_emit_data_labelref (name, offset)
	char *name;
	int offset;
	{
	seg_refsym (bc_data_seg, name, offset);
	}

	/* Emit a common block of the given name and size. Note that
	when the .o file is actually written non-global "common"
	blocks will have to be turned into space in the data section. */

	int
	bc_emit_common (name, size)
	char *name;
	unsigned int size;
	{
	struct bc_sym *sym;

	sym = sym_lookup (name);
	if (sym->defined)
	return 0;

	sym->defined = 1;
	sym->common = 1;
	sym->val = size;
	return 1;
	}

	/* Globalize the given label. */

	void
	bc_globalize_label (name)
	char *name;
	{
	struct bc_sym *sym;

	sym = sym_lookup (name);
	sym->global = 1;
	}

	static enum { in_text, in_data } section = in_text;

	void
	bc_text ()
	{
	section = in_text;
	}

	void
	bc_data ()
	{
	section = in_data;
	}

	void
	bc_align (align)
	int align;
	{
	if (section == in_text)
	bc_align_const (align);
	else
	bc_align_data (align);
	}

	void
	bc_emit (data, size)
	char *data;
	unsigned int size;
	{
	if (section == in_text)
	bc_emit_const (data, size);
	else
	bc_emit_data (data, size);
	}

	void
	bc_emit_skip (size)
	unsigned int size;
	{
	if (section == in_text)
	bc_emit_const_skip (size);
	else
	bc_emit_data_skip (size);
	}

	int
	bc_emit_labeldef (name)
	char *name;
	{
	if (section == in_text)
	return bc_emit_const_labeldef (name);
	else
	return bc_emit_data_labeldef (name);
	}

	void
	bc_emit_labelref (name, offset)
	char *name;
	int offset;
	{
	if (section == in_text)
	bc_emit_const_labelref (name, offset);
	else
	bc_emit_data_labelref (name, offset);
	}

	void
	bc_write_file (file)
	FILE *file;
	{
	BC_WRITE_FILE (file);
	}


	/* Allocate a new bytecode rtx.
	If you supply a null BC_LABEL, we generate one. */

	rtx
	bc_gen_rtx (label, offset, bc_label)
	char *label;
	int offset;
	struct bc_label *bc_label;
	{
	rtx r;

	if (bc_label == 0)
	bc_label = (struct bc_label *) xmalloc (sizeof (struct bc_label));

	r = gen_rtx (CODE_LABEL, VOIDmode, label, bc_label);
	bc_label->offset = offset;

	return r;
	}


	/* Print bytecode rtx */

	void
	bc_print_rtl (fp, r)
	FILE *fp;
	rtx r;
	{
	#if 0 /* This needs to get fixed to really work again. */
	/* BC_WRITE_RTL has a definition
	that doesn't even make sense for this use. */
	BC_WRITE_RTL (r, fp);
	#endif
	}


	/* Emit a bytecode, keeping a running tally of the stack depth. */

	void
	bc_emit_bytecode (bytecode)
	enum bytecode_opcode bytecode;
	{
	char byte;
	static int prev_lineno = -1;

	byte = (char) bytecode;

	#ifdef BCDEBUG_PRINT_CODE
	if (lineno != prev_lineno)
	{
	fprintf (stderr, "<line %d>\n", lineno);
	prev_lineno = lineno;
	}

	fputs (opcode_name[(unsigned int) bytecode], stderr);
	#endif

	/* Due to errors we are often requested to output bytecodes that
	will cause an interpreter stack undeflow when executed. Instead of
	dumping core on such occasions, we omit the bytecode. Erroneous code
	should not be executed, regardless. This makes life much easier, since
	we don't have to deceive ourselves about the known stack depth. */

	bc_emit_bytecode_const (&byte, 1);

	if ((stack_depth -= arityvec[(int) bytecode].ninputs) >= 0)
	{
	if ((stack_depth += arityvec[(int) bytecode].noutputs) > max_stack_depth)
	max_stack_depth = stack_depth;
	}

	#ifdef VALIDATE_STACK_FOR_BC
	VALIDATE_STACK_FOR_BC ();
	#endif
	}


	#ifdef BCDEBUG_PRINT_CODE
	#define PRLIT(TYPE, PTR) fprintf (stderr, " [%x]", (TYPE ) PTR)
	#else
	#define PRLIT(X,Y)
	#endif

	/* Emit a complete bytecode instruction, expecting the correct number
	of literal values in the call. First argument is the instruction, the
	remaining arguments are literals of size HOST_WIDE_INT or smaller. */

	void
	bc_emit_instruction VPROTO((enum bytecode_opcode opcode, ...))
	{
	#ifndef __STDC__
	enum bytecode_opcode opcode;
	#endif
	va_list arguments;
	int nliteral, instruction;

	VA_START (arguments, opcode);

	#ifndef __STDC__
	opcode = va_arg (arguments, enum bytecode_opcode);
	#endif

	/* Emit instruction bytecode */
	bc_emit_bytecode (opcode);
	instruction = (int) opcode;

	/* Loop literals and emit as bytecode constants */
	for (nliteral = 0; nliteral < arityvec[instruction].nliterals; nliteral++)
	{
	switch (arityvec[instruction].literals[nliteral])
	{
	/* This conditional is a kludge, but it's necessary
	because TYPE might be long long. */
	#ifdef __GNUC__
	/* Expand definitions into case statements */
	#define DEFTYPECODE(CODE, NAME, MODE, TYPE) \
	case CODE: \
	{ \
	TYPE temp = va_arg (arguments, TYPE); \
	bc_emit_bytecode_const ((void *) &temp, sizeof temp); \
	PRLIT (TYPE, &temp); } \
	break;

	#include "bc-typecd.def"

	#undef DEFTYPECODE
	#endif /* __GNUC__ */

	default:
	abort ();
	}
	}

	va_end (arguments);

	#ifdef BCDEBUG_PRINT_CODE
	fputc ('\n', stderr);
	#endif
	}

	/* Emit the machine-code interface trampoline at the beginning of a byte
	coded function. The argument is a label name of the interpreter
	bytecode callinfo structure; the return value is a label name for
	the beginning of the actual bytecode. */

	char *
	bc_emit_trampoline (callinfo)
	char *callinfo;
	{
	char mylab[20];
	static int n;

	sprintf (mylab, "*LB%d", n++);

	BC_EMIT_TRAMPOLINE (trampoline, callinfo);

	seg_defsym (bytecode, mylab);
	return sym_lookup (mylab)->name;
	}