PDP10/pdp10_fe.c - emulators/simh - Rivoreo Source Code Repositories

 /* pdp10_fe.c: PDP-10 front end (console terminal) simulator

    Copyright (c) 1993-2012, Robert M Supnik

    Permission is hereby granted, free of charge, to any person obtaining a
    copy of this software and associated documentation files (the "Software"),
    to deal in the Software without restriction, including without limitation
    the rights to use, copy, modify, merge, publish, distribute, sublicense,
    and/or sell copies of the Software, and to permit persons to whom the
    Software is furnished to do so, subject to the following conditions:

    The above copyright notice and this permission notice shall be included in
    all copies or substantial portions of the Software.

    THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
    IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
    FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL
    ROBERT M SUPNIK BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
    IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
    CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.

    Except as contained in this notice, the name of Robert M Supnik shall not be
    used in advertising or otherwise to promote the sale, use or other dealings
    in this Software without prior written authorization from Robert M Supnik.

    fe           KS10 console front end

    18-Apr-12    RMS     Added clock coscheduling
    18-Jun-07    RMS     Added UNIT_IDLE flag to console input
    17-Oct-06    RMS     Synced keyboard to clock for idling
    28-May-04    RMS     Removed SET FE CTRL-C
    29-Dec-03    RMS     Added console backpressure support
    25-Apr-03    RMS     Revised for extended file support
    22-Dec-02    RMS     Added break support
    30-May-02    RMS     Widened COUNT to 32b
    30-Nov-01    RMS     Added extended SET/SHOW support
    23-Oct-01    RMS     New IO page address constants
    07-Sep-01    RMS     Moved function prototypes
 */

 #include "pdp10_defs.h"
 #include "sim_tmxr.h"
 #define UNIT_DUMMY      (1 << UNIT_V_UF)

 extern int32 tmxr_poll;
 t_stat fei_svc (UNIT *uptr);
 t_stat feo_svc (UNIT *uptr);
 static t_stat kaf_svc (UNIT *uptr);
 t_stat fe_reset (DEVICE *dptr);
 t_stat fe_stop_os (UNIT *uptr, int32 val, CONST char *cptr, void *desc);
 a10 fe_xct = 0;
 uint32 fe_bootrh = 0;
 int32 fe_bootunit = -1;
 extern DIB *dib_tab[];

 /* FE data structures

    fe_dev       FE device descriptor
    fe_unit      FE unit descriptor
    fe_reg       FE register list
 */

 #define fei_unit        fe_unit[0]
 #define feo_unit        fe_unit[1]
 #define kaf_unit        fe_unit[2]

 UNIT fe_unit[] = {
     { UDATA (&fei_svc, UNIT_IDLE, 0), 0 },
     { UDATA (&feo_svc, 0, 0), SERIAL_OUT_WAIT },
     { UDATA (&kaf_svc, 0, 0), (1*1000*1000) }
     };

 REG fe_reg[] = {
     { ORDATAD (IBUF, fei_unit.buf, 8, "input buffer") },
     { DRDATAD (ICOUNT, fei_unit.pos, T_ADDR_W, "count of input characters"), REG_RO + PV_LEFT },
     { DRDATAD (ITIME, fei_unit.wait, 24, "input polling interval (if 0, the keyboard is polled                            synchronously with the clock"), PV_LEFT },
     { ORDATAD (OBUF, feo_unit.buf, 8, "output buffer") },
     { DRDATAD (OCOUNT, feo_unit.pos, T_ADDR_W, "count of output characters"), REG_RO + PV_LEFT },
     { DRDATAD (OTIME, feo_unit.wait, 24, "console output response time"), REG_NZ + PV_LEFT },
     { NULL }
     };

 MTAB fe_mod[] = {
     { UNIT_DUMMY, 0, NULL, "STOP", &fe_stop_os },
     { 0 }
     };

 DEVICE fe_dev = {
     "FE", fe_unit, fe_reg, fe_mod,
     3, 10, 31, 1, 8, 8,
     NULL, NULL, &fe_reset,
     NULL, NULL, NULL
     };

 /* Front end processor (console terminal)

    Communications between the KS10 and its front end is based on an in-memory
    status block and two interrupt lines: interrupt-to-control (APR_ITC) and
    interrupt-from-console (APR_CON).  When the KS10 wants to print a character
    on the terminal,

    1. It places a character, plus the valid flag, in FE_CTYOUT.
    2. It interrupts the front end processor.
    3. The front end processor types the character and then zeroes FE_CTYOUT.
    4. The front end procesor interrupts the KS10.

