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/* hp2100_dp.c: HP 2100 12557A/13210A disk simulator
Copyright (c) 1993-2008, 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.
DP 12557A 2871 disk subsystem
13210A 7900 disk subsystem
10-Aug-08 JDB Added REG_FIT to register variables < 32-bit size
26-Jun-08 JDB Rewrote device I/O to model backplane signals
28-Dec-06 JDB Added ioCRS state to I/O decoders
01-Mar-05 JDB Added SET UNLOAD/LOAD
07-Oct-04 JDB Fixed enable/disable from either device
Fixed ANY ERROR status for 12557A interface
Fixed unattached drive status for 12557A interface
Status cmd without prior STC DC now completes (12557A)
OTA/OTB CC on 13210A interface also does CLC CC
Fixed RAR model
Fixed seek check on 13210 if sector out of range
20-Aug-04 JDB Fixes from Dave Bryan
- Check status on unattached drive set busy and not ready
- Check status tests wrong unit for write protect status
- Drive on line sets ATN, will set FLG if polling
15-Aug-04 RMS Controller resumes polling for ATN interrupts after
read status (found by Dave Bryan)
22-Jul-04 RMS Controller sets ATN for all commands except
read status (found by Dave Bryan)
21-Apr-04 RMS Fixed typo in boot loader (found by Dave Bryan)
26-Apr-04 RMS Fixed SFS x,C and SFC x,C
Fixed SR setting in IBL
Fixed interpretation of SR<0>
Revised IBL loader
Implemented DMA SRQ (follows FLG)
25-Apr-03 RMS Revised for extended file support
Fixed bug(s) in boot (found by Terry Newton)
10-Nov-02 RMS Added BOOT command, fixed numerous bugs
15-Jan-02 RMS Fixed INIT handling (found by Bill McDermith)
10-Jan-02 RMS Fixed f(x)write call (found by Bill McDermith)
03-Dec-01 RMS Changed DEVNO to use extended SET/SHOW
24-Nov-01 RMS Changed STA to be an array
07-Sep-01 RMS Moved function prototypes
29-Nov-00 RMS Made variable names unique
21-Nov-00 RMS Fixed flag, buffer power up state
References:
- 7900A Disc Drive Operating and Service Manual (07900-90002, Feb-1975)
- 13210A Disc Drive Interface Kit Operating and Service Manual
(13210-90003, Nov-1974)
- 12557A Cartridge Disc Interface Kit Operating and Service Manual
(12557-90001, Sep-1970)
The simulator uses a number of state variables:
dpc_busy set to drive number + 1 when the controller is busy
of the unit in use
dpd_xfer set to 1 if the data channel is executing a data transfer
dpd_wval set to 1 by OTx if either !dpc_busy or dpd_xfer
dpc_poll set to 1 if attention polling is enabled
dpc_busy and dpd_xfer are set together at the start of a read, write, refine,
or init. When data transfers are complete (CLC DC), dpd_xfer is cleared, but the
operation is not necessarily over. When the operation is complete, dpc_busy
is cleared and the command channel flag is set.
dpc_busy && !dpd_xfer && STC DC (controller is busy, data channel transfer has
been terminated by CLC DC, but a word has been placed in the data channel buffer)
indicates data overrun.
dpd_wval is used in write operations to fill out the sector buffer with 0's
if only a partial sector has been transferred.
dpc_poll indicates whether seek completion polling can occur. It is cleared
by reset and CLC CC and set by issuance of a seek or completion of check status.
The controller's "Record Address Register" (RAR) contains the CHS address of
the last Seek or Address Record command executed. The RAR is shared among
all drives on the controller. In addition, each drive has an internal
position register that contains the last cylinder position transferred to the
drive during Seek command execution (data operations always start with the
RAR head and sector position).
In a real drive, the address field of the sector under the head is read and
compared to the RAR. When they match, the target sector is under the head
and is ready for reading or writing. If a match doesn't occur, an Address
Error is indicated. In the simulator, the address field is obtained from the
drive's current position register during a read, i.e., the "on-disc" address
field is assumed to match the current position.
The following implemented behaviors have been inferred from secondary sources
(diagnostics, operating system drivers, etc.), due to absent or contradictory
authoritative information; future correction may be needed:
