sim/erc32/interf.c - binutils-gdb - Git at Google

 /*
  * This file is part of SIS.
  *
  * SIS, SPARC instruction simulator V1.6 Copyright (C) 1995 Jiri Gaisler,
  * European Space Agency
  *
  * 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., 675
  * Mass Ave, Cambridge, MA 02139, USA.
  *
  */

 #include <signal.h>
 #include <string.h>
 #include <stdio.h>
 #include <stdlib.h>
 #include <time.h>
 #include <sys/fcntl.h>
 #include "sis.h"
 #include "bfd.h"
 #include <dis-asm.h>
 #include "sim-config.h"

 #include "gdb/remote-sim.h"

 #ifndef fprintf
 extern          fprintf();
 #endif

 #define PSR_CWP 0x7

 #define	VAL(x)	strtol(x,(char **)NULL,0)

 extern char   **buildargv(char *input);

 extern struct disassemble_info dinfo;
 extern struct pstate sregs;
 extern struct estate ebase;

 extern int	current_target_byte_order;
 extern int      ctrl_c;
 extern int      nfp;
 extern int      ift;
 extern int      rom8;
 extern int      wrp;
 extern int      uben;
 extern int      sis_verbose;
 extern char    *sis_version;
 extern struct estate ebase;
 extern struct evcell evbuf[];
 extern struct irqcell irqarr[];
 extern int      irqpend, ext_irl;
 extern int      sparclite;
 extern int      dumbio;
 extern int      sparclite_board;
 extern int      termsave;
 extern char     uart_dev1[], uart_dev2[];

 int             sis_gdb_break = 1;

 host_callback *sim_callback;

 int
 run_sim(sregs, icount, dis)
     struct pstate  *sregs;
     unsigned int    icount;
     int             dis;
 {
     int             mexc, irq;

     if (sis_verbose)
 	(*sim_callback->printf_filtered) (sim_callback, "resuming at %x\n",
 					  sregs->pc);
    init_stdio();
    sregs->starttime = time(NULL);
    irq = 0;
    while (!sregs->err_mode & (icount > 0)) {

 	sregs->fhold = 0;
 	sregs->hold = 0;
 	sregs->icnt = 1;

         if (sregs->psr & 0x080)
             sregs->asi = 8;
         else
             sregs->asi = 9;

 #if 0	/* DELETE ME! for debugging purposes only */
         if (sis_verbose > 1)
             if (sregs->pc == 0 || sregs->npc == 0)
                 printf ("bogus pc or npc\n");
 #endif
         mexc = memory_read(sregs->asi, sregs->pc, &sregs->inst,
                            2, &sregs->hold);
 #if 1	/* DELETE ME! for debugging purposes only */
         if (sis_verbose > 2)
             printf("pc %x, np %x, sp %x, fp %x, wm %x, cw %x, i %08x\n",
                    sregs->pc, sregs->npc,
                    sregs->r[(((sregs->psr & 7) << 4) + 14) & 0x7f],
                    sregs->r[(((sregs->psr & 7) << 4) + 30) & 0x7f],
                    sregs->wim,
                    sregs->psr & 7,
                    sregs->inst);
 #endif
         if (sregs->annul) {
             sregs->annul = 0;
             sregs->icnt = 1;
             sregs->pc = sregs->npc;
             sregs->npc = sregs->npc + 4;
         } else {
 	    if (ext_irl) irq = check_interrupts(sregs);
 	    if (!irq) {
 		if (mexc) {
 		    sregs->trap = I_ACC_EXC;
 		} else {
 		    if ((sis_gdb_break) && (sregs->inst == 0x91d02001)) {
 			if (sis_verbose)
 			    (*sim_callback->printf_filtered) (sim_callback,
 							      "SW BP hit at %x\n", sregs->pc);
                         sim_halt();
 			restore_stdio();
 			clearerr(stdin);
 			return (BPT_HIT);
 		    } else
 			dispatch_instruction(sregs);
 		}
 		icount--;
 	    }
 	    if (sregs->trap) {
                 irq = 0;
 		sregs->err_mode = execute_trap(sregs);
 	    }
 	}
 	advance_time(sregs);
 	if (ctrl_c) {
 	    icount = 0;
 	}
     }
     sim_halt();
     sregs->tottime += time(NULL) - sregs->starttime;
     restore_stdio();
     clearerr(stdin);
     if (sregs->err_mode)
 	error_mode(sregs->pc);
     if (sregs->err_mode)
 	return (ERROR);
     if (sregs->bphit) {
 	if (sis_verbose)
 	    (*sim_callback->printf_filtered) (sim_callback,
 					      "HW BP hit at %x\n", sregs->pc);
 	return (BPT_HIT);
     }
     if (ctrl_c) {
 	ctrl_c = 0;
 	return (CTRL_C);
     }
     return (TIME_OUT);
 }