    When the front end wants to send an input character to the KS10,

    1. It places a character, plus the valid flag, in FE_CTYIN.
    2. It interrupts the KS10.
    3. It waits for the KS10 to take the character and clear the valid flag.
    4. It can then send more input (the KS10 may signal this by interrupting
       the front end).

    Note that the protocol has both ambiguity (interrupt to the KS10 may mean
    character printed, or input character available, or both) and lack of
    symmetry (the KS10 does not inform the front end that it has taken an
    input character).
 */

 /* Here is the definition of the communications area:
 XPP RLWORD,31           ;RELOAD WORD  [FE_KEEPA]
     KSRLD==1B4          ;RELOAD REQUEST    (8080 will reload -10 if this is set)
     KPACT==1B5          ;KEEP ALIVE ACTIVE (8080 reloads -10 if KPALIV doesn't change)
     KLACT==1B6          ;KLINIK ACTIVE     (Remote diagnosis line enabled)
     PAREN==1B7          ;PARITY ERROR DETECT ENABLED
     CRMPAR==1B8         ;CRAM PAR ERR DETECT ENABLED
     DRMPAR==1B9         ;DRAM PAR ERR DETECT ENABLED
     CASHEN==1B10        ;CACHE ENABLED
     MILSEN==1B11        ;1MSEC ENABLED
     TRPENA==1B12        ;TRAPS ENABLED
     MFGMOD==1B13        ;MANUFACTURING MODE
     KPALIV==377B27      ;KEEP ALIVE WORD CHECKED EVERY 1 SEC, AFTER 15, FAIL
     ; Why reload (8080->10)
     AUTOBT==1B32        ;BOOT SWITCH OR POWER UP CONDITION
     PWRFAL==1B33        ;POWER FAIL restart (Start at 70)
     FORREL==1B34        ;FORCED RELOAD
     KEPFAL==1B35        ;KEEP ALIVE FAILURE (XCT exec 71)

 XPP CTYIWD,32       ;CTY INPUT WORD [FE_CTYIN]
     CTYICH==377B35      ;CTY INPUT CHARACTER
     CTYIVL==1B27        ;INPUT VALID BIT (Actually, this is an 8-bit function code)

 XPP CTYOWD,33       ;CTY OUTPUT WORD [FE_CTYOUT]
     CTYOCH==377B35      ;CTY OUTPUT CHARACTER
     CTYOVL==1B27        ;OUTPUT VALID FLAG

 XPP KLIIWD,34       ;KLINIK INPUT WORD [FE_KLININ]
     KLIICH==377B35      ;KLINIK INPUT CHARACTER
     KLIIVL==1B27        ;KLINIK INPUT VALID (Historical)
     KLICHR==1B27        ;KLINIK CHARACTER
     KLIINI==2B27        ;KLINIK INITED
     KLICAR==3B27        ;CARRIER LOST


 XPP KLIOWD,35       ;KLINIK OUTPUT WORD [FE_KLINOUT]
     KLIOCH==377B35      ;KLINIK OUTPUT CHARACTER
     KLIOVL==1B27        ;KLINIK OUTPUT VALID (Historical)
     KLOCHR==1B27        ;KLINIK CHARACTER AVAILABLE
     KLIHUP==2B27        ;KLINIK HANGUP REQUEST
 */

 void fe_intr (void)
 {
 if (M[FE_CTYOUT] & FE_CVALID) {                         /* char to print? */
     feo_unit.buf = (int32) M[FE_CTYOUT] & 0177;         /* pick it up */
     feo_unit.pos = feo_unit.pos + 1;
     sim_activate (&feo_unit, feo_unit.wait);            /* sched completion */
     }
 else if ((M[FE_CTYIN] & FE_CVALID) == 0) {              /* input char taken? */
     sim_cancel (&fei_unit);                             /* sched immediate */
     sim_activate (&fei_unit, 0);                        /* keyboard poll */
     }
 return;
 }