1. Status bit 15 (ATTENTION) does not set bit 0 (ANY ERROR) on the 12557A.
2. Omitting STC DC before Status Check does not set DC flag but does poll.
*/
#include "hp2100_defs.h"
#define UNIT_V_WLK (UNIT_V_UF + 0) /* write locked */
#define UNIT_V_UNLOAD (UNIT_V_UF + 1) /* heads unloaded */
#define UNIT_WLK (1 << UNIT_V_WLK)
#define UNIT_UNLOAD (1 << UNIT_V_UNLOAD)
#define FNC u3 /* saved function */
#define DRV u4 /* drive number (DC) */
#define UNIT_WPRT (UNIT_WLK | UNIT_RO) /* write prot */
#define DP_N_NUMWD 7
#define DP_NUMWD (1 << DP_N_NUMWD) /* words/sector */
#define DP_NUMSC2 12 /* sectors/srf 12557 */
#define DP_NUMSC3 24 /* sectors/srf 13210 */
#define DP_NUMSC (dp_ctype? DP_NUMSC3: DP_NUMSC2)
#define DP_NUMSF 4 /* surfaces/cylinder */
#define DP_NUMCY 203 /* cylinders/disk */
#define DP_SIZE2 (DP_NUMSF * DP_NUMCY * DP_NUMSC2 * DP_NUMWD)
#define DP_SIZE3 (DP_NUMSF * DP_NUMCY * DP_NUMSC3 * DP_NUMWD)
#define DP_NUMDRV 4 /* # drives */
/* Command word */
#define CW_V_FNC 12 /* function */
#define CW_M_FNC 017
#define CW_GETFNC(x) (((x) >> CW_V_FNC) & CW_M_FNC)
#define FNC_STA 000 /* status check */
#define FNC_WD 001 /* write */
#define FNC_RD 002 /* read */
#define FNC_SEEK 003 /* seek */
#define FNC_REF 005 /* refine */
#define FNC_CHK 006 /* check */
#define FNC_INIT 011 /* init */
#define FNC_AR 013 /* address */
#define FNC_SEEK1 020 /* fake - seek1 */
#define FNC_SEEK2 021 /* fake - seek2 */
#define FNC_SEEK3 022 /* fake - seek3 */
#define FNC_CHK1 023 /* fake - check1 */
#define FNC_AR1 024 /* fake - arec1 */
#define CW_V_DRV 0 /* drive */
#define CW_M_DRV 03
#define CW_GETDRV(x) (((x) >> CW_V_DRV) & CW_M_DRV)
/* Disk address words */
#define DA_V_CYL 0 /* cylinder */
#define DA_M_CYL 0377
#define DA_GETCYL(x) (((x) >> DA_V_CYL) & DA_M_CYL)
#define DA_V_HD 8 /* head */
#define DA_M_HD 03
#define DA_GETHD(x) (((x) >> DA_V_HD) & DA_M_HD)
#define DA_V_SC 0 /* sector */
#define DA_M_SC2 017
#define DA_M_SC3 037
#define DA_M_SC (dp_ctype? DA_M_SC3: DA_M_SC2)
#define DA_GETSC(x) (((x) >> DA_V_SC) & DA_M_SC)
#define DA_CKMASK2 037 /* check mask */
#define DA_CKMASK3 077
#define DA_CKMASK (dp_ctype? DA_CKMASK3: DA_CKMASK2)
/* Status in dpc_sta[drv], (u) = unused in 13210, (d) = dynamic */
#define STA_ATN 0100000 /* attention (u) */
#define STA_1ST 0040000 /* first status */
#define STA_OVR 0020000 /* overrun */
#define STA_RWU 0010000 /* rw unsafe NI (u) */
#define STA_ACU 0004000 /* access unsafe NI */
#define STA_HUNT 0002000 /* hunting NI (12557) */
#define STA_PROT 0002000 /* protected (13210) */
#define STA_SKI 0001000 /* incomplete NI (u) */
#define STA_SKE 0000400 /* seek error */
/* 0000200 /* unused */
#define STA_NRDY 0000100 /* not ready (d) */
#define STA_EOC 0000040 /* end of cylinder */
#define STA_AER 0000020 /* addr error */
#define STA_FLG 0000010 /* flagged */
#define STA_BSY 0000004 /* seeking */
#define STA_DTE 0000002 /* data error */
#define STA_ERR 0000001 /* any error (d) */
#define STA_ERSET2 (STA_1ST | STA_OVR | STA_RWU | STA_ACU | \
STA_SKI | STA_SKE | STA_NRDY | \
STA_EOC | STA_AER | STA_DTE) /* 12557A error set */
#define STA_ERSET3 (STA_ATN | STA_1ST | STA_OVR | STA_RWU | STA_ACU | \
STA_SKI | STA_SKE | STA_NRDY | STA_EOC | STA_AER | \
STA_FLG | STA_BSY | STA_DTE) /* 13210A error set */
#define STA_ANYERR (dp_ctype ? STA_ERSET3 : STA_ERSET2)
#define STA_UNLOADED (dp_ctype ? (STA_NRDY | STA_BSY) : STA_NRDY)
#define STA_MBZ13 (STA_ATN | STA_RWU | STA_SKI) /* zero in 13210 */
FLIP_FLOP dpc_command = CLEAR; /* cch command flip-flop */
FLIP_FLOP dpc_control = CLEAR; /* cch control flip-flop */
FLIP_FLOP dpc_flag = CLEAR; /* cch flag flip-flop */
FLIP_FLOP dpc_flagbuf = CLEAR; /* cch flag buffer flip-flop */
enum { A12557, A13210 } dp_ctype = A13210; /* ctrl type */
int32 dpc_busy = 0; /* cch unit */
int32 dpc_poll = 0; /* cch poll enable */
int32 dpc_cnt = 0; /* check count */
