Interdata/id_io.c - emulators/simh - Rivoreo Source Code Repositories

 /* id_io.c: Interdata CPU-independent I/O routines

    Copyright (c) 2001-2008, 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.

    30-Mar-06    RMS     Fixed bug, GO preserves EXA and SSTA (Davis Johnson)
    21-Jun-03    RMS     Changed subroutine argument for ARM compiler conflict

    Interdata I/O devices are defined by a device information block:

         dno             base device number
         sch             selector channel, -1 if none
         irq             interrupt request flag
         tplte           device number template, NULL if one device number
         iot             I/O processing routine
         ini             initialization routine

    Interdata I/O uses the following interconnected tables:

         dev_tab[dev]    Indexed by device number, points to the I/O instruction
                         processing routine for the device.

         sch_tab[dev]    Indexed by device number, if non-zero, the number + 1
                         of the selector channel used by the device.

         int_req[level]  Indexed by interrupt level, device interrupt flags.

         int_enb[level]  Indexed by interrupt level, device interrupt enable flags.

         int_tab[idx]    Indexed by ((interrupt level * 32) + interrupt number),
                         maps bit positions in int_req to device numbers.
 */

 #include "id_defs.h"

 /* Selector channel */

 #define SCHC_EXA        0x40                            /* read ext addr */
 #define SCHC_RD         0x20                            /* read */
 #define SCHC_GO         0x10                            /* go */
 #define SCHC_STOP       0x08                            /* stop */
 #define SCHC_SSTA       0x04                            /* sel ch status */
 #define SCHC_EXM        0x03                            /* ext mem */

 extern uint32 int_req[INTSZ], int_enb[INTSZ];
 extern uint32 (*dev_tab[DEVNO])(uint32 dev, uint32 op, uint32 datout);
 extern uint32 pawidth;
 extern UNIT cpu_unit;

 uint32 sch_max = 2;                                     /* sch count */
 uint32 sch_sa[SCH_NUMCH] = { 0 };                       /* start addr */
 uint32 sch_ea[SCH_NUMCH] = { 0 };                       /* end addr */
 uint8 sch_sdv[SCH_NUMCH] = { 0 };                       /* device */
 uint8 sch_cmd[SCH_NUMCH] = { 0 };                       /* command */
 uint8 sch_rdp[SCH_NUMCH] = { 0 };                       /* read ptr */
 uint8 sch_wdc[SCH_NUMCH] = { 0 };                       /* write ctr */
 uint32 sch_tab[DEVNO] = { 0 };                          /* dev to sch map */
 uint32 int_tab[INTSZ * 32] = { 0 };                     /* int to dev map */
 uint8 sch_tplte[SCH_NUMCH + 1];                         /* dnum template */

 uint32 sch (uint32 dev, uint32 op, uint32 dat);
 void sch_ini (t_bool dtpl);
 t_stat sch_reset (DEVICE *dptr);
 t_stat sch_set_nchan (UNIT *uptr, int32 val, CONST char *cptr, void *desc);
 t_stat sch_show_nchan (FILE *st, UNIT *uptr, int32 val, CONST void *desc);
 t_stat sch_show_reg (FILE *st, UNIT *uptr, int32 val, CONST void *desc);

 /* Selector channel data structures

    sch_dev      channel device descriptor
    sch_unit     channel unit descriptor
    sch_mod      channel modifiers list
    sch_reg      channel register list
 */

 DIB sch_dib = { d_SCH, -1, v_SCH, sch_tplte, &sch, &sch_ini };

 UNIT sch_unit = { UDATA (NULL, 0, 0) };

 REG sch_reg[] = {
     { HRDATA (CHAN, sch_max, 3), REG_HRO },
     { BRDATA (SA, sch_sa, 16, 20, SCH_NUMCH) },
     { BRDATA (EA, sch_ea, 16, 20, SCH_NUMCH) },
     { BRDATA (CMD, sch_cmd, 16, 8, SCH_NUMCH) },
     { BRDATA (DEV, sch_sdv, 16, 8, SCH_NUMCH) },
     { BRDATA (RDP, sch_rdp, 16, 2, SCH_NUMCH) },
     { BRDATA (WDC, sch_wdc, 16, 3, SCH_NUMCH) },
     { GRDATA (IREQ, int_req[l_SCH], 16, SCH_NUMCH, i_SCH) },
     { GRDATA (IENB, int_enb[l_SCH], 16, SCH_NUMCH, i_SCH) },
     { HRDATA (DEVNO, sch_dib.dno, 8), REG_HRO },
     { NULL }
     };

 MTAB sch_mod[] = {
     { MTAB_XTD|MTAB_VDV, 0, "channels", "CHANNELS",
       &sch_set_nchan, &sch_show_nchan, NULL },
     { MTAB_XTD | MTAB_VDV | MTAB_NMO, 0, "0", NULL,
       NULL, &sch_show_reg, NULL },
     { MTAB_XTD | MTAB_VDV | MTAB_NMO, 1, "1", NULL,
       NULL, &sch_show_reg, NULL },
     { MTAB_XTD | MTAB_VDV | MTAB_NMO, 2, "2", NULL,
       NULL, &sch_show_reg, NULL },
     { MTAB_XTD | MTAB_VDV | MTAB_NMO, 3, "3", NULL,
       NULL, &sch_show_reg, NULL },
     { MTAB_XTD|MTAB_VDV, 0, "DEVNO", "DEVNO",
       &set_dev, &show_dev, &sch_dib },
     { 0 }
     };

 DEVICE sch_dev = {
     "SELCH", &sch_unit, sch_reg, sch_mod,
     1, 16, 8, 1, 16, 8,
     NULL, NULL, &sch_reset,
     NULL, NULL, NULL,
     &sch_dib, 0
     };

 /* (Extended) selector channel

    There are really three different selector channels:
         - 16b selector channel (max 4B of data)
         - 18b selector channel (max 4B of data)
         - 20b selector channel (max 6B of data)
    The algorithm for loading the start and end addresses is taken
    from the maintenance manual for the Extended Selector Channel.
 */