 t_stat feo_svc (UNIT *uptr)
 {
 t_stat r;

 if ((r = sim_putchar_s (uptr->buf)) != SCPE_OK) {       /* output; error? */
     sim_activate (uptr, uptr->wait);                    /* try again */
     return ((r == SCPE_STALL)? SCPE_OK: r);             /* !stall? report */
     }
 M[FE_CTYOUT] = 0;                                       /* clear char */
 apr_flg = apr_flg | APRF_CON;                           /* interrupt KS10 */
 return SCPE_OK;
 }

 t_stat fei_svc (UNIT *uptr)
 {
 int32 temp;

 sim_clock_coschedule (uptr, tmxr_poll);                 /* continue poll */
 if ((temp = sim_poll_kbd ()) < SCPE_KFLAG)              /* no char or error? */
     return temp;
 if (temp & SCPE_BREAK)                                  /* ignore break */
     return SCPE_OK;
 uptr->buf = temp & 0177;
 uptr->pos = uptr->pos + 1;
 M[FE_CTYIN] = uptr->buf | FE_CVALID;                    /* put char in mem */
 apr_flg = apr_flg | APRF_CON;                           /* interrupt KS10 */
 return SCPE_OK;
 }

 /* Keep-alive service
  * If the 8080 detects the 'force reload' bit, it initiates a disk
  * boot.  IO is reset, but memory is preserved.
  *
  * If the keep-alive enable bit is set, the -10 updates the keep-alive
  * count field every second.  The 8080 also checks the word every second.
  * If the 8080 finds that the count hasn't changed for 15 consecutive seconds,
  * a Keep-Alive Failure is declared.  This forces the -10 to execute the
  * contents of exec location 71 to collect status and initiate error recovery.
  */
 static t_stat kaf_svc (UNIT *uptr)
 {
 if (M[FE_KEEPA] & INT64_C(0020000000000)) {              /* KSRLD - "Forced" (actually, requested) reload */
     uint32 oldsw = sim_switches;
     DEVICE *bdev = NULL;
     int32 i;

     sim_switches &= ~SWMASK ('P');
     reset_all (4);                                      /* RESET IO starting with UBA */
     sim_switches = oldsw;

     M[FE_KEEPA] &= ~INT64_C(0030000177777);             /* Clear KAF, RLD, KPALIV & reason
                                                          * 8080 ucode actually clears HW
                                                          * status too, but that's a bug. */
     M[FE_KEEPA] |= 02;                                  /* Reason = FORREL */
     fei_unit.buf = feo_unit.buf = 0;
     M[FE_CTYIN] = M[FE_CTYOUT] = 0;
     M[FE_KLININ] = M[FE_KLINOUT] = 0;

     /* The 8080 has the disk RH address & unit in its memory, even if
      * the previous boot was from tape.  It has no NVM, so the last opr
      * selection will do here.  The case of DS MT <rld> would require a
      * SET FE command.  It's not a common case.
      */

     /* The device may have been detached, disabled or reconfigured since boot time.
      * Therefore, search for it by CSR address & validate that it's bootable.
      * If there are problems, the processor is halted.
      */

     for (i = 0; fe_bootrh && (bdev = sim_devices[i]) != NULL; i++ ) {
         DIB *dibp = (DIB *)bdev->ctxt;
         if (dibp && (fe_bootrh >= dibp->ba) &&
            (fe_bootrh < (dibp->ba + dibp->lnt))) {
             break;
             }
         }

     fe_xct = 2;
     if ((bdev != NULL) && (fe_bootunit >= 0) && (fe_bootunit < (int32) bdev->numunits)) {
         UNIT *bunit = bdev->units + fe_bootunit;

