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/* nova_mta.c: NOVA magnetic tape simulator
Copyright (c) 1993-2000, 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.
mta magnetic tape
15-Oct-00 RMS Editorial changes
04-Oct-98 RMS V2.4 magtape format
18-Jan-97 RMS V2.3 magtape format
29-Jun-96 RMS Added unit disable support
Magnetic tapes are represented as a series of variable records
of the form:
32b byte count byte count is little endian
byte 0
byte 1
:
byte n-2
byte n-1
32b byte count
If the byte count is odd, the record is padded with an extra byte
of junk. File marks are represented by a byte count of 0 and are
not duplicated; end of tape by end of file.
*/
#include "nova_defs.h"
#define MTA_NUMDR 8 /* #drives */
#define UNIT_V_WLK (UNIT_V_UF + 0) /* write locked */
#define UNIT_W_UF 2 /* saved flags width */
#define UNIT_WLK 1 << UNIT_V_WLK
#define USTAT u3 /* unit status */
#define UNUM u4 /* unit number */
#define DTSIZE (1 << 14) /* max data xfer */
#define DTMASK (DTSIZE - 1)
/* Command/unit */
#define CU_CI 0100000 /* clear interrupt */
#define CU_EP 0002000 /* poll enable */
#define CU_DE 0001000 /* disable erase */
#define CU_DA 0000400 /* disable autoretry */
#define CU_PE 0000400 /* PE mode */
#define CU_V_CMD 3 /* command */
#define CU_M_CMD 027
#define CU_READ 000
#define CU_REWIND 001
#define CU_CMODE 002
#define CU_SPACEF 003
#define CU_SPACER 004
#define CU_WRITE 005
#define CU_WREOF 006
#define CU_ERASE 007
#define CU_READNS 020
#define CU_UNLOAD 021
#define CU_DMODE 022
#define CU_V_UNIT 0 /* unit */
#define CU_M_UNIT 07
#define GET_CMD(x) (((x) >> CU_V_CMD) & CU_M_CMD)
#define GET_UNIT(x) (((x) >> CU_V_UNIT) & CU_M_UNIT)
/* Status 1 - stored in mta_sta<31:16> or (*) uptr -> USTAT<31:16> */
#define STA_ERR1 (0100000u << 16) /* error */
#define STA_DLT (0040000 << 16) /* data late */
#define STA_REW (0020000 << 16) /* *rewinding */
#define STA_ILL (0010000 << 16) /* illegal */
#define STA_HDN (0004000 << 16) /* high density */
#define STA_DAE (0002000 << 16) /* data error */
#define STA_EOT (0001000 << 16) /* *end of tape */
#define STA_EOF (0000400 << 16) /* *end of file */
#define STA_BOT (0000200 << 16) /* *start of tape */
#define STA_9TK (0000100 << 16) /* nine track */
#define STA_BAT (0000040 << 16) /* bad tape */
#define STA_CHG (0000010 << 16) /* status change */
#define STA_WLK (0000004 << 16) /* *write lock */
#define STA_ODD (0000002 << 16) /* odd character */
#define STA_RDY (0000001 << 16) /* *drive ready */
/* Status 2 - stored in mta_sta<15:0> or (*) uptr -> USTAT<15:0> */
#define STA_ERR2 0100000 /* error */
#define STA_RWY 0040000 /* runaway tape */
