t_stat dp_attach(UNIT *uptr, CONST char *cptr)
{
struct dpio_unit *iou = (struct dpio_unit *)uptr->up7;
const char *drivetype = ((uptr->flags & UNIT_854) != 0) ? "854" : "853";
t_addr capac = ((uptr->flags & UNIT_854) != 0) ? DP854_SIZE : DP853_SIZE;
t_stat r;
uptr->capac = capac;
r = attach_unit(uptr, cptr);
if (r != SCPE_OK)
return r;
/*
* If this is a newly created file, set the drive size appropriately.
*/
if (sim_fsize_ex(uptr->fileref) == 0)
sim_set_fsize(uptr->fileref, capac);
if (sim_fsize_ex(uptr->fileref) != capac) {
if (ExecutionStarted) {
detach_unit(uptr);
return sim_messagef(SCPE_OPENERR, "Unable to autosize drive after execution started\n");
}
/*
* This is not the correct size according the drive type but this is the
* first attach. Force the drive to match the size of the disk.
*/
switch (sim_fsize_ex(uptr->fileref)) {
case DP854_SIZE:
uptr->capac = DP854_SIZE;
uptr->flags |= UNIT_854;
break;
case DP853_SIZE:
uptr->capac = DP853_SIZE;
uptr->flags &= ~UNIT_854;
break;
default:
detach_unit(uptr);
return sim_messagef(SCPE_OPENERR, "Unsupported disk size\n");
}
}
/*
* Set unit to cylinder 0, head 0, sector 0 and indicate on-cylinder.
*/
iou->cylinder = 0;
iou->head = 0;
iou->sector = 0;
iou->oncyl = TRUE;
return SCPE_OK;
}
/* Detach routine */
t_stat mfdc_detach(UNIT *uptr)
{
t_stat r;
int8 i;
for(i = 0; i < MFDC_MAX_DRIVES; i++) {
if(mfdc_dev.units[i].fileref == uptr->fileref) {
break;
}
}
if (i >= MFDC_MAX_DRIVES)
return SCPE_ARG;
DBG_PRINT(("Detach MFDC%d\n", i));
r = diskClose(&mfdc_info->drive[i].imd);
if (r != SCPE_OK)
return r;
r = detach_unit(uptr); /* detach unit */
if (r != SCPE_OK)
return r;
return SCPE_OK;
}
/* Detach routine */
t_stat hdc1001_detach(UNIT *uptr)
{
HDC1001_DRIVE_INFO *pDrive;
t_stat r;
int8 i;
i = find_unit_index(uptr);
if (i == -1) {
return (SCPE_IERR);
}
pDrive = &hdc1001_info->drive[i];
pDrive->ready = 0;
if (uptr->flags & UNIT_HDC1001_VERBOSE)
printf("Detach HDC1001%d\n", i);
r = detach_unit(uptr); /* detach unit */
if ( r != SCPE_OK)
return r;
return SCPE_OK;
}
/* Detach routine */
static t_stat disk3_detach(UNIT *uptr)
{
DISK3_DRIVE_INFO *pDrive;
t_stat r;
int8 i;
i = find_unit_index(uptr);
if (i == -1) {
return (SCPE_IERR);
}
pDrive = &disk3_info->drive[i];
pDrive->ready = 0;
if (uptr->flags & UNIT_DISK3_VERBOSE)
printf("Detach DISK3%d\n", i);
r = detach_unit(uptr); /* detach unit */
if ( r != SCPE_OK)
return r;
return SCPE_OK;
}
t_stat rp_detach (UNIT *uptr)
{
t_stat reason;
reason = detach_unit (uptr);
rp_updsta (0, 0);
return reason;
}
t_stat clk_detach (UNIT *uptr)
{
t_stat r;
r = detach_unit (uptr);
if ((uptr->flags & UNIT_ATT) == 0)
uptr->flags = uptr->flags & ~(UNIT_ATTABLE | UNIT_BUFABLE);
return r;
}
t_stat cdp_detach (UNIT *uptr)
{
t_stat r;
r = cdp_npr (NULL, 0, NULL, NULL);
if (r != SCPE_OK)
return r;
return detach_unit (uptr);
}
t_stat dp_detach (UNIT *uptr)
{
uint32 u = uptr - dp_dev.units;