int32 dpc_eoc = 0; /* end of cyl */
int32 dpc_stime = 100; /* seek time */
int32 dpc_ctime = 100; /* command time */
int32 dpc_xtime = 5; /* xfer time */
int32 dpc_dtime = 2; /* dch time */
int32 dpd_obuf = 0, dpd_ibuf = 0; /* dch buffers */
int32 dpc_obuf = 0; /* cch buffers */
FLIP_FLOP dpd_command = CLEAR; /* dch command flip-flop */
FLIP_FLOP dpd_control = CLEAR; /* dch control flip-flop */
FLIP_FLOP dpd_flag = CLEAR; /* dch flag flip-flop */
FLIP_FLOP dpd_flagbuf = CLEAR; /* dch flag buffer flip-flop */
int32 dpd_xfer = 0; /* xfer in prog */
int32 dpd_wval = 0; /* write data valid */
int32 dp_ptr = 0; /* buffer ptr */
uint8 dpc_rarc = 0; /* RAR cylinder */
uint8 dpc_rarh = 0; /* RAR head */
uint8 dpc_rars = 0; /* RAR sector */
uint8 dpc_ucyl[DP_NUMDRV] = { 0 }; /* unit cylinder */
uint16 dpc_sta[DP_NUMDRV] = { 0 }; /* status regs */
uint16 dpxb[DP_NUMWD]; /* sector buffer */
DEVICE dpd_dev, dpc_dev;
uint32 dpdio (uint32 select_code, IOSIG signal, uint32 data);
uint32 dpcio (uint32 select_code, IOSIG signal, uint32 data);
t_stat dpc_svc (UNIT *uptr);
t_stat dpd_svc (UNIT *uptr);
t_stat dpc_reset (DEVICE *dptr);
t_stat dpc_attach (UNIT *uptr, char *cptr);
t_stat dpc_detach (UNIT* uptr);
t_stat dpc_boot (int32 unitno, DEVICE *dptr);
void dp_god (int32 fnc, int32 drv, int32 time);
void dp_goc (int32 fnc, int32 drv, int32 time);
t_stat dpc_load_unload (UNIT *uptr, int32 value, char *cptr, void *desc);
t_stat dp_settype (UNIT *uptr, int32 val, char *cptr, void *desc);
t_stat dp_showtype (FILE *st, UNIT *uptr, int32 val, void *desc);
/* DPD data structures
dpd_dev DPD device descriptor
dpd_unit DPD unit list
dpd_reg DPD register list
*/
DIB dp_dib[] = {
{ DPD, &dpdio },
{ DPC, &dpcio }
};
#define dpd_dib dp_dib[0]
#define dpc_dib dp_dib[1]
UNIT dpd_unit = { UDATA (&dpd_svc, 0, 0) };
REG dpd_reg[] = {
{ ORDATA (IBUF, dpd_ibuf, 16) },
{ ORDATA (OBUF, dpd_obuf, 16) },
{ BRDATA (DBUF, dpxb, 8, 16, DP_NUMWD) },
{ DRDATA (BPTR, dp_ptr, DP_N_NUMWD) },
{ FLDATA (CMD, dpd_command, 0) },
{ FLDATA (CTL, dpd_control, 0) },
{ FLDATA (FLG, dpd_flag, 0) },
{ FLDATA (FBF, dpd_flagbuf, 0) },
{ FLDATA (XFER, dpd_xfer, 0) },
{ FLDATA (WVAL, dpd_wval, 0) },
{ ORDATA (DEVNO, dpd_dib.devno, 6), REG_HRO },
{ NULL }
};
MTAB dpd_mod[] = {
{ MTAB_XTD | MTAB_VDV, 1, "DEVNO", "DEVNO",
&hp_setdev, &hp_showdev, &dpd_dev },
{ 0 }
};
DEVICE dpd_dev = {
"DPD", &dpd_unit, dpd_reg, dpd_mod,
1, 10, DP_N_NUMWD, 1, 8, 16,
NULL, NULL, &dpc_reset,
NULL, NULL, NULL,
&dpd_dib, DEV_DISABLE
};
/* DPC data structures
dpc_dev DPC device descriptor
dpc_unit DPC unit list
dpc_reg DPC register list
dpc_mod DPC modifier list
*/
UNIT dpc_unit[] = {
{ UDATA (&dpc_svc, UNIT_FIX | UNIT_ATTABLE | UNIT_ROABLE |
UNIT_DISABLE | UNIT_UNLOAD, DP_SIZE3) },
{ UDATA (&dpc_svc, UNIT_FIX | UNIT_ATTABLE | UNIT_ROABLE |
UNIT_DISABLE | UNIT_UNLOAD, DP_SIZE3) },
{ UDATA (&dpc_svc, UNIT_FIX | UNIT_ATTABLE | UNIT_ROABLE |
UNIT_DISABLE | UNIT_UNLOAD, DP_SIZE3) },
{ UDATA (&dpc_svc, UNIT_FIX | UNIT_ATTABLE | UNIT_ROABLE |
UNIT_DISABLE | UNIT_UNLOAD, DP_SIZE3) }
};
REG dpc_reg[] = {
{ ORDATA (OBUF, dpc_obuf, 16) },
{ ORDATA (BUSY, dpc_busy, 4), REG_RO },
{ ORDATA (CNT, dpc_cnt, 5) },
{ FLDATA (CMD, dpc_command, 0) },
{ FLDATA (CTL, dpc_control, 0) },
{ FLDATA (FLG, dpc_flag, 0) },
{ FLDATA (FBF, dpc_flagbuf, 0) },
{ FLDATA (EOC, dpc_eoc, 0) },
{ FLDATA (POLL, dpc_poll, 0) },
{ DRDATA (RARC, dpc_rarc, 8), PV_RZRO | REG_FIT },
{ DRDATA (RARH, dpc_rarh, 2), PV_RZRO | REG_FIT },
{ DRDATA (RARS, dpc_rars, 5), PV_RZRO | REG_FIT },
{ BRDATA (CYL, dpc_ucyl, 10, 8, DP_NUMDRV), PV_RZRO },
{ BRDATA (STA, dpc_sta, 8, 16, DP_NUMDRV) },
{ DRDATA (CTIME, dpc_ctime, 24), PV_LEFT },
{ DRDATA (DTIME, dpc_dtime, 24), PV_LEFT },
{ DRDATA (STIME, dpc_stime, 24), PV_LEFT },
{ DRDATA (XTIME, dpc_xtime, 24), REG_NZ | PV_LEFT },
{ FLDATA (CTYPE, dp_ctype, 0), REG_HRO },
{ URDATA (UFNC, dpc_unit[0].FNC, 8, 8, 0,