 void
 sim_set_callbacks (ptr)
      host_callback *ptr;
 {
   sim_callback = ptr;
 }

 void
 sim_size (memsize)
      int memsize;
 {
 }

 SIM_DESC
 sim_open (kind, callback, abfd, argv)
      SIM_OPEN_KIND kind;
      struct host_callback_struct *callback;
      struct bfd *abfd;
      char **argv;
 {

     int             argc = 0;
     int             stat = 1;
     int             freq = 0;

     sim_callback = callback;

     while (argv[argc])
       argc++;
     while (stat < argc) {
 	if (argv[stat][0] == '-') {
 	    if (strcmp(argv[stat], "-v") == 0) {
 		sis_verbose++;
 	    } else
 	    if (strcmp(argv[stat], "-nfp") == 0) {
 		nfp = 1;
 	    } else
             if (strcmp(argv[stat], "-ift") == 0) {
                 ift = 1;
 	    } else
 	    if (strcmp(argv[stat], "-sparclite") == 0) {
 		sparclite = 1;
 	    } else
 	    if (strcmp(argv[stat], "-sparclite-board") == 0) {
 		sparclite_board = 1;
             } else
             if (strcmp(argv[stat], "-dumbio") == 0) {
 		dumbio = 1;
 	    } else
             if (strcmp(argv[stat], "-wrp") == 0) {
                 wrp = 1;
 	    } else
             if (strcmp(argv[stat], "-rom8") == 0) {
                 rom8 = 1;
 	    } else
             if (strcmp(argv[stat], "-uben") == 0) {
                 uben = 1;
 	    } else
 	    if (strcmp(argv[stat], "-uart1") == 0) {
 		if ((stat + 1) < argc)
 		    strcpy(uart_dev1, argv[++stat]);
 	    } else
 	    if (strcmp(argv[stat], "-uart2") == 0) {
 		if ((stat + 1) < argc)
 		    strcpy(uart_dev2, argv[++stat]);
 	    } else
 	    if (strcmp(argv[stat], "-nogdb") == 0) {
 		sis_gdb_break = 0;
 	    } else
 	    if (strcmp(argv[stat], "-freq") == 0) {
 		if ((stat + 1) < argc) {
 		    freq = VAL(argv[++stat]);
 		}
 	    } else {
 		(*sim_callback->printf_filtered) (sim_callback,
 						  "unknown option %s\n",
 						  argv[stat]);
 	    }
 	} else
 	    bfd_load(argv[stat]);
 	stat++;
     }

     if (sis_verbose) {
 	(*sim_callback->printf_filtered) (sim_callback, "\n SIS - SPARC instruction simulator %s\n", sis_version);
 	(*sim_callback->printf_filtered) (sim_callback, " Bug-reports to Jiri Gaisler ESA/ESTEC (jgais@wd.estec.esa.nl)\n");
 	if (nfp)
 	  (*sim_callback->printf_filtered) (sim_callback, "no FPU\n");
 	if (sparclite)
 	  (*sim_callback->printf_filtered) (sim_callback, "simulating Sparclite\n");
 	if (dumbio)
 	  (*sim_callback->printf_filtered) (sim_callback, "dumb IO (no input, dumb output)\n");
 	if (sis_gdb_break == 0)
 	  (*sim_callback->printf_filtered) (sim_callback, "disabling GDB trap handling for breakpoints\n");
 	if (freq)
 	  (*sim_callback->printf_filtered) (sim_callback, " ERC32 freq %d Mhz\n", freq);
     }

     sregs.freq = freq ? freq : 15;
     termsave = fcntl(0, F_GETFL, 0);
     INIT_DISASSEMBLE_INFO(dinfo, stdout,(fprintf_ftype)fprintf);
     dinfo.endian = BFD_ENDIAN_BIG;
     reset_all();
     ebase.simtime = 0;
     init_sim();
     init_bpt(&sregs);
     reset_stat(&sregs);

