sim/common/sim-core.c - binutils-gdb - Git at Google

 /* The common simulator framework for GDB, the GNU Debugger.

    Copyright 2002 Free Software Foundation, Inc.

    Contributed by Andrew Cagney and Red Hat.

    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., 59 Temple Place - Suite 330,
    Boston, MA 02111-1307, USA.  */


 #ifndef SIM_CORE_C
 #define SIM_CORE_C

 #include "sim-main.h"
 #include "sim-assert.h"

 #if (WITH_HW)
 #include "sim-hw.h"
 #endif

 /* "core" module install handler.

    This is called via sim_module_install to install the "core"
    subsystem into the simulator.  */

 #if EXTERN_SIM_CORE_P
 static MODULE_INIT_FN sim_core_init;
 static MODULE_UNINSTALL_FN sim_core_uninstall;
 #endif

 #if EXTERN_SIM_CORE_P
 SIM_RC
 sim_core_install (SIM_DESC sd)
 {
   SIM_ASSERT (STATE_MAGIC (sd) == SIM_MAGIC_NUMBER);

   /* establish the other handlers */
   sim_module_add_uninstall_fn (sd, sim_core_uninstall);
   sim_module_add_init_fn (sd, sim_core_init);

   /* establish any initial data structures - none */
   return SIM_RC_OK;
 }
 #endif


 /* Uninstall the "core" subsystem from the simulator.  */

 #if EXTERN_SIM_CORE_P
 static void
 sim_core_uninstall (SIM_DESC sd)
 {
   sim_core *core = STATE_CORE(sd);
   unsigned map;
   /* blow away any mappings */
   for (map = 0; map < nr_maps; map++) {
     sim_core_mapping *curr = core->common.map[map].first;
     while (curr != NULL) {
       sim_core_mapping *tbd = curr;
       curr = curr->next;
       if (tbd->free_buffer != NULL) {
 	SIM_ASSERT(tbd->buffer != NULL);
 	zfree(tbd->free_buffer);
       }
       zfree(tbd);
     }
     core->common.map[map].first = NULL;
   }
 }
 #endif


 #if EXTERN_SIM_CORE_P
 static SIM_RC
 sim_core_init (SIM_DESC sd)
 {
   /* Nothing to do */
   return SIM_RC_OK;
 }
 #endif


 #ifndef SIM_CORE_SIGNAL
 #define SIM_CORE_SIGNAL(SD,CPU,CIA,MAP,NR_BYTES,ADDR,TRANSFER,ERROR) \
 sim_core_signal ((SD), (CPU), (CIA), (MAP), (NR_BYTES), (ADDR), (TRANSFER), (ERROR))
 #endif

 #if EXTERN_SIM_CORE_P
 void
 sim_core_signal (SIM_DESC sd,
 		 sim_cpu *cpu,
 		 sim_cia cia,
 		 unsigned map,
 		 int nr_bytes,
 		 address_word addr,
 		 transfer_type transfer,
 		 sim_core_signals sig)
 {
   const char *copy = (transfer == read_transfer ? "read" : "write");
   address_word ip = CIA_ADDR (cia);
   switch (sig)
     {
     case sim_core_unmapped_signal:
       sim_io_eprintf (sd, "core: %d byte %s to unmapped address 0x%lx at 0x%lx\n",
 		      nr_bytes, copy, (unsigned long) addr, (unsigned long) ip);
       sim_engine_halt (sd, cpu, NULL, cia, sim_stopped, SIM_SIGSEGV);
       break;
     case sim_core_unaligned_signal:
       sim_io_eprintf (sd, "core: %d byte misaligned %s to address 0x%lx at 0x%lx\n",
 		      nr_bytes, copy, (unsigned long) addr, (unsigned long) ip);
       sim_engine_halt (sd, cpu, NULL, cia, sim_stopped, SIM_SIGBUS);
       break;
     default:
       sim_engine_abort (sd, cpu, cia,
 			"sim_core_signal - internal error - bad switch");
     }
 }
 #endif


 #if EXTERN_SIM_CORE_P
 static sim_core_mapping *
 new_sim_core_mapping (SIM_DESC sd,
 		      int level,
 		      int space,
 		      address_word addr,
 		      address_word nr_bytes,
 		      unsigned modulo,
 #if WITH_HW
 		      struct hw *device,
 #else
 		      device *device,
 #endif
 		      void *buffer,
 		      void *free_buffer)
 {
   sim_core_mapping *new_mapping = ZALLOC(sim_core_mapping);
   /* common */
   new_mapping->level = level;
   new_mapping->space = space;
   new_mapping->base = addr;
   new_mapping->nr_bytes = nr_bytes;
   new_mapping->bound = addr + (nr_bytes - 1);
   if (modulo == 0)
     new_mapping->mask = (unsigned) 0 - 1;
   else
     new_mapping->mask = modulo - 1;
   new_mapping->buffer = buffer;
   new_mapping->free_buffer = free_buffer;
   new_mapping->device = device;
   return new_mapping;
 }
 #endif


 #if EXTERN_SIM_CORE_P
 static void
 sim_core_map_attach (SIM_DESC sd,
 		     sim_core_map *access_map,
 		     int level,
 		     int space,
 		     address_word addr,
 		     address_word nr_bytes,
 		     unsigned modulo,
 #if WITH_HW
 		     struct hw *client, /*callback/default*/
 #else
 		     device *client, /*callback/default*/
 #endif
 		     void *buffer, /*raw_memory*/
 		     void *free_buffer) /*raw_memory*/
 {
   /* find the insertion point for this additional mapping and then
      insert */
   sim_core_mapping *next_mapping;
   sim_core_mapping **last_mapping;

   SIM_ASSERT ((client == NULL) != (buffer == NULL));
   SIM_ASSERT ((client == NULL) >= (free_buffer != NULL));

   /* actually do occasionally get a zero size map */
   if (nr_bytes == 0)
     {
 #if (WITH_DEVICES)
       device_error(client, "called on sim_core_map_attach with size zero");
 #endif
 #if (WITH_HW)
       sim_hw_abort (sd, client, "called on sim_core_map_attach with size zero");
 #endif
       sim_io_error (sd, "called on sim_core_map_attach with size zero");
     }

   /* find the insertion point (between last/next) */
   next_mapping = access_map->first;
   last_mapping = &access_map->first;
   while(next_mapping != NULL
 	&& (next_mapping->level < level
 	    || (next_mapping->level == level
 		&& next_mapping->bound < addr)))
     {
       /* provided levels are the same */
       /* assert: next_mapping->base > all bases before next_mapping */
       /* assert: next_mapping->bound >= all bounds before next_mapping */
       last_mapping = &next_mapping->next;
       next_mapping = next_mapping->next;
     }