DP_NUMDRV, REG_HRO) },
{ URDATA (CAPAC, dpc_unit[0].capac, 10, T_ADDR_W, 0,
DP_NUMDRV, PV_LEFT | REG_HRO) },
{ ORDATA (DEVNO, dpc_dib.devno, 6), REG_HRO },
{ NULL }
};
MTAB dpc_mod[] = {
{ UNIT_UNLOAD, UNIT_UNLOAD, "heads unloaded", "UNLOADED", dpc_load_unload },
{ UNIT_UNLOAD, 0, "heads loaded", "LOADED", dpc_load_unload },
{ UNIT_WLK, 0, "write enabled", "WRITEENABLED", NULL },
{ UNIT_WLK, UNIT_WLK, "write locked", "LOCKED", NULL },
{ MTAB_XTD | MTAB_VDV, 1, NULL, "13210A",
&dp_settype, NULL, NULL },
{ MTAB_XTD | MTAB_VDV, 0, NULL, "12557A",
&dp_settype, NULL, NULL },
{ MTAB_XTD | MTAB_VDV, 0, "TYPE", NULL,
NULL, &dp_showtype, NULL },
{ MTAB_XTD | MTAB_VDV, 1, "DEVNO", "DEVNO",
&hp_setdev, &hp_showdev, &dpd_dev },
{ 0 }
};
DEVICE dpc_dev = {
"DPC", dpc_unit, dpc_reg, dpc_mod,
DP_NUMDRV, 8, 24, 1, 8, 16,
NULL, NULL, &dpc_reset,
&dpc_boot, &dpc_attach, &dpc_detach,
&dpc_dib, DEV_DISABLE
};
/* Data channel I/O signal handler.
For the 12557A, the card contains the usual control, flag, and flag buffer
flip-flops. PRL, IRQ, and SRQ are standard. A command flip-flop indicates
that data is available.
For the 13210A, the card has a flag and a flag buffer flip-flop, but no
control or interrupt flip-flop. SRQ is standard. IRQ and PRL are not
driven, and the card does not respond to IAK. STC sets the command flip-flop
to initiate a data transfer. CLC has no effect.
Implementation notes:
1. The CRS signal clears the drive attention register. Under simulation,
drive attention status is generated dynamically, so there is no attention
register.
*/
uint32 dpdio (uint32 select_code, IOSIG signal, uint32 data)
{
const IOSIG base_signal = IOBASE (signal); /* derive base signal */
switch (base_signal) { /* dispatch base I/O signal */
case ioCLF: /* clear flag flip-flop */
dpd_flag = dpd_flagbuf = CLEAR;
break;
case ioSTF: /* set flag flip-flop */
case ioENF: /* enable flag */
dpd_flag = dpd_flagbuf = SET;
break;
case ioSFC: /* skip if flag is clear */
setstdSKF (dpd);
break;
case ioSFS: /* skip if flag is set */
setstdSKF (dpd);
break;
case ioIOI: /* I/O data input */
data = dpd_ibuf;
break;
case ioIOO: /* I/O data output */
dpd_obuf = data;
if (!dpc_busy || dpd_xfer) /* if !overrun */
dpd_wval = 1; /* valid */
break;
case ioPOPIO: /* power-on preset to I/O */
dpd_flag = dpd_flagbuf = SET; /* set flag buffer and flag */
if (dp_ctype == A12557) /* 12557? */
dpd_obuf = 0; /* clear output buffer */
/* fall into CRS handler */
case ioCRS: /* control reset */
dpd_command = CLEAR; /* clear command */
if (dp_ctype == A12557) /* 12557? */
dpd_control = CLEAR; /* clear control */
else { /* 13210 */
dpc_rarc = 0; /* clear controller cylinder address */
dpc_ucyl [CW_GETDRV (dpc_obuf)] = 0; /* clear last drive addressed cylinder */
}
break;
case ioCLC: /* clear control flip-flop */
if (dp_ctype == A12557) /* 12557? */
dpd_control = CLEAR; /* clear control */
dpd_xfer = 0; /* clr xfer in progress */
break;
case ioSTC: /* set control flip-flop */
if (dp_ctype == A12557) /* 12557? */
dpd_control = SET; /* set control */
dpd_command = SET; /* set cmd */
if (dpc_busy && !dpd_xfer) /* overrun? */
dpc_sta[dpc_busy - 1] |= STA_OVR;
break;
case ioSIR: /* set interrupt request */
if (dp_ctype == A12557) { /* 12557? */
setstdPRL (select_code, dpd); /* set standard PRL signal */
setstdIRQ (select_code, dpd); /* set standard IRQ signal */
}
setstdSRQ (select_code, dpd); /* set standard SRQ signal */
break;
case ioIAK: /* interrupt acknowledge */
if (dp_ctype == A12557) /* 12557? */
dpd_flagbuf = CLEAR; /* clear flag buffer */
break;
default: /* all other signals */
break; /* are ignored */
}
if (signal > ioCLF) /* multiple signals? */
dpdio (select_code, ioCLF, 0); /* issue CLF */
else if (signal > ioSIR) /* signal affected interrupt status? */
dpdio (select_code, ioSIR, 0); /* set interrupt request */
return data;
}
/* Command channel I/O signal handler.