if (!(uptr->flags & UNIT_ATT)) /* attached? */
return SCPE_OK;
if (dpd_arm[u]) /* if arm, intr */
SET_INT (v_DPC + u + 1);
return detach_unit (uptr);
}
t_stat dp_detach(UNIT *uptr)
{
struct dpio_unit *iou = (struct dpio_unit *)uptr->up7;
t_stat stat;
sim_cancel(uptr);
stat = detach_unit(uptr);
iou->oncyl = FALSE;
return stat;
}
t_stat cdr_detach (UNIT *uptr)
{
t_stat r;
cdr_unit.flags |= UNIT_ATTABLE; /* must be attachable */
r = detach_unit (uptr); /* detach */
if (((cdr_unit.flags & UNIT_ATT) == 0) && /* attached clear? */
((cdr_unit.flags & UNIT_CONS) != 0)) /* default on? */
cdr_unit.flags &= ~UNIT_ATTABLE; /* clear attachable */
return r;
}
static t_stat hdsk_detach(UNIT *uptr) {
t_stat result;
if (uptr == NULL)
return SCPE_IERR;
result = detach_unit(uptr);
uptr -> capac = HDSK_CAPACITY;
uptr -> HDSK_FORMAT_TYPE = 0;
uptr -> HDSK_SECTOR_SIZE = 0;
uptr -> HDSK_SECTORS_PER_TRACK = 0;
uptr -> HDSK_NUMBER_OF_TRACKS = 0;
return result;
}
static t_stat hdsk_detach(UNIT *uptr) {
t_stat result;
int32 unitIndex;
if (uptr == NULL)
return SCPE_IERR;
if (is_imd(uptr)) {
unitIndex = find_unit_index(uptr);
if (unitIndex == -1)
return SCPE_IERR;
assert((0 <= unitIndex) && (unitIndex < HDSK_NUMBER));
diskClose(&hdsk_imd[unitIndex]);
}
result = detach_unit(uptr);
uptr -> capac = HDSK_CAPACITY;
uptr -> HDSK_FORMAT_TYPE = 0;
uptr -> HDSK_SECTOR_SIZE = 0;
uptr -> HDSK_SECTORS_PER_TRACK = 0;
uptr -> HDSK_NUMBER_OF_TRACKS = 0;
return result;
}
/* Detach routine */
static t_stat vfdhd_detach(UNIT *uptr)
{
t_stat r;
int8 i;
for(i = 0; i < VFDHD_MAX_DRIVES; i++) {
if(vfdhd_dev.units[i].fileref == uptr->fileref) {
break;
}
}
DBG_PRINT(("Detach VFDHD%d\n", i));
r = diskClose(&vfdhd_info->drive[i].imd);
if (r != SCPE_OK)
return r;
r = detach_unit(uptr); /* detach unit */
if (r != SCPE_OK)
return r;
return SCPE_OK;
}
/* Detach routine */
t_stat mdsad_detach(UNIT *uptr)
{
t_stat r;
int8 i;
for(i = 0; i < MDSAD_MAX_DRIVES; i++) {
if(mdsad_dev.units[i].fileref == uptr->fileref) {
break;
}
}
if (i >= MDSAD_MAX_DRIVES)
return SCPE_ARG;
DBG_PRINT(("Detach MDSAD%d\n", i));
r = detach_unit(uptr); /* detach unit */
if(r != SCPE_OK)
return r;
mdsad_dev.units[i].fileref = NULL;
return SCPE_OK;
}
/* Detach routine */
t_stat wd179x_detach(UNIT *uptr)
{
t_stat r;
int8 i;
i = find_unit_index(uptr);
if (i == -1) {
return SCPE_IERR;
}
DBG_PRINT(("Detach WD179X%d\n", i));
r = diskClose(&wd179x_info->drive[i].imd);
wd179x_info->drive[i].ready = 0;
if (r != SCPE_OK)
return r;
r = detach_unit(uptr); /* detach unit */
if (r != SCPE_OK)
return r;
return SCPE_OK;
}
/* Detach routine */
t_stat i8272_detach(UNIT *uptr)
{
t_stat r;
int8 i;
i = find_unit_index(uptr);
if (i == -1) {
return (SCPE_IERR);
}
DBG_PRINT(("Detach I8272%d\n", i));
r = diskClose(&i8272_info->drive[i].imd);
i8272_info->drive[i].ready = 0;
if (r != SCPE_OK)
return r;
r = detach_unit(uptr); /* detach unit */
if (r != SCPE_OK)
return r;
return SCPE_OK;