   /* check insertion point correct */
   SIM_ASSERT (next_mapping == NULL || next_mapping->level >= level);
   if (next_mapping != NULL && next_mapping->level == level
       && next_mapping->base < (addr + (nr_bytes - 1)))
     {
 #if (WITH_DEVICES)
       device_error (client, "memory map %d:0x%lx..0x%lx (%ld bytes) overlaps %d:0x%lx..0x%lx (%ld bytes)",
 		    space,
 		    (long) addr,
 		    (long) (addr + nr_bytes - 1),
 		    (long) nr_bytes,
 		    next_mapping->space,
 		    (long) next_mapping->base,
 		    (long) next_mapping->bound,
 		    (long) next_mapping->nr_bytes);
 #endif
 #if WITH_HW
       sim_hw_abort (sd, client, "memory map %d:0x%lx..0x%lx (%ld bytes) overlaps %d:0x%lx..0x%lx (%ld bytes)",
 		    space,
 		    (long) addr,
 		    (long) (addr + (nr_bytes - 1)),
 		    (long) nr_bytes,
 		    next_mapping->space,
 		    (long) next_mapping->base,
 		    (long) next_mapping->bound,
 		    (long) next_mapping->nr_bytes);
 #endif
       sim_io_error (sd, "memory map %d:0x%lx..0x%lx (%ld bytes) overlaps %d:0x%lx..0x%lx (%ld bytes)",
 		    space,
 		    (long) addr,
 		    (long) (addr + (nr_bytes - 1)),
 		    (long) nr_bytes,
 		    next_mapping->space,
 		    (long) next_mapping->base,
 		    (long) next_mapping->bound,
 		    (long) next_mapping->nr_bytes);
   }

   /* create/insert the new mapping */
   *last_mapping = new_sim_core_mapping(sd,
 				       level,
 				       space, addr, nr_bytes, modulo,
 				       client, buffer, free_buffer);
   (*last_mapping)->next = next_mapping;
 }
 #endif


 /* Attach memory or a memory mapped device to the simulator.
    See sim-core.h for a full description.  */

 #if EXTERN_SIM_CORE_P
 void
 sim_core_attach (SIM_DESC sd,
 		 sim_cpu *cpu,
 		 int level,
 		 unsigned mapmask,
 		 int space,
 		 address_word addr,
 		 address_word nr_bytes,
 		 unsigned modulo,
 #if WITH_HW
 		 struct hw *client,
 #else
 		 device *client,
 #endif
 		 void *optional_buffer)
 {
   sim_core *memory = STATE_CORE(sd);
   unsigned map;
   void *buffer;
   void *free_buffer;

   /* check for for attempt to use unimplemented per-processor core map */
   if (cpu != NULL)
     sim_io_error (sd, "sim_core_map_attach - processor specific memory map not yet supported");

   /* verify modulo memory */
   if (!WITH_MODULO_MEMORY && modulo != 0)
     {
 #if (WITH_DEVICES)
       device_error (client, "sim_core_attach - internal error - modulo memory disabled");
 #endif
 #if (WITH_HW)
       sim_hw_abort (sd, client, "sim_core_attach - internal error - modulo memory disabled");
 #endif
       sim_io_error (sd, "sim_core_attach - internal error - modulo memory disabled");
     }
   if (client != NULL && modulo != 0)
     {
 #if (WITH_DEVICES)
       device_error (client, "sim_core_attach - internal error - modulo and callback memory conflict");
 #endif
 #if (WITH_HW)
       sim_hw_abort (sd, client, "sim_core_attach - internal error - modulo and callback memory conflict");
 #endif
       sim_io_error (sd, "sim_core_attach - internal error - modulo and callback memory conflict");
     }
   if (modulo != 0)
     {
       unsigned mask = modulo - 1;
       /* any zero bits */
       while (mask >= sizeof (unsigned64)) /* minimum modulo */
 	{
 	  if ((mask & 1) == 0)
 	    mask = 0;
 	  else
 	    mask >>= 1;
 	}
       if (mask != sizeof (unsigned64) - 1)
 	{
 #if (WITH_DEVICES)
 	  device_error (client, "sim_core_attach - internal error - modulo %lx not power of two", (long) modulo);
 #endif
 #if (WITH_HW)
 	  sim_hw_abort (sd, client, "sim_core_attach - internal error - modulo %lx not power of two", (long) modulo);
 #endif
 	  sim_io_error (sd, "sim_core_attach - internal error - modulo %lx not power of two", (long) modulo);
 	}
     }

   /* verify consistency between device and buffer */
   if (client != NULL && optional_buffer != NULL)
     {
 #if (WITH_DEVICES)
       device_error (client, "sim_core_attach - internal error - conflicting buffer and attach arguments");
 #endif
 #if (WITH_HW)
       sim_hw_abort (sd, client, "sim_core_attach - internal error - conflicting buffer and attach arguments");
 #endif
       sim_io_error (sd, "sim_core_attach - internal error - conflicting buffer and attach arguments");
     }
   if (client == NULL)
     {
       if (optional_buffer == NULL)
 	{
 	  int padding = (addr % sizeof (unsigned64));
 	  unsigned long bytes = (modulo == 0 ? nr_bytes : modulo) + padding;
 	  free_buffer = zalloc (bytes);
 	  buffer = (char*) free_buffer + padding;
 	}
       else
 	{
 	  buffer = optional_buffer;
 	  free_buffer = NULL;
 	}
     }
   else
     {
       /* a device */
       buffer = NULL;
       free_buffer = NULL;
     }

   /* attach the region to all applicable access maps */
   for (map = 0;
        map < nr_maps;
        map++)
     {
       if (mapmask & (1 << map))
 	{
 	  sim_core_map_attach (sd, &memory->common.map[map],
 			       level, space, addr, nr_bytes, modulo,
 			       client, buffer, free_buffer);
 	  free_buffer = NULL;
 	}
     }

   /* Just copy this map to each of the processor specific data structures.
      FIXME - later this will be replaced by true processor specific
      maps. */
   {
     int i;
     for (i = 0; i < MAX_NR_PROCESSORS; i++)
       {
 	CPU_CORE (STATE_CPU (sd, i))->common = STATE_CORE (sd)->common;
       }
   }
 }
 #endif


 /* Remove any memory reference related to this address */
 #if EXTERN_SIM_CORE_P
 static void
 sim_core_map_detach (SIM_DESC sd,
 		     sim_core_map *access_map,
 		     int level,
 		     int space,
 		     address_word addr)
 {
   sim_core_mapping **entry;
   for (entry = &access_map->first;
        (*entry) != NULL;
        entry = &(*entry)->next)
     {
       if ((*entry)->base == addr
 	  && (*entry)->level == level
 	  && (*entry)->space == space)
 	{
 	  sim_core_mapping *dead = (*entry);
 	  (*entry) = dead->next;
 	  if (dead->free_buffer != NULL)
 	    zfree (dead->free_buffer);
 	  zfree (dead);
 	  return;
 	}
     }
 }
 #endif