#define STA_FGP 0020000 /* false gap */
#define STA_CDL 0004000 /* corrected dlt */
#define STA_V_UNIT 8
#define STA_M_UNIT 07 /* unit */
#define STA_WCO 0000200 /* word count ovflo */
#define STA_BDS 0000100 /* bad signal */
#define STA_OVS 0000040 /* overskew */
#define STA_CRC 0000020 /* check error */
#define STA_STE 0000010 /* single trk error */
#define STA_FPR 0000004 /* false preamble */
#define STA_FMT 0000002 /* format error */
#define STA_PEM 0000001 /* *PE mode */
#define STA_EFLGS1 (STA_DLT | STA_ILL | STA_DAE | STA_EOT | \
STA_EOF | STA_BOT | STA_BAT | STA_ODD)
#define STA_EFLGS2 (STA_FGP | STA_CDL | STA_BDS | STA_OVS | \
STA_CRC | STA_FPR | STA_FPR) /* set error 2 */
#define STA_CLR ((020 << 16) | 0010000) /* always clear */
#define STA_SET (STA_HDN | STA_9TK) /* always set */
#define STA_DYN (STA_REW | STA_EOT | STA_EOF | STA_BOT | \
STA_WLK | STA_RDY | STA_PEM) /* kept in USTAT */
#define STA_MON (STA_REW | STA_BOT | STA_WLK | STA_RDY | \
STA_PEM) /* set status chg */
extern unsigned int16 M[];
extern UNIT cpu_unit;
extern int32 int_req, dev_busy, dev_done, dev_disable;
int32 mta_ma = 0; /* memory address */
int32 mta_wc = 0; /* word count */
int32 mta_cu = 0; /* command/unit */
int32 mta_sta = 0; /* status register */
int32 mta_ep = 0; /* enable polling */
int32 mta_cwait = 100; /* command latency */
int32 mta_rwait = 100; /* record latency */
t_stat mta_svc (UNIT *uptr);
t_stat mta_reset (DEVICE *dptr);
t_stat mta_boot (int32 unitno);
t_stat mta_attach (UNIT *uptr, char *cptr);
t_stat mta_detach (UNIT *uptr);
int32 mta_updcsta (UNIT *uptr);
void mta_upddsta (UNIT *uptr, int32 newsta);
t_stat mta_vlock (UNIT *uptr, int32 val);
extern t_stat sim_activate (UNIT *uptr, int32 delay);
extern t_stat sim_cancel (UNIT *uptr);
extern int32 sim_is_active (UNIT *uptr);
extern size_t fxread (void *bptr, size_t size, size_t count, FILE *fptr);
extern size_t fxwrite (void *bptr, size_t size, size_t count, FILE *fptr);
static const int ctype[32] = { /* c vs r timing */
0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 0,
0, 0, 1, 1, 1, 1, 1, 1, 0, 0, 1, 1, 1, 1, 1, 1 };
/* MTA data structures
mta_dev MTA device descriptor
mta_unit MTA unit list
mta_reg MTA register list
mta_mod MTA modifier list
*/
UNIT mta_unit[] = {
{ UDATA (&mta_svc, UNIT_ATTABLE + UNIT_DISABLE, 0) },
{ UDATA (&mta_svc, UNIT_ATTABLE + UNIT_DISABLE, 0) },
{ UDATA (&mta_svc, UNIT_ATTABLE + UNIT_DISABLE, 0) },
{ UDATA (&mta_svc, UNIT_ATTABLE + UNIT_DISABLE, 0) },
{ UDATA (&mta_svc, UNIT_ATTABLE + UNIT_DISABLE, 0) },
{ UDATA (&mta_svc, UNIT_ATTABLE + UNIT_DISABLE, 0) },
{ UDATA (&mta_svc, UNIT_ATTABLE + UNIT_DISABLE, 0) },
{ UDATA (&mta_svc, UNIT_ATTABLE + UNIT_DISABLE, 0) } };