     /* Fudge our descriptor for now.  */
     return (SIM_DESC) 1;
 }

 void
 sim_close(sd, quitting)
      SIM_DESC sd;
      int quitting;
 {

     exit_sim();
     fcntl(0, F_SETFL, termsave);

 };

 SIM_RC
 sim_load(sd, prog, abfd, from_tty)
      SIM_DESC sd;
      char *prog;
      bfd *abfd;
      int from_tty;
 {
     bfd_load (prog);
     return SIM_RC_OK;
 }

 SIM_RC
 sim_create_inferior(sd, abfd, argv, env)
      SIM_DESC sd;
      struct bfd *abfd;
      char **argv;
      char **env;
 {
     bfd_vma start_address = 0;
     if (abfd != NULL)
       start_address = bfd_get_start_address (abfd);

     ebase.simtime = 0;
     reset_all();
     reset_stat(&sregs);
     sregs.pc = start_address & ~3;
     sregs.npc = sregs.pc + 4;
     return SIM_RC_OK;
 }

 int
 sim_store_register(sd, regno, value, length)
     SIM_DESC sd;
     int             regno;
     unsigned char  *value;
     int length;
 {
     /* FIXME: Review the computation of regval.  */
     int regval;
     if (current_target_byte_order == BIG_ENDIAN)
 	regval = (value[0] << 24) | (value[1] << 16)
 		 | (value[2] << 8) | value[3];
     else
 	regval = (value[3] << 24) | (value[2] << 16)
 		 | (value[1] << 8) | value[0];
     set_regi(&sregs, regno, regval);
     return -1;
 }


 int
 sim_fetch_register(sd, regno, buf, length)
      SIM_DESC sd;
     int             regno;
     unsigned char  *buf;
      int length;
 {
     get_regi(&sregs, regno, buf);
     return -1;
 }

 int
 sim_write(sd, mem, buf, length)
      SIM_DESC sd;
     SIM_ADDR             mem;
     unsigned char  *buf;
     int             length;
 {
     return (sis_memory_write(mem, buf, length));
 }

 int
 sim_read(sd, mem, buf, length)
      SIM_DESC sd;
      SIM_ADDR mem;
      unsigned char *buf;
      int length;
 {
     return (sis_memory_read(mem, buf, length));
 }

 void
 sim_info(sd, verbose)
      SIM_DESC sd;
      int verbose;
 {
     show_stat(&sregs);
 }

 int             simstat = OK;

 void
 sim_stop_reason(sd, reason, sigrc)
      SIM_DESC sd;
      enum sim_stop * reason;
      int *sigrc;
 {

     switch (simstat) {
 	case CTRL_C:
 	*reason = sim_stopped;
 	*sigrc = SIGINT;
 	break;
     case OK:
     case TIME_OUT:
     case BPT_HIT:
 	*reason = sim_stopped;
 #ifdef _WIN32
 #define SIGTRAP 5
 #endif
 	*sigrc = SIGTRAP;
 	break;
     case ERROR:
 	*sigrc = 0;
 	*reason = sim_exited;
     }
     ctrl_c = 0;
     simstat = OK;
 }

 /* Flush all register windows out to the stack.  Starting after the invalid
    window, flush all windows up to, and including the current window.  This
    allows GDB to do backtraces and look at local variables for frames that
    are still in the register windows.  Note that strictly speaking, this
    behavior is *wrong* for several reasons.  First, it doesn't use the window
    overflow handlers.  It therefore assumes standard frame layouts and window
    handling policies.  Second, it changes system state behind the back of the
    target program.  I expect this to mainly pose problems when debugging trap
    handlers.
 */

 static void
 flush_windows ()
 {
   int invwin;
   int cwp;
   int win;
   int ws;

   /* Keep current window handy */

   cwp = sregs.psr & PSR_CWP;

   /* Calculate the invalid window from the wim. */

   for (invwin = 0; invwin <= PSR_CWP; invwin++)
     if ((sregs.wim >> invwin) & 1)
       break;