 #define SCH_EXR(ch)     ((sch_cmd[ch] & SCHC_EXA) && (pawidth == PAWIDTH32))

 uint32 sch (uint32 dev, uint32 op, uint32 dat)
 {
 uint32 t, bank, sdv, ch = dev - sch_dib.dno;

 switch (op) {                                           /* case IO op */

     case IO_ADR:                                        /* select */
         return BY;                                      /* byte only */

     case IO_RD:                                         /* read data */
         t = (sch_sa[ch] >> (sch_rdp[ch] * 8)) & DMASK8; /* get sa byte */
         if (sch_rdp[ch] == 0) sch_rdp[ch] =             /* wrap? */
             SCH_EXR (ch)? 2: 1;
         else sch_rdp[ch] = sch_rdp[ch] - 1;             /* dec byte ptr */
         return t;

     case IO_WD:                                         /* write data */
         if (pawidth != PAWIDTH32) {                     /* 16b? max 4 */
             if (sch_wdc[ch] >= 4)                       /* stop at 4 */
                 break;
             sch_sa[ch] = ((sch_sa[ch] << 8) |           /* ripple ea to sa */
                 (sch_ea[ch] >> 8)) & DMASK16;
             sch_ea[ch] = ((sch_ea[ch] << 8) |           /* ripple ea low */
                 dat) & DMASK16;                         /* insert byte */
             }
         else {                                          /* 32b? max 6 */
             if (sch_wdc[ch] >= 6)                       /* stop at 6 */
                 break;
             if (sch_wdc[ch] != 5) {                     /* if not last */
                 sch_sa[ch] = ((sch_sa[ch] << 8) |       /* ripple ea<15:8> to sa */
                     ((sch_ea[ch] >> 8) & DMASK8)) & PAMASK32;
                 sch_ea[ch] =                            /* ripple ea<7:0> */
                     (((sch_ea[ch] & DMASK8) << 8) | dat) & PAMASK32;
                 }
             else sch_ea[ch] = ((sch_ea[ch] << 8) | dat) & PAMASK32;
             }
         sch_wdc[ch] = sch_wdc[ch] + 1;                  /* adv sequencer */
         break;

     case IO_SS:                                         /* status */
         if (sch_cmd[ch] & SCHC_GO)                      /* test busy */
             return STA_BSY;
         if (sch_cmd[ch] & SCHC_SSTA)                    /* test sch sta */
             return 0;
         else {
             sdv = sch_sdv[ch];                          /* get dev */
             if (dev_tab[sdv] == 0)                      /* not there? */
                 return CC_V;
             dev_tab[sdv] (sdv, IO_ADR, 0);              /* select dev */
             t = dev_tab[sdv] (sdv, IO_SS, 0);           /* get status */
             return t & ~STA_BSY;                        /* clr busy */
             }

     case IO_OC:                                         /* command */
         bank = 0;                                       /* assume no bank */
         if (pawidth != PAWIDTH32) {                     /* 16b/18b proc? */
             dat = dat & ~(SCHC_EXA | SCHC_SSTA);        /* clr ext func */
             if (pawidth == PAWIDTH16E)                  /* 18b proc? */
                 bank = (dat & SCHC_EXM) << 16;
             }
         if (dat & SCHC_STOP) {                          /* stop? */
             sch_cmd[ch] = dat & (SCHC_EXA | SCHC_SSTA); /* clr go */
             CLR_INT (v_SCH + ch);                       /* clr intr */
             sch_rdp[ch] = SCH_EXR (ch)? 2: 1;           /* init sequencers */
             sch_wdc[ch] = 0;
             }
         else if (dat & SCHC_GO) {                       /* go? */
             sch_cmd[ch] = dat & (SCHC_EXA | SCHC_SSTA| SCHC_GO | SCHC_RD);
             if (sch_wdc[ch] <= 4) {                     /* 4 bytes? */
                 sch_sa[ch] = (sch_sa[ch] & PAMASK16) | bank;    /* 16b addr */
                 sch_ea[ch] = (sch_ea[ch] & PAMASK16) | bank;
                 }
             sch_sa[ch] = sch_sa[ch] & ~1;
             if (sch_ea[ch] <= sch_sa[ch])               /* wrap? */
                 sch_ea[ch] = sch_ea[ch] |               /* modify end addr */
                 ((pawidth == PAWIDTH32)? PAMASK32: PAMASK16);
             }
         break;
         }

 return 0;
 }

 /* CPU call to test if channel blocks access to device */

 t_bool sch_blk (uint32 dev)
 {
 uint32 ch = sch_tab[dev] - 1;

 if ((ch < sch_max) && (sch_cmd[ch] & SCHC_GO))
     return TRUE;
 return FALSE;
 }

 /* Device call to 'remember' last dev on channel */

 void sch_adr (uint32 ch, uint32 dev)
 {
 if (ch < sch_max)
     sch_sdv[ch] = dev;
 return;
 }

 /* Device call to see if selector channel is active for device */

 t_bool sch_actv (uint32 ch, uint32 dev)
 {
 if ((ch < sch_max) &&                                   /* chan valid, */
     (sch_cmd[ch] & SCHC_GO) &&                          /* on, and */
     (sch_sdv[ch] == dev))                               /* set for dev? */
     return TRUE;
 return FALSE;                                           /* no */
 }

 /* Device call to read a block of memory */

 uint32 sch_rdmem (uint32 ch, uint8 *buf, uint32 cnt)
 {
 uint32 addr, end, xfr, inc;

 if ((ch >= sch_max) || ((sch_cmd[ch] & SCHC_GO) == 0))
     return 0;
 addr = sch_sa[ch];                                      /* start */
 end = sch_ea[ch];                                       /* end */
 xfr = MIN (cnt, end - addr + 1);                        /* sch xfr cnt */
 inc = IOReadBlk (addr, xfr, buf);                       /* read mem */
 if ((addr + inc) > end) {                               /* end? */
     SET_INT (v_SCH + ch);                               /* interrupt */
     sch_cmd[ch] &= ~(SCHC_GO | SCHC_RD);                /* clear GO */
     sch_sa[ch] = sch_sa[ch] + inc - 1;                  /* end addr */
     }
 else sch_sa[ch] = sch_sa[ch] + inc;                     /* next addr */
 return inc;
 }