The 12557A and 13210A have the usual control, flag, and flag buffer
flip-flops. Only the 12557A has a command flip-flop. IRQ, PRL, and SRQ are
standard.
Implementation notes:
1. In hardware, the command channel card passes PRH to PRL. The data card
actually drives PRL with the command channel's control and flag states,
even though the command channel's control, flag, and flag buffer drive
IRQH. That is, the priority chain is broken at the data card, although
the command card is interrupting. This works in hardware, but we must
break PRL at the command card under simulation to allow the command card
to interrupt.
*/
uint32 dpcio (uint32 select_code, IOSIG signal, uint32 data)
{
const IOSIG base_signal = IOBASE (signal); /* derive base signal */
int32 i, fnc, drv;
switch (base_signal) { /* dispatch base I/O signal */
case ioCLF: /* clear flag flip-flop */
dpc_flag = dpc_flagbuf = CLEAR;
break;
case ioSTF: /* set flag flip-flop */
case ioENF: /* enable flag */
dpc_flag = dpc_flagbuf = SET;
break;
case ioSFC: /* skip if flag is clear */
setstdSKF (dpc);
break;
case ioSFS: /* skip if flag is set */
setstdSKF (dpc);
break;
case ioIOI: /* I/O data input */
data = 0;
for (i = 0; i < DP_NUMDRV; i++) /* form attention register value */
if (dpc_sta[i] & STA_ATN) data = data | (1 << i);
break;
case ioIOO: /* I/O data output */
dpc_obuf = data;
if (dp_ctype == A13210) /* 13210? */
dpcio (select_code, ioCLC, 0); /* OTx causes CLC */
break;
case ioPOPIO: /* power-on preset to I/O */
dpc_flag = dpc_flagbuf = SET; /* set flag buffer and flag */
if (dp_ctype == A12557) /* 12557? */
dpd_obuf = 0; /* clear output buffer */
/* fall into CRS handler */
case ioCRS: /* control reset */
dpc_control = CLEAR; /* clear control */
if (dp_ctype == A12557) /* 12557? */
dpc_command = CLEAR; /* clear command */
break;
case ioCLC: /* clear control flip-flop */
dpc_control = CLEAR; /* clr ctl */
if (dp_ctype == A12557) /* 12557? */
dpc_command = CLEAR; /* cancel non-seek */
if (dpc_busy)
sim_cancel (&dpc_unit[dpc_busy - 1]);
sim_cancel (&dpd_unit); /* cancel dch */
dpd_xfer = 0; /* clr dch xfer */
dpc_busy = 0; /* clr cch busy */
dpc_poll = 0; /* clr cch poll */
break;
case ioSTC: /* set control flip-flop */
dpc_control = SET; /* set ctl */
if ((dp_ctype == A13210) || !dpc_command) { /* 13210 or command is clear? */
if (dp_ctype == A12557) /* 12557? */
dpc_command = SET; /* set command */
drv = CW_GETDRV (dpc_obuf); /* get fnc, drv */
fnc = CW_GETFNC (dpc_obuf); /* from cmd word */
switch (fnc) { /* case on fnc */
case FNC_SEEK: /* seek */
dpc_poll = 1; /* enable polling */
dp_god (fnc, drv, dpc_dtime); /* sched dch xfr */
break;
case FNC_STA: /* rd sta */
if (dp_ctype == A13210) /* 13210? clr dch flag */
dpdio (dpd_dib.devno, ioCLF, 0);
case FNC_CHK: /* check */
case FNC_AR: /* addr rec */
dp_god (fnc, drv, dpc_dtime); /* sched dch xfr */
break;
case FNC_RD: case FNC_WD: /* read, write */
case FNC_REF: case FNC_INIT: /* refine, init */
dp_goc (fnc, drv, dpc_ctime); /* sched drive */
break;
} /* end case */
} /* end if */
break;
case ioSIR: /* set interrupt request */
setstdPRL (select_code, dpc); /* set standard PRL signal */
setstdIRQ (select_code, dpc); /* set standard IRQ signal */
setstdSRQ (select_code, dpc); /* set standard SRQ signal */
break;
case ioIAK: /* interrupt acknowledge */
dpc_flagbuf = CLEAR; /* clear flag buffer */
break;
default: /* all other signals */
break; /* are ignored */
}
if (signal > ioCLF) /* multiple signals? */
dpcio (select_code, ioCLF, 0); /* issue CLF */
else if (signal > ioSIR) /* signal affected interrupt status? */
dpcio (select_code, ioSIR, 0); /* set interrupt request */
return data;
}
/* Start data channel operation */
void dp_god (int32 fnc, int32 drv, int32 time)
{
dpd_unit.DRV = drv; /* save unit */
dpd_unit.FNC = fnc; /* save function */
sim_activate (&dpd_unit, time);
return;
}
/* Start controller operation */
void dp_goc (int32 fnc, int32 drv, int32 time)
{
int32 t;
if (t = sim_is_active (&dpc_unit[drv])) { /* still seeking? */
sim_cancel (&dpc_unit[drv]); /* stop seek */
dpc_sta[drv] = dpc_sta[drv] & ~STA_BSY; /* clear busy */
time = time + t; /* include seek time */
}
dp_ptr = 0; /* init buf ptr */
dpc_eoc = 0; /* clear end cyl */
dpc_busy = drv + 1; /* set busy */
dpd_xfer = 1; /* xfer in prog */
dpc_unit[drv].FNC = fnc; /* save function */
dpc_sta[drv] = dpc_sta[drv] & ~STA_ATN; /* clear ATN */
sim_activate (&dpc_unit[drv], time); /* activate unit */
return;
}
/* Data channel unit service
This routine handles the data channel transfers. It also handles
data transfers that are blocked by seek in progress.