 #if EXTERN_SIM_CORE_P
 void
 sim_core_detach (SIM_DESC sd,
 		 sim_cpu *cpu,
 		 int level,
 		 int address_space,
 		 address_word addr)
 {
   sim_core *memory = STATE_CORE (sd);
   unsigned map;
   for (map = 0; map < nr_maps; map++)
     {
       sim_core_map_detach (sd, &memory->common.map[map],
 			   level, address_space, addr);
     }
   /* Just copy this update to each of the processor specific data
      structures.  FIXME - later this will be replaced by true
      processor specific maps. */
   {
     int i;
     for (i = 0; i < MAX_NR_PROCESSORS; i++)
       {
 	CPU_CORE (STATE_CPU (sd, i))->common = STATE_CORE (sd)->common;
       }
   }
 }
 #endif


 STATIC_INLINE_SIM_CORE\
 (sim_core_mapping *)
 sim_core_find_mapping(sim_core_common *core,
 		      unsigned map,
 		      address_word addr,
 		      unsigned nr_bytes,
 		      transfer_type transfer,
 		      int abort, /*either 0 or 1 - hint to inline/-O */
 		      sim_cpu *cpu, /* abort => cpu != NULL */
 		      sim_cia cia)
 {
   sim_core_mapping *mapping = core->map[map].first;
   ASSERT ((addr & (nr_bytes - 1)) == 0); /* must be aligned */
   ASSERT ((addr + (nr_bytes - 1)) >= addr); /* must not wrap */
   ASSERT (!abort || cpu != NULL); /* abort needs a non null CPU */
   while (mapping != NULL)
     {
       if (addr >= mapping->base
 	  && (addr + (nr_bytes - 1)) <= mapping->bound)
 	return mapping;
       mapping = mapping->next;
     }
   if (abort)
     {
       SIM_CORE_SIGNAL (CPU_STATE (cpu), cpu, cia, map, nr_bytes, addr, transfer,
 		       sim_core_unmapped_signal);
     }
   return NULL;
 }


 STATIC_INLINE_SIM_CORE\
 (void *)
 sim_core_translate (sim_core_mapping *mapping,
 		    address_word addr)
 {
   if (WITH_MODULO_MEMORY)
     return (void *)((unsigned8 *) mapping->buffer
 		    + ((addr - mapping->base) & mapping->mask));
   else
     return (void *)((unsigned8 *) mapping->buffer
 		    + addr - mapping->base);
 }


 #if EXTERN_SIM_CORE_P
 unsigned
 sim_core_read_buffer (SIM_DESC sd,
 		      sim_cpu *cpu,
 		      unsigned map,
 		      void *buffer,
 		      address_word addr,
 		      unsigned len)
 {
   sim_core_common *core = (cpu == NULL ? &STATE_CORE (sd)->common : &CPU_CORE (cpu)->common);
   unsigned count = 0;
   while (count < len)
  {
     unsigned_word raddr = addr + count;
     sim_core_mapping *mapping =
       sim_core_find_mapping (core, map,
 			    raddr, /*nr-bytes*/1,
 			    read_transfer,
 			    0 /*dont-abort*/, NULL, NULL_CIA);
     if (mapping == NULL)
       break;
 #if (WITH_DEVICES)
     if (mapping->device != NULL)
       {
 	int nr_bytes = len - count;
 	sim_cia cia = cpu ? CIA_GET (cpu) : NULL_CIA;
 	if (raddr + nr_bytes - 1> mapping->bound)
 	  nr_bytes = mapping->bound - raddr + 1;
 	if (device_io_read_buffer (mapping->device,
 				   (unsigned_1*)buffer + count,
 				   mapping->space,
 				   raddr,
 				   nr_bytes,
 				   sd,
 				   cpu,
 				   cia) != nr_bytes)
 	  break;
 	count += nr_bytes;
 	continue;
       }
 #endif
 #if (WITH_HW)
     if (mapping->device != NULL)
       {
 	int nr_bytes = len - count;
 	if (raddr + nr_bytes - 1> mapping->bound)
 	  nr_bytes = mapping->bound - raddr + 1;
 	if (sim_hw_io_read_buffer (sd, mapping->device,
 				   (unsigned_1*)buffer + count,
 				   mapping->space,
 				   raddr,
 				   nr_bytes) != nr_bytes)
 	  break;
 	count += nr_bytes;
 	continue;
       }
 #endif
     ((unsigned_1*)buffer)[count] =
       *(unsigned_1*)sim_core_translate(mapping, raddr);
     count += 1;
  }
   return count;
 }
 #endif


 #if EXTERN_SIM_CORE_P
 unsigned
 sim_core_write_buffer (SIM_DESC sd,
 		       sim_cpu *cpu,
 		       unsigned map,
 		       const void *buffer,
 		       address_word addr,
 		       unsigned len)
 {
   sim_core_common *core = (cpu == NULL ? &STATE_CORE (sd)->common : &CPU_CORE (cpu)->common);
   unsigned count = 0;
   while (count < len)
     {
       unsigned_word raddr = addr + count;
       sim_core_mapping *mapping =
 	sim_core_find_mapping (core, map,
 			       raddr, /*nr-bytes*/1,
 			       write_transfer,
 			       0 /*dont-abort*/, NULL, NULL_CIA);
       if (mapping == NULL)
 	break;
 #if (WITH_DEVICES)
       if (WITH_CALLBACK_MEMORY
 	  && mapping->device != NULL)
 	{
 	  int nr_bytes = len - count;
 	  sim_cia cia = cpu ? CIA_GET (cpu) : NULL_CIA;
 	  if (raddr + nr_bytes - 1 > mapping->bound)
 	    nr_bytes = mapping->bound - raddr + 1;
 	  if (device_io_write_buffer (mapping->device,
 				      (unsigned_1*)buffer + count,
 				      mapping->space,
 				      raddr,
 				      nr_bytes,
 				      sd,
 				      cpu,
 				      cia) != nr_bytes)
 	    break;
 	  count += nr_bytes;
 	  continue;
 	}
 #endif
 #if (WITH_HW)
       if (WITH_CALLBACK_MEMORY
 	  && mapping->device != NULL)
 	{
 	  int nr_bytes = len - count;
 	  if (raddr + nr_bytes - 1 > mapping->bound)
 	    nr_bytes = mapping->bound - raddr + 1;
 	  if (sim_hw_io_write_buffer (sd, mapping->device,
 				      (unsigned_1*)buffer + count,
 				      mapping->space,
 				      raddr,
 				      nr_bytes) != nr_bytes)
 	    break;
 	  count += nr_bytes;
 	  continue;
 	}
 #endif
       *(unsigned_1*)sim_core_translate(mapping, raddr) =
 	((unsigned_1*)buffer)[count];
       count += 1;
     }
   return count;
 }
 #endif