 /* Device call to write a block of memory */

 uint32 sch_wrmem (uint32 ch, uint8 *buf, uint32 cnt)
 {
 uint32 addr, end, xfr, inc;

 if ((ch >= sch_max) || ((sch_cmd[ch] & SCHC_GO) == 0))
     return 0;
 addr = sch_sa[ch];                                      /* start */
 end = sch_ea[ch];                                       /* end */
 xfr = MIN (cnt, end - addr + 1);                        /* sch xfr cnt */
 inc = IOWriteBlk (addr, xfr, buf);                      /* write mem */
 if ((addr + inc) > end) {                               /* end? */
     SET_INT (v_SCH + ch);                               /* interrupt */
     sch_cmd[ch] &= ~(SCHC_GO | SCHC_RD);                /* clear GO */
     sch_sa[ch] = sch_sa[ch] + inc - 1;                  /* end addr */
     }
 else sch_sa[ch] = sch_sa[ch] + inc;                     /* next addr */
 return inc;
 }

 /* Device call to stop a selector channel */

 void sch_stop (uint32 ch)
 {
 if (ch < sch_max) {
     SET_INT (v_SCH + ch);                               /* interrupt */
     sch_cmd[ch] &= ~(SCHC_GO | SCHC_RD);                /* clear GO */
     }
 return;
 }

 /* Reset */

 void sch_reset_ch (uint32 rst_lim)
 {
 uint32 ch;

 for (ch = 0; ch < SCH_NUMCH; ch++) {
     if (ch >= rst_lim) {
         CLR_INT (v_SCH + ch);
         SET_ENB (v_SCH + ch);
         sch_sa[ch] = sch_ea[ch] = 0;
         sch_cmd[ch] = sch_sdv[ch] = 0;
         sch_wdc[ch] = 0;
         sch_rdp[ch] = 1;
         }
     }
 return;
 }

 t_stat sch_reset (DEVICE *dptr)
 {
 sch_reset_ch (0);                                       /* reset all chan */
 return SCPE_OK;
 }

 /* Set number of channels */

 t_stat sch_set_nchan (UNIT *uptr, int32 val, CONST char *cptr, void *desc)
 {
 DEVICE *dptr;
 DIB *dibp;
 uint32 i, newmax;
 t_stat r;

 if (cptr == NULL)
     return SCPE_ARG;
 newmax = get_uint (cptr, 10, SCH_NUMCH, &r);            /* get new max */
 if ((r != SCPE_OK) || (newmax == sch_max))              /* err or no chg? */
     return r;
 if (newmax == 0)                                        /* must be > 0 */
     return SCPE_ARG;
 if (newmax < sch_max) {                                 /* reducing? */
     for (i = 0; (dptr = sim_devices[i]); i++) {           /* loop thru dev */
         dibp = (DIB *) dptr->ctxt;                      /* get DIB */
         if (dibp && (dibp->sch >= (int32) newmax)) {    /* dev using chan? */
             sim_printf ("Device %02X uses channel %d\n",
                     dibp->dno, dibp->sch);
             return SCPE_OK;
             }
         }
     }
 sch_max = newmax;                                       /* set new max */
 sch_reset_ch (sch_max);                                 /* reset chan */
 return SCPE_OK;
 }

 /* Show number of channels */

 t_stat sch_show_nchan (FILE *st, UNIT *uptr, int32 val, CONST void *desc)
 {
 fprintf (st, "channels=%d", sch_max);
 return SCPE_OK;
 }

 /* Show channel registers */

 t_stat sch_show_reg (FILE *st, UNIT *uptr, int32 val, CONST void *desc)
 {
 if (val < 0)
     return SCPE_IERR;
 if (val >= (int32) sch_max)
     fprintf (st, "Channel %d disabled\n", val);
 else {
     fprintf (st, "SA:   %05X\n", sch_sa[val]);
     fprintf (st, "EA:   %05X\n", sch_ea[val]);
     fprintf (st, "CMD:  %02X\n", sch_cmd[val]);
     fprintf (st, "DEV:  %02X\n", sch_sdv[val]);
     fprintf (st, "RDP:  %X\n", sch_rdp[val]);
     fprintf (st, "WDC:  %X\n", sch_wdc[val]);
     }
 return SCPE_OK;
 }

 /* Initialize template */

 void sch_ini (t_bool dtpl)
 {
 uint32 i;

 for (i = 0; i < sch_max; i++)
     sch_tplte[i] = i;
 sch_tplte[sch_max] = TPL_END;
 return;
 }

 /* Evaluate interrupt */

 void int_eval (void)
 {
 int i;
 extern uint32 qevent;

 for (i = 0; i < INTSZ; i++) {
     if (int_req[i] & int_enb[i]) {
         qevent = qevent | EV_INT;
         return;
         }
     }
 qevent = qevent & ~EV_INT;
 return;
 }

 /* Return interrupting device */

 uint32 int_getdev (void)
 {
 int32 i, j, t;
 uint32 r;

 for (i = t = 0; i < INTSZ; i++) {                       /* loop thru array */
     if ((r = int_req[i] & int_enb[i])) {                /* find nz int wd */
         for (j = 0; j < 32; t++, j++) {
             if (r & (1u << j)) {
                 int_req[i] = int_req[i] & ~(1u << j);   /* clr request */
                 return int_tab[t];
                 }
             }
         }
     else t = t + 32;
     }
 return 0;
 }

 /* Update device interrupt status */

 int32 int_chg (uint32 irq, int32 dat, int32 armdis)
 {
 int32 t = CMD_GETINT (dat);                             /* get int ctrl */

 if (t == CMD_IENB) {                                    /* enable? */
     SET_ENB (irq);
     return 1;
     }
 else if (t == CMD_IDIS) {                               /* disable? */
     CLR_ENB (irq);
     return 1;
     }
 if (t == CMD_IDSA) {                                    /* disarm? */
     CLR_ENB (irq);
     CLR_INT (irq);
     return 0;
     }
 return armdis;
 }