}
t_stat sim_tape_detach (UNIT *uptr)
{
uint32 f = MT_GET_FMT (uptr);
t_stat r;
r = detach_unit (uptr); /* detach unit */
if (r != SCPE_OK)
return r;
switch (f) { /* case on format */
case MTUF_F_TPC: /* TPC */
if (uptr->filebuf) /* free map */
free (uptr->filebuf);
uptr->filebuf = NULL;
uptr->hwmark = 0;
break;
default:
break;
}
sim_tape_rewind (uptr);
return SCPE_OK;
}
t_stat dp_svc (UNIT *uptr)
{
int32 dcyl = 0; /* assume recalibrate */
int32 ch = dp_dib.chan - 1; /* DMA/DMC chan */
uint32 h = CW1_GETHEAD (dp_cw1); /* head */
int32 st;
uint32 i, offs, lnt, ming, tpos;
t_stat r;
if (!(uptr->flags & UNIT_ATT)) { /* not attached? */
dp_done (1, STA_OFLER); /* offline */
return IORETURN (dp_stopioe, SCPE_UNATT);
}
switch (uptr->FNC) { /* case on function */
case FNC_SEEK: /* seek, need cyl */
offs = CW1_GETOFFS (dp_cw1); /* get offset */
if (dp_cw1 & CW1_DIR) /* get desired cyl */
dcyl = uptr->CYL - offs;
else dcyl = uptr->CYL + offs;
if ((offs == 0) ||
(dcyl < 0) ||
(dcyl >= (int32) dp_tab[dp_ctype].cyl))
return dp_done (1, STA_SEKER); /* bad seek? */
case FNC_SK0: /* recalibrate */
dp_sta = dp_sta & ~STA_BUSY; /* clear busy */
uptr->FNC = FNC_SEEK | FNC_2ND; /* next state */
st = (abs (dcyl - uptr->CYL)) * dp_stime; /* schedule seek */
if (st == 0)
st = dp_stime;
uptr->CYL = dcyl; /* put on cylinder */
sim_activate (uptr, st);
return SCPE_OK;
case FNC_SEEK | FNC_2ND: /* seek, 2nd state */
if (dp_sta & STA_BUSY) /* busy? queue intr */
dp_defint = 1;
else SET_INT (INT_DP); /* no, req intr */
return SCPE_OK;
case FNC_UNL: /* unload */
detach_unit (uptr); /* detach unit */
return dp_done (0, 0); /* clear busy, no intr */
case FNC_RCA: /* read current addr */
if (h >= dp_tab[dp_ctype].surf) /* invalid head? */
return dp_done (1, STA_ADRER); /* error */
if (r = dp_rdtrk (uptr, dpxb, uptr->CYL, h)) /* get track; error? */
return r;
dp_rptr = 0; /* init rec ptr */
if (dpxb[dp_rptr + REC_LNT] == 0) /* unformated? */
return dp_done (1, STA_ADRER); /* error */
tpos = (uint32) (fmod (sim_gtime () / (double) dp_xtime, DP_TRKLEN));
do { /* scan down track */
dp_buf = dpxb[dp_rptr + REC_ADDR]; /* get rec addr */
dp_rptr = dp_rptr + dpxb[dp_rptr + REC_LNT] + REC_OVHD;
} while ((dp_rptr < tpos) && (dpxb[dp_rptr + REC_LNT] != 0));
if (dp_dma) { /* DMA/DMC? */
if (Q_DMA (ch)) /* DMA? */
dma_ad[ch] = dma_ad[ch] | DMA_IN; /* force input */
SET_CH_REQ (ch); /* request chan */
}
return dp_done (1, STA_RDY); /* clr busy, set rdy */
/* Formating takes place in five states:
init - clear track buffer, start at first record
address - store address word
data - store data word(s) until end of range
pause - wait for gap word or stop command
gap - validate gap word, advance to next record
Note that formating is stopped externally by an OCP command; the
track buffer is flushed at that point. If the stop does not occur
in the proper state (gap word received), a format error occurs.