 #if EXTERN_SIM_CORE_P
 void
 sim_core_set_xor (SIM_DESC sd,
 		  sim_cpu *cpu,
 		  int is_xor)
 {
   /* set up the XOR map if required. */
   if (WITH_XOR_ENDIAN) {
     {
       sim_core *core = STATE_CORE (sd);
       sim_cpu_core *cpu_core = (cpu != NULL ? CPU_CORE (cpu) : NULL);
       if (cpu_core != NULL)
 	{
 	  int i = 1;
 	  unsigned mask;
 	  if (is_xor)
 	    mask = WITH_XOR_ENDIAN - 1;
 	  else
 	    mask = 0;
 	  while (i - 1 < WITH_XOR_ENDIAN)
 	    {
 	      cpu_core->xor[i-1] = mask;
 	      mask = (mask << 1) & (WITH_XOR_ENDIAN - 1);
 	      i = (i << 1);
 	    }
 	}
       else
 	{
 	  if (is_xor)
 	    core->byte_xor = WITH_XOR_ENDIAN - 1;
 	  else
 	    core->byte_xor = 0;
 	}
     }
   }
   else {
     if (is_xor)
       sim_engine_abort (sd, NULL, NULL_CIA,
 			"Attempted to enable xor-endian mode when permenantly disabled.");
   }
 }
 #endif


 #if EXTERN_SIM_CORE_P
 static void
 reverse_n (unsigned_1 *dest,
 	   const unsigned_1 *src,
 	   int nr_bytes)
 {
   int i;
   for (i = 0; i < nr_bytes; i++)
     {
       dest [nr_bytes - i - 1] = src [i];
     }
 }
 #endif


 #if EXTERN_SIM_CORE_P
 unsigned
 sim_core_xor_read_buffer (SIM_DESC sd,
 			  sim_cpu *cpu,
 			  unsigned map,
 			  void *buffer,
 			  address_word addr,
 			  unsigned nr_bytes)
 {
   address_word byte_xor = (cpu == NULL ? STATE_CORE (sd)->byte_xor : CPU_CORE (cpu)->xor[0]);
   if (!WITH_XOR_ENDIAN || !byte_xor)
     return sim_core_read_buffer (sd, cpu, map, buffer, addr, nr_bytes);
   else
     /* only break up transfers when xor-endian is both selected and enabled */
     {
       unsigned_1 x[WITH_XOR_ENDIAN + 1]; /* +1 to avoid zero-sized array */
       unsigned nr_transfered = 0;
       address_word start = addr;
       unsigned nr_this_transfer = (WITH_XOR_ENDIAN - (addr & ~(WITH_XOR_ENDIAN - 1)));
       address_word stop;
       /* initial and intermediate transfers are broken when they cross
          an XOR endian boundary */
       while (nr_transfered + nr_this_transfer < nr_bytes)
 	/* initial/intermediate transfers */
 	{
 	  /* since xor-endian is enabled stop^xor defines the start
              address of the transfer */
 	  stop = start + nr_this_transfer - 1;
 	  SIM_ASSERT (start <= stop);
 	  SIM_ASSERT ((stop ^ byte_xor) <= (start ^ byte_xor));
 	  if (sim_core_read_buffer (sd, cpu, map, x, stop ^ byte_xor, nr_this_transfer)
 	      != nr_this_transfer)
 	    return nr_transfered;
 	  reverse_n (&((unsigned_1*)buffer)[nr_transfered], x, nr_this_transfer);
 	  nr_transfered += nr_this_transfer;
 	  nr_this_transfer = WITH_XOR_ENDIAN;
 	  start = stop + 1;
 	}
       /* final transfer */
       nr_this_transfer = nr_bytes - nr_transfered;
       stop = start + nr_this_transfer - 1;
       SIM_ASSERT (stop == (addr + nr_bytes - 1));
       if (sim_core_read_buffer (sd, cpu, map, x, stop ^ byte_xor, nr_this_transfer)
 	  != nr_this_transfer)
 	return nr_transfered;
       reverse_n (&((unsigned_1*)buffer)[nr_transfered], x, nr_this_transfer);
       return nr_bytes;
     }
 }
 #endif


 #if EXTERN_SIM_CORE_P
 unsigned
 sim_core_xor_write_buffer (SIM_DESC sd,
 			   sim_cpu *cpu,
 			   unsigned map,
 			   const void *buffer,
 			   address_word addr,
 			   unsigned nr_bytes)
 {
   address_word byte_xor = (cpu == NULL ? STATE_CORE (sd)->byte_xor : CPU_CORE (cpu)->xor[0]);
   if (!WITH_XOR_ENDIAN || !byte_xor)
     return sim_core_write_buffer (sd, cpu, map, buffer, addr, nr_bytes);
   else
     /* only break up transfers when xor-endian is both selected and enabled */
     {
       unsigned_1 x[WITH_XOR_ENDIAN + 1]; /* +1 to avoid zero sized array */
       unsigned nr_transfered = 0;
       address_word start = addr;
       unsigned nr_this_transfer = (WITH_XOR_ENDIAN - (addr & ~(WITH_XOR_ENDIAN - 1)));
       address_word stop;
       /* initial and intermediate transfers are broken when they cross
          an XOR endian boundary */
       while (nr_transfered + nr_this_transfer < nr_bytes)
 	/* initial/intermediate transfers */
 	{
 	  /* since xor-endian is enabled stop^xor defines the start
              address of the transfer */
 	  stop = start + nr_this_transfer - 1;
 	  SIM_ASSERT (start <= stop);
 	  SIM_ASSERT ((stop ^ byte_xor) <= (start ^ byte_xor));
 	  reverse_n (x, &((unsigned_1*)buffer)[nr_transfered], nr_this_transfer);
 	  if (sim_core_read_buffer (sd, cpu, map, x, stop ^ byte_xor, nr_this_transfer)
 	      != nr_this_transfer)
 	    return nr_transfered;
 	  nr_transfered += nr_this_transfer;
 	  nr_this_transfer = WITH_XOR_ENDIAN;
 	  start = stop + 1;
 	}
       /* final transfer */
       nr_this_transfer = nr_bytes - nr_transfered;
       stop = start + nr_this_transfer - 1;
       SIM_ASSERT (stop == (addr + nr_bytes - 1));
       reverse_n (x, &((unsigned_1*)buffer)[nr_transfered], nr_this_transfer);
       if (sim_core_read_buffer (sd, cpu, map, x, stop ^ byte_xor, nr_this_transfer)
 	  != nr_this_transfer)
 	return nr_transfered;
       return nr_bytes;
     }
 }
 #endif


 /* define the read/write 1/2/4/8/16/word functions */

 #define N 16
 #include "sim-n-core.h"

 #define N 8
 #include "sim-n-core.h"

 #define N 7
 #define M 8
 #include "sim-n-core.h"

 #define N 6
 #define M 8
 #include "sim-n-core.h"

 #define N 5
 #define M 8
 #include "sim-n-core.h"

 #define N 4
 #include "sim-n-core.h"

 #define N 3
 #define M 4
 #include "sim-n-core.h"

 #define N 2
 #include "sim-n-core.h"

 #define N 1
 #include "sim-n-core.h"

 #endif
	/* The common simulator framework for GDB, the GNU Debugger.