 /* Process a 2b field and return unchanged, set, clear, complement */

 int32 io_2b (int32 val, int32 pos, int32 old)
 {
 int32 t = (val >> pos) & 3;
 if (t == 0)
     return old;
 if (t == 1)
     return 1;
 if (t == 2)
     return 0;
 return old ^1;
 }

 /* Block transfer routines */

 uint32 IOReadBlk (uint32 loc, uint32 cnt, uint8 *buf)
 {
 uint32 i;

 if (!MEM_ADDR_OK (loc) || (cnt == 0))
     return 0;
 if (!MEM_ADDR_OK (loc + cnt - 1))
     cnt = MEMSIZE - loc;
 for (i = 0; i < cnt; i++)
     buf[i] = IOReadB (loc + i);
 return cnt;
 }

 uint32 IOWriteBlk (uint32 loc, uint32 cnt, uint8 *buf)
 {
 uint32 i;

 if (!MEM_ADDR_OK (loc) || (cnt == 0))
     return 0;
 if (!MEM_ADDR_OK (loc + cnt - 1))
     cnt = MEMSIZE - loc;
 for (i = 0; i < cnt; i++)
     IOWriteB (loc + i, buf[i]);
 return cnt;
 }

 /* Change selector channel for a device */

 t_stat set_sch (UNIT *uptr, int32 val, CONST char *cptr, void *desc)
 {
 DEVICE *dptr;
 DIB *dibp;
 uint32 newch;
 t_stat r;

 if (cptr == NULL)
     return SCPE_ARG;
 if (uptr == NULL)
     return SCPE_IERR;
 dptr = find_dev_from_unit (uptr);
 if (dptr == NULL)
     return SCPE_IERR;
 dibp = (DIB *) dptr->ctxt;
 if ((dibp == NULL) || (dibp->sch < 0))
     return SCPE_IERR;
 newch = get_uint (cptr, 16, sch_max - 1, &r);           /* get new */
 if (r != SCPE_OK)
     return r;
 dibp->sch = newch;                                      /* store */
 return SCPE_OK;
 }

 /* Show selector channel for a device */

 t_stat show_sch (FILE *st, UNIT *uptr, int32 val, CONST void *desc)
 {
 DEVICE *dptr;
 DIB *dibp;

 if (uptr == NULL)
     return SCPE_IERR;
 dptr = find_dev_from_unit (uptr);
 if (dptr == NULL)
     return SCPE_IERR;
 dibp = (DIB *) dptr->ctxt;
 if ((dibp == NULL) || (dibp->sch < 0))
     return SCPE_IERR;
 fprintf (st, "selch=%X", dibp->sch);
 return SCPE_OK;
 }

 /* Change device number for a device */

 t_stat set_dev (UNIT *uptr, int32 val, CONST char *cptr, void *desc)
 {
 DEVICE *dptr;
 DIB *dibp;
 uint32 newdev;
 t_stat r;

 if (cptr == NULL)
     return SCPE_ARG;
 if (uptr == NULL)
     return SCPE_IERR;
 dptr = find_dev_from_unit (uptr);
 if (dptr == NULL)
     return SCPE_IERR;
 dibp = (DIB *) dptr->ctxt;
 if (dibp == NULL)
     return SCPE_IERR;
 newdev = get_uint (cptr, 16, DEV_MAX, &r);              /* get new */
 if ((r != SCPE_OK) || (newdev == dibp->dno))
     return r;
 if (newdev == 0)                                        /* must be > 0 */
     return SCPE_ARG;
 dibp->dno = newdev;                                     /* store */
 return SCPE_OK;
 }

 /* Show device number for a device */

 t_stat show_dev (FILE *st, UNIT *uptr, int32 val, CONST void *desc)
 {
 DEVICE *dptr;
 DIB *dibp;

 if (uptr == NULL)
     return SCPE_IERR;
 dptr = find_dev_from_unit (uptr);
 if (dptr == NULL)
     return SCPE_IERR;
 dibp = (DIB *) dptr->ctxt;
 if ((dibp == NULL) || (dibp->dno == 0))
     return SCPE_IERR;
 fprintf (st, "devno=%02X", dibp->dno);
 return SCPE_OK;
 }

 /* Init device tables */

 t_bool devtab_init (void)
 {
 DEVICE *dptr;
 DIB *dibp;
 uint32 i, j, dno, dmsk, doff, t, dmap[DEVNO / 32];
 uint8 *tplte, dflt_tplte[] = { 0, TPL_END };

 /* Clear tables, device map */

 for (i = 0; i < DEVNO; i++) {
     dev_tab[i] = NULL;
     sch_tab[i] = 0;
     }
 for (i = 0; i < (INTSZ * 32); i++)
     int_tab[i] = 0;
 for (i = 0; i < (DEVNO / 32); i++)
     dmap[i] = 0;

 /* Test each device for conflict; add to map; init tables */

 for (i = 0; (dptr = sim_devices[i]); i++) {               /* loop thru devices */
     dibp = (DIB *) dptr->ctxt;                          /* get DIB */
     if ((dibp == NULL) || (dptr->flags & DEV_DIS))      /* exist, enabled? */
         continue;
     dno = dibp->dno;                                    /* get device num */
     if (dibp->ini)                                      /* gen dno template */
         dibp->ini (TRUE);
     tplte = dibp->tplte;                                /* get template */
     if (tplte == NULL)                                  /* none? use default */
         tplte = dflt_tplte;
     for ( ; *tplte != TPL_END; tplte++) {               /* loop thru template */
         t = (dno + *tplte) & DEV_MAX;                   /* loop thru template */
         dmsk = 1u << (t & 0x1F);                        /* bit to test */
         doff = t / 32;                                  /* word to test */
         if (dmap[doff] & dmsk) {                        /* in use? */
             sim_printf ("Device number conflict, devno = %02X\n", t);
             return TRUE;
             }
         dmap[doff] = dmap[doff] | dmsk;
         if (dibp->sch >= 0)
             sch_tab[t] = dibp->sch + 1;
         dev_tab[t] = dibp->iot;
         }
     if (dibp->ini)                                      /* gen int template */
         dibp->ini (FALSE);
     tplte = dibp->tplte;                                /* get template */
     if (tplte == NULL)                                  /* none? use default */
         tplte = dflt_tplte;
     for (j = dibp->irq; *tplte != TPL_END; j++, tplte++)
         int_tab[j] = (dno + *tplte) & DEV_MAX;
     }                                                   /* end for i */
 return FALSE;
 }
	/* id_io.c: Interdata CPU-independent I/O routines

	Copyright (c) 2001-2008, 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.

