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

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

    Copyright 2002-2016 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 3 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, see <http://www.gnu.org/licenses/>.  */


 #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);
 	free (tbd->free_buffer);
       }
       free (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,
 		      struct hw *device,
 		      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);
   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,
 		     struct hw *client, /*callback/default*/
 		     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_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_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,
 		 struct hw *client,
 		 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");

   if (client != NULL && modulo != 0)
     {
 #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_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_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)
 	    free (dead->free_buffer);
 	  free (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)
 {
   return (void *)((unsigned8 *) mapping->buffer
 		  + ((addr - mapping->base) & mapping->mask));
 }


 #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)
  {
     address_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_HW)
     if (mapping->device != NULL)
       {
 	int nr_bytes = len - count;
 	if (raddr + nr_bytes - 1> mapping->bound)
 	  nr_bytes = mapping->bound - raddr + 1;
 	/* If the access was initiated by a cpu, pass it down so errors can
 	   be propagated properly.  For other sources (e.g. GDB or DMA), we
 	   can only signal errors via the return value.  */
 	if (cpu)
 	  {
 	    sim_cia cia = cpu ? CPU_PC_GET (cpu) : NULL_CIA;
 	    sim_cpu_hw_io_read_buffer (cpu, cia, mapping->device,
 				       (unsigned_1*)buffer + count,
 				       mapping->space,
 				       raddr,
 				       nr_bytes);
 	  }
 	else 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)
     {
       address_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_HW)
       if (mapping->device != NULL)
 	{
 	  int nr_bytes = len - count;
 	  if (raddr + nr_bytes - 1 > mapping->bound)
 	    nr_bytes = mapping->bound - raddr + 1;
 	  /* If the access was initiated by a cpu, pass it down so errors can
 	     be propagated properly.  For other sources (e.g. GDB or DMA), we
 	     can only signal errors via the return value.  */
 	  if (cpu)
 	    {
 	      sim_cia cia = cpu ? CPU_PC_GET (cpu) : NULL_CIA;
 	      sim_cpu_hw_io_write_buffer (cpu, cia, mapping->device,
 					  (unsigned_1*)buffer + count,
 					  mapping->space,
 					  raddr,
 					  nr_bytes);
 	    }
 	  else 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

 #if EXTERN_SIM_CORE_P
 void *
 sim_core_trans_addr (SIM_DESC sd,
                      sim_cpu *cpu,
                      unsigned map,
                      address_word addr)
 {
   sim_core_common *core = (cpu == NULL ? &STATE_CORE (sd)->common : &CPU_CORE (cpu)->common);
   sim_core_mapping *mapping =
     sim_core_find_mapping (core, map,
                            addr, /*nr-bytes*/1,
                            write_transfer,
                            0 /*dont-abort*/, NULL, NULL_CIA);
   if (mapping == NULL)
     return NULL;
   return sim_core_translate (mapping, addr);
 }
 #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 2002-2016 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 3 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, see <http://www.gnu.org/licenses/>. */


	#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);
	free (tbd->free_buffer);
	}
	free (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,
	struct hw *device,
	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);
	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,
	struct hw client, /callback/default*/
	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_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_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,
	struct hw *client,
	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");

	if (client != NULL && modulo != 0)
	{
	#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_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_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)
	free (dead->free_buffer);
	free (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)
	{
	return (void )((unsigned8 ) mapping->buffer
	+ ((addr - mapping->base) & mapping->mask));
	}


	#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)
	{
	address_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_HW)
	if (mapping->device != NULL)
	{
	int nr_bytes = len - count;
	if (raddr + nr_bytes - 1> mapping->bound)
	nr_bytes = mapping->bound - raddr + 1;
	/* If the access was initiated by a cpu, pass it down so errors can
	be propagated properly. For other sources (e.g. GDB or DMA), we
	can only signal errors via the return value. */
	if (cpu)
	{
	sim_cia cia = cpu ? CPU_PC_GET (cpu) : NULL_CIA;
	sim_cpu_hw_io_read_buffer (cpu, cia, mapping->device,
	(unsigned_1*)buffer + count,
	mapping->space,
	raddr,
	nr_bytes);
	}
	else 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)
	{
	address_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_HW)
	if (mapping->device != NULL)
	{
	int nr_bytes = len - count;
	if (raddr + nr_bytes - 1 > mapping->bound)
	nr_bytes = mapping->bound - raddr + 1;
	/* If the access was initiated by a cpu, pass it down so errors can
	be propagated properly. For other sources (e.g. GDB or DMA), we
	can only signal errors via the return value. */
	if (cpu)
	{
	sim_cia cia = cpu ? CPU_PC_GET (cpu) : NULL_CIA;
	sim_cpu_hw_io_write_buffer (cpu, cia, mapping->device,
	(unsigned_1*)buffer + count,
	mapping->space,
	raddr,
	nr_bytes);
	}
	else 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

	#if EXTERN_SIM_CORE_P
	void *
	sim_core_trans_addr (SIM_DESC sd,
	sim_cpu *cpu,
	unsigned map,
	address_word addr)
	{
	sim_core_common *core = (cpu == NULL ? &STATE_CORE (sd)->common : &CPU_CORE (cpu)->common);
	sim_core_mapping *mapping =
	sim_core_find_mapping (core, map,
	addr, /nr-bytes/1,
	write_transfer,
	0 /dont-abort/, NULL, NULL_CIA);
	if (mapping == NULL)
	return NULL;
	return sim_core_translate (mapping, addr);
	}
	#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