	Copyright 2002 Free Software Foundation, Inc.

	Contributed by Andrew Cagney and Red Hat.

	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., 59 Temple Place - Suite 330,
	Boston, MA 02111-1307, USA. */


	#ifndef SIM_CORE_C
	#define SIM_CORE_C

	#include "sim-main.h"
	#include "sim-assert.h"

	#if (WITH_HW)
	#include "sim-hw.h"
	#endif

	/* "core" module install handler.

	This is called via sim_module_install to install the "core"
	subsystem into the simulator. */

	#if EXTERN_SIM_CORE_P
	static MODULE_INIT_FN sim_core_init;
	static MODULE_UNINSTALL_FN sim_core_uninstall;
	#endif

	#if EXTERN_SIM_CORE_P
	SIM_RC
	sim_core_install (SIM_DESC sd)
	{
	SIM_ASSERT (STATE_MAGIC (sd) == SIM_MAGIC_NUMBER);

	/* establish the other handlers */
	sim_module_add_uninstall_fn (sd, sim_core_uninstall);
	sim_module_add_init_fn (sd, sim_core_init);

	/* establish any initial data structures - none */
	return SIM_RC_OK;
	}
	#endif


	/* Uninstall the "core" subsystem from the simulator. */

	#if EXTERN_SIM_CORE_P
	static void
	sim_core_uninstall (SIM_DESC sd)
	{
	sim_core *core = STATE_CORE(sd);
	unsigned map;
	/* blow away any mappings */
	for (map = 0; map < nr_maps; map++) {
	sim_core_mapping *curr = core->common.map[map].first;
	while (curr != NULL) {
	sim_core_mapping *tbd = curr;
	curr = curr->next;
	if (tbd->free_buffer != NULL) {
	SIM_ASSERT(tbd->buffer != NULL);
	zfree(tbd->free_buffer);
	}
	zfree(tbd);
	}
	core->common.map[map].first = NULL;
	}
	}
	#endif


	#if EXTERN_SIM_CORE_P
	static SIM_RC
	sim_core_init (SIM_DESC sd)
	{
	/* Nothing to do */
	return SIM_RC_OK;
	}
	#endif



	#ifndef SIM_CORE_SIGNAL
	#define SIM_CORE_SIGNAL(SD,CPU,CIA,MAP,NR_BYTES,ADDR,TRANSFER,ERROR) \
	sim_core_signal ((SD), (CPU), (CIA), (MAP), (NR_BYTES), (ADDR), (TRANSFER), (ERROR))
	#endif

	#if EXTERN_SIM_CORE_P
	void
	sim_core_signal (SIM_DESC sd,
	sim_cpu *cpu,
	sim_cia cia,
	unsigned map,
	int nr_bytes,
	address_word addr,
	transfer_type transfer,
	sim_core_signals sig)
	{
	const char *copy = (transfer == read_transfer ? "read" : "write");
	address_word ip = CIA_ADDR (cia);
	switch (sig)
	{
	case sim_core_unmapped_signal:
	sim_io_eprintf (sd, "core: %d byte %s to unmapped address 0x%lx at 0x%lx\n",
	nr_bytes, copy, (unsigned long) addr, (unsigned long) ip);
	sim_engine_halt (sd, cpu, NULL, cia, sim_stopped, SIM_SIGSEGV);
	break;
	case sim_core_unaligned_signal:
	sim_io_eprintf (sd, "core: %d byte misaligned %s to address 0x%lx at 0x%lx\n",
	nr_bytes, copy, (unsigned long) addr, (unsigned long) ip);
	sim_engine_halt (sd, cpu, NULL, cia, sim_stopped, SIM_SIGBUS);
	break;
	default:
	sim_engine_abort (sd, cpu, cia,
	"sim_core_signal - internal error - bad switch");
	}
	}
	#endif


	#if EXTERN_SIM_CORE_P
	static sim_core_mapping *
	new_sim_core_mapping (SIM_DESC sd,
	int level,
	int space,
	address_word addr,
	address_word nr_bytes,
	unsigned modulo,
	#if WITH_HW
	struct hw *device,
	#else
	device *device,
	#endif
	void *buffer,
	void *free_buffer)
	{
	sim_core_mapping *new_mapping = ZALLOC(sim_core_mapping);
	/* common */
	new_mapping->level = level;
	new_mapping->space = space;
	new_mapping->base = addr;
	new_mapping->nr_bytes = nr_bytes;
	new_mapping->bound = addr + (nr_bytes - 1);
	if (modulo == 0)
	new_mapping->mask = (unsigned) 0 - 1;
	else
	new_mapping->mask = modulo - 1;
	new_mapping->buffer = buffer;
	new_mapping->free_buffer = free_buffer;
	new_mapping->device = device;
	return new_mapping;
	}
	#endif


	#if EXTERN_SIM_CORE_P
	static void
	sim_core_map_attach (SIM_DESC sd,
	sim_core_map *access_map,
	int level,
	int space,
	address_word addr,
	address_word nr_bytes,
	unsigned modulo,
	#if WITH_HW
	struct hw client, /callback/default*/
	#else
	device client, /callback/default*/
	#endif
	void buffer, /raw_memory*/
	void free_buffer) /raw_memory*/
	{
	/* find the insertion point for this additional mapping and then
	insert */
	sim_core_mapping *next_mapping;
	sim_core_mapping **last_mapping;

	SIM_ASSERT ((client == NULL) != (buffer == NULL));
	SIM_ASSERT ((client == NULL) >= (free_buffer != NULL));

	/* actually do occasionally get a zero size map */
	if (nr_bytes == 0)
	{
	#if (WITH_DEVICES)
	device_error(client, "called on sim_core_map_attach with size zero");
	#endif
	#if (WITH_HW)
	sim_hw_abort (sd, client, "called on sim_core_map_attach with size zero");
	#endif
	sim_io_error (sd, "called on sim_core_map_attach with size zero");
	}

