gdb/testsuite/gdb.base/m32rovly.c - third_party/binutils-gdb - Git at Google


 /*
  * Ovlymgr.c -- Runtime Overlay Manager for the GDB testsuite.
  */

 #include "ovlymgr.h"

 /* Local functions and data: */

 extern unsigned long _ovly_table[][4];
 extern unsigned long _novlys __attribute__ ((section (".data")));
 enum ovly_index { VMA, SIZE, LMA, MAPPED};

 static void ovly_copy (unsigned long dst, unsigned long src, long size);

 /* Flush the data and instruction caches at address START for SIZE bytes.
    Support for each new port must be added here.  */
 /* FIXME: Might be better to have a standard libgloss function that
    ports provide that we can then use.  Use libgloss instead of newlib
    since libgloss is the one intended to handle low level system issues.
    I would suggest something like _flush_cache to avoid the user's namespace
    but not be completely obscure as other things may need this facility.  */

 static void
 FlushCache (void)
 {
 #ifdef __M32R__
   volatile char *mspr = (char *) 0xfffffff7;
   *mspr = 1;
 #endif
 }

 /* OverlayLoad:
  * Copy the overlay into its runtime region,
  * and mark the overlay as "mapped".
  */

 bool
 OverlayLoad (unsigned long ovlyno)
 {
   unsigned long i;

   if (ovlyno < 0 || ovlyno >= _novlys)
     exit (-1);	/* fail, bad ovly number */

   if (_ovly_table[ovlyno][MAPPED])
     return TRUE;	/* this overlay already mapped -- nothing to do! */

   for (i = 0; i < _novlys; i++)
     if (i == ovlyno)
       _ovly_table[i][MAPPED] = 1;	/* this one now mapped */
     else if (_ovly_table[i][VMA] == _ovly_table[ovlyno][VMA])
       _ovly_table[i][MAPPED] = 0;	/* this one now un-mapped */

   ovly_copy (_ovly_table[ovlyno][VMA],
 	     _ovly_table[ovlyno][LMA],
 	     _ovly_table[ovlyno][SIZE]);

   FlushCache ();

   return TRUE;
 }

 /* OverlayUnload:
  * Copy the overlay back into its "load" region.
  * Does NOT mark overlay as "unmapped", therefore may be called
  * more than once for the same mapped overlay.
  */

 bool
 OverlayUnload (unsigned long ovlyno)
 {
   if (ovlyno < 0 || ovlyno >= _novlys)
     exit (-1);  /* fail, bad ovly number */

   if (!_ovly_table[ovlyno][MAPPED])
     exit (-1);  /* error, can't copy out a segment that's not "in" */

   ovly_copy (_ovly_table[ovlyno][LMA],
 	     _ovly_table[ovlyno][VMA],
 	     _ovly_table[ovlyno][SIZE]);

   return TRUE;
 }

 #ifdef __D10V__
 #define IMAP0       (*(short *)(0xff00))
 #define IMAP1       (*(short *)(0xff02))
 #define DMAP        (*(short *)(0xff04))

 static void
 D10VTranslate (unsigned long logical,
 	       short *dmap,
 	       unsigned long **addr)
 {
   unsigned long physical;
   unsigned long seg;
   unsigned long off;

   /* to access data, we use the following mapping
      0x00xxxxxx: Logical data address segment        (DMAP translated memory)
      0x01xxxxxx: Logical instruction address segment (IMAP translated memory)
      0x10xxxxxx: Physical data memory segment        (On-chip data memory)
      0x11xxxxxx: Physical instruction memory segment (On-chip insn memory)
      0x12xxxxxx: Phisical unified memory segment     (Unified memory)
      */

   /* Addresses must be correctly aligned */
   if (logical & (sizeof (**addr) - 1))
     exit (-1);

   /* If the address is in one of the two logical address spaces, it is
      first translated into a physical address */
   seg = (logical >> 24);
   off = (logical & 0xffffffL);
   switch (seg)
       {
       case 0x00: /* in logical data address segment */
 	if (off <= 0x7fffL)
 	  physical = (0x10L << 24) + off;
 	else
 	  /* Logical address out side of on-chip segment, not
              supported */
 	  exit (-1);
 	break;
       case 0x01: /* in logical instruction address segment */
 	{
 	  short map;
 	  if (off <= 0x1ffffL)
 	    map = IMAP0;
 	  else if (off <= 0x3ffffL)
 	    map = IMAP1;
 	  else
 	    /* Logical address outside of IMAP[01] segment, not
 	       supported */
 	    exit (-1);
 	  if (map & 0x1000L)
 	    {
 	    /* Instruction memory */
 	      physical = (0x11L << 24) | off;
 	    }
 	  else
 	    {
 	    /* Unified memory */
 	      physical = ((map & 0x7fL) << 17) + (off & 0x1ffffL);
 	      if (physical > 0xffffffL)
 		/* Address outside of unified address segment */
 		exit (-1);
 	      physical |= (0x12L << 24);
 	    }
 	  break;
 	}
       case 0x10:
       case 0x11:
       case 0x12:
 	physical = logical;
 	break;
       default:
 	exit (-1);	/* error */
       }

