PDP8/pdp8_rf.c - emulators/simh - Rivoreo Source Code Repositories

 /* pdp8_rf.c: RF08 fixed head disk simulator

    Copyright (c) 1993-2013, 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.

    rf           RF08 fixed head disk

    17-Sep-13    RMS     Changed to use central set_bootpc routine
    03-Sep-13    RMS     Added explicit void * cast
    15-May-06    RMS     Fixed bug in autosize attach (Dave Gesswein)
    07-Jan-06    RMS     Fixed unaligned register access bug (Doug Carman)
    04-Jan-04    RMS     Changed sim_fsize calling sequence
    26-Oct-03    RMS     Cleaned up buffer copy code
    26-Jul-03    RMS     Fixed bug in set size routine
    14-Mar-03    RMS     Fixed variable platter interaction with save/restore
    03-Mar-03    RMS     Fixed autosizing
    02-Feb-03    RMS     Added variable platter and autosizing support
    04-Oct-02    RMS     Added DIB, device number support
    28-Nov-01    RMS     Added RL8A support
    25-Apr-01    RMS     Added device enable/disable support
    19-Mar-01    RMS     Added disk monitor bootstrap, fixed IOT decoding
    15-Feb-01    RMS     Fixed 3 cycle data break sequence
    14-Apr-99    RMS     Changed t_addr to unsigned
    30-Mar-98    RMS     Fixed bug in RF bootstrap

    The RF08 is a head-per-track disk.  It uses the three cycle data break
    facility.  To minimize overhead, the entire RF08 is buffered in memory.

    Two timing parameters are provided:

    rf_time      Interword timing, must be non-zero
    rf_burst     Burst mode, if 0, DMA occurs cycle by cycle; otherwise,
                 DMA occurs in a burst
 */

 #include "pdp8_defs.h"
 #include <math.h>

 #define UNIT_V_AUTO     (UNIT_V_UF + 0)                 /* autosize */
 #define UNIT_V_PLAT     (UNIT_V_UF + 1)                 /* #platters - 1 */
 #define UNIT_M_PLAT     03
 #define UNIT_GETP(x)    ((((x) >> UNIT_V_PLAT) & UNIT_M_PLAT) + 1)
 #define UNIT_AUTO       (1 << UNIT_V_AUTO)
 #define UNIT_PLAT       (UNIT_M_PLAT << UNIT_V_PLAT)

 /* Constants */

 #define RF_NUMWD        2048                            /* words/track */
 #define RF_NUMTR        128                             /* tracks/disk */
 #define RF_DKSIZE       (RF_NUMTR * RF_NUMWD)           /* words/disk */
 #define RF_NUMDK        4                               /* disks/controller */
 #define RF_WC           07750                           /* word count */
 #define RF_MA           07751                           /* mem address */
 #define RF_WMASK        (RF_NUMWD - 1)                  /* word mask */

 /* Parameters in the unit descriptor */

 #define FUNC            u4                              /* function */
 #define RF_READ         2                               /* read */
 #define RF_WRITE        4                               /* write */

 /* Status register */

 #define RFS_PCA         04000                           /* photocell status */
 #define RFS_DRE         02000                           /* data req enable */
 #define RFS_WLS         01000                           /* write lock status */
 #define RFS_EIE         00400                           /* error int enable */
 #define RFS_PIE         00200                           /* photocell int enb */
 #define RFS_CIE         00100                           /* done int enable */
 #define RFS_MEX         00070                           /* memory extension */
 #define RFS_DRL         00004                           /* data late error */
 #define RFS_NXD         00002                           /* non-existent disk */
 #define RFS_PER         00001                           /* parity error */
 #define RFS_ERR         (RFS_WLS + RFS_DRL + RFS_NXD + RFS_PER)
 #define RFS_V_MEX       3

 #define GET_MEX(x)      (((x) & RFS_MEX) << (12 - RFS_V_MEX))
 #define GET_POS(x)      ((int) fmod (sim_gtime() / ((double) (x)), \
                         ((double) RF_NUMWD)))
 #define UPDATE_PCELL    if (GET_POS(rf_time) < 6) rf_sta = rf_sta | RFS_PCA; \
                         else rf_sta = rf_sta & ~RFS_PCA
 #define RF_INT_UPDATE   if ((rf_done && (rf_sta & RFS_CIE)) || \
                             ((rf_sta & RFS_ERR) && (rf_sta & RFS_EIE)) || \
                             ((rf_sta & RFS_PCA) && (rf_sta & RFS_PIE))) \
                             int_req = int_req | INT_RF; \
                         else int_req = int_req & ~INT_RF