	/* find the insertion point (between last/next) */
	next_mapping = access_map->first;
	last_mapping = &access_map->first;
	while(next_mapping != NULL
	&& (next_mapping->level < level
	\|\| (next_mapping->level == level
	&& next_mapping->bound < addr)))
	{
	/* provided levels are the same */
	/* assert: next_mapping->base > all bases before next_mapping */
	/* assert: next_mapping->bound >= all bounds before next_mapping */
	last_mapping = &next_mapping->next;
	next_mapping = next_mapping->next;
	}

	/* check insertion point correct */
	SIM_ASSERT (next_mapping == NULL \|\| next_mapping->level >= level);
	if (next_mapping != NULL && next_mapping->level == level
	&& next_mapping->base < (addr + (nr_bytes - 1)))
	{
	#if (WITH_DEVICES)
	device_error (client, "memory map %d:0x%lx..0x%lx (%ld bytes) overlaps %d:0x%lx..0x%lx (%ld bytes)",
	space,
	(long) addr,
	(long) (addr + nr_bytes - 1),
	(long) nr_bytes,
	next_mapping->space,
	(long) next_mapping->base,
	(long) next_mapping->bound,
	(long) next_mapping->nr_bytes);
	#endif
	#if WITH_HW
	sim_hw_abort (sd, client, "memory map %d:0x%lx..0x%lx (%ld bytes) overlaps %d:0x%lx..0x%lx (%ld bytes)",
	space,
	(long) addr,
	(long) (addr + (nr_bytes - 1)),
	(long) nr_bytes,
	next_mapping->space,
	(long) next_mapping->base,
	(long) next_mapping->bound,
	(long) next_mapping->nr_bytes);
	#endif
	sim_io_error (sd, "memory map %d:0x%lx..0x%lx (%ld bytes) overlaps %d:0x%lx..0x%lx (%ld bytes)",
	space,
	(long) addr,
	(long) (addr + (nr_bytes - 1)),
	(long) nr_bytes,
	next_mapping->space,
	(long) next_mapping->base,
	(long) next_mapping->bound,
	(long) next_mapping->nr_bytes);
	}

	/* create/insert the new mapping */
	*last_mapping = new_sim_core_mapping(sd,
	level,
	space, addr, nr_bytes, modulo,
	client, buffer, free_buffer);
	(*last_mapping)->next = next_mapping;
	}
	#endif


	/* Attach memory or a memory mapped device to the simulator.
	See sim-core.h for a full description. */

	#if EXTERN_SIM_CORE_P
	void
	sim_core_attach (SIM_DESC sd,
	sim_cpu *cpu,
	int level,
	unsigned mapmask,
	int space,
	address_word addr,
	address_word nr_bytes,
	unsigned modulo,
	#if WITH_HW
	struct hw *client,
	#else
	device *client,
	#endif
	void *optional_buffer)
	{
	sim_core *memory = STATE_CORE(sd);
	unsigned map;
	void *buffer;
	void *free_buffer;

	/* check for for attempt to use unimplemented per-processor core map */
	if (cpu != NULL)
	sim_io_error (sd, "sim_core_map_attach - processor specific memory map not yet supported");

	/* verify modulo memory */
	if (!WITH_MODULO_MEMORY && modulo != 0)
	{
	#if (WITH_DEVICES)
	device_error (client, "sim_core_attach - internal error - modulo memory disabled");
	#endif
	#if (WITH_HW)
	sim_hw_abort (sd, client, "sim_core_attach - internal error - modulo memory disabled");
	#endif
	sim_io_error (sd, "sim_core_attach - internal error - modulo memory disabled");
	}
	if (client != NULL && modulo != 0)
	{
	#if (WITH_DEVICES)
	device_error (client, "sim_core_attach - internal error - modulo and callback memory conflict");
	#endif
	#if (WITH_HW)
	sim_hw_abort (sd, client, "sim_core_attach - internal error - modulo and callback memory conflict");
	#endif
	sim_io_error (sd, "sim_core_attach - internal error - modulo and callback memory conflict");
	}
	if (modulo != 0)
	{
	unsigned mask = modulo - 1;
	/* any zero bits */
	while (mask >= sizeof (unsigned64)) /* minimum modulo */
	{
	if ((mask & 1) == 0)
	mask = 0;
	else
	mask >>= 1;
	}
	if (mask != sizeof (unsigned64) - 1)
	{
	#if (WITH_DEVICES)
	device_error (client, "sim_core_attach - internal error - modulo %lx not power of two", (long) modulo);
	#endif
	#if (WITH_HW)
	sim_hw_abort (sd, client, "sim_core_attach - internal error - modulo %lx not power of two", (long) modulo);
	#endif
	sim_io_error (sd, "sim_core_attach - internal error - modulo %lx not power of two", (long) modulo);
	}
	}

	/* verify consistency between device and buffer */
	if (client != NULL && optional_buffer != NULL)
	{
	#if (WITH_DEVICES)
	device_error (client, "sim_core_attach - internal error - conflicting buffer and attach arguments");
	#endif
	#if (WITH_HW)
	sim_hw_abort (sd, client, "sim_core_attach - internal error - conflicting buffer and attach arguments");
	#endif
	sim_io_error (sd, "sim_core_attach - internal error - conflicting buffer and attach arguments");
	}
	if (client == NULL)
	{
	if (optional_buffer == NULL)
	{
	int padding = (addr % sizeof (unsigned64));
	unsigned long bytes = (modulo == 0 ? nr_bytes : modulo) + padding;
	free_buffer = zalloc (bytes);
	buffer = (char*) free_buffer + padding;
	}
	else
	{
	buffer = optional_buffer;
	free_buffer = NULL;
	}
	}
	else
	{
	/* a device */
	buffer = NULL;
	free_buffer = NULL;
	}

	/* attach the region to all applicable access maps */
	for (map = 0;
	map < nr_maps;
	map++)
	{
	if (mapmask & (1 << map))
	{
	sim_core_map_attach (sd, &memory->common.map[map],
	level, space, addr, nr_bytes, modulo,
	client, buffer, free_buffer);
	free_buffer = NULL;
	}
	}

	/* Just copy this map to each of the processor specific data structures.
	FIXME - later this will be replaced by true processor specific
	maps. */
	{
	int i;
	for (i = 0; i < MAX_NR_PROCESSORS; i++)
	{
	CPU_CORE (STATE_CPU (sd, i))->common = STATE_CORE (sd)->common;
	}
	}
	}
	#endif


	/* Remove any memory reference related to this address */
	#if EXTERN_SIM_CORE_P
	static void
	sim_core_map_detach (SIM_DESC sd,
	sim_core_map *access_map,
	int level,
	int space,
	address_word addr)
	{
	sim_core_mapping **entry;
	for (entry = &access_map->first;
	(*entry) != NULL;
	entry = &(*entry)->next)
	{
	if ((*entry)->base == addr
	&& (*entry)->level == level
	&& (*entry)->space == space)
	{
	sim_core_mapping dead = (entry);
	(*entry) = dead->next;
	if (dead->free_buffer != NULL)
	zfree (dead->free_buffer);
	zfree (dead);
	return;
	}
	}
	}
	#endif