REG mta_reg[] = {
{ ORDATA (CU, mta_cu, 16) },
{ ORDATA (MA, mta_ma, 16) },
{ ORDATA (WC, mta_wc, 16) },
{ GRDATA (STA1, mta_sta, 8, 16, 16) },
{ ORDATA (STA2, mta_sta, 16) },
{ FLDATA (EP, mta_ep, 0) },
{ FLDATA (BUSY, dev_busy, INT_V_MTA) },
{ FLDATA (DONE, dev_done, INT_V_MTA) },
{ FLDATA (DISABLE, dev_disable, INT_V_MTA) },
{ FLDATA (INT, int_req, INT_V_MTA) },
{ DRDATA (CTIME, mta_cwait, 24), PV_LEFT },
{ DRDATA (RTIME, mta_rwait, 24), PV_LEFT },
{ ORDATA (UST0, mta_unit[0].USTAT, 32) },
{ ORDATA (UST1, mta_unit[1].USTAT, 32) },
{ ORDATA (UST2, mta_unit[2].USTAT, 32) },
{ ORDATA (UST3, mta_unit[3].USTAT, 32) },
{ ORDATA (UST4, mta_unit[4].USTAT, 32) },
{ ORDATA (UST5, mta_unit[5].USTAT, 32) },
{ ORDATA (UST6, mta_unit[6].USTAT, 32) },
{ ORDATA (UST7, mta_unit[7].USTAT, 32) },
{ DRDATA (POS0, mta_unit[0].pos, 31), REG_RO + PV_LEFT },
{ DRDATA (POS1, mta_unit[1].pos, 31), REG_RO + PV_LEFT },
{ DRDATA (POS2, mta_unit[2].pos, 31), REG_RO + PV_LEFT },
{ DRDATA (POS3, mta_unit[3].pos, 31), REG_RO + PV_LEFT },
{ DRDATA (POS4, mta_unit[4].pos, 31), REG_RO + PV_LEFT },
{ DRDATA (POS5, mta_unit[5].pos, 31), REG_RO + PV_LEFT },
{ DRDATA (POS6, mta_unit[6].pos, 31), REG_RO + PV_LEFT },
{ DRDATA (POS7, mta_unit[7].pos, 31), REG_RO + PV_LEFT },
{ GRDATA (FLG0, mta_unit[0].flags, 8, UNIT_W_UF, UNIT_V_UF - 1),
REG_HRO },
{ GRDATA (FLG1, mta_unit[1].flags, 8, UNIT_W_UF, UNIT_V_UF - 1),
REG_HRO },
{ GRDATA (FLG2, mta_unit[2].flags, 8, UNIT_W_UF, UNIT_V_UF - 1),
REG_HRO },
{ GRDATA (FLG3, mta_unit[3].flags, 8, UNIT_W_UF, UNIT_V_UF - 1),
REG_HRO },
{ GRDATA (FLG4, mta_unit[4].flags, 8, UNIT_W_UF, UNIT_V_UF - 1),
REG_HRO },
{ GRDATA (FLG5, mta_unit[5].flags, 8, UNIT_W_UF, UNIT_V_UF - 1),
REG_HRO },
{ GRDATA (FLG6, mta_unit[6].flags, 8, UNIT_W_UF, UNIT_V_UF - 1),
REG_HRO },
{ GRDATA (FLG7, mta_unit[7].flags, 8, UNIT_W_UF, UNIT_V_UF - 1),
REG_HRO },
{ NULL } };
MTAB mta_mod[] = {
{ UNIT_WLK, 0, "write enabled", "ENABLED", &mta_vlock },
{ UNIT_WLK, UNIT_WLK, "write locked", "LOCKED", &mta_vlock },
{ 0 } };
DEVICE mta_dev = {
"MT", mta_unit, mta_reg, mta_mod,
MTA_NUMDR, 10, 31, 1, 8, 8,
NULL, NULL, &mta_reset,
&mta_boot, &mta_attach, &mta_detach };
/* IOT routine */
int32 mta (int32 pulse, int32 code, int32 AC)
{
UNIT *uptr;
int32 u, c, rval;
rval = 0;
uptr = mta_dev.units + GET_UNIT(mta_cu); /* get unit */
switch (code) { /* decode IR<5:7> */
case ioDIA: /* DIA */
rval = (mta_updcsta (uptr) >> 16) & DMASK; /* return status 1 */
break;
case ioDOA: /* DOA */
/* if (AC & CU_CI) ... clear ep int */
mta_cu = AC; /* save cmd/unit */
uptr = mta_dev.units + GET_UNIT(mta_cu); /* get unit */
mta_updcsta (uptr); /* update status */