 extern uint16 M[];
 extern int32 int_req, stop_inst;
 extern UNIT cpu_unit;

 int32 rf_sta = 0;                                       /* status register */
 int32 rf_da = 0;                                        /* disk address */
 int32 rf_done = 0;                                      /* done flag */
 int32 rf_wlk = 0;                                       /* write lock */
 int32 rf_time = 10;                                     /* inter-word time */
 int32 rf_burst = 1;                                     /* burst mode flag */
 int32 rf_stopioe = 1;                                   /* stop on error */

 int32 rf60 (int32 IR, int32 AC);
 int32 rf61 (int32 IR, int32 AC);
 int32 rf62 (int32 IR, int32 AC);
 int32 rf64 (int32 IR, int32 AC);
 t_stat rf_svc (UNIT *uptr);
 t_stat pcell_svc (UNIT *uptr);
 t_stat rf_reset (DEVICE *dptr);
 t_stat rf_boot (int32 unitno, DEVICE *dptr);
 t_stat rf_attach (UNIT *uptr, CONST char *cptr);
 t_stat rf_set_size (UNIT *uptr, int32 val, CONST char *cptr, void *desc);

 /* RF08 data structures

    rf_dev       RF device descriptor
    rf_unit      RF unit descriptor
    pcell_unit   photocell timing unit (orphan)
    rf_reg       RF register list
 */

 DIB rf_dib = { DEV_RF, 5, { &rf60, &rf61, &rf62, NULL, &rf64 } };

 UNIT rf_unit = {
     UDATA (&rf_svc, UNIT_FIX+UNIT_ATTABLE+
            UNIT_BUFABLE+UNIT_MUSTBUF, RF_DKSIZE)
     };

 UNIT pcell_unit = { UDATA (&pcell_svc, 0, 0) };

 REG rf_reg[] = {
     { ORDATAD (STA, rf_sta, 12, "status") },
     { ORDATAD (DA, rf_da, 20, "low order disk address") },
     { ORDATAD (WC, M[RF_WC], 12, "word count (in memory)"), REG_FIT },
     { ORDATAD (MA, M[RF_MA], 12, "memory address (in memory)"), REG_FIT },
     { FLDATAD (DONE, rf_done, 0, "device done flag") },
     { FLDATAD (INT, int_req, INT_V_RF, "interrupt pending flag") },
     { ORDATAD (WLK, rf_wlk, 32, "write lock switches") },
     { DRDATAD (TIME, rf_time, 24, "rotational delay, per word"), REG_NZ + PV_LEFT },
     { FLDATAD (BURST, rf_burst, 0, "burst flag") },
     { FLDATAD (STOP_IOE, rf_stopioe, 0, "stop on I/O error") },
     { DRDATA (CAPAC, rf_unit.capac, 21), REG_HRO },
     { ORDATA (DEVNUM, rf_dib.dev, 6), REG_HRO },
     { NULL }
     };

 MTAB rf_mod[] = {
     { UNIT_PLAT, (0 << UNIT_V_PLAT), NULL, "1P", &rf_set_size },
     { UNIT_PLAT, (1 << UNIT_V_PLAT), NULL, "2P", &rf_set_size },
     { UNIT_PLAT, (2 << UNIT_V_PLAT), NULL, "3P", &rf_set_size },
     { UNIT_PLAT, (3 << UNIT_V_PLAT), NULL, "4P", &rf_set_size },
     { UNIT_AUTO, UNIT_AUTO, "autosize", "AUTOSIZE", NULL },
     { MTAB_XTD|MTAB_VDV, 0, "DEVNO", "DEVNO",
       &set_dev, &show_dev, NULL },
     { 0 }
     };

 DEVICE rf_dev = {
     "RF", &rf_unit, rf_reg, rf_mod,
     1, 8, 20, 1, 8, 12,
     NULL, NULL, &rf_reset,
     &rf_boot, &rf_attach, NULL,
     &rf_dib, DEV_DISABLE | DEV_DIS
     };

 /* IOT routines */

 int32 rf60 (int32 IR, int32 AC)
 {
 int32 t;
 int32 pulse = IR & 07;

 UPDATE_PCELL;                                           /* update photocell */
 if (pulse & 1) {                                        /* DCMA */
     rf_da = rf_da & ~07777;                             /* clear DAR<8:19> */
     rf_done = 0;                                        /* clear done */
     rf_sta = rf_sta & ~RFS_ERR;                         /* clear errors */
     RF_INT_UPDATE;                                      /* update int req */
     }
 if (pulse & 6) {                                        /* DMAR, DMAW */
     rf_da = rf_da | AC;                                 /* DAR<8:19> |= AC */
     rf_unit.FUNC = pulse & ~1;                          /* save function */
     t = (rf_da & RF_WMASK) - GET_POS (rf_time);         /* delta to new loc */
     if (t < 0)                                          /* wrap around? */
         t = t + RF_NUMWD;
     sim_activate (&rf_unit, t * rf_time);               /* schedule op */
     AC = 0;                                             /* clear AC */
     }
 return AC;
 }

 int32 rf61 (int32 IR, int32 AC)
 {
 int32 pulse = IR & 07;