*/
case FNC_FMT: /* format */
for (i = 0; i < DP_TRKLEN; i++) /* clear track */
dpxb[i] = 0;
dp_xip = dp_xip | XIP_FMT; /* format in progress */
dp_rptr = 0; /* init record ptr */
dp_gap = 0; /* no gap before first */
dp_bctr = (uint32) (16.0 * dp_tab[dp_ctype].wrds); /* init bit cntr */
uptr->FNC = uptr->FNC | FNC_2ND; /* address state */
break; /* set up next word */
case FNC_FMT | FNC_2ND: /* format, address word */
dp_wptr = 0; /* clear word ptr */
if (dp_bctr < (dp_gap + REC_OVHD_BITS + 16)) /* room for gap, record? */
return dp_wrdone (uptr, STA_FMTER); /* no, format error */
dp_bctr = dp_bctr - dp_gap - REC_OVHD_BITS; /* charge for gap, ovhd */
dpxb[dp_rptr + REC_ADDR] = dp_buf; /* store address */
uptr->FNC = FNC_FMT | FNC_3RD; /* data state */
if (dp_eor) { /* record done? */
dp_eor = 0; /* clear for restart */
if (dp_dma) /* DMA/DMC? intr */
SET_INT (INT_DP);
}
break; /* set up next word */
case FNC_FMT | FNC_3RD: /* format, data word */
if (dp_sta & STA_RDY) /* timing failure? */
return dp_wrdone (uptr, STA_DTRER); /* write trk, err */
else { /* no, have word */
if (dp_bctr < 16) /* room for it? */
return dp_wrdone (uptr, STA_FMTER); /* no, error */
dp_bctr = dp_bctr - 16; /* charge for word */
dp_csum = dp_csum ^ dp_buf; /* update checksum */
dpxb[dp_rptr + REC_DATA + dp_wptr] = dp_buf;/* store word */
dpxb[dp_rptr + REC_LNT]++; /* incr rec lnt */
dp_wptr++; /* incr word ptr */
}
if (dp_eor) { /* record done? */
dp_eor = 0; /* clear for restart */
if (dp_dma) /* DMA/DMC? intr */
SET_INT (INT_DP);
dpxb[dp_rptr + REC_DATA + dp_wptr] = dp_csum; /* store checksum */
uptr->FNC = uptr->FNC | FNC_4TH; /* pause state */
sim_activate (uptr, 5 * dp_xtime); /* schedule pause */
return SCPE_OK; /* don't request word */
}
break; /* set up next word */
case FNC_FMT | FNC_4TH: /* format, pause */
uptr->FNC = FNC_FMT | FNC_5TH; /* gap state */
break; /* request word */
case FNC_FMT | FNC_5TH: /* format, gap word */
ming = ((16 * dp_wptr) + REC_OVHD_BITS) / 20; /* min 5% gap */
if (dp_buf < ming) /* too small? */
return dp_wrdone (uptr, STA_FMTER); /* yes, format error */
dp_rptr = dp_rptr + dp_wptr + REC_OVHD; /* next record */
uptr->FNC = FNC_FMT | FNC_2ND; /* address state */
if (dp_eor) { /* record done? */
dp_eor = 0; /* clear for restart */
if (dp_dma) SET_INT (INT_DP); /* DMA/DMC? intr */
}
dp_gap = dp_buf; /* save gap */
dp_csum = 0; /* clear checksum */
break; /* set up next word */
/* Read and write take place in two states:
init - read track into buffer, find record, validate parameters
data - (read) fetch data from buffer, stop on end of range
- (write) write data into buffer, flush on end of range
*/
case FNC_RW: /* read/write */
if (h >= dp_tab[dp_ctype].surf) /* invalid head? */
return dp_done (1, STA_ADRER); /* error */