break;
case ioDIB: /* DIB */
rval = mta_ma & AMASK; /* return ma */
break;
case ioDOB: /* DOB */
mta_ma = AC & AMASK; /* save ma */
break;
case ioDIC: /* DIC */
rval = mta_updcsta (uptr) & DMASK; /* return status 2 */
break;
case ioDOC: /* DOC */
mta_wc = ((AC & 040000) << 1) | (AC & 077777); /* save wc */
break; } /* end switch code */
/* IOT, continued */
switch (pulse) { /* decode IR<8:9> */
case iopS: /* start */
c = GET_CMD (mta_cu); /* get command */
if (dev_busy & INT_MTA) break; /* ignore if busy */
if ((uptr -> USTAT & STA_RDY) == 0) { /* drive not ready? */
mta_sta = mta_sta | STA_ILL; /* illegal op */
dev_busy = dev_busy & ~INT_MTA; /* clear busy */
dev_done = dev_done | INT_MTA; /* set done */
int_req = (int_req & ~INT_DEV) | (dev_done & ~dev_disable); }
else if ((c == CU_REWIND) || (c == CU_UNLOAD)) { /* rewind, unload? */
mta_upddsta (uptr, (uptr -> USTAT & /* update status */
~(STA_BOT | STA_EOF | STA_EOT | STA_RDY)) | STA_REW);
sim_activate (uptr, mta_rwait); /* start IO */
if (c == CU_UNLOAD) detach_unit (uptr); }
else { mta_sta = 0; /* clear errors */
dev_busy = dev_busy | INT_MTA; /* set busy */
dev_done = dev_done & ~INT_MTA; /* clear done */
int_req = int_req & ~INT_MTA; /* clear int */
if (ctype[c]) sim_activate (uptr, mta_cwait);
else { mta_upddsta (uptr, uptr -> USTAT &
~(STA_BOT | STA_EOF | STA_EOT | STA_RDY));
sim_activate (uptr, mta_rwait); } }
mta_updcsta (uptr); /* update status */
break;
case iopC: /* clear */
for (u = 0; u < MTA_NUMDR; u++) { /* loop thru units */
uptr = mta_dev.units + u; /* cancel IO */
if (sim_is_active (uptr) && !(uptr -> USTAT & STA_REW)) {
mta_upddsta (uptr, uptr -> USTAT | STA_RDY);
sim_cancel (uptr); } }
dev_busy = dev_busy & ~INT_MTA; /* clear busy */
dev_done = dev_done & ~INT_MTA; /* clear done */
int_req = int_req & ~INT_MTA; /* clear int */
mta_sta = mta_cu = mta_ma = 0; /* clear registers */
mta_updcsta (&mta_unit[0]); /* update status */
break; } /* end case pulse */
return rval;
}
/* Unit service
If rewind done, reposition to start of tape, set status
else, do operation, clear busy, set done, interrupt
*/
t_stat mta_svc (UNIT *uptr)
{
int32 c, i, p, u, err;
t_stat rval;
t_mtrlnt cbc, tbc, wc;
unsigned int16 c1, c2;
unsigned int8 dbuf[2 * DTSIZE];
static t_mtrlnt bceof = { 0 };
rval = SCPE_OK;
u = uptr -> UNUM; /* get unit number */
if (uptr -> USTAT & STA_REW) { /* rewind? */
uptr -> pos = 0; /* update position */
mta_upddsta (uptr, (uptr -> USTAT & ~STA_REW) | STA_BOT | STA_RDY);
if (u == GET_UNIT (mta_cu)) mta_updcsta (uptr);
return rval; }
err = 0;
c = GET_CMD (mta_cu); /* command */
wc = DTSIZE - (mta_wc & DTMASK); /* io wc */