   /* Start saving with the window after the invalid window. */

   invwin = (invwin - 1) & PSR_CWP;

   for (win = invwin; ; win = (win - 1) & PSR_CWP)
     {
       uint32 sp;
       int i;

       sp = sregs.r[(win * 16 + 14) & 0x7f];
 #if 1
       if (sis_verbose > 2) {
 	uint32 fp = sregs.r[(win * 16 + 30) & 0x7f];
 	printf("flush_window: win %d, sp %x, fp %x\n", win, sp, fp);
       }
 #endif

       for (i = 0; i < 16; i++)
 	memory_write (11, sp + 4 * i, &sregs.r[(win * 16 + 16 + i) & 0x7f], 2,
 		      &ws);

       if (win == cwp)
 	break;
     }
 }

 void
 sim_resume(SIM_DESC sd, int step, int siggnal)
 {
     simstat = run_sim(&sregs, -1, 0);

     if (sis_gdb_break) flush_windows ();
 }

 int
 sim_trace (sd)
      SIM_DESC sd;
 {
   /* FIXME: unfinished */
   sim_resume (sd, 0, 0);
   return 1;
 }

 void
 sim_do_command(sd, cmd)
      SIM_DESC sd;
     char           *cmd;
 {
     exec_cmd(&sregs, cmd);
 }

 #if 0 /* FIXME: These shouldn't exist.  */

 int
 sim_insert_breakpoint(int addr)
 {
     if (sregs.bptnum < BPT_MAX) {
 	sregs.bpts[sregs.bptnum] = addr & ~0x3;
 	sregs.bptnum++;
 	if (sis_verbose)
 	    (*sim_callback->printf_filtered) (sim_callback, "inserted HW BP at %x\n", addr);
 	return 0;
     } else
 	return 1;
 }

 int
 sim_remove_breakpoint(int addr)
 {
     int             i = 0;

     while ((i < sregs.bptnum) && (sregs.bpts[i] != addr))
 	i++;
     if (addr == sregs.bpts[i]) {
 	for (; i < sregs.bptnum - 1; i++)
 	    sregs.bpts[i] = sregs.bpts[i + 1];
 	sregs.bptnum -= 1;
 	if (sis_verbose)
 	    (*sim_callback->printf_filtered) (sim_callback, "removed HW BP at %x\n", addr);
 	return 0;
     }
     return 1;
 }

 #endif
	/*
	* This file is part of SIS.
	*
	* SIS, SPARC instruction simulator V1.6 Copyright (C) 1995 Jiri Gaisler,
	* European Space Agency
	*
	* 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., 675
	* Mass Ave, Cambridge, MA 02139, USA.
	*
	*/

	#include <signal.h>
	#include <string.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <time.h>
	#include <sys/fcntl.h>
	#include "sis.h"
	#include "bfd.h"
	#include <dis-asm.h>
	#include "sim-config.h"

	#include "gdb/remote-sim.h"

	#ifndef fprintf
	extern fprintf();
	#endif

	#define PSR_CWP 0x7

	#define VAL(x) strtol(x,(char **)NULL,0)

	extern char *buildargv(char input);

	extern struct disassemble_info dinfo;
	extern struct pstate sregs;
	extern struct estate ebase;

	extern int current_target_byte_order;
	extern int ctrl_c;
	extern int nfp;
	extern int ift;
	extern int rom8;
	extern int wrp;
	extern int uben;
	extern int sis_verbose;
	extern char *sis_version;
	extern struct estate ebase;
	extern struct evcell evbuf[];
	extern struct irqcell irqarr[];
	extern int irqpend, ext_irl;
	extern int sparclite;
	extern int dumbio;
	extern int sparclite_board;
	extern int termsave;
	extern char uart_dev1[], uart_dev2[];

	int sis_gdb_break = 1;

	host_callback *sim_callback;

	int
	run_sim(sregs, icount, dis)
	struct pstate *sregs;
	unsigned int icount;
	int dis;
	{
	int mexc, irq;

	if (sis_verbose)
	(*sim_callback->printf_filtered) (sim_callback, "resuming at %x\n",
	sregs->pc);
	init_stdio();
	sregs->starttime = time(NULL);
	irq = 0;
	while (!sregs->err_mode & (icount > 0)) {

	sregs->fhold = 0;
	sregs->hold = 0;
	sregs->icnt = 1;

	if (sregs->psr & 0x080)
	sregs->asi = 8;
	else
	sregs->asi = 9;