 UPDATE_PCELL;                                           /* update photocell */
 switch (pulse) {                                        /* decode IR<9:11> */

     case 1:                                             /* DCIM */
         rf_sta = rf_sta & 07007;                        /* clear STA<3:8> */
         int_req = int_req & ~INT_RF;                    /* clear int req */
         sim_cancel (&pcell_unit);                       /* cancel photocell */
         return AC;

     case 2:                                             /* DSAC */
         return ((rf_da & RF_WMASK) == GET_POS (rf_time))? IOT_SKP: 0;

     case 5:                                             /* DIML */
         rf_sta = (rf_sta & 07007) | (AC & 0770);        /* STA<3:8> <- AC */
         if (rf_sta & RFS_PIE)                           /* photocell int? */
             sim_activate (&pcell_unit, (RF_NUMWD - GET_POS (rf_time)) *
                 rf_time);
         else sim_cancel (&pcell_unit);
         RF_INT_UPDATE;                                  /* update int req */
         return 0;                                       /* clear AC */

     case 6:                                             /* DIMA */
         return rf_sta;                                  /* AC <- STA<0:11> */
         }

 return AC;
 }

 int32 rf62 (int32 IR, int32 AC)
 {
 int32 pulse = IR & 07;

 UPDATE_PCELL;                                           /* update photocell */
 if (pulse & 1) {                                        /* DFSE */
     if (rf_sta & RFS_ERR)
         AC = AC | IOT_SKP;
     }
 if (pulse & 2) {                                        /* DFSC */
     if (pulse & 4)                                      /* for DMAC */
         AC = AC & ~07777;
     else if (rf_done)
         AC = AC | IOT_SKP;
     }
 if (pulse & 4)                                          /* DMAC */
     AC = AC | (rf_da & 07777);
 return AC;
 }

 int32 rf64 (int32 IR, int32 AC)
 {
 int32 pulse = IR & 07;

 UPDATE_PCELL;                                           /* update photocell */
 switch (pulse) {                                        /* decode IR<9:11> */

     case 1:                                             /* DCXA */
         rf_da = rf_da & 07777;                          /* clear DAR<0:7> */
         break;

     case 3:                                             /* DXAL */
         rf_da = rf_da & 07777;                          /* clear DAR<0:7> */
     case 2:                                             /* DXAL w/o clear */
         rf_da = rf_da | ((AC & 0377) << 12);            /* DAR<0:7> |= AC */
         AC = 0;                                         /* clear AC */
         break;

     case 5:                                             /* DXAC */
         AC = 0;                                         /* clear AC */
     case 4:                                             /* DXAC w/o clear */
         AC = AC | ((rf_da >> 12) & 0377);               /* AC |= DAR<0:7> */
         break;

     default:
         AC = (stop_inst << IOT_V_REASON) + AC;
         break;
         }                                               /* end switch */

 if ((uint32) rf_da >= rf_unit.capac)
     rf_sta = rf_sta | RFS_NXD;
 else rf_sta = rf_sta & ~RFS_NXD;
 RF_INT_UPDATE;
 return AC;
 }

 /* Unit service

    Note that for reads and writes, memory addresses wrap around in the
    current field.  This code assumes the entire disk is buffered.
 */

 t_stat rf_svc (UNIT *uptr)
 {
 int32 pa, t, mex;
 int16 *fbuf = (int16 *) uptr->filebuf;

 UPDATE_PCELL;                                           /* update photocell */
 if ((uptr->flags & UNIT_BUF) == 0) {                    /* not buf? abort */
     rf_sta = rf_sta | RFS_NXD;
     rf_done = 1;
     RF_INT_UPDATE;                                      /* update int req */
     return IORETURN (rf_stopioe, SCPE_UNATT);
     }