if (r = dp_rdtrk (uptr, dpxb, uptr->CYL, h)) /* get track; error? */
return r;
if (!dp_findrec (dp_cw2)) /* find rec; error? */
return dp_done (1, STA_ADRER); /* address error */
if ((dpxb[dp_rptr + REC_LNT] >= (DP_TRKLEN - dp_rptr - REC_OVHD)) ||
(dpxb[dp_rptr + REC_EXT] >= REC_MAXEXT)) { /* bad lnt or ext? */
dp_done (1, STA_UNSER); /* stop simulation */
return STOP_DPFMT; /* bad format */
}
uptr->FNC = uptr->FNC | FNC_2ND; /* next state */
if (dp_cw1 & CW1_RW) { /* write? */
if (uptr->flags & UNIT_WPRT) /* write protect? */
return dp_done (1, STA_WPRER); /* error */
dp_xip = dp_xip | XIP_WRT; /* write in progress */
dp_sta = dp_sta | STA_RDY; /* set ready */
if (dp_dma) /* if DMA/DMC, req chan */
SET_CH_REQ (ch);
}
else if (Q_DMA (ch)) /* read; DMA? */
dma_ad[ch] = dma_ad[ch] | DMA_IN; /* force input */
sim_activate (uptr, dp_xtime); /* schedule word */
dp_wptr = 0; /* init word pointer */
return SCPE_OK;
case FNC_RW | FNC_2ND: /* read/write, word */
if (dp_cw1 & CW1_RW) { /* write? */
if (dp_sta & STA_RDY) /* timing failure? */
return dp_wrdone (uptr, STA_DTRER); /* yes, error */
if (r = dp_wrwd (uptr, dp_buf)) /* wr word, error? */
return r;
if (dp_eor) { /* transfer done? */
dpxb[dp_rptr + REC_DATA + dp_wptr] = dp_csum;
return dp_wrdone (uptr, 0); /* clear busy, intr req */
}
}
else { /* read? */
lnt = dpxb[dp_rptr + REC_LNT] + dpxb[dp_rptr + REC_EXT];
dp_buf = dpxb[dp_rptr + REC_DATA + dp_wptr];/* current word */
dp_csum = dp_csum ^ dp_buf; /* xor to csum */
if ((dp_wptr > lnt) || dp_eor) /* transfer done? */
return dp_done (1,
(dp_csum? STA_CSMER: 0) | ((dp_wptr >= lnt)? STA_EOR: 0));
if (dp_sta & STA_RDY) /* data buf full? */
return dp_done (1, STA_DTRER); /* no, underrun */
dp_wptr++; /* next word */
}
break;
default:
return SCPE_IERR;
} /* end case */
dp_sta = dp_sta | STA_RDY; /* set ready */
if (dp_dma) /* if DMA/DMC, req chan */
SET_CH_REQ (ch);
sim_activate (uptr, dp_xtime); /* schedule word */
return SCPE_OK;
}
t_stat mtu_svc (UNIT *uptr)
{
uint32 cmd = uptr->UCMD;
uint32 un = uptr - mt_unit;
uint32 c;
uint32 st;
int32 t;
t_mtrlnt tbc;
t_stat r;
if (cmd == MCM_INIT) { /* init state */
if ((t = sim_activate_time (uptr + MT_REW)) != 0) { /* rewinding? */
sim_activate (uptr, t); /* retry later */
return SCPE_OK;
}
st = chan_get_cmd (mt_dib.dva, &cmd); /* get command */
if (CHS_IFERR (st)) /* channel error? */
return mt_chan_err (st);
if ((cmd & 0x80) || /* invalid cmd? */
(mt_op[cmd] == 0)) {
uptr->UCMD = MCM_END; /* end state */
sim_activate (uptr, chan_ctl_time); /* resched ctlr */
return SCPE_OK;
}
else { /* valid cmd */
if ((mt_op[cmd] & O_REV) && /* reverse op */
(mt_unit[un].UST & MTDV_BOT)) { /* at load point? */
chan_uen (mt_dib.dva); /* channel end */
return SCPE_OK;
}
uptr->UCMD = cmd; /* unit state */
if (!(mt_op[cmd] & O_NMT)) /* motion? */