	#if 0 /* DELETE ME! for debugging purposes only */
	if (sis_verbose > 1)
	if (sregs->pc == 0 \|\| sregs->npc == 0)
	printf ("bogus pc or npc\n");
	#endif
	mexc = memory_read(sregs->asi, sregs->pc, &sregs->inst,
	2, &sregs->hold);
	#if 1 /* DELETE ME! for debugging purposes only */
	if (sis_verbose > 2)
	printf("pc %x, np %x, sp %x, fp %x, wm %x, cw %x, i %08x\n",
	sregs->pc, sregs->npc,
	sregs->r[(((sregs->psr & 7) << 4) + 14) & 0x7f],
	sregs->r[(((sregs->psr & 7) << 4) + 30) & 0x7f],
	sregs->wim,
	sregs->psr & 7,
	sregs->inst);
	#endif
	if (sregs->annul) {
	sregs->annul = 0;
	sregs->icnt = 1;
	sregs->pc = sregs->npc;
	sregs->npc = sregs->npc + 4;
	} else {
	if (ext_irl) irq = check_interrupts(sregs);
	if (!irq) {
	if (mexc) {
	sregs->trap = I_ACC_EXC;
	} else {
	if ((sis_gdb_break) && (sregs->inst == 0x91d02001)) {
	if (sis_verbose)
	(*sim_callback->printf_filtered) (sim_callback,
	"SW BP hit at %x\n", sregs->pc);
	sim_halt();
	restore_stdio();
	clearerr(stdin);
	return (BPT_HIT);
	} else
	dispatch_instruction(sregs);
	}
	icount--;
	}
	if (sregs->trap) {
	irq = 0;
	sregs->err_mode = execute_trap(sregs);
	}
	}
	advance_time(sregs);
	if (ctrl_c) {
	icount = 0;
	}
	}
	sim_halt();
	sregs->tottime += time(NULL) - sregs->starttime;
	restore_stdio();
	clearerr(stdin);
	if (sregs->err_mode)
	error_mode(sregs->pc);
	if (sregs->err_mode)
	return (ERROR);
	if (sregs->bphit) {
	if (sis_verbose)
	(*sim_callback->printf_filtered) (sim_callback,
	"HW BP hit at %x\n", sregs->pc);
	return (BPT_HIT);
	}
	if (ctrl_c) {
	ctrl_c = 0;
	return (CTRL_C);
	}
	return (TIME_OUT);
	}

	void
	sim_set_callbacks (ptr)
	host_callback *ptr;
	{
	sim_callback = ptr;
	}

	void
	sim_size (memsize)
	int memsize;
	{
	}

	SIM_DESC
	sim_open (kind, callback, abfd, argv)
	SIM_OPEN_KIND kind;
	struct host_callback_struct *callback;
	struct bfd *abfd;
	char **argv;
	{

	int argc = 0;
	int stat = 1;
	int freq = 0;

	sim_callback = callback;

	while (argv[argc])
	argc++;
	while (stat < argc) {
	if (argv[stat][0] == '-') {
	if (strcmp(argv[stat], "-v") == 0) {
	sis_verbose++;
	} else
	if (strcmp(argv[stat], "-nfp") == 0) {
	nfp = 1;
	} else
	if (strcmp(argv[stat], "-ift") == 0) {
	ift = 1;
	} else
	if (strcmp(argv[stat], "-sparclite") == 0) {
	sparclite = 1;
	} else
	if (strcmp(argv[stat], "-sparclite-board") == 0) {
	sparclite_board = 1;
	} else
	if (strcmp(argv[stat], "-dumbio") == 0) {
	dumbio = 1;
	} else
	if (strcmp(argv[stat], "-wrp") == 0) {
	wrp = 1;
	} else
	if (strcmp(argv[stat], "-rom8") == 0) {
	rom8 = 1;
	} else
	if (strcmp(argv[stat], "-uben") == 0) {
	uben = 1;
	} else
	if (strcmp(argv[stat], "-uart1") == 0) {
	if ((stat + 1) < argc)
	strcpy(uart_dev1, argv[++stat]);
	} else
	if (strcmp(argv[stat], "-uart2") == 0) {
	if ((stat + 1) < argc)
	strcpy(uart_dev2, argv[++stat]);
	} else
	if (strcmp(argv[stat], "-nogdb") == 0) {
	sis_gdb_break = 0;
	} else
	if (strcmp(argv[stat], "-freq") == 0) {
	if ((stat + 1) < argc) {
	freq = VAL(argv[++stat]);
	}
	} else {
	(*sim_callback->printf_filtered) (sim_callback,
	"unknown option %s\n",
	argv[stat]);
	}
	} else
	bfd_load(argv[stat]);
	stat++;
	}