	30-Mar-06 RMS Fixed bug, GO preserves EXA and SSTA (Davis Johnson)
	21-Jun-03 RMS Changed subroutine argument for ARM compiler conflict

	Interdata I/O devices are defined by a device information block:

	dno base device number
	sch selector channel, -1 if none
	irq interrupt request flag
	tplte device number template, NULL if one device number
	iot I/O processing routine
	ini initialization routine

	Interdata I/O uses the following interconnected tables:

	dev_tab[dev] Indexed by device number, points to the I/O instruction
	processing routine for the device.

	sch_tab[dev] Indexed by device number, if non-zero, the number + 1
	of the selector channel used by the device.

	int_req[level] Indexed by interrupt level, device interrupt flags.

	int_enb[level] Indexed by interrupt level, device interrupt enable flags.

	int_tab[idx] Indexed by ((interrupt level * 32) + interrupt number),
	maps bit positions in int_req to device numbers.
	*/

	#include "id_defs.h"

	/* Selector channel */

	#define SCHC_EXA 0x40 /* read ext addr */
	#define SCHC_RD 0x20 /* read */
	#define SCHC_GO 0x10 /* go */
	#define SCHC_STOP 0x08 /* stop */
	#define SCHC_SSTA 0x04 /* sel ch status */
	#define SCHC_EXM 0x03 /* ext mem */

	extern uint32 int_req[INTSZ], int_enb[INTSZ];
	extern uint32 (*dev_tab[DEVNO])(uint32 dev, uint32 op, uint32 datout);
	extern uint32 pawidth;
	extern UNIT cpu_unit;

	uint32 sch_max = 2; /* sch count */
	uint32 sch_sa[SCH_NUMCH] = { 0 }; /* start addr */
	uint32 sch_ea[SCH_NUMCH] = { 0 }; /* end addr */
	uint8 sch_sdv[SCH_NUMCH] = { 0 }; /* device */
	uint8 sch_cmd[SCH_NUMCH] = { 0 }; /* command */
	uint8 sch_rdp[SCH_NUMCH] = { 0 }; /* read ptr */
	uint8 sch_wdc[SCH_NUMCH] = { 0 }; /* write ctr */
	uint32 sch_tab[DEVNO] = { 0 }; /* dev to sch map */
	uint32 int_tab[INTSZ * 32] = { 0 }; /* int to dev map */
	uint8 sch_tplte[SCH_NUMCH + 1]; /* dnum template */

	uint32 sch (uint32 dev, uint32 op, uint32 dat);
	void sch_ini (t_bool dtpl);
	t_stat sch_reset (DEVICE *dptr);
	t_stat sch_set_nchan (UNIT uptr, int32 val, CONST char cptr, void *desc);
	t_stat sch_show_nchan (FILE st, UNIT uptr, int32 val, CONST void *desc);
	t_stat sch_show_reg (FILE st, UNIT uptr, int32 val, CONST void *desc);

	/* Selector channel data structures

	sch_dev channel device descriptor
	sch_unit channel unit descriptor
	sch_mod channel modifiers list
	sch_reg channel register list
	*/

	DIB sch_dib = { d_SCH, -1, v_SCH, sch_tplte, &sch, &sch_ini };

	UNIT sch_unit = { UDATA (NULL, 0, 0) };

	REG sch_reg[] = {
	{ HRDATA (CHAN, sch_max, 3), REG_HRO },
	{ BRDATA (SA, sch_sa, 16, 20, SCH_NUMCH) },
	{ BRDATA (EA, sch_ea, 16, 20, SCH_NUMCH) },
	{ BRDATA (CMD, sch_cmd, 16, 8, SCH_NUMCH) },
	{ BRDATA (DEV, sch_sdv, 16, 8, SCH_NUMCH) },
	{ BRDATA (RDP, sch_rdp, 16, 2, SCH_NUMCH) },
	{ BRDATA (WDC, sch_wdc, 16, 3, SCH_NUMCH) },
	{ GRDATA (IREQ, int_req[l_SCH], 16, SCH_NUMCH, i_SCH) },
	{ GRDATA (IENB, int_enb[l_SCH], 16, SCH_NUMCH, i_SCH) },
	{ HRDATA (DEVNO, sch_dib.dno, 8), REG_HRO },
	{ NULL }
	};

	MTAB sch_mod[] = {
	{ MTAB_XTD\|MTAB_VDV, 0, "channels", "CHANNELS",
	&sch_set_nchan, &sch_show_nchan, NULL },
	{ MTAB_XTD \| MTAB_VDV \| MTAB_NMO, 0, "0", NULL,
	NULL, &sch_show_reg, NULL },
	{ MTAB_XTD \| MTAB_VDV \| MTAB_NMO, 1, "1", NULL,
	NULL, &sch_show_reg, NULL },
	{ MTAB_XTD \| MTAB_VDV \| MTAB_NMO, 2, "2", NULL,
	NULL, &sch_show_reg, NULL },
	{ MTAB_XTD \| MTAB_VDV \| MTAB_NMO, 3, "3", NULL,
	NULL, &sch_show_reg, NULL },
	{ MTAB_XTD\|MTAB_VDV, 0, "DEVNO", "DEVNO",
	&set_dev, &show_dev, &sch_dib },
	{ 0 }
	};

	DEVICE sch_dev = {
	"SELCH", &sch_unit, sch_reg, sch_mod,
	1, 16, 8, 1, 16, 8,
	NULL, NULL, &sch_reset,
	NULL, NULL, NULL,
	&sch_dib, 0
	};

	/* (Extended) selector channel

	There are really three different selector channels:
	- 16b selector channel (max 4B of data)
	- 18b selector channel (max 4B of data)
	- 20b selector channel (max 6B of data)
	The algorithm for loading the start and end addresses is taken
	from the maintenance manual for the Extended Selector Channel.
	*/