 mex = GET_MEX (rf_sta);
 do {
     if ((uint32) rf_da >= rf_unit.capac) {              /* disk overflow? */
         rf_sta = rf_sta | RFS_NXD;
         break;
         }
     M[RF_WC] = (M[RF_WC] + 1) & 07777;                  /* incr word count */
     M[RF_MA] = (M[RF_MA] + 1) & 07777;                  /* incr mem addr */
     pa = mex | M[RF_MA];                                /* add extension */
     if (uptr->FUNC == RF_READ) {                        /* read? */
         if (MEM_ADDR_OK (pa))                           /* if !nxm */
             M[pa] = fbuf[rf_da];                        /* read word */
         }
     else {                                              /* write */
         t = ((rf_da >> 15) & 030) | ((rf_da >> 14) & 07);
         if ((rf_wlk >> t) & 1)                          /* write locked? */
             rf_sta = rf_sta | RFS_WLS;
         else {                                          /* not locked */
             fbuf[rf_da] = M[pa];                        /* write word */
             if (((uint32) rf_da) >= uptr->hwmark)
                 uptr->hwmark = rf_da + 1;
             }
         }
     rf_da = (rf_da + 1) & 03777777;                     /* incr disk addr */
     } while ((M[RF_WC] != 0) && (rf_burst != 0));       /* brk if wc, no brst */

 if ((M[RF_WC] != 0) && ((rf_sta & RFS_ERR) == 0))       /* more to do? */
     sim_activate (&rf_unit, rf_time);                   /* sched next */
 else {
     rf_done = 1;                                        /* done */
     RF_INT_UPDATE;                                      /* update int req */
     }
 return SCPE_OK;
 }

 /* Photocell unit service */

 t_stat pcell_svc (UNIT *uptr)
 {
 rf_sta = rf_sta | RFS_PCA;                              /* set photocell */
 if (rf_sta & RFS_PIE) {                                 /* int enable? */
     sim_activate (&pcell_unit, RF_NUMWD * rf_time);
     int_req = int_req | INT_RF;
     }
 return SCPE_OK;
 }

 /* Reset routine */

 t_stat rf_reset (DEVICE *dptr)
 {
 rf_sta = rf_da = 0;
 rf_done = 1;
 int_req = int_req & ~INT_RF;                            /* clear interrupt */
 sim_cancel (&rf_unit);
 sim_cancel (&pcell_unit);
 return SCPE_OK;
 }

 /* Bootstrap routine */

 #define OS8_START       07750
 #define OS8_LEN         (sizeof (os8_rom) / sizeof (int16))
 #define DM4_START       00200
 #define DM4_LEN         (sizeof (dm4_rom) / sizeof (int16))

 static const uint16 os8_rom[] = {
     07600,                      /* 7750, CLA CLL        ; also word count */
     06603,                      /* 7751, DMAR           ; also address */
     06622,                      /* 7752, DFSC           ; done? */
     05352,                      /* 7753, JMP .-1        ; no */
     05752                       /* 7754, JMP @.-2       ; enter boot */
     };

 static const uint16 dm4_rom[] = {
     00200, 07600,               /* 0200, CLA CLL */
     00201, 06603,               /* 0201, DMAR           ; read */
     00202, 06622,               /* 0202, DFSC           ; done? */
     00203, 05202,               /* 0203, JMP .-1        ; no */
     00204, 05600,               /* 0204, JMP @.-4       ; enter boot */
     07750, 07576,               /* 7750, 7576           ; word count */
     07751, 07576                /* 7751, 7576           ; address */
     };

 t_stat rf_boot (int32 unitno, DEVICE *dptr)
 {
 size_t i;

 if (rf_dib.dev != DEV_RF)                               /* only std devno */
     return STOP_NOTSTD;
 if (sim_switches & SWMASK ('D')) {
     for (i = 0; i < DM4_LEN; i = i + 2)
         M[dm4_rom[i]] = dm4_rom[i + 1];
     cpu_set_bootpc (DM4_START);
     }
 else {
     for (i = 0; i < OS8_LEN; i++)
         M[OS8_START + i] = os8_rom[i];
     cpu_set_bootpc (OS8_START);
     }
 return SCPE_OK;
 }

 /* Attach routine */

 t_stat rf_attach (UNIT *uptr, CONST char *cptr)
 {
 uint32 sz, p;
 uint32 ds_bytes = RF_DKSIZE * sizeof (int16);

 if ((uptr->flags & UNIT_AUTO) && (sz = sim_fsize_name (cptr))) {
     p = (sz + ds_bytes - 1) / ds_bytes;
     if (p >= RF_NUMDK)
         p = RF_NUMDK - 1;
     uptr->flags = (uptr->flags & ~UNIT_PLAT) |
         (p << UNIT_V_PLAT);
     }
 uptr->capac = UNIT_GETP (uptr->flags) * RF_DKSIZE;
 return attach_unit (uptr, cptr);
 }