uptr->UST = 0; /* clear status */
}
mt_blim = 0; /* no buffer yet */
sim_activate (uptr, chan_ctl_time); /* continue thread */
return SCPE_OK; /* done */
}
if (cmd == MCM_END) { /* end state */
st = chan_end (mt_dib.dva); /* set channel end */
if (CHS_IFERR (st)) /* channel error? */
return mt_chan_err (st);
if (st == CHS_CCH) { /* command chain? */
uptr->UCMD = MCM_INIT; /* restart thread */
sim_activate (uptr, chan_ctl_time);
}
else uptr->UCMD = 0; /* ctlr idle */
return SCPE_OK; /* done */
}
if ((mt_op[cmd] & O_ATT) && /* op req att and */
((uptr->flags & UNIT_ATT) == 0)) { /* not attached? */
sim_activate (uptr, mt_ctime); /* retry */
return mt_stopioe? SCPE_UNATT: SCPE_OK;
}
if ((mt_op[cmd] & O_WRE) && /* write op and */
sim_tape_wrp (uptr)) { /* write protected? */
uptr->UST |= MTDV_WLE; /* set status */
chan_uen (mt_dib.dva); /* unusual end */
return SCPE_OK;
}
r = SCPE_OK;
switch (cmd) { /* case on command */
case MCM_SFWR: /* space forward */
if (r = sim_tape_sprecf (uptr, &tbc)) /* spc rec fwd, err? */
r = mt_map_err (uptr, r); /* map error */
break;
case MCM_SBKR: /* space reverse */
if (r = sim_tape_sprecr (uptr, &tbc)) /* spc rec rev, err? */
r = mt_map_err (uptr, r); /* map error */
break;
case MCM_SFWF: /* space fwd file */
while ((r = sim_tape_sprecf (uptr, &tbc)) == MTSE_OK) ;
if (r != MTSE_TMK) /* stopped by tmk? */
r = mt_map_err (uptr, r); /* no, map error */
else r = SCPE_OK;
break;
case MCM_SBKF: /* space rev file */
while ((r = sim_tape_sprecr (uptr, &tbc)) == MTSE_OK) ;
if (r != MTSE_TMK) /* stopped by tmk? */
r = mt_map_err (uptr, r); /* no, map error */
else r = SCPE_OK;
break;
case MCM_WTM: /* write eof */
if (r = sim_tape_wrtmk (uptr)) /* write tmk, err? */
r = mt_map_err (uptr, r); /* map error */
uptr->UST |= MTDV_EOF; /* set eof */
break;
case MCM_RWU: /* rewind unload */
r = detach_unit (uptr);
break;
case MCM_REW: /* rewind */
case MCM_RWI: /* rewind and int */
if (r = sim_tape_rewind (uptr)) /* rewind */
r = mt_map_err (uptr, r); /* map error */
mt_unit[un + MT_REW].UCMD = uptr->UCMD; /* copy command */
sim_activate (uptr + MT_REW, mt_rwtime); /* sched compl */
break;
case MCM_READ: /* read */
if (mt_blim == 0) { /* first read? */
r = sim_tape_rdrecf (uptr, mt_xb, &mt_blim, MT_MAXFR);
if (r != MTSE_OK) { /* tape error? */
r = mt_map_err (uptr, r); /* map error */
break;
}
mt_bptr = 0; /* init rec ptr */
}
c = mt_xb[mt_bptr++]; /* get char */
st = chan_WrMemB (mt_dib.dva, c); /* write to memory */
if (CHS_IFERR (st)) /* channel error? */
return mt_chan_err (st);
if ((st != CHS_ZBC) && (mt_bptr != mt_blim)) { /* not done? */
sim_activate (uptr, mt_time); /* continue thread */
return SCPE_OK;
}
if (((st == CHS_ZBC) ^ (mt_bptr == mt_blim)) && /* length err? */
chan_set_chf (mt_dib.dva, CHF_LNTE)) /* uend taken? */
return SCPE_OK; /* finished */