	#define SCH_EXR(ch) ((sch_cmd[ch] & SCHC_EXA) && (pawidth == PAWIDTH32))

	uint32 sch (uint32 dev, uint32 op, uint32 dat)
	{
	uint32 t, bank, sdv, ch = dev - sch_dib.dno;

	switch (op) { /* case IO op */

	case IO_ADR: /* select */
	return BY; /* byte only */

	case IO_RD: /* read data */
	t = (sch_sa[ch] >> (sch_rdp[ch] * 8)) & DMASK8; /* get sa byte */
	if (sch_rdp[ch] == 0) sch_rdp[ch] = /* wrap? */
	SCH_EXR (ch)? 2: 1;
	else sch_rdp[ch] = sch_rdp[ch] - 1; /* dec byte ptr */
	return t;

	case IO_WD: /* write data */
	if (pawidth != PAWIDTH32) { /* 16b? max 4 */
	if (sch_wdc[ch] >= 4) /* stop at 4 */
	break;
	sch_sa[ch] = ((sch_sa[ch] << 8) \| /* ripple ea to sa */
	(sch_ea[ch] >> 8)) & DMASK16;
	sch_ea[ch] = ((sch_ea[ch] << 8) \| /* ripple ea low */
	dat) & DMASK16; /* insert byte */
	}
	else { /* 32b? max 6 */
	if (sch_wdc[ch] >= 6) /* stop at 6 */
	break;
	if (sch_wdc[ch] != 5) { /* if not last */
	sch_sa[ch] = ((sch_sa[ch] << 8) \| /* ripple ea<15:8> to sa */
	((sch_ea[ch] >> 8) & DMASK8)) & PAMASK32;
	sch_ea[ch] = /* ripple ea<7:0> */
	(((sch_ea[ch] & DMASK8) << 8) \| dat) & PAMASK32;
	}
	else sch_ea[ch] = ((sch_ea[ch] << 8) \| dat) & PAMASK32;
	}
	sch_wdc[ch] = sch_wdc[ch] + 1; /* adv sequencer */
	break;

	case IO_SS: /* status */
	if (sch_cmd[ch] & SCHC_GO) /* test busy */
	return STA_BSY;
	if (sch_cmd[ch] & SCHC_SSTA) /* test sch sta */
	return 0;
	else {
	sdv = sch_sdv[ch]; /* get dev */
	if (dev_tab[sdv] == 0) /* not there? */
	return CC_V;
	dev_tab[sdv] (sdv, IO_ADR, 0); /* select dev */
	t = dev_tab[sdv] (sdv, IO_SS, 0); /* get status */
	return t & ~STA_BSY; /* clr busy */
	}

	case IO_OC: /* command */
	bank = 0; /* assume no bank */
	if (pawidth != PAWIDTH32) { /* 16b/18b proc? */
	dat = dat & ~(SCHC_EXA \| SCHC_SSTA); /* clr ext func */
	if (pawidth == PAWIDTH16E) /* 18b proc? */
	bank = (dat & SCHC_EXM) << 16;
	}
	if (dat & SCHC_STOP) { /* stop? */
	sch_cmd[ch] = dat & (SCHC_EXA \| SCHC_SSTA); /* clr go */
	CLR_INT (v_SCH + ch); /* clr intr */
	sch_rdp[ch] = SCH_EXR (ch)? 2: 1; /* init sequencers */
	sch_wdc[ch] = 0;
	}
	else if (dat & SCHC_GO) { /* go? */
	sch_cmd[ch] = dat & (SCHC_EXA \| SCHC_SSTA\| SCHC_GO \| SCHC_RD);
	if (sch_wdc[ch] <= 4) { /* 4 bytes? */
	sch_sa[ch] = (sch_sa[ch] & PAMASK16) \| bank; /* 16b addr */
	sch_ea[ch] = (sch_ea[ch] & PAMASK16) \| bank;
	}
	sch_sa[ch] = sch_sa[ch] & ~1;
	if (sch_ea[ch] <= sch_sa[ch]) /* wrap? */
	sch_ea[ch] = sch_ea[ch] \| /* modify end addr */
	((pawidth == PAWIDTH32)? PAMASK32: PAMASK16);
	}
	break;
	}

	return 0;
	}

	/* CPU call to test if channel blocks access to device */

	t_bool sch_blk (uint32 dev)
	{
	uint32 ch = sch_tab[dev] - 1;

	if ((ch < sch_max) && (sch_cmd[ch] & SCHC_GO))
	return TRUE;
	return FALSE;
	}

	/* Device call to 'remember' last dev on channel */

	void sch_adr (uint32 ch, uint32 dev)
	{
	if (ch < sch_max)
	sch_sdv[ch] = dev;
	return;
	}

	/* Device call to see if selector channel is active for device */

	t_bool sch_actv (uint32 ch, uint32 dev)
	{
	if ((ch < sch_max) && /* chan valid, */
	(sch_cmd[ch] & SCHC_GO) && /* on, and */
	(sch_sdv[ch] == dev)) /* set for dev? */
	return TRUE;
	return FALSE; /* no */
	}

	/* Device call to read a block of memory */

	uint32 sch_rdmem (uint32 ch, uint8 *buf, uint32 cnt)
	{
	uint32 addr, end, xfr, inc;

	if ((ch >= sch_max) \|\| ((sch_cmd[ch] & SCHC_GO) == 0))
	return 0;
	addr = sch_sa[ch]; /* start */
	end = sch_ea[ch]; /* end */
	xfr = MIN (cnt, end - addr + 1); /* sch xfr cnt */
	inc = IOReadBlk (addr, xfr, buf); /* read mem */
	if ((addr + inc) > end) { /* end? */
	SET_INT (v_SCH + ch); /* interrupt */
	sch_cmd[ch] &= ~(SCHC_GO \| SCHC_RD); /* clear GO */
	sch_sa[ch] = sch_sa[ch] + inc - 1; /* end addr */
	}
	else sch_sa[ch] = sch_sa[ch] + inc; /* next addr */
	return inc;
	}