 /* Change disk size */

 t_stat rf_set_size (UNIT *uptr, int32 val, CONST char *cptr, void *desc)
 {
 if (val < 0)
     return SCPE_IERR;
 if (uptr->flags & UNIT_ATT)
     return SCPE_ALATT;
 uptr->capac = UNIT_GETP (val) * RF_DKSIZE;
 uptr->flags = uptr->flags & ~UNIT_AUTO;
 return SCPE_OK;
 }
	/* pdp8_rf.c: RF08 fixed head disk simulator

	Copyright (c) 1993-2013, 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.

	rf RF08 fixed head disk

	17-Sep-13 RMS Changed to use central set_bootpc routine
	03-Sep-13 RMS Added explicit void * cast
	15-May-06 RMS Fixed bug in autosize attach (Dave Gesswein)
	07-Jan-06 RMS Fixed unaligned register access bug (Doug Carman)
	04-Jan-04 RMS Changed sim_fsize calling sequence
	26-Oct-03 RMS Cleaned up buffer copy code
	26-Jul-03 RMS Fixed bug in set size routine
	14-Mar-03 RMS Fixed variable platter interaction with save/restore
	03-Mar-03 RMS Fixed autosizing
	02-Feb-03 RMS Added variable platter and autosizing support
	04-Oct-02 RMS Added DIB, device number support
	28-Nov-01 RMS Added RL8A support
	25-Apr-01 RMS Added device enable/disable support
	19-Mar-01 RMS Added disk monitor bootstrap, fixed IOT decoding
	15-Feb-01 RMS Fixed 3 cycle data break sequence
	14-Apr-99 RMS Changed t_addr to unsigned
	30-Mar-98 RMS Fixed bug in RF bootstrap

	The RF08 is a head-per-track disk. It uses the three cycle data break
	facility. To minimize overhead, the entire RF08 is buffered in memory.

	Two timing parameters are provided:

	rf_time Interword timing, must be non-zero
	rf_burst Burst mode, if 0, DMA occurs cycle by cycle; otherwise,
	DMA occurs in a burst
	*/

	#include "pdp8_defs.h"
	#include <math.h>

	#define UNIT_V_AUTO (UNIT_V_UF + 0) /* autosize */
	#define UNIT_V_PLAT (UNIT_V_UF + 1) /* #platters - 1 */
	#define UNIT_M_PLAT 03
	#define UNIT_GETP(x) ((((x) >> UNIT_V_PLAT) & UNIT_M_PLAT) + 1)
	#define UNIT_AUTO (1 << UNIT_V_AUTO)
	#define UNIT_PLAT (UNIT_M_PLAT << UNIT_V_PLAT)

	/* Constants */

	#define RF_NUMWD 2048 /* words/track */
	#define RF_NUMTR 128 /* tracks/disk */
	#define RF_DKSIZE (RF_NUMTR * RF_NUMWD) /* words/disk */
	#define RF_NUMDK 4 /* disks/controller */
	#define RF_WC 07750 /* word count */
	#define RF_MA 07751 /* mem address */
	#define RF_WMASK (RF_NUMWD - 1) /* word mask */

	/* Parameters in the unit descriptor */

	#define FUNC u4 /* function */
	#define RF_READ 2 /* read */
	#define RF_WRITE 4 /* write */

	/* Status register */

	#define RFS_PCA 04000 /* photocell status */
	#define RFS_DRE 02000 /* data req enable */
	#define RFS_WLS 01000 /* write lock status */
	#define RFS_EIE 00400 /* error int enable */
	#define RFS_PIE 00200 /* photocell int enb */
	#define RFS_CIE 00100 /* done int enable */
	#define RFS_MEX 00070 /* memory extension */
	#define RFS_DRL 00004 /* data late error */
	#define RFS_NXD 00002 /* non-existent disk */
	#define RFS_PER 00001 /* parity error */
	#define RFS_ERR (RFS_WLS + RFS_DRL + RFS_NXD + RFS_PER)
	#define RFS_V_MEX 3

	#define GET_MEX(x) (((x) & RFS_MEX) << (12 - RFS_V_MEX))
	#define GET_POS(x) ((int) fmod (sim_gtime() / ((double) (x)), \
	((double) RF_NUMWD)))
	#define UPDATE_PCELL if (GET_POS(rf_time) < 6) rf_sta = rf_sta \| RFS_PCA; \
	else rf_sta = rf_sta & ~RFS_PCA
	#define RF_INT_UPDATE if ((rf_done && (rf_sta & RFS_CIE)) \|\| \
	((rf_sta & RFS_ERR) && (rf_sta & RFS_EIE)) \|\| \
	((rf_sta & RFS_PCA) && (rf_sta & RFS_PIE))) \
	int_req = int_req \| INT_RF; \
	else int_req = int_req & ~INT_RF