         if (!(bunit->flags & UNIT_DIS) && (bunit->flags & UNIT_ATTABLE) && (bunit->flags & UNIT_ATT)) {
             if (bdev->boot (fe_bootunit, bdev) == SCPE_OK) /* boot the device */
                 fe_xct = 1;
             }
         }
     }
 else if (M[FE_KEEPA] & INT64_C(0010000000000)) {        /* KPACT */
     d10 kav = M[FE_KEEPA] & INT64_C(0000000177400);     /* KPALIV */
     if (kaf_unit.u3 != (int32)kav) {
         kaf_unit.u3 = (int32)kav;
         kaf_unit.u4 = 0;
         }
     else if (++kaf_unit.u4 >= 15) {
         kaf_unit.u4 = 0;
         M[FE_KEEPA] = (M[FE_KEEPA] & ~INT64_C(0000000000377)) | 01; /* RSN = KAF (leaves enabled) */
         fei_unit.buf = feo_unit.buf = 0;
         M[FE_CTYIN] = M[FE_CTYOUT] = 0;
         M[FE_KLININ] = M[FE_KLINOUT] = 0;
         fe_xct = 071;
         }
     }

 sim_activate_after (&kaf_unit, kaf_unit.wait);
 if (fe_xct == 2) {
     fe_xct = 0;
     return STOP_CONSOLE;
     }
 return SCPE_OK;
 }
 /* Reset */

 t_stat fe_reset (DEVICE *dptr)
 {
 tmxr_set_console_units (&fe_unit[0], &fe_unit[1]);
 fei_unit.buf = feo_unit.buf = 0;

 M[FE_CTYIN] = M[FE_CTYOUT] = 0;
 M[FE_KLININ] = M[FE_KLINOUT] = 0;

 M[FE_KEEPA] = INT64_C(0003740000000);                  /* PARITY STOP, CRM, DP PAREN, CACHE EN, 1MSTMR, TRAPEN */
 kaf_unit.u3 = 0;
 kaf_unit.u4 = 0;
 apr_flg = apr_flg & ~(APRF_ITC | APRF_CON);
 sim_activate (&fei_unit, tmxr_poll);
 sim_activate_after (&kaf_unit, kaf_unit.wait);
 return SCPE_OK;
 }

 /* Stop operating system */

 t_stat fe_stop_os (UNIT *uptr, int32 val, CONST char *cptr, void *desc)
 {
 M[FE_SWITCH] = IOBA_RP;                                 /* tell OS to stop */
 return SCPE_OK;
 }
	/* pdp10_fe.c: PDP-10 front end (console terminal) simulator

	Copyright (c) 1993-2012, Robert M Supnik

	Permission is hereby granted, free of charge, to any person obtaining a
	copy of this software and associated documentation files (the "Software"),
	to deal in the Software without restriction, including without limitation
	the rights to use, copy, modify, merge, publish, distribute, sublicense,
	and/or sell copies of the Software, and to permit persons to whom the
	Software is furnished to do so, subject to the following conditions:

	The above copyright notice and this permission notice shall be included in
	all copies or substantial portions of the Software.

	THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
	ROBERT M SUPNIK BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
	IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
	CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.

	Except as contained in this notice, the name of Robert M Supnik shall not be
	used in advertising or otherwise to promote the sale, use or other dealings
	in this Software without prior written authorization from Robert M Supnik.

	fe KS10 console front end

	18-Apr-12 RMS Added clock coscheduling
	18-Jun-07 RMS Added UNIT_IDLE flag to console input
	17-Oct-06 RMS Synced keyboard to clock for idling
	28-May-04 RMS Removed SET FE CTRL-C
	29-Dec-03 RMS Added console backpressure support
	25-Apr-03 RMS Revised for extended file support
	22-Dec-02 RMS Added break support
	30-May-02 RMS Widened COUNT to 32b
	30-Nov-01 RMS Added extended SET/SHOW support
	23-Oct-01 RMS New IO page address constants
	07-Sep-01 RMS Moved function prototypes
	*/

	#include "pdp10_defs.h"
	#include "sim_tmxr.h"
	#define UNIT_DUMMY (1 << UNIT_V_UF)

	extern int32 tmxr_poll;
	t_stat fei_svc (UNIT *uptr);
	t_stat feo_svc (UNIT *uptr);
	static t_stat kaf_svc (UNIT *uptr);
	t_stat fe_reset (DEVICE *dptr);
	t_stat fe_stop_os (UNIT uptr, int32 val, CONST char cptr, void *desc);
	a10 fe_xct = 0;
	uint32 fe_bootrh = 0;
	int32 fe_bootunit = -1;
	extern DIB *dib_tab[];