	/* Device call to write a block of memory */

	uint32 sch_wrmem (uint32 ch, uint8 *buf, uint32 cnt)
	{
	uint32 addr, end, xfr, inc;

	if ((ch >= sch_max) \|\| ((sch_cmd[ch] & SCHC_GO) == 0))
	return 0;
	addr = sch_sa[ch]; /* start */
	end = sch_ea[ch]; /* end */
	xfr = MIN (cnt, end - addr + 1); /* sch xfr cnt */
	inc = IOWriteBlk (addr, xfr, buf); /* write mem */
	if ((addr + inc) > end) { /* end? */
	SET_INT (v_SCH + ch); /* interrupt */
	sch_cmd[ch] &= ~(SCHC_GO \| SCHC_RD); /* clear GO */
	sch_sa[ch] = sch_sa[ch] + inc - 1; /* end addr */
	}
	else sch_sa[ch] = sch_sa[ch] + inc; /* next addr */
	return inc;
	}

	/* Device call to stop a selector channel */

	void sch_stop (uint32 ch)
	{
	if (ch < sch_max) {
	SET_INT (v_SCH + ch); /* interrupt */
	sch_cmd[ch] &= ~(SCHC_GO \| SCHC_RD); /* clear GO */
	}
	return;
	}

	/* Reset */

	void sch_reset_ch (uint32 rst_lim)
	{
	uint32 ch;

	for (ch = 0; ch < SCH_NUMCH; ch++) {
	if (ch >= rst_lim) {
	CLR_INT (v_SCH + ch);
	SET_ENB (v_SCH + ch);
	sch_sa[ch] = sch_ea[ch] = 0;
	sch_cmd[ch] = sch_sdv[ch] = 0;
	sch_wdc[ch] = 0;
	sch_rdp[ch] = 1;
	}
	}
	return;
	}

	t_stat sch_reset (DEVICE *dptr)
	{
	sch_reset_ch (0); /* reset all chan */
	return SCPE_OK;
	}

	/* Set number of channels */

	t_stat sch_set_nchan (UNIT uptr, int32 val, CONST char cptr, void *desc)
	{
	DEVICE *dptr;
	DIB *dibp;
	uint32 i, newmax;
	t_stat r;

	if (cptr == NULL)
	return SCPE_ARG;
	newmax = get_uint (cptr, 10, SCH_NUMCH, &r); /* get new max */
	if ((r != SCPE_OK) \|\| (newmax == sch_max)) /* err or no chg? */
	return r;
	if (newmax == 0) /* must be > 0 */
	return SCPE_ARG;
	if (newmax < sch_max) { /* reducing? */
	for (i = 0; (dptr = sim_devices[i]); i++) { /* loop thru dev */
	dibp = (DIB ) dptr->ctxt; / get DIB */
	if (dibp && (dibp->sch >= (int32) newmax)) { /* dev using chan? */
	sim_printf ("Device %02X uses channel %d\n",
	dibp->dno, dibp->sch);
	return SCPE_OK;
	}
	}
	}
	sch_max = newmax; /* set new max */
	sch_reset_ch (sch_max); /* reset chan */
	return SCPE_OK;
	}

	/* Show number of channels */

	t_stat sch_show_nchan (FILE st, UNIT uptr, int32 val, CONST void *desc)
	{
	fprintf (st, "channels=%d", sch_max);
	return SCPE_OK;
	}

	/* Show channel registers */

	t_stat sch_show_reg (FILE st, UNIT uptr, int32 val, CONST void *desc)
	{
	if (val < 0)
	return SCPE_IERR;
	if (val >= (int32) sch_max)
	fprintf (st, "Channel %d disabled\n", val);
	else {
	fprintf (st, "SA: %05X\n", sch_sa[val]);
	fprintf (st, "EA: %05X\n", sch_ea[val]);
	fprintf (st, "CMD: %02X\n", sch_cmd[val]);
	fprintf (st, "DEV: %02X\n", sch_sdv[val]);
	fprintf (st, "RDP: %X\n", sch_rdp[val]);
	fprintf (st, "WDC: %X\n", sch_wdc[val]);
	}
	return SCPE_OK;
	}

	/* Initialize template */

	void sch_ini (t_bool dtpl)
	{
	uint32 i;

	for (i = 0; i < sch_max; i++)
	sch_tplte[i] = i;
	sch_tplte[sch_max] = TPL_END;
	return;
	}

	/* Evaluate interrupt */

	void int_eval (void)
	{
	int i;
	extern uint32 qevent;

	for (i = 0; i < INTSZ; i++) {
	if (int_req[i] & int_enb[i]) {
	qevent = qevent \| EV_INT;
	return;
	}
	}
	qevent = qevent & ~EV_INT;
	return;
	}

	/* Return interrupting device */

	uint32 int_getdev (void)
	{
	int32 i, j, t;
	uint32 r;

	for (i = t = 0; i < INTSZ; i++) { /* loop thru array */
	if ((r = int_req[i] & int_enb[i])) { /* find nz int wd */
	for (j = 0; j < 32; t++, j++) {
	if (r & (1u << j)) {
	int_req[i] = int_req[i] & ~(1u << j); /* clr request */
	return int_tab[t];
	}
	}
	}
	else t = t + 32;
	}
	return 0;
	}

	/* Update device interrupt status */

	int32 int_chg (uint32 irq, int32 dat, int32 armdis)
	{
	int32 t = CMD_GETINT (dat); /* get int ctrl */

	if (t == CMD_IENB) { /* enable? */
	SET_ENB (irq);
	return 1;
	}
	else if (t == CMD_IDIS) { /* disable? */
	CLR_ENB (irq);
	return 1;
	}
	if (t == CMD_IDSA) { /* disarm? */
	CLR_ENB (irq);
	CLR_INT (irq);
	return 0;
	}
	return armdis;
	}

	/* Process a 2b field and return unchanged, set, clear, complement */

	int32 io_2b (int32 val, int32 pos, int32 old)
	{
	int32 t = (val >> pos) & 3;
	if (t == 0)
	return old;
	if (t == 1)
	return 1;
	if (t == 2)
	return 0;
	return old ^1;
	}