if ((uptr -> flags & UNIT_ATT) == 0) { /* not attached? */
mta_upddsta (uptr, 0); /* unit off line */
mta_sta = mta_sta | STA_ILL; } /* illegal operation */
else if ((uptr -> flags & UNIT_WLK) && /* write locked? */
((c == CU_WRITE) || (c == CU_WREOF) || (c == CU_ERASE))) {
mta_upddsta (uptr, uptr -> USTAT | STA_WLK | STA_RDY);
mta_sta = mta_sta | STA_ILL; } /* illegal operation */
else switch (c) { /* case on command */
case CU_CMODE: /* controller mode */
mta_ep = mta_cu & CU_EP;
break;
case CU_DMODE: /* drive mode */
if (uptr -> pos) mta_sta = mta_sta | STA_ILL; /* must be BOT */
else mta_upddsta (uptr, (mta_cu & CU_PE)? /* update drv status */
uptr -> USTAT | STA_PEM: uptr -> USTAT & ~ STA_PEM);
break;
/* Unit service, continued */
case CU_READ: /* read */
case CU_READNS: /* read non-stop */
fseek (uptr -> fileref, uptr -> pos, SEEK_SET);
fxread (&tbc, sizeof (t_mtrlnt), 1, uptr -> fileref); /* read byte count */
if ((err = ferror (uptr -> fileref)) || /* error or eof? */
(feof (uptr -> fileref))) {
mta_upddsta (uptr, uptr -> USTAT | STA_RDY | STA_EOT);
break; }
if (tbc == 0) { /* tape mark? */
mta_upddsta (uptr, uptr -> USTAT | STA_RDY | STA_EOF);
uptr -> pos = uptr -> pos + sizeof (t_mtrlnt);
break; }
tbc = MTRL (tbc); /* ignore error flag */
cbc = wc * 2; /* expected bc */
if (tbc & 1) mta_sta = mta_sta | STA_ODD; /* odd byte count? */
if (tbc > cbc) mta_sta = mta_sta | STA_WCO; /* too big? */
else { cbc = tbc; /* no, use it */
wc = (cbc + 1) / 2; } /* adjust wc */
i = fxread (dbuf, sizeof (int8), cbc, uptr -> fileref);
for ( ; i < cbc; i++) dbuf[i] = 0;
err = ferror (uptr -> fileref);
for (i = p = 0; i < wc; i++) { /* copy buf to mem */
c1 = dbuf[p++];
c2 = dbuf[p++];
if (MEM_ADDR_OK (mta_ma)) M[mta_ma] = (c1 << 8) | c2;
mta_ma = (mta_ma + 1) & AMASK; }
mta_wc = (mta_wc + wc) & DMASK;
uptr -> pos = uptr -> pos + ((tbc + 1) & ~1) +
(2 * sizeof (t_mtrlnt));
mta_upddsta (uptr, uptr -> USTAT | STA_RDY);
break;
case CU_WRITE: /* write */
fseek (uptr -> fileref, uptr -> pos, SEEK_SET);
tbc = wc * 2; /* io byte count */
fxwrite (&tbc, sizeof (t_mtrlnt), 1, uptr -> fileref);
for (i = p = 0; i < wc; i++) { /* copy to buffer */
dbuf[p++] = (M[mta_ma] >> 8) & 0377;
dbuf[p++] = M[mta_ma] & 0377;
mta_ma = (mta_ma + 1) & AMASK; }
fxwrite (dbuf, sizeof (int8), tbc, uptr -> fileref);
fxwrite (&tbc, sizeof (t_mtrlnt), 1, uptr -> fileref);
err = ferror (uptr -> fileref);
mta_wc = 0;
uptr -> pos = uptr -> pos + tbc + (2 * sizeof (t_mtrlnt));
mta_upddsta (uptr, uptr -> USTAT | STA_RDY);
break;
case CU_WREOF: /* write eof */
fseek (uptr -> fileref, uptr -> pos, SEEK_SET);
fxwrite (&bceof, sizeof (t_mtrlnt), 1, uptr -> fileref);
err = ferror (uptr -> fileref);