	/* FE data structures

	fe_dev FE device descriptor
	fe_unit FE unit descriptor
	fe_reg FE register list
	*/

	#define fei_unit fe_unit[0]
	#define feo_unit fe_unit[1]
	#define kaf_unit fe_unit[2]

	UNIT fe_unit[] = {
	{ UDATA (&fei_svc, UNIT_IDLE, 0), 0 },
	{ UDATA (&feo_svc, 0, 0), SERIAL_OUT_WAIT },
	{ UDATA (&kaf_svc, 0, 0), (110001000) }
	};

	REG fe_reg[] = {
	{ ORDATAD (IBUF, fei_unit.buf, 8, "input buffer") },
	{ DRDATAD (ICOUNT, fei_unit.pos, T_ADDR_W, "count of input characters"), REG_RO + PV_LEFT },
	{ DRDATAD (ITIME, fei_unit.wait, 24, "input polling interval (if 0, the keyboard is polled synchronously with the clock"), PV_LEFT },
	{ ORDATAD (OBUF, feo_unit.buf, 8, "output buffer") },
	{ DRDATAD (OCOUNT, feo_unit.pos, T_ADDR_W, "count of output characters"), REG_RO + PV_LEFT },
	{ DRDATAD (OTIME, feo_unit.wait, 24, "console output response time"), REG_NZ + PV_LEFT },
	{ NULL }
	};

	MTAB fe_mod[] = {
	{ UNIT_DUMMY, 0, NULL, "STOP", &fe_stop_os },
	{ 0 }
	};

	DEVICE fe_dev = {
	"FE", fe_unit, fe_reg, fe_mod,
	3, 10, 31, 1, 8, 8,
	NULL, NULL, &fe_reset,
	NULL, NULL, NULL
	};

	/* Front end processor (console terminal)

	Communications between the KS10 and its front end is based on an in-memory
	status block and two interrupt lines: interrupt-to-control (APR_ITC) and
	interrupt-from-console (APR_CON). When the KS10 wants to print a character
	on the terminal,

	1. It places a character, plus the valid flag, in FE_CTYOUT.
	2. It interrupts the front end processor.
	3. The front end processor types the character and then zeroes FE_CTYOUT.
	4. The front end procesor interrupts the KS10.

	When the front end wants to send an input character to the KS10,

	1. It places a character, plus the valid flag, in FE_CTYIN.
	2. It interrupts the KS10.
	3. It waits for the KS10 to take the character and clear the valid flag.
	4. It can then send more input (the KS10 may signal this by interrupting
	the front end).

	Note that the protocol has both ambiguity (interrupt to the KS10 may mean
	character printed, or input character available, or both) and lack of
	symmetry (the KS10 does not inform the front end that it has taken an
	input character).
	*/

	/* Here is the definition of the communications area:
	XPP RLWORD,31 ;RELOAD WORD [FE_KEEPA]
	KSRLD==1B4 ;RELOAD REQUEST (8080 will reload -10 if this is set)
	KPACT==1B5 ;KEEP ALIVE ACTIVE (8080 reloads -10 if KPALIV doesn't change)
	KLACT==1B6 ;KLINIK ACTIVE (Remote diagnosis line enabled)
	PAREN==1B7 ;PARITY ERROR DETECT ENABLED
	CRMPAR==1B8 ;CRAM PAR ERR DETECT ENABLED
	DRMPAR==1B9 ;DRAM PAR ERR DETECT ENABLED
	CASHEN==1B10 ;CACHE ENABLED
	MILSEN==1B11 ;1MSEC ENABLED
	TRPENA==1B12 ;TRAPS ENABLED
	MFGMOD==1B13 ;MANUFACTURING MODE
	KPALIV==377B27 ;KEEP ALIVE WORD CHECKED EVERY 1 SEC, AFTER 15, FAIL
	; Why reload (8080->10)
	AUTOBT==1B32 ;BOOT SWITCH OR POWER UP CONDITION
	PWRFAL==1B33 ;POWER FAIL restart (Start at 70)
	FORREL==1B34 ;FORCED RELOAD
	KEPFAL==1B35 ;KEEP ALIVE FAILURE (XCT exec 71)