   seg = (physical >> 24);
   off = (physical & 0xffffffL);
   switch (seg)
     {
     case 0x10:	/* dst is a 15 bit offset into the on-chip memory */
       *dmap = 0;
       *addr = (long *) (0x0000 + ((short)off & 0x7fff));
       break;
     case 0x11:	/* dst is an 18-bit offset into the on-chip
 		   instruction memory */
       *dmap = 0x1000L | ((off & 0x3ffffL) >> 14);
       *addr = (long *) (0x8000 + ((short)off & 0x3fff));
       break;
     case 0x12:	/* dst is a 24-bit offset into unified memory */
       *dmap = off >> 14;
       *addr = (long *) (0x8000 + ((short)off & 0x3fff));
       break;
     default:
       exit (-1);	/* error */
     }
 }
 #endif /* __D10V__ */

 static void
 ovly_copy (unsigned long dst, unsigned long src, long size)
 {
 #ifdef  __M32R__
   memcpy ((void *) dst, (void *) src, size);
   return;
 #endif /* M32R */

 #ifdef  __D10V__
   unsigned long *s, *d, tmp;
   short dmap_src, dmap_dst;
   short dmap_save;

   /* all section sizes should by multiples of 4 bytes */
   dmap_save = DMAP;

   D10VTranslate (src, &dmap_src, &s);
   D10VTranslate (dst, &dmap_dst, &d);

   while (size > 0)
     {
       /* NB: Transfer 4 byte (long) quantites, problems occure
 	 when only two bytes are transfered */
       DMAP = dmap_src;
       tmp = *s;
       DMAP = dmap_dst;
       *d = tmp;
       d++;
       s++;
       size -= sizeof (tmp);
       src += sizeof (tmp);
       dst += sizeof (tmp);
       if ((src & 0x3fff) == 0)
 	D10VTranslate (src, &dmap_src, &s);
       if ((dst & 0x3fff) == 0)
 	D10VTranslate (dst, &dmap_dst, &d);
     }
   DMAP = dmap_save;
 #endif /* D10V */
 }

	/*
	* Ovlymgr.c -- Runtime Overlay Manager for the GDB testsuite.
	*/

	#include "ovlymgr.h"

	/* Local functions and data: */

	extern unsigned long _ovly_table[][4];
	extern unsigned long _novlys __attribute__ ((section (".data")));
	enum ovly_index { VMA, SIZE, LMA, MAPPED};

	static void ovly_copy (unsigned long dst, unsigned long src, long size);

	/* Flush the data and instruction caches at address START for SIZE bytes.
	Support for each new port must be added here. */
	/* FIXME: Might be better to have a standard libgloss function that
	ports provide that we can then use. Use libgloss instead of newlib
	since libgloss is the one intended to handle low level system issues.
	I would suggest something like _flush_cache to avoid the user's namespace
	but not be completely obscure as other things may need this facility. */

	static void
	FlushCache (void)
	{
	#ifdef __M32R__
	volatile char mspr = (char ) 0xfffffff7;
	*mspr = 1;
	#endif
	}

	/* OverlayLoad:
	* Copy the overlay into its runtime region,
	* and mark the overlay as "mapped".
	*/

	bool
	OverlayLoad (unsigned long ovlyno)
	{
	unsigned long i;

	if (ovlyno < 0 \|\| ovlyno >= _novlys)
	exit (-1); /* fail, bad ovly number */

	if (_ovly_table[ovlyno][MAPPED])
	return TRUE; /* this overlay already mapped -- nothing to do! */

	for (i = 0; i < _novlys; i++)
	if (i == ovlyno)
	_ovly_table[i][MAPPED] = 1; /* this one now mapped */
	else if (_ovly_table[i][VMA] == _ovly_table[ovlyno][VMA])
	_ovly_table[i][MAPPED] = 0; /* this one now un-mapped */

	ovly_copy (_ovly_table[ovlyno][VMA],
	_ovly_table[ovlyno][LMA],
	_ovly_table[ovlyno][SIZE]);