	if (sis_verbose) {
	(*sim_callback->printf_filtered) (sim_callback, "\n SIS - SPARC instruction simulator %s\n", sis_version);
	(*sim_callback->printf_filtered) (sim_callback, " Bug-reports to Jiri Gaisler ESA/ESTEC (jgais@wd.estec.esa.nl)\n");
	if (nfp)
	(*sim_callback->printf_filtered) (sim_callback, "no FPU\n");
	if (sparclite)
	(*sim_callback->printf_filtered) (sim_callback, "simulating Sparclite\n");
	if (dumbio)
	(*sim_callback->printf_filtered) (sim_callback, "dumb IO (no input, dumb output)\n");
	if (sis_gdb_break == 0)
	(*sim_callback->printf_filtered) (sim_callback, "disabling GDB trap handling for breakpoints\n");
	if (freq)
	(*sim_callback->printf_filtered) (sim_callback, " ERC32 freq %d Mhz\n", freq);
	}

	sregs.freq = freq ? freq : 15;
	termsave = fcntl(0, F_GETFL, 0);
	INIT_DISASSEMBLE_INFO(dinfo, stdout,(fprintf_ftype)fprintf);
	dinfo.endian = BFD_ENDIAN_BIG;
	reset_all();
	ebase.simtime = 0;
	init_sim();
	init_bpt(&sregs);
	reset_stat(&sregs);

	/* Fudge our descriptor for now. */
	return (SIM_DESC) 1;
	}

	void
	sim_close(sd, quitting)
	SIM_DESC sd;
	int quitting;
	{

	exit_sim();
	fcntl(0, F_SETFL, termsave);

	};

	SIM_RC
	sim_load(sd, prog, abfd, from_tty)
	SIM_DESC sd;
	char *prog;
	bfd *abfd;
	int from_tty;
	{
	bfd_load (prog);
	return SIM_RC_OK;
	}

	SIM_RC
	sim_create_inferior(sd, abfd, argv, env)
	SIM_DESC sd;
	struct bfd *abfd;
	char **argv;
	char **env;
	{
	bfd_vma start_address = 0;
	if (abfd != NULL)
	start_address = bfd_get_start_address (abfd);

	ebase.simtime = 0;
	reset_all();
	reset_stat(&sregs);
	sregs.pc = start_address & ~3;
	sregs.npc = sregs.pc + 4;
	return SIM_RC_OK;
	}

	int
	sim_store_register(sd, regno, value, length)
	SIM_DESC sd;
	int regno;
	unsigned char *value;
	int length;
	{
	/* FIXME: Review the computation of regval. */
	int regval;
	if (current_target_byte_order == BIG_ENDIAN)
	regval = (value[0] << 24) \| (value[1] << 16)
	\| (value[2] << 8) \| value[3];
	else
	regval = (value[3] << 24) \| (value[2] << 16)
	\| (value[1] << 8) \| value[0];
	set_regi(&sregs, regno, regval);
	return -1;
	}


	int
	sim_fetch_register(sd, regno, buf, length)
	SIM_DESC sd;
	int regno;
	unsigned char *buf;
	int length;
	{
	get_regi(&sregs, regno, buf);
	return -1;
	}

	int
	sim_write(sd, mem, buf, length)
	SIM_DESC sd;
	SIM_ADDR mem;
	unsigned char *buf;
	int length;
	{
	return (sis_memory_write(mem, buf, length));
	}