uptr -> pos = uptr -> pos + sizeof (t_mtrlnt);
mta_upddsta (uptr, uptr -> USTAT | STA_EOF | STA_RDY);
break;
case CU_ERASE: /* erase */
mta_upddsta (uptr, uptr -> USTAT | STA_RDY);
break;
/* Unit service, continued */
case CU_SPACEF: /* space forward */
do { mta_wc = (mta_wc + 1) & DMASK; /* incr wc */
fseek (uptr -> fileref, uptr -> pos, SEEK_SET);
fxread (&tbc, sizeof (t_mtrlnt), 1, uptr -> fileref);
if ((err = ferror (uptr -> fileref)) || /* error or eof? */
(feof (uptr -> fileref))) {
mta_upddsta (uptr, uptr -> USTAT | STA_RDY | STA_EOT);
break; }
if (tbc == 0) { /* zero bc? */
mta_upddsta (uptr, uptr -> USTAT | STA_RDY | STA_EOF);
uptr -> pos = uptr -> pos + sizeof (t_mtrlnt);
break; }
uptr -> pos = uptr -> pos + ((MTRL (tbc) + 1) & ~1) +
(2 * sizeof (t_mtrlnt)); }
while (mta_wc != 0);
mta_upddsta (uptr, uptr -> USTAT | STA_RDY);
break;
case CU_SPACER: /* space reverse */
if (uptr -> pos == 0) { /* at BOT? */
mta_upddsta (uptr, uptr -> USTAT | STA_RDY | STA_BOT);
break; }
do { mta_wc = (mta_wc + 1) & DMASK; /* incr wc */
fseek (uptr -> fileref, uptr -> pos - sizeof (t_mtrlnt),
SEEK_SET); /* bs to reclnt */
fxread (&tbc, sizeof (t_mtrlnt), 1, uptr -> fileref);
if ((err = ferror (uptr -> fileref)) || /* error or eof? */
(feof (uptr -> fileref))) {
mta_upddsta (uptr, uptr -> USTAT | STA_RDY | STA_BOT);
uptr -> pos = 0;
break; }
if (tbc == 0) { /* zero bc? */
mta_upddsta (uptr, uptr -> USTAT | STA_RDY | STA_EOF);
uptr -> pos = uptr -> pos - sizeof (t_mtrlnt);
break; }
uptr -> pos = uptr -> pos - ((MTRL (tbc) + 1) & ~1) -
(2 * sizeof (t_mtrlnt));
if (uptr -> pos == 0) { /* start of tape? */
mta_upddsta (uptr, uptr -> USTAT | STA_RDY | STA_BOT);
break; } }
while (mta_wc != 0);
mta_upddsta (uptr, uptr -> USTAT | STA_RDY);
break;
default: /* reserved */
mta_sta = mta_sta | STA_ILL;
break; } /* end case */
/* Unit service, continued */
if (err != 0) { /* I/O error */
mta_sta = mta_sta | STA_DAE; /* flag error */
perror ("MTA I/O error");
rval = SCPE_IOERR;
clearerr (uptr -> fileref); }
mta_updcsta (uptr); /* update status */
dev_busy = dev_busy & ~INT_MTA; /* clear busy */
dev_done = dev_done | INT_MTA; /* set done */
int_req = (int_req & ~INT_DEV) | (dev_done & ~dev_disable);
return rval;
}
/* Update controller status */
int32 mta_updcsta (UNIT *uptr) /* update ctrl */
{
mta_sta = (mta_sta & ~(STA_DYN | STA_CLR | STA_ERR1 | STA_ERR2)) |
(uptr -> USTAT & STA_DYN) | STA_SET;
if (mta_sta & STA_EFLGS1) mta_sta = mta_sta | STA_ERR1;
if (mta_sta & STA_EFLGS2) mta_sta = mta_sta | STA_ERR2;
return mta_sta;
}
/* Update drive status */
void mta_upddsta (UNIT *uptr, int32 newsta) /* drive status */
{
int32 change;