	#if EXTERN_SIM_CORE_P
	void
	sim_core_detach (SIM_DESC sd,
	sim_cpu *cpu,
	int level,
	int address_space,
	address_word addr)
	{
	sim_core *memory = STATE_CORE (sd);
	unsigned map;
	for (map = 0; map < nr_maps; map++)
	{
	sim_core_map_detach (sd, &memory->common.map[map],
	level, address_space, addr);
	}
	/* Just copy this update to each of the processor specific data
	structures. FIXME - later this will be replaced by true
	processor specific maps. */
	{
	int i;
	for (i = 0; i < MAX_NR_PROCESSORS; i++)
	{
	CPU_CORE (STATE_CPU (sd, i))->common = STATE_CORE (sd)->common;
	}
	}
	}
	#endif


	STATIC_INLINE_SIM_CORE\
	(sim_core_mapping *)
	sim_core_find_mapping(sim_core_common *core,
	unsigned map,
	address_word addr,
	unsigned nr_bytes,
	transfer_type transfer,
	int abort, /either 0 or 1 - hint to inline/-O /
	sim_cpu cpu, / abort => cpu != NULL */
	sim_cia cia)
	{
	sim_core_mapping *mapping = core->map[map].first;
	ASSERT ((addr & (nr_bytes - 1)) == 0); /* must be aligned */
	ASSERT ((addr + (nr_bytes - 1)) >= addr); /* must not wrap */
	ASSERT (!abort \|\| cpu != NULL); /* abort needs a non null CPU */
	while (mapping != NULL)
	{
	if (addr >= mapping->base
	&& (addr + (nr_bytes - 1)) <= mapping->bound)
	return mapping;
	mapping = mapping->next;
	}
	if (abort)
	{
	SIM_CORE_SIGNAL (CPU_STATE (cpu), cpu, cia, map, nr_bytes, addr, transfer,
	sim_core_unmapped_signal);
	}
	return NULL;
	}


	STATIC_INLINE_SIM_CORE\
	(void *)
	sim_core_translate (sim_core_mapping *mapping,
	address_word addr)
	{
	if (WITH_MODULO_MEMORY)
	return (void )((unsigned8 ) mapping->buffer
	+ ((addr - mapping->base) & mapping->mask));
	else
	return (void )((unsigned8 ) mapping->buffer
	+ addr - mapping->base);
	}


	#if EXTERN_SIM_CORE_P
	unsigned
	sim_core_read_buffer (SIM_DESC sd,
	sim_cpu *cpu,
	unsigned map,
	void *buffer,
	address_word addr,
	unsigned len)
	{
	sim_core_common *core = (cpu == NULL ? &STATE_CORE (sd)->common : &CPU_CORE (cpu)->common);
	unsigned count = 0;
	while (count < len)
	{
	unsigned_word raddr = addr + count;
	sim_core_mapping *mapping =
	sim_core_find_mapping (core, map,
	raddr, /nr-bytes/1,
	read_transfer,
	0 /dont-abort/, NULL, NULL_CIA);
	if (mapping == NULL)
	break;
	#if (WITH_DEVICES)
	if (mapping->device != NULL)
	{
	int nr_bytes = len - count;
	sim_cia cia = cpu ? CIA_GET (cpu) : NULL_CIA;
	if (raddr + nr_bytes - 1> mapping->bound)
	nr_bytes = mapping->bound - raddr + 1;
	if (device_io_read_buffer (mapping->device,
	(unsigned_1*)buffer + count,
	mapping->space,
	raddr,
	nr_bytes,
	sd,
	cpu,
	cia) != nr_bytes)
	break;
	count += nr_bytes;
	continue;
	}
	#endif
	#if (WITH_HW)
	if (mapping->device != NULL)
	{
	int nr_bytes = len - count;
	if (raddr + nr_bytes - 1> mapping->bound)
	nr_bytes = mapping->bound - raddr + 1;
	if (sim_hw_io_read_buffer (sd, mapping->device,
	(unsigned_1*)buffer + count,
	mapping->space,
	raddr,
	nr_bytes) != nr_bytes)
	break;
	count += nr_bytes;
	continue;
	}
	#endif
	((unsigned_1*)buffer)[count] =
	(unsigned_1)sim_core_translate(mapping, raddr);
	count += 1;
	}
	return count;
	}
	#endif


	#if EXTERN_SIM_CORE_P
	unsigned
	sim_core_write_buffer (SIM_DESC sd,
	sim_cpu *cpu,
	unsigned map,
	const void *buffer,
	address_word addr,
	unsigned len)
	{
	sim_core_common *core = (cpu == NULL ? &STATE_CORE (sd)->common : &CPU_CORE (cpu)->common);
	unsigned count = 0;
	while (count < len)
	{
	unsigned_word raddr = addr + count;
	sim_core_mapping *mapping =
	sim_core_find_mapping (core, map,
	raddr, /nr-bytes/1,
	write_transfer,
	0 /dont-abort/, NULL, NULL_CIA);
	if (mapping == NULL)
	break;
	#if (WITH_DEVICES)
	if (WITH_CALLBACK_MEMORY
	&& mapping->device != NULL)
	{
	int nr_bytes = len - count;
	sim_cia cia = cpu ? CIA_GET (cpu) : NULL_CIA;
	if (raddr + nr_bytes - 1 > mapping->bound)
	nr_bytes = mapping->bound - raddr + 1;
	if (device_io_write_buffer (mapping->device,
	(unsigned_1*)buffer + count,
	mapping->space,
	raddr,
	nr_bytes,
	sd,
	cpu,
	cia) != nr_bytes)
	break;
	count += nr_bytes;
	continue;
	}
	#endif
	#if (WITH_HW)
	if (WITH_CALLBACK_MEMORY
	&& mapping->device != NULL)
	{
	int nr_bytes = len - count;
	if (raddr + nr_bytes - 1 > mapping->bound)
	nr_bytes = mapping->bound - raddr + 1;
	if (sim_hw_io_write_buffer (sd, mapping->device,
	(unsigned_1*)buffer + count,
	mapping->space,
	raddr,
	nr_bytes) != nr_bytes)
	break;
	count += nr_bytes;
	continue;
	}
	#endif
	(unsigned_1)sim_core_translate(mapping, raddr) =
	((unsigned_1*)buffer)[count];
	count += 1;
	}
	return count;
	}
	#endif