	XPP CTYIWD,32 ;CTY INPUT WORD [FE_CTYIN]
	CTYICH==377B35 ;CTY INPUT CHARACTER
	CTYIVL==1B27 ;INPUT VALID BIT (Actually, this is an 8-bit function code)

	XPP CTYOWD,33 ;CTY OUTPUT WORD [FE_CTYOUT]
	CTYOCH==377B35 ;CTY OUTPUT CHARACTER
	CTYOVL==1B27 ;OUTPUT VALID FLAG

	XPP KLIIWD,34 ;KLINIK INPUT WORD [FE_KLININ]
	KLIICH==377B35 ;KLINIK INPUT CHARACTER
	KLIIVL==1B27 ;KLINIK INPUT VALID (Historical)
	KLICHR==1B27 ;KLINIK CHARACTER
	KLIINI==2B27 ;KLINIK INITED
	KLICAR==3B27 ;CARRIER LOST


	XPP KLIOWD,35 ;KLINIK OUTPUT WORD [FE_KLINOUT]
	KLIOCH==377B35 ;KLINIK OUTPUT CHARACTER
	KLIOVL==1B27 ;KLINIK OUTPUT VALID (Historical)
	KLOCHR==1B27 ;KLINIK CHARACTER AVAILABLE
	KLIHUP==2B27 ;KLINIK HANGUP REQUEST
	*/

	void fe_intr (void)
	{
	if (M[FE_CTYOUT] & FE_CVALID) { /* char to print? */
	feo_unit.buf = (int32) M[FE_CTYOUT] & 0177; /* pick it up */
	feo_unit.pos = feo_unit.pos + 1;
	sim_activate (&feo_unit, feo_unit.wait); /* sched completion */
	}
	else if ((M[FE_CTYIN] & FE_CVALID) == 0) { /* input char taken? */
	sim_cancel (&fei_unit); /* sched immediate */
	sim_activate (&fei_unit, 0); /* keyboard poll */
	}
	return;
	}

	t_stat feo_svc (UNIT *uptr)
	{
	t_stat r;

	if ((r = sim_putchar_s (uptr->buf)) != SCPE_OK) { /* output; error? */
	sim_activate (uptr, uptr->wait); /* try again */
	return ((r == SCPE_STALL)? SCPE_OK: r); /* !stall? report */
	}
	M[FE_CTYOUT] = 0; /* clear char */
	apr_flg = apr_flg \| APRF_CON; /* interrupt KS10 */
	return SCPE_OK;
	}

	t_stat fei_svc (UNIT *uptr)
	{
	int32 temp;

	sim_clock_coschedule (uptr, tmxr_poll); /* continue poll */
	if ((temp = sim_poll_kbd ()) < SCPE_KFLAG) /* no char or error? */
	return temp;
	if (temp & SCPE_BREAK) /* ignore break */
	return SCPE_OK;
	uptr->buf = temp & 0177;
	uptr->pos = uptr->pos + 1;
	M[FE_CTYIN] = uptr->buf \| FE_CVALID; /* put char in mem */
	apr_flg = apr_flg \| APRF_CON; /* interrupt KS10 */
	return SCPE_OK;
	}

	/* Keep-alive service
	* If the 8080 detects the 'force reload' bit, it initiates a disk
	* boot. IO is reset, but memory is preserved.
	*
	* If the keep-alive enable bit is set, the -10 updates the keep-alive
	* count field every second. The 8080 also checks the word every second.
	* If the 8080 finds that the count hasn't changed for 15 consecutive seconds,
	* a Keep-Alive Failure is declared. This forces the -10 to execute the
	* contents of exec location 71 to collect status and initiate error recovery.
	*/
	static t_stat kaf_svc (UNIT *uptr)
	{
	if (M[FE_KEEPA] & INT64_C(0020000000000)) { /* KSRLD - "Forced" (actually, requested) reload */
	uint32 oldsw = sim_switches;
	DEVICE *bdev = NULL;
	int32 i;

	sim_switches &= ~SWMASK ('P');
	reset_all (4); /* RESET IO starting with UBA */
	sim_switches = oldsw;