	extern uint16 M[];
	extern int32 int_req, stop_inst;
	extern UNIT cpu_unit;

	int32 rf_sta = 0; /* status register */
	int32 rf_da = 0; /* disk address */
	int32 rf_done = 0; /* done flag */
	int32 rf_wlk = 0; /* write lock */
	int32 rf_time = 10; /* inter-word time */
	int32 rf_burst = 1; /* burst mode flag */
	int32 rf_stopioe = 1; /* stop on error */

	int32 rf60 (int32 IR, int32 AC);
	int32 rf61 (int32 IR, int32 AC);
	int32 rf62 (int32 IR, int32 AC);
	int32 rf64 (int32 IR, int32 AC);
	t_stat rf_svc (UNIT *uptr);
	t_stat pcell_svc (UNIT *uptr);
	t_stat rf_reset (DEVICE *dptr);
	t_stat rf_boot (int32 unitno, DEVICE *dptr);
	t_stat rf_attach (UNIT uptr, CONST char cptr);
	t_stat rf_set_size (UNIT uptr, int32 val, CONST char cptr, void *desc);

	/* RF08 data structures

	rf_dev RF device descriptor
	rf_unit RF unit descriptor
	pcell_unit photocell timing unit (orphan)
	rf_reg RF register list
	*/

	DIB rf_dib = { DEV_RF, 5, { &rf60, &rf61, &rf62, NULL, &rf64 } };

	UNIT rf_unit = {
	UDATA (&rf_svc, UNIT_FIX+UNIT_ATTABLE+
	UNIT_BUFABLE+UNIT_MUSTBUF, RF_DKSIZE)
	};

	UNIT pcell_unit = { UDATA (&pcell_svc, 0, 0) };

	REG rf_reg[] = {
	{ ORDATAD (STA, rf_sta, 12, "status") },
	{ ORDATAD (DA, rf_da, 20, "low order disk address") },
	{ ORDATAD (WC, M[RF_WC], 12, "word count (in memory)"), REG_FIT },
	{ ORDATAD (MA, M[RF_MA], 12, "memory address (in memory)"), REG_FIT },
	{ FLDATAD (DONE, rf_done, 0, "device done flag") },
	{ FLDATAD (INT, int_req, INT_V_RF, "interrupt pending flag") },
	{ ORDATAD (WLK, rf_wlk, 32, "write lock switches") },
	{ DRDATAD (TIME, rf_time, 24, "rotational delay, per word"), REG_NZ + PV_LEFT },
	{ FLDATAD (BURST, rf_burst, 0, "burst flag") },
	{ FLDATAD (STOP_IOE, rf_stopioe, 0, "stop on I/O error") },
	{ DRDATA (CAPAC, rf_unit.capac, 21), REG_HRO },
	{ ORDATA (DEVNUM, rf_dib.dev, 6), REG_HRO },
	{ NULL }
	};

	MTAB rf_mod[] = {
	{ UNIT_PLAT, (0 << UNIT_V_PLAT), NULL, "1P", &rf_set_size },
	{ UNIT_PLAT, (1 << UNIT_V_PLAT), NULL, "2P", &rf_set_size },
	{ UNIT_PLAT, (2 << UNIT_V_PLAT), NULL, "3P", &rf_set_size },
	{ UNIT_PLAT, (3 << UNIT_V_PLAT), NULL, "4P", &rf_set_size },
	{ UNIT_AUTO, UNIT_AUTO, "autosize", "AUTOSIZE", NULL },
	{ MTAB_XTD\|MTAB_VDV, 0, "DEVNO", "DEVNO",
	&set_dev, &show_dev, NULL },
	{ 0 }
	};

	DEVICE rf_dev = {
	"RF", &rf_unit, rf_reg, rf_mod,
	1, 8, 20, 1, 8, 12,
	NULL, NULL, &rf_reset,
	&rf_boot, &rf_attach, NULL,
	&rf_dib, DEV_DISABLE \| DEV_DIS
	};

	/* IOT routines */

	int32 rf60 (int32 IR, int32 AC)
	{
	int32 t;
	int32 pulse = IR & 07;