break; /* normal end */
case MCM_RDBK: /* read reverse */
if (mt_blim == 0) { /* first read? */
r = sim_tape_rdrecr (uptr, mt_xb, &mt_blim, MT_MAXFR);
if (r != MTSE_OK) { /* tape error? */
r = mt_map_err (uptr, r); /* map error */
break;
}
mt_bptr = mt_blim; /* init rec ptr */
}
c = mt_xb[--mt_bptr]; /* get char */
st = chan_WrMemBR (mt_dib.dva, c); /* write mem rev */
if (CHS_IFERR (st)) /* channel error? */
return mt_chan_err (st);
if ((st != CHS_ZBC) && (mt_bptr != 0)) { /* not done? */
sim_activate (uptr, mt_time); /* continue thread */
return SCPE_OK;
}
if (((st == CHS_ZBC) ^ (mt_bptr == 0)) && /* length err? */
chan_set_chf (mt_dib.dva, CHF_LNTE)) /* uend taken? */
return SCPE_OK; /* finished */
break; /* normal end */
case MCM_WRITE: /* write */
st = chan_RdMemB (mt_dib.dva, &c); /* read char */
if (CHS_IFERR (st)) { /* channel error? */
mt_flush_buf (uptr); /* flush buffer */
return mt_chan_err (st);
}
mt_xb[mt_blim++] = c; /* store in buffer */
if (st != CHS_ZBC) { /* end record? */
sim_activate (uptr, mt_time); /* continue thread */
return SCPE_OK;
}
r = mt_flush_buf (uptr); /* flush buffer */
break;
}
if (r != SCPE_OK) /* error? abort */
return CHS_IFERR(r)? SCPE_OK: r;
uptr->UCMD = MCM_END; /* end state */
sim_activate (uptr, mt_ctime); /* sched ctlr */
return SCPE_OK;
}
t_stat
lpt_detach(UNIT * uptr)
{
lpt_csr = lpt_csr | CSR_ERR;
return detach_unit(uptr);
}
/* Attach routine */
static t_stat hdsk_attach(UNIT *uptr, char *cptr) {
int32 thisUnitIndex;
char unitChar;
const t_stat r = attach_unit(uptr, cptr); /* attach unit */
if (r != SCPE_OK) /* error? */
return r;
assert(uptr != NULL);
thisUnitIndex = find_unit_index(uptr);
unitChar = '0' + thisUnitIndex;
assert((0 <= thisUnitIndex) && (thisUnitIndex < HDSK_NUMBER));
if (is_imd(uptr)) {
if ((sim_fsize(uptr -> fileref) == 0) &&
(diskCreate(uptr -> fileref, "$Id: SIMH hdsk.c $") != SCPE_OK)) {
printf("HDSK%c (IMD): Failed to create IMD disk.\n", unitChar);
detach_unit(uptr);
return SCPE_OPENERR;
}
hdsk_imd[thisUnitIndex] = diskOpen(uptr -> fileref, sim_deb && (hdsk_dev.dctrl & VERBOSE_MSG));
if (hdsk_imd[thisUnitIndex] == NULL)
return SCPE_IOERR;
verifyDiskInfo(*hdsk_imd[thisUnitIndex], '0' + thisUnitIndex);
uptr -> HDSK_NUMBER_OF_TRACKS = hdsk_imd[thisUnitIndex] -> ntracks;
uptr -> HDSK_SECTORS_PER_TRACK = hdsk_imd[thisUnitIndex] -> track[1][0].nsects;
uptr -> HDSK_SECTOR_SIZE = hdsk_imd[thisUnitIndex] -> track[1][0].sectsize;
uptr -> capac = ((uptr -> HDSK_NUMBER_OF_TRACKS) *
(uptr -> HDSK_SECTORS_PER_TRACK) *
(uptr -> HDSK_SECTOR_SIZE));
assignFormat(uptr);
if (uptr -> HDSK_FORMAT_TYPE == -1) { /* Case 1: no disk parameter block found*/
uptr -> HDSK_FORMAT_TYPE = 0;
printf("HDSK%c (IMD): WARNING: Unsupported disk capacity, assuming HDSK type "
"with capacity %iKB.\n", unitChar, uptr -> capac / 1000);