	M[FE_KEEPA] &= ~INT64_C(0030000177777); /* Clear KAF, RLD, KPALIV & reason
	* 8080 ucode actually clears HW
	* status too, but that's a bug. */
	M[FE_KEEPA] \|= 02; /* Reason = FORREL */
	fei_unit.buf = feo_unit.buf = 0;
	M[FE_CTYIN] = M[FE_CTYOUT] = 0;
	M[FE_KLININ] = M[FE_KLINOUT] = 0;

	/* The 8080 has the disk RH address & unit in its memory, even if
	* the previous boot was from tape. It has no NVM, so the last opr
	* selection will do here. The case of DS MT <rld> would require a
	* SET FE command. It's not a common case.
	*/

	/* The device may have been detached, disabled or reconfigured since boot time.
	* Therefore, search for it by CSR address & validate that it's bootable.
	* If there are problems, the processor is halted.
	*/

	for (i = 0; fe_bootrh && (bdev = sim_devices[i]) != NULL; i++ ) {
	DIB dibp = (DIB )bdev->ctxt;
	if (dibp && (fe_bootrh >= dibp->ba) &&
	(fe_bootrh < (dibp->ba + dibp->lnt))) {
	break;
	}
	}

	fe_xct = 2;
	if ((bdev != NULL) && (fe_bootunit >= 0) && (fe_bootunit < (int32) bdev->numunits)) {
	UNIT *bunit = bdev->units + fe_bootunit;

	if (!(bunit->flags & UNIT_DIS) && (bunit->flags & UNIT_ATTABLE) && (bunit->flags & UNIT_ATT)) {
	if (bdev->boot (fe_bootunit, bdev) == SCPE_OK) /* boot the device */
	fe_xct = 1;
	}
	}
	}
	else if (M[FE_KEEPA] & INT64_C(0010000000000)) { /* KPACT */
	d10 kav = M[FE_KEEPA] & INT64_C(0000000177400); /* KPALIV */
	if (kaf_unit.u3 != (int32)kav) {
	kaf_unit.u3 = (int32)kav;
	kaf_unit.u4 = 0;
	}
	else if (++kaf_unit.u4 >= 15) {
	kaf_unit.u4 = 0;
	M[FE_KEEPA] = (M[FE_KEEPA] & ~INT64_C(0000000000377)) \| 01; /* RSN = KAF (leaves enabled) */
	fei_unit.buf = feo_unit.buf = 0;
	M[FE_CTYIN] = M[FE_CTYOUT] = 0;
	M[FE_KLININ] = M[FE_KLINOUT] = 0;
	fe_xct = 071;
	}
	}

	sim_activate_after (&kaf_unit, kaf_unit.wait);
	if (fe_xct == 2) {
	fe_xct = 0;
	return STOP_CONSOLE;
	}
	return SCPE_OK;
	}
	/* Reset */

	t_stat fe_reset (DEVICE *dptr)
	{
	tmxr_set_console_units (&fe_unit[0], &fe_unit[1]);
	fei_unit.buf = feo_unit.buf = 0;

	M[FE_CTYIN] = M[FE_CTYOUT] = 0;
	M[FE_KLININ] = M[FE_KLINOUT] = 0;

	M[FE_KEEPA] = INT64_C(0003740000000); /* PARITY STOP, CRM, DP PAREN, CACHE EN, 1MSTMR, TRAPEN */
	kaf_unit.u3 = 0;
	kaf_unit.u4 = 0;
	apr_flg = apr_flg & ~(APRF_ITC \| APRF_CON);
	sim_activate (&fei_unit, tmxr_poll);
	sim_activate_after (&kaf_unit, kaf_unit.wait);
	return SCPE_OK;
	}

	/* Stop operating system */

	t_stat fe_stop_os (UNIT uptr, int32 val, CONST char cptr, void *desc)
	{
	M[FE_SWITCH] = IOBA_RP; /* tell OS to stop */
	return SCPE_OK;
	}