	UPDATE_PCELL; /* update photocell */
	if (pulse & 1) { /* DCMA */
	rf_da = rf_da & ~07777; /* clear DAR<8:19> */
	rf_done = 0; /* clear done */
	rf_sta = rf_sta & ~RFS_ERR; /* clear errors */
	RF_INT_UPDATE; /* update int req */
	}
	if (pulse & 6) { /* DMAR, DMAW */
	rf_da = rf_da \| AC; /* DAR<8:19> \|= AC */
	rf_unit.FUNC = pulse & ~1; /* save function */
	t = (rf_da & RF_WMASK) - GET_POS (rf_time); /* delta to new loc */
	if (t < 0) /* wrap around? */
	t = t + RF_NUMWD;
	sim_activate (&rf_unit, t * rf_time); /* schedule op */
	AC = 0; /* clear AC */
	}
	return AC;
	}

	int32 rf61 (int32 IR, int32 AC)
	{
	int32 pulse = IR & 07;

	UPDATE_PCELL; /* update photocell */
	switch (pulse) { /* decode IR<9:11> */

	case 1: /* DCIM */
	rf_sta = rf_sta & 07007; /* clear STA<3:8> */
	int_req = int_req & ~INT_RF; /* clear int req */
	sim_cancel (&pcell_unit); /* cancel photocell */
	return AC;

	case 2: /* DSAC */
	return ((rf_da & RF_WMASK) == GET_POS (rf_time))? IOT_SKP: 0;

	case 5: /* DIML */
	rf_sta = (rf_sta & 07007) \| (AC & 0770); /* STA<3:8> <- AC */
	if (rf_sta & RFS_PIE) /* photocell int? */
	sim_activate (&pcell_unit, (RF_NUMWD - GET_POS (rf_time)) *
	rf_time);
	else sim_cancel (&pcell_unit);
	RF_INT_UPDATE; /* update int req */
	return 0; /* clear AC */

	case 6: /* DIMA */
	return rf_sta; /* AC <- STA<0:11> */
	}

	return AC;
	}

	int32 rf62 (int32 IR, int32 AC)
	{
	int32 pulse = IR & 07;

	UPDATE_PCELL; /* update photocell */
	if (pulse & 1) { /* DFSE */
	if (rf_sta & RFS_ERR)
	AC = AC \| IOT_SKP;
	}
	if (pulse & 2) { /* DFSC */
	if (pulse & 4) /* for DMAC */
	AC = AC & ~07777;
	else if (rf_done)
	AC = AC \| IOT_SKP;
	}
	if (pulse & 4) /* DMAC */
	AC = AC \| (rf_da & 07777);
	return AC;
	}

	int32 rf64 (int32 IR, int32 AC)
	{
	int32 pulse = IR & 07;

	UPDATE_PCELL; /* update photocell */
	switch (pulse) { /* decode IR<9:11> */

	case 1: /* DCXA */
	rf_da = rf_da & 07777; /* clear DAR<0:7> */
	break;

	case 3: /* DXAL */
	rf_da = rf_da & 07777; /* clear DAR<0:7> */
	case 2: /* DXAL w/o clear */
	rf_da = rf_da \| ((AC & 0377) << 12); /* DAR<0:7> \|= AC */
	AC = 0; /* clear AC */
	break;

	case 5: /* DXAC */
	AC = 0; /* clear AC */
	case 4: /* DXAC w/o clear */
	AC = AC \| ((rf_da >> 12) & 0377); /* AC \|= DAR<0:7> */
	break;

	default:
	AC = (stop_inst << IOT_V_REASON) + AC;
	break;
	} /* end switch */

	if ((uint32) rf_da >= rf_unit.capac)
	rf_sta = rf_sta \| RFS_NXD;
	else rf_sta = rf_sta & ~RFS_NXD;
	RF_INT_UPDATE;
	return AC;
	}

	/* Unit service

	Note that for reads and writes, memory addresses wrap around in the
	current field. This code assumes the entire disk is buffered.
	*/

	t_stat rf_svc (UNIT *uptr)
	{
	int32 pa, t, mex;
	int16 fbuf = (int16 ) uptr->filebuf;

	UPDATE_PCELL; /* update photocell */
	if ((uptr->flags & UNIT_BUF) == 0) { /* not buf? abort */
	rf_sta = rf_sta \| RFS_NXD;
	rf_done = 1;
	RF_INT_UPDATE; /* update int req */
	return IORETURN (rf_stopioe, SCPE_UNATT);
	}