if ((uptr -> flags & UNIT_ATT) == 0) newsta = 0; /* offline? */
change = (uptr -> USTAT ^ newsta) & STA_MON; /* changes? */
uptr -> USTAT = newsta & STA_DYN; /* update status */
if (change) {
/* if (mta_ep) { /* if polling */
/* u = uptr -> UNUM; /* unit num */
/* mta_sta = (mta_sta & ~STA_UNIT) | (u << STA_V_UNIT);
/* set polling interupt... } */
mta_sta = mta_sta | STA_CHG; } /* flag change */
return;
}
/* Reset routine */
t_stat mta_reset (DEVICE *dptr)
{
int32 u;
UNIT *uptr;
dev_busy = dev_busy & ~INT_MTA; /* clear busy */
dev_done = dev_done & ~INT_MTA; /* clear done, int */
int_req = int_req & ~INT_MTA;
mta_cu = mta_wc = mta_ma = mta_sta = 0; /* clear registers */
mta_ep = 0;
for (u = 0; u < MTA_NUMDR; u++) { /* loop thru units */
uptr = mta_dev.units + u;
sim_cancel (uptr); /* cancel activity */
uptr -> UNUM = u;
if (uptr -> flags & UNIT_ATT) uptr -> USTAT = STA_RDY |
(uptr -> USTAT & STA_PEM) |
((uptr -> flags & UNIT_WLK)? STA_WLK: 0) |
((uptr -> pos)? 0: STA_BOT);
else uptr -> USTAT = 0; }
mta_updcsta (&mta_unit[0]); /* update status */
return SCPE_OK;
}
/* Attach routine */
t_stat mta_attach (UNIT *uptr, char *cptr)
{
t_stat r;
r = attach_unit (uptr, cptr);
if (r != SCPE_OK) return r;
if (!sim_is_active (uptr)) mta_upddsta (uptr, STA_RDY | STA_BOT | STA_PEM |
((uptr -> flags & UNIT_WLK)? STA_WLK: 0));
return r;
}
/* Detach routine */
t_stat mta_detach (UNIT* uptr)
{
if (!sim_is_active (uptr)) mta_upddsta (uptr, 0);
return detach_unit (uptr);
}
/* Write lock/unlock validate routine */
t_stat mta_vlock (UNIT *uptr, int32 val)
{
if ((uptr -> flags & UNIT_ATT) && val)
mta_upddsta (uptr, uptr -> USTAT | STA_WLK);
else mta_upddsta (uptr, uptr -> USTAT & ~STA_WLK);
return SCPE_OK;
}
/* Bootstrap routine */
#define BOOT_START 02000
#define BOOT_UNIT 02020
#define BOOT_LEN (sizeof (boot_rom) / sizeof (int))
static const int32 boot_rom[] = {
060222, /* NIOC 0,MTA ; clear disk */
020417, /* LDA 0,UNIT ; unit */
024417, /* LDA 1,REWIND ; cmd */
0107000, /* ADD 0,1 ; cmd + unit */
065122, /* DOAS 1,MTA ; start rewind */
070422, /* DIA 2,MTA ; get status */
0151213, /* MOVR# 2,2,SNC ; skip if done */
000776, /* JMP .-2 */
0126400, /* SUB 1,1 ; ma, wc = 0 */
066022, /* DOB 1,MTA */
067022, /* DOC 1,MTA */
061122, /* DOAS 0,MTA ; start read */
070422, /* DIA 2,MTA ; get status */
0151213, /* MOVR# 2,2,SNC ; skip if done */
000776, /* JMP .-2 */
000377, /* JMP 377 */
000000, /* UNIT: */
000010 /* REWIND: 10 */
};
t_stat mta_boot (int32 unitno)
{
int32 i;
extern int32 saved_PC;
for (i = 0; i < BOOT_LEN; i++) M[BOOT_START + i] = boot_rom[i];
M[BOOT_UNIT] = (unitno & CU_M_UNIT) << CU_V_UNIT;
saved_PC = BOOT_START;
return SCPE_OK;
}