uptr -> flags |= UNIT_HDSK_WLK;
printf("HDSK%c (IMD): WARNING: Forcing WRTLCK.\n", unitChar);
}
return SCPE_OK;
}
/* Step 1: Determine capacity of this disk */
uptr -> capac = sim_fsize(uptr -> fileref); /* the file length is a good indication */
if (uptr -> capac == 0) { /* file does not exist or has length 0 */
uptr -> capac = (uptr -> HDSK_NUMBER_OF_TRACKS *
uptr -> HDSK_SECTORS_PER_TRACK * uptr -> HDSK_SECTOR_SIZE);
if (uptr -> capac == 0)
uptr -> capac = HDSK_CAPACITY;
} /* post condition: uptr -> capac > 0 */
assert(uptr -> capac);
/* Step 2: Determine format based on disk capacity */
assignFormat(uptr);
/* Step 3: Set number of sectors per track and sector size */
if (uptr -> HDSK_FORMAT_TYPE == -1) { /* Case 1: no disk parameter block found */
uptr -> HDSK_FORMAT_TYPE = 0;
printf("HDSK%c: WARNING: Unsupported disk capacity, assuming HDSK type with capacity %iKB.\n",
unitChar, uptr -> capac / 1000);
uptr -> flags |= UNIT_HDSK_WLK;
printf("HDSK%c: WARNING: Forcing WRTLCK.\n", unitChar);
/* check whether capacity corresponds to setting of tracks, sectors per track and sector size */
if (uptr -> capac != (uint32)(uptr -> HDSK_NUMBER_OF_TRACKS *
uptr -> HDSK_SECTORS_PER_TRACK * uptr -> HDSK_SECTOR_SIZE)) {
printf("HDSK%c: WARNING: Fixing geometry.\n", unitChar);
if (uptr -> HDSK_SECTORS_PER_TRACK == 0)
uptr -> HDSK_SECTORS_PER_TRACK = 32;
if (uptr -> HDSK_SECTOR_SIZE == 0)
uptr -> HDSK_SECTOR_SIZE = 128;
}
}
else { /* Case 2: disk parameter block found */
uptr -> HDSK_SECTORS_PER_TRACK = dpb[uptr -> HDSK_FORMAT_TYPE].spt >> dpb[uptr -> HDSK_FORMAT_TYPE].psh;
uptr -> HDSK_SECTOR_SIZE = (128 << dpb[uptr -> HDSK_FORMAT_TYPE].psh);
}
assert((uptr -> HDSK_SECTORS_PER_TRACK) && (uptr -> HDSK_SECTOR_SIZE) && (uptr -> HDSK_FORMAT_TYPE >= 0));
/* Step 4: Number of tracks is smallest number to accomodate capacity */
uptr -> HDSK_NUMBER_OF_TRACKS = (uptr -> capac + uptr -> HDSK_SECTORS_PER_TRACK *
uptr -> HDSK_SECTOR_SIZE - 1) / (uptr -> HDSK_SECTORS_PER_TRACK * uptr -> HDSK_SECTOR_SIZE);
assert( ( (t_addr) ((uptr -> HDSK_NUMBER_OF_TRACKS - 1) * uptr -> HDSK_SECTORS_PER_TRACK *
uptr -> HDSK_SECTOR_SIZE) < uptr -> capac) &&
(uptr -> capac <= (t_addr) (uptr -> HDSK_NUMBER_OF_TRACKS *
uptr -> HDSK_SECTORS_PER_TRACK * uptr -> HDSK_SECTOR_SIZE) ) );
return SCPE_OK;
}
t_stat dqc_detach (UNIT* uptr)
{
dqc_load_unload (uptr, UNIT_UNLOAD, NULL, NULL); /* unload heads */
return detach_unit (uptr); /* detach unit */
}
t_stat ptp_detach (UNIT *uptr)
{
ptp_csr = ptp_csr | CSR_ERR;
return detach_unit (uptr);
}
t_stat pt_detach (UNIT *uptr)
{
if (!(sim_switches & SIM_SW_REST)) sim_cancel (uptr); /* stop motion */
uptr->STA = 0;
return detach_unit (uptr);
}
static t_stat sagelp_detach (UNIT *uptr)
{
u39.portb |= U39B_PAPER; /* no paper */
return detach_unit (uptr);
}