	mex = GET_MEX (rf_sta);
	do {
	if ((uint32) rf_da >= rf_unit.capac) { /* disk overflow? */
	rf_sta = rf_sta \| RFS_NXD;
	break;
	}
	M[RF_WC] = (M[RF_WC] + 1) & 07777; /* incr word count */
	M[RF_MA] = (M[RF_MA] + 1) & 07777; /* incr mem addr */
	pa = mex \| M[RF_MA]; /* add extension */
	if (uptr->FUNC == RF_READ) { /* read? */
	if (MEM_ADDR_OK (pa)) /* if !nxm */
	M[pa] = fbuf[rf_da]; /* read word */
	}
	else { /* write */
	t = ((rf_da >> 15) & 030) \| ((rf_da >> 14) & 07);
	if ((rf_wlk >> t) & 1) /* write locked? */
	rf_sta = rf_sta \| RFS_WLS;
	else { /* not locked */
	fbuf[rf_da] = M[pa]; /* write word */
	if (((uint32) rf_da) >= uptr->hwmark)
	uptr->hwmark = rf_da + 1;
	}
	}
	rf_da = (rf_da + 1) & 03777777; /* incr disk addr */
	} while ((M[RF_WC] != 0) && (rf_burst != 0)); /* brk if wc, no brst */

	if ((M[RF_WC] != 0) && ((rf_sta & RFS_ERR) == 0)) /* more to do? */
	sim_activate (&rf_unit, rf_time); /* sched next */
	else {
	rf_done = 1; /* done */
	RF_INT_UPDATE; /* update int req */
	}
	return SCPE_OK;
	}

	/* Photocell unit service */

	t_stat pcell_svc (UNIT *uptr)
	{
	rf_sta = rf_sta \| RFS_PCA; /* set photocell */
	if (rf_sta & RFS_PIE) { /* int enable? */
	sim_activate (&pcell_unit, RF_NUMWD * rf_time);
	int_req = int_req \| INT_RF;
	}
	return SCPE_OK;
	}

	/* Reset routine */

	t_stat rf_reset (DEVICE *dptr)
	{
	rf_sta = rf_da = 0;
	rf_done = 1;
	int_req = int_req & ~INT_RF; /* clear interrupt */
	sim_cancel (&rf_unit);
	sim_cancel (&pcell_unit);
	return SCPE_OK;
	}

	/* Bootstrap routine */

	#define OS8_START 07750
	#define OS8_LEN (sizeof (os8_rom) / sizeof (int16))
	#define DM4_START 00200
	#define DM4_LEN (sizeof (dm4_rom) / sizeof (int16))

	static const uint16 os8_rom[] = {
	07600, /* 7750, CLA CLL ; also word count */
	06603, /* 7751, DMAR ; also address */
	06622, /* 7752, DFSC ; done? */
	05352, /* 7753, JMP .-1 ; no */
	05752 /* 7754, JMP @.-2 ; enter boot */
	};

	static const uint16 dm4_rom[] = {
	00200, 07600, /* 0200, CLA CLL */
	00201, 06603, /* 0201, DMAR ; read */
	00202, 06622, /* 0202, DFSC ; done? */
	00203, 05202, /* 0203, JMP .-1 ; no */
	00204, 05600, /* 0204, JMP @.-4 ; enter boot */
	07750, 07576, /* 7750, 7576 ; word count */
	07751, 07576 /* 7751, 7576 ; address */
	};

	t_stat rf_boot (int32 unitno, DEVICE *dptr)
	{
	size_t i;

	if (rf_dib.dev != DEV_RF) /* only std devno */
	return STOP_NOTSTD;
	if (sim_switches & SWMASK ('D')) {
	for (i = 0; i < DM4_LEN; i = i + 2)
	M[dm4_rom[i]] = dm4_rom[i + 1];
	cpu_set_bootpc (DM4_START);
	}
	else {
	for (i = 0; i < OS8_LEN; i++)
	M[OS8_START + i] = os8_rom[i];
	cpu_set_bootpc (OS8_START);
	}
	return SCPE_OK;
	}

	/* Attach routine */

	t_stat rf_attach (UNIT uptr, CONST char cptr)
	{
	uint32 sz, p;
	uint32 ds_bytes = RF_DKSIZE * sizeof (int16);

	if ((uptr->flags & UNIT_AUTO) && (sz = sim_fsize_name (cptr))) {
	p = (sz + ds_bytes - 1) / ds_bytes;
	if (p >= RF_NUMDK)
	p = RF_NUMDK - 1;
	uptr->flags = (uptr->flags & ~UNIT_PLAT) \|
	(p << UNIT_V_PLAT);
	}
	uptr->capac = UNIT_GETP (uptr->flags) * RF_DKSIZE;
	return attach_unit (uptr, cptr);
	}

	/* Change disk size */

	t_stat rf_set_size (UNIT uptr, int32 val, CONST char cptr, void *desc)
	{
	if (val < 0)
	return SCPE_IERR;
	if (uptr->flags & UNIT_ATT)
	return SCPE_ALATT;
	uptr->capac = UNIT_GETP (val) * RF_DKSIZE;
	uptr->flags = uptr->flags & ~UNIT_AUTO;
	return SCPE_OK;
	}