uptr->DRV = target drive
uptr->FNC = target function
Seek substates
seek - transfer cylinder
seek1 - transfer head/surface
Address record
ar - transfer cylinder
ar1 - transfer head/surface, finish operation
Status check - transfer status, finish operation
Check data
chk - transfer sector count
*/
t_stat dpd_svc (UNIT *uptr)
{
int32 i, drv, st;
drv = uptr->DRV; /* get drive no */
switch (uptr->FNC) { /* case function */
case FNC_AR: /* arec, need cyl */
case FNC_SEEK: /* seek, need cyl */
if (dpd_command) { /* dch active? */
dpc_rarc = DA_GETCYL (dpd_obuf); /* set RAR from cyl word */
dpd_wval = 0; /* clr data valid */
dpd_command = CLEAR; /* clr dch cmd */
dpdio (dpd_dib.devno, ioENF, 0); /* set dch flg */
if (uptr->FNC == FNC_AR) uptr->FNC = FNC_AR1;
else uptr->FNC = FNC_SEEK1; /* advance state */
}
sim_activate (uptr, dpc_xtime); /* no, wait more */
break;
case FNC_AR1: /* arec, need hd/sec */
case FNC_SEEK1: /* seek, need hd/sec */
if (dpd_command) { /* dch active? */
dpc_rarh = DA_GETHD (dpd_obuf); /* set RAR from head */
dpc_rars = DA_GETSC (dpd_obuf); /* set RAR from sector */
dpd_wval = 0; /* clr data valid */
dpd_command = CLEAR; /* clr dch cmd */
dpdio (dpd_dib.devno, ioENF, 0); /* set dch flg */
if (uptr->FNC == FNC_AR1) {
dpc_command = CLEAR; /* clr cch cmd */
dpcio (dpc_dib.devno, ioENF, 0); /* set cch flg */
dpc_sta[drv] = dpc_sta[drv] | STA_ATN; /* set drv attn */
break; /* done if Address Record */
}
if (sim_is_active (&dpc_unit[drv])) { /* if busy, */
dpc_sta[drv] = dpc_sta[drv] | STA_SKE; /* seek check */
break; /* allow prev seek to cmpl */
}
if ((dpc_rarc >= DP_NUMCY) || /* invalid cyl? */
((dp_ctype == A13210) && /* or 13210A */
(dpc_rars >= DP_NUMSC3))) { /* and invalid sector? */
dpc_sta[drv] = dpc_sta[drv] | STA_SKE; /* seek check */
sim_activate (&dpc_unit[drv], 1); /* schedule drive no-wait */
dpc_unit[drv].FNC = FNC_SEEK3; /* do immed compl w/poll */
break;
}
st = abs (dpc_rarc - dpc_ucyl[drv]) * dpc_stime;
if (st == 0) st = dpc_stime; /* min time */
dpc_ucyl[drv] = dpc_rarc; /* transfer RAR */
sim_activate (&dpc_unit[drv], st); /* schedule drive */
dpc_sta[drv] = (dpc_sta[drv] | STA_BSY) &
~(STA_SKE | STA_SKI | STA_HUNT);
dpc_unit[drv].FNC = FNC_SEEK2; /* set operation */
}
else sim_activate (uptr, dpc_xtime); /* no, wait more */
break;
case FNC_STA: /* read status */
if (dpd_command || (dp_ctype == A13210)) { /* dch act or 13210? */
if ((dpc_unit[drv].flags & UNIT_UNLOAD) == 0) { /* drive up? */
dpd_ibuf = dpc_sta[drv] & ~STA_ERR; /* clear err */
if (dp_ctype == A13210) dpd_ibuf = /* 13210? */
(dpd_ibuf & ~(STA_MBZ13 | STA_PROT)) |
(dpc_unit[drv].flags & UNIT_WPRT? STA_PROT: 0);
}
else dpd_ibuf = STA_UNLOADED; /* not ready */
if (dpd_ibuf & STA_ANYERR) /* errors? set flg */
dpd_ibuf = dpd_ibuf | STA_ERR;
dpc_command = CLEAR; /* clr cch cmd */
dpd_command = CLEAR; /* clr dch cmd */
dpdio (dpd_dib.devno, ioENF, 0); /* set dch flg */
}
dpc_sta[drv] = dpc_sta[drv] & /* clr sta flags */
~(STA_ATN | STA_1ST | STA_OVR |
STA_RWU | STA_ACU | STA_EOC |
STA_AER | STA_FLG | STA_DTE);
dpc_poll = 1; /* enable polling */
for (i = 0; i < DP_NUMDRV; i++) { /* loop thru drives */
if (dpc_sta[i] & STA_ATN) { /* any ATN set? */
dpcio (dpc_dib.devno, ioENF, 0); /* set cch flg */
break;
}
}
break;
case FNC_CHK: /* check, need cnt */
if (dpd_command) { /* dch active? */
dpc_cnt = dpd_obuf & DA_CKMASK; /* get count */
dpd_wval = 0; /* clr data valid */
dp_goc (FNC_CHK1, drv, dpc_xtime); /* sched drv */
}
else sim_activate (uptr, dpc_xtime); /* wait more */
break;
default:
return SCPE_IERR;
}
return SCPE_OK;
}
/* Drive unit service
This routine handles the data transfers.