	int
	sim_read(sd, mem, buf, length)
	SIM_DESC sd;
	SIM_ADDR mem;
	unsigned char *buf;
	int length;
	{
	return (sis_memory_read(mem, buf, length));
	}

	void
	sim_info(sd, verbose)
	SIM_DESC sd;
	int verbose;
	{
	show_stat(&sregs);
	}

	int simstat = OK;

	void
	sim_stop_reason(sd, reason, sigrc)
	SIM_DESC sd;
	enum sim_stop * reason;
	int *sigrc;
	{

	switch (simstat) {
	case CTRL_C:
	*reason = sim_stopped;
	*sigrc = SIGINT;
	break;
	case OK:
	case TIME_OUT:
	case BPT_HIT:
	*reason = sim_stopped;
	#ifdef _WIN32
	#define SIGTRAP 5
	#endif
	*sigrc = SIGTRAP;
	break;
	case ERROR:
	*sigrc = 0;
	*reason = sim_exited;
	}
	ctrl_c = 0;
	simstat = OK;
	}

	/* Flush all register windows out to the stack. Starting after the invalid
	window, flush all windows up to, and including the current window. This
	allows GDB to do backtraces and look at local variables for frames that
	are still in the register windows. Note that strictly speaking, this
	behavior is wrong for several reasons. First, it doesn't use the window
	overflow handlers. It therefore assumes standard frame layouts and window
	handling policies. Second, it changes system state behind the back of the
	target program. I expect this to mainly pose problems when debugging trap
	handlers.
	*/

	static void
	flush_windows ()
	{
	int invwin;
	int cwp;
	int win;
	int ws;

	/* Keep current window handy */

	cwp = sregs.psr & PSR_CWP;

	/* Calculate the invalid window from the wim. */

	for (invwin = 0; invwin <= PSR_CWP; invwin++)
	if ((sregs.wim >> invwin) & 1)
	break;

	/* Start saving with the window after the invalid window. */

	invwin = (invwin - 1) & PSR_CWP;

	for (win = invwin; ; win = (win - 1) & PSR_CWP)
	{
	uint32 sp;
	int i;

	sp = sregs.r[(win * 16 + 14) & 0x7f];
	#if 1
	if (sis_verbose > 2) {
	uint32 fp = sregs.r[(win * 16 + 30) & 0x7f];
	printf("flush_window: win %d, sp %x, fp %x\n", win, sp, fp);
	}
	#endif

	for (i = 0; i < 16; i++)
	memory_write (11, sp + 4 * i, &sregs.r[(win * 16 + 16 + i) & 0x7f], 2,
	&ws);

	if (win == cwp)
	break;
	}
	}

	void
	sim_resume(SIM_DESC sd, int step, int siggnal)
	{
	simstat = run_sim(&sregs, -1, 0);

	if (sis_gdb_break) flush_windows ();
	}

	int
	sim_trace (sd)
	SIM_DESC sd;
	{
	/* FIXME: unfinished */
	sim_resume (sd, 0, 0);
	return 1;
	}

	void
	sim_do_command(sd, cmd)
	SIM_DESC sd;
	char *cmd;
	{
	exec_cmd(&sregs, cmd);
	}

	#if 0 /* FIXME: These shouldn't exist. */

	int
	sim_insert_breakpoint(int addr)
	{
	if (sregs.bptnum < BPT_MAX) {
	sregs.bpts[sregs.bptnum] = addr & ~0x3;
	sregs.bptnum++;
	if (sis_verbose)
	(*sim_callback->printf_filtered) (sim_callback, "inserted HW BP at %x\n", addr);
	return 0;
	} else
	return 1;
	}

	int
	sim_remove_breakpoint(int addr)
	{
	int i = 0;

	while ((i < sregs.bptnum) && (sregs.bpts[i] != addr))
	i++;
	if (addr == sregs.bpts[i]) {
	for (; i < sregs.bptnum - 1; i++)
	sregs.bpts[i] = sregs.bpts[i + 1];
	sregs.bptnum -= 1;
	if (sis_verbose)
	(*sim_callback->printf_filtered) (sim_callback, "removed HW BP at %x\n", addr);
	return 0;
	}
	return 1;
	}

	#endif