	/* Block transfer routines */

	uint32 IOReadBlk (uint32 loc, uint32 cnt, uint8 *buf)
	{
	uint32 i;

	if (!MEM_ADDR_OK (loc) \|\| (cnt == 0))
	return 0;
	if (!MEM_ADDR_OK (loc + cnt - 1))
	cnt = MEMSIZE - loc;
	for (i = 0; i < cnt; i++)
	buf[i] = IOReadB (loc + i);
	return cnt;
	}

	uint32 IOWriteBlk (uint32 loc, uint32 cnt, uint8 *buf)
	{
	uint32 i;

	if (!MEM_ADDR_OK (loc) \|\| (cnt == 0))
	return 0;
	if (!MEM_ADDR_OK (loc + cnt - 1))
	cnt = MEMSIZE - loc;
	for (i = 0; i < cnt; i++)
	IOWriteB (loc + i, buf[i]);
	return cnt;
	}

	/* Change selector channel for a device */

	t_stat set_sch (UNIT uptr, int32 val, CONST char cptr, void *desc)
	{
	DEVICE *dptr;
	DIB *dibp;
	uint32 newch;
	t_stat r;

	if (cptr == NULL)
	return SCPE_ARG;
	if (uptr == NULL)
	return SCPE_IERR;
	dptr = find_dev_from_unit (uptr);
	if (dptr == NULL)
	return SCPE_IERR;
	dibp = (DIB *) dptr->ctxt;
	if ((dibp == NULL) \|\| (dibp->sch < 0))
	return SCPE_IERR;
	newch = get_uint (cptr, 16, sch_max - 1, &r); /* get new */
	if (r != SCPE_OK)
	return r;
	dibp->sch = newch; /* store */
	return SCPE_OK;
	}

	/* Show selector channel for a device */

	t_stat show_sch (FILE st, UNIT uptr, int32 val, CONST void *desc)
	{
	DEVICE *dptr;
	DIB *dibp;

	if (uptr == NULL)
	return SCPE_IERR;
	dptr = find_dev_from_unit (uptr);
	if (dptr == NULL)
	return SCPE_IERR;
	dibp = (DIB *) dptr->ctxt;
	if ((dibp == NULL) \|\| (dibp->sch < 0))
	return SCPE_IERR;
	fprintf (st, "selch=%X", dibp->sch);
	return SCPE_OK;
	}

	/* Change device number for a device */

	t_stat set_dev (UNIT uptr, int32 val, CONST char cptr, void *desc)
	{
	DEVICE *dptr;
	DIB *dibp;
	uint32 newdev;
	t_stat r;

	if (cptr == NULL)
	return SCPE_ARG;
	if (uptr == NULL)
	return SCPE_IERR;
	dptr = find_dev_from_unit (uptr);
	if (dptr == NULL)
	return SCPE_IERR;
	dibp = (DIB *) dptr->ctxt;
	if (dibp == NULL)
	return SCPE_IERR;
	newdev = get_uint (cptr, 16, DEV_MAX, &r); /* get new */
	if ((r != SCPE_OK) \|\| (newdev == dibp->dno))
	return r;
	if (newdev == 0) /* must be > 0 */
	return SCPE_ARG;
	dibp->dno = newdev; /* store */
	return SCPE_OK;
	}

	/* Show device number for a device */

	t_stat show_dev (FILE st, UNIT uptr, int32 val, CONST void *desc)
	{
	DEVICE *dptr;
	DIB *dibp;

	if (uptr == NULL)
	return SCPE_IERR;
	dptr = find_dev_from_unit (uptr);
	if (dptr == NULL)
	return SCPE_IERR;
	dibp = (DIB *) dptr->ctxt;
	if ((dibp == NULL) \|\| (dibp->dno == 0))
	return SCPE_IERR;
	fprintf (st, "devno=%02X", dibp->dno);
	return SCPE_OK;
	}

	/* Init device tables */

	t_bool devtab_init (void)
	{
	DEVICE *dptr;
	DIB *dibp;
	uint32 i, j, dno, dmsk, doff, t, dmap[DEVNO / 32];
	uint8 *tplte, dflt_tplte[] = { 0, TPL_END };

	/* Clear tables, device map */

	for (i = 0; i < DEVNO; i++) {
	dev_tab[i] = NULL;
	sch_tab[i] = 0;
	}
	for (i = 0; i < (INTSZ * 32); i++)
	int_tab[i] = 0;
	for (i = 0; i < (DEVNO / 32); i++)
	dmap[i] = 0;

	/* Test each device for conflict; add to map; init tables */

	for (i = 0; (dptr = sim_devices[i]); i++) { /* loop thru devices */
	dibp = (DIB ) dptr->ctxt; / get DIB */
	if ((dibp == NULL) \|\| (dptr->flags & DEV_DIS)) /* exist, enabled? */
	continue;
	dno = dibp->dno; /* get device num */
	if (dibp->ini) /* gen dno template */
	dibp->ini (TRUE);
	tplte = dibp->tplte; /* get template */
	if (tplte == NULL) /* none? use default */
	tplte = dflt_tplte;
	for ( ; tplte != TPL_END; tplte++) { / loop thru template */
	t = (dno + tplte) & DEV_MAX; / loop thru template */
	dmsk = 1u << (t & 0x1F); /* bit to test */
	doff = t / 32; /* word to test */
	if (dmap[doff] & dmsk) { /* in use? */
	sim_printf ("Device number conflict, devno = %02X\n", t);
	return TRUE;
	}
	dmap[doff] = dmap[doff] \| dmsk;
	if (dibp->sch >= 0)
	sch_tab[t] = dibp->sch + 1;
	dev_tab[t] = dibp->iot;
	}
	if (dibp->ini) /* gen int template */
	dibp->ini (FALSE);
	tplte = dibp->tplte; /* get template */
	if (tplte == NULL) /* none? use default */
	tplte = dflt_tplte;
	for (j = dibp->irq; *tplte != TPL_END; j++, tplte++)
	int_tab[j] = (dno + *tplte) & DEV_MAX;
	} /* end for i */
	return FALSE;
	}