Seek substates
seek2 - done
Refine sector - erase sector, finish operation
Check data
chk1 - finish operation
Read
Write
*/
#define GETDA(x,y,z) \
(((((x) * DP_NUMSF) + (y)) * DP_NUMSC) + (z)) * DP_NUMWD
t_stat dpc_svc (UNIT *uptr)
{
int32 da, drv, err;
err = 0; /* assume no err */
drv = uptr - dpc_dev.units; /* get drive no */
if (uptr->flags & UNIT_UNLOAD) { /* drive down? */
dpc_command = CLEAR; /* clr cch cmd */
dpcio (dpc_dib.devno, ioENF, 0); /* set cch flg */
dpc_sta[drv] = 0; /* clr status */
dpc_busy = 0; /* ctlr is free */
dpc_poll = 0; /* polling disabled */
dpd_xfer = 0;
dpd_wval = 0;
return SCPE_OK;
}
switch (uptr->FNC) { /* case function */
case FNC_SEEK2: /* positioning done */
dpc_sta[drv] = (dpc_sta[drv] | STA_ATN) & ~STA_BSY; /* fall into cmpl */
case FNC_SEEK3: /* seek complete */
if (dpc_poll) { /* polling enabled? */
dpc_command = CLEAR; /* clr cch cmd */
dpcio (dpc_dib.devno, ioENF, 0); /* set cch flg */
}
return SCPE_OK;
case FNC_REF: /* refine sector */
break; /* just a NOP */
case FNC_RD: /* read */
case FNC_CHK1: /* check */
if (dp_ptr == 0) { /* new sector? */
if (!dpd_command && (uptr->FNC != FNC_CHK1)) break;
if (dpc_rarc != dpc_ucyl[drv]) /* RAR cyl miscompare? */
dpc_sta[drv] = dpc_sta[drv] | STA_AER; /* set flag, read */
if (dpc_rars >= DP_NUMSC) { /* bad sector? */
dpc_sta[drv] = dpc_sta[drv] | STA_AER; /* set flag, stop */
break;
}
if (dpc_eoc) { /* end of cyl? */
dpc_sta[drv] = dpc_sta[drv] | STA_EOC;
break;
}
da = GETDA (dpc_rarc, dpc_rarh, dpc_rars); /* calc disk addr */
dpc_rars = (dpc_rars + 1) % DP_NUMSC; /* incr sector */
if (dpc_rars == 0) { /* wrap? */
dpc_rarh = dpc_rarh ^ 1; /* incr head */
dpc_eoc = ((dpc_rarh & 1) == 0); /* calc eoc */
}
if (err = fseek (uptr->fileref, da * sizeof (int16),
SEEK_SET)) break;
fxread (dpxb, sizeof (int16), DP_NUMWD, uptr->fileref);
if (err = ferror (uptr->fileref)) break;
}
dpd_ibuf = dpxb[dp_ptr++]; /* get word */
if (dp_ptr >= DP_NUMWD) { /* end of sector? */
if (uptr->FNC == FNC_CHK1) { /* check? */
dpc_cnt = (dpc_cnt - 1) & DA_CKMASK; /* decr count */
if (dpc_cnt == 0) break; /* stop at zero */
}
dp_ptr = 0; /* wrap buf ptr */
}
if (dpd_command && dpd_xfer) /* dch on, xfer? */
dpdio (dpd_dib.devno, ioENF, 0); /* set dch flg */
dpd_command = CLEAR; /* clr dch cmd */
sim_activate (uptr, dpc_xtime); /* sched next word */
return SCPE_OK;
case FNC_INIT: /* init */
case FNC_WD: /* write */
if (dp_ptr == 0) { /* start sector? */
if (!dpd_command && !dpd_wval) break; /* xfer done? */
if (uptr->flags & UNIT_WPRT) { /* wr prot? */
dpc_sta[drv] = dpc_sta[drv] | STA_FLG; /* set status */
break; /* done */
}
if ((dpc_rarc != dpc_ucyl[drv]) || /* RAR cyl miscompare? */
(dpc_rars >= DP_NUMSC)) { /* bad sector? */
dpc_sta[drv] = dpc_sta[drv] | STA_AER; /* address error */
break;
}
if (dpc_eoc) { /* end of cyl? */
dpc_sta[drv] = dpc_sta[drv] | STA_EOC; /* set status */
break; /* done */
}
}
dpxb[dp_ptr++] = dpd_wval? dpd_obuf: 0; /* store word/fill */
dpd_wval = 0; /* clr data valid */
if (dp_ptr >= DP_NUMWD) { /* buffer full? */
da = GETDA (dpc_rarc, dpc_rarh, dpc_rars); /* calc disk addr */