	#if EXTERN_SIM_CORE_P
	void
	sim_core_set_xor (SIM_DESC sd,
	sim_cpu *cpu,
	int is_xor)
	{
	/* set up the XOR map if required. */
	if (WITH_XOR_ENDIAN) {
	{
	sim_core *core = STATE_CORE (sd);
	sim_cpu_core *cpu_core = (cpu != NULL ? CPU_CORE (cpu) : NULL);
	if (cpu_core != NULL)
	{
	int i = 1;
	unsigned mask;
	if (is_xor)
	mask = WITH_XOR_ENDIAN - 1;
	else
	mask = 0;
	while (i - 1 < WITH_XOR_ENDIAN)
	{
	cpu_core->xor[i-1] = mask;
	mask = (mask << 1) & (WITH_XOR_ENDIAN - 1);
	i = (i << 1);
	}
	}
	else
	{
	if (is_xor)
	core->byte_xor = WITH_XOR_ENDIAN - 1;
	else
	core->byte_xor = 0;
	}
	}
	}
	else {
	if (is_xor)
	sim_engine_abort (sd, NULL, NULL_CIA,
	"Attempted to enable xor-endian mode when permenantly disabled.");
	}
	}
	#endif


	#if EXTERN_SIM_CORE_P
	static void
	reverse_n (unsigned_1 *dest,
	const unsigned_1 *src,
	int nr_bytes)
	{
	int i;
	for (i = 0; i < nr_bytes; i++)
	{
	dest [nr_bytes - i - 1] = src [i];
	}
	}
	#endif


	#if EXTERN_SIM_CORE_P
	unsigned
	sim_core_xor_read_buffer (SIM_DESC sd,
	sim_cpu *cpu,
	unsigned map,
	void *buffer,
	address_word addr,
	unsigned nr_bytes)
	{
	address_word byte_xor = (cpu == NULL ? STATE_CORE (sd)->byte_xor : CPU_CORE (cpu)->xor[0]);
	if (!WITH_XOR_ENDIAN \|\| !byte_xor)
	return sim_core_read_buffer (sd, cpu, map, buffer, addr, nr_bytes);
	else
	/* only break up transfers when xor-endian is both selected and enabled */
	{
	unsigned_1 x[WITH_XOR_ENDIAN + 1]; /* +1 to avoid zero-sized array */
	unsigned nr_transfered = 0;
	address_word start = addr;
	unsigned nr_this_transfer = (WITH_XOR_ENDIAN - (addr & ~(WITH_XOR_ENDIAN - 1)));
	address_word stop;
	/* initial and intermediate transfers are broken when they cross
	an XOR endian boundary */
	while (nr_transfered + nr_this_transfer < nr_bytes)
	/* initial/intermediate transfers */
	{
	/* since xor-endian is enabled stop^xor defines the start
	address of the transfer */
	stop = start + nr_this_transfer - 1;
	SIM_ASSERT (start <= stop);
	SIM_ASSERT ((stop ^ byte_xor) <= (start ^ byte_xor));
	if (sim_core_read_buffer (sd, cpu, map, x, stop ^ byte_xor, nr_this_transfer)
	!= nr_this_transfer)
	return nr_transfered;
	reverse_n (&((unsigned_1*)buffer)[nr_transfered], x, nr_this_transfer);
	nr_transfered += nr_this_transfer;
	nr_this_transfer = WITH_XOR_ENDIAN;
	start = stop + 1;
	}
	/* final transfer */
	nr_this_transfer = nr_bytes - nr_transfered;
	stop = start + nr_this_transfer - 1;
	SIM_ASSERT (stop == (addr + nr_bytes - 1));
	if (sim_core_read_buffer (sd, cpu, map, x, stop ^ byte_xor, nr_this_transfer)
	!= nr_this_transfer)
	return nr_transfered;
	reverse_n (&((unsigned_1*)buffer)[nr_transfered], x, nr_this_transfer);
	return nr_bytes;
	}
	}
	#endif


	#if EXTERN_SIM_CORE_P
	unsigned
	sim_core_xor_write_buffer (SIM_DESC sd,
	sim_cpu *cpu,
	unsigned map,
	const void *buffer,
	address_word addr,
	unsigned nr_bytes)
	{
	address_word byte_xor = (cpu == NULL ? STATE_CORE (sd)->byte_xor : CPU_CORE (cpu)->xor[0]);
	if (!WITH_XOR_ENDIAN \|\| !byte_xor)
	return sim_core_write_buffer (sd, cpu, map, buffer, addr, nr_bytes);
	else
	/* only break up transfers when xor-endian is both selected and enabled */
	{
	unsigned_1 x[WITH_XOR_ENDIAN + 1]; /* +1 to avoid zero sized array */
	unsigned nr_transfered = 0;
	address_word start = addr;
	unsigned nr_this_transfer = (WITH_XOR_ENDIAN - (addr & ~(WITH_XOR_ENDIAN - 1)));
	address_word stop;
	/* initial and intermediate transfers are broken when they cross
	an XOR endian boundary */
	while (nr_transfered + nr_this_transfer < nr_bytes)
	/* initial/intermediate transfers */
	{
	/* since xor-endian is enabled stop^xor defines the start
	address of the transfer */
	stop = start + nr_this_transfer - 1;
	SIM_ASSERT (start <= stop);
	SIM_ASSERT ((stop ^ byte_xor) <= (start ^ byte_xor));
	reverse_n (x, &((unsigned_1*)buffer)[nr_transfered], nr_this_transfer);
	if (sim_core_read_buffer (sd, cpu, map, x, stop ^ byte_xor, nr_this_transfer)
	!= nr_this_transfer)
	return nr_transfered;
	nr_transfered += nr_this_transfer;
	nr_this_transfer = WITH_XOR_ENDIAN;
	start = stop + 1;
	}
	/* final transfer */
	nr_this_transfer = nr_bytes - nr_transfered;
	stop = start + nr_this_transfer - 1;
	SIM_ASSERT (stop == (addr + nr_bytes - 1));
	reverse_n (x, &((unsigned_1*)buffer)[nr_transfered], nr_this_transfer);
	if (sim_core_read_buffer (sd, cpu, map, x, stop ^ byte_xor, nr_this_transfer)
	!= nr_this_transfer)
	return nr_transfered;
	return nr_bytes;
	}
	}
	#endif



	/* define the read/write 1/2/4/8/16/word functions */

	#define N 16
	#include "sim-n-core.h"

	#define N 8
	#include "sim-n-core.h"

	#define N 7
	#define M 8
	#include "sim-n-core.h"

	#define N 6
	#define M 8
	#include "sim-n-core.h"

	#define N 5
	#define M 8
	#include "sim-n-core.h"

	#define N 4
	#include "sim-n-core.h"

	#define N 3
	#define M 4
	#include "sim-n-core.h"

	#define N 2
	#include "sim-n-core.h"

	#define N 1
	#include "sim-n-core.h"

	#endif