	FlushCache ();

	return TRUE;
	}

	/* OverlayUnload:
	* Copy the overlay back into its "load" region.
	* Does NOT mark overlay as "unmapped", therefore may be called
	* more than once for the same mapped overlay.
	*/

	bool
	OverlayUnload (unsigned long ovlyno)
	{
	if (ovlyno < 0 \|\| ovlyno >= _novlys)
	exit (-1); /* fail, bad ovly number */

	if (!_ovly_table[ovlyno][MAPPED])
	exit (-1); /* error, can't copy out a segment that's not "in" */

	ovly_copy (_ovly_table[ovlyno][LMA],
	_ovly_table[ovlyno][VMA],
	_ovly_table[ovlyno][SIZE]);

	return TRUE;
	}

	#ifdef __D10V__
	#define IMAP0 ((short )(0xff00))
	#define IMAP1 ((short )(0xff02))
	#define DMAP ((short )(0xff04))

	static void
	D10VTranslate (unsigned long logical,
	short *dmap,
	unsigned long **addr)
	{
	unsigned long physical;
	unsigned long seg;
	unsigned long off;

	/* to access data, we use the following mapping
	0x00xxxxxx: Logical data address segment (DMAP translated memory)
	0x01xxxxxx: Logical instruction address segment (IMAP translated memory)
	0x10xxxxxx: Physical data memory segment (On-chip data memory)
	0x11xxxxxx: Physical instruction memory segment (On-chip insn memory)
	0x12xxxxxx: Phisical unified memory segment (Unified memory)
	*/

	/* Addresses must be correctly aligned */
	if (logical & (sizeof (**addr) - 1))
	exit (-1);

	/* If the address is in one of the two logical address spaces, it is
	first translated into a physical address */
	seg = (logical >> 24);
	off = (logical & 0xffffffL);
	switch (seg)
	{
	case 0x00: /* in logical data address segment */
	if (off <= 0x7fffL)
	physical = (0x10L << 24) + off;
	else
	/* Logical address out side of on-chip segment, not
	supported */
	exit (-1);
	break;
	case 0x01: /* in logical instruction address segment */
	{
	short map;
	if (off <= 0x1ffffL)
	map = IMAP0;
	else if (off <= 0x3ffffL)
	map = IMAP1;
	else
	/* Logical address outside of IMAP[01] segment, not
	supported */
	exit (-1);
	if (map & 0x1000L)
	{
	/* Instruction memory */
	physical = (0x11L << 24) \| off;
	}
	else
	{
	/* Unified memory */
	physical = ((map & 0x7fL) << 17) + (off & 0x1ffffL);
	if (physical > 0xffffffL)
	/* Address outside of unified address segment */
	exit (-1);
	physical \|= (0x12L << 24);
	}
	break;
	}
	case 0x10:
	case 0x11:
	case 0x12:
	physical = logical;
	break;
	default:
	exit (-1); /* error */
	}

	seg = (physical >> 24);
	off = (physical & 0xffffffL);
	switch (seg)
	{
	case 0x10: /* dst is a 15 bit offset into the on-chip memory */
	*dmap = 0;
	addr = (long ) (0x0000 + ((short)off & 0x7fff));
	break;
	case 0x11: /* dst is an 18-bit offset into the on-chip
	instruction memory */
	*dmap = 0x1000L \| ((off & 0x3ffffL) >> 14);
	addr = (long ) (0x8000 + ((short)off & 0x3fff));
	break;
	case 0x12: /* dst is a 24-bit offset into unified memory */
	*dmap = off >> 14;
	addr = (long ) (0x8000 + ((short)off & 0x3fff));
	break;
	default:
	exit (-1); /* error */
	}
	}
	#endif /* __D10V__ */

	static void
	ovly_copy (unsigned long dst, unsigned long src, long size)
	{
	#ifdef __M32R__
	memcpy ((void ) dst, (void ) src, size);
	return;
	#endif /* M32R */

	#ifdef __D10V__
	unsigned long s, d, tmp;
	short dmap_src, dmap_dst;
	short dmap_save;

	/* all section sizes should by multiples of 4 bytes */
	dmap_save = DMAP;

	D10VTranslate (src, &dmap_src, &s);
	D10VTranslate (dst, &dmap_dst, &d);

	while (size > 0)
	{
	/* NB: Transfer 4 byte (long) quantites, problems occure
	when only two bytes are transfered */
	DMAP = dmap_src;
	tmp = *s;
	DMAP = dmap_dst;
	*d = tmp;
	d++;
	s++;
	size -= sizeof (tmp);
	src += sizeof (tmp);
	dst += sizeof (tmp);
	if ((src & 0x3fff) == 0)
	D10VTranslate (src, &dmap_src, &s);
	if ((dst & 0x3fff) == 0)
	D10VTranslate (dst, &dmap_dst, &d);
	}
	DMAP = dmap_save;
	#endif /* D10V */
	}