dpc_rars = (dpc_rars + 1) % DP_NUMSC; /* incr sector */
if (dpc_rars == 0) { /* wrap? */
dpc_rarh = dpc_rarh ^ 1; /* incr head */
dpc_eoc = ((dpc_rarh & 1) == 0); /* calc eoc */
}
if (err = fseek (uptr->fileref, da * sizeof (int16),
SEEK_SET)) break;
fxwrite (dpxb, sizeof (int16), DP_NUMWD, uptr->fileref);
if (err = ferror (uptr->fileref)) break; /* error? */
dp_ptr = 0; /* next sector */
}
if (dpd_command && dpd_xfer) /* dch on, xfer? */
dpdio (dpd_dib.devno, ioENF, 0); /* set dch flg */
dpd_command = CLEAR; /* clr dch cmd */
sim_activate (uptr, dpc_xtime); /* sched next word */
return SCPE_OK;
default:
return SCPE_IERR;
} /* end case fnc */
dpc_sta[drv] = dpc_sta[drv] | STA_ATN; /* set ATN */
dpc_command = CLEAR; /* clr cch cmd */
dpcio (dpc_dib.devno, ioENF, 0); /* set cch flg */
dpc_busy = 0; /* ctlr is free */
dpd_xfer = dpd_wval = 0;
if (err != 0) { /* error? */
perror ("DP I/O error");
clearerr (uptr->fileref);
return SCPE_IOERR;
}
return SCPE_OK;
}
/* Reset routine */
t_stat dpc_reset (DEVICE *dptr)
{
int32 drv;
hp_enbdis_pair (dptr, /* make pair cons */
(dptr == &dpd_dev)? &dpc_dev: &dpd_dev);
if (sim_switches & SWMASK ('P')) { /* PON reset? */
dpd_ibuf = 0; /* clear buffers */
dpd_obuf = 0;
dpc_obuf = 0;
dpc_rarc = dpc_rarh = dpc_rars = 0; /* clear RAR */
}
if (dptr == &dpc_dev) /* command channel reset? */
dpcio (dpc_dib.devno, ioPOPIO, 0); /* send POPIO signal to command channel */
else /* data channel reset */
dpdio (dpd_dib.devno, ioPOPIO, 0); /* send POPIO signal to data channel */
dpc_busy = 0; /* reset controller state */
dpc_poll = 0;
dpd_xfer = 0;
dpd_wval = 0;
dpc_eoc = 0;
dp_ptr = 0;
sim_cancel (&dpd_unit); /* cancel dch */
for (drv = 0; drv < DP_NUMDRV; drv++) { /* loop thru drives */
sim_cancel (&dpc_unit[drv]); /* cancel activity */
dpc_unit[drv].FNC = 0; /* clear function */
dpc_ucyl[drv] = 0; /* clear drive pos */
if (dpc_unit[drv].flags & UNIT_ATT)
dpc_sta[drv] = dpc_sta[drv] & STA_1ST; /* first seek status */
else dpc_sta[drv] = 0; /* clear status */
}
return SCPE_OK;
}
/* Attach routine */
t_stat dpc_attach (UNIT *uptr, char *cptr)
{
t_stat r;
r = attach_unit (uptr, cptr); /* attach unit */
if (r == SCPE_OK) dpc_load_unload (uptr, 0, NULL, NULL);/* if OK, load heads */
return r;
}
/* Detach routine */
t_stat dpc_detach (UNIT* uptr)
{
dpc_load_unload (uptr, UNIT_UNLOAD, NULL, NULL); /* unload heads */
return detach_unit (uptr); /* detach unit */
}
/* Load and unload heads */
t_stat dpc_load_unload (UNIT *uptr, int32 value, char *cptr, void *desc)
{
uint32 drv;
if ((uptr->flags & UNIT_ATT) == 0) return SCPE_UNATT; /* must be attached to load */
if (value == UNIT_UNLOAD) /* unload heads? */
uptr->flags = uptr->flags | UNIT_UNLOAD; /* indicate unload */
else { /* load heads */
uptr->flags = uptr->flags & ~UNIT_UNLOAD; /* indicate load */
drv = uptr - dpc_dev.units; /* get drive no */
dpc_sta[drv] = dpc_sta[drv] | STA_ATN | STA_1ST; /* update status */
if (dpc_poll) /* polling enabled? */
dpcio (dpc_dib.devno, ioENF, 0); /* set flag */
}
return SCPE_OK;
}
/* Set controller type */
t_stat dp_settype (UNIT *uptr, int32 val, char *cptr, void *desc)
{
int32 i;
if ((val < 0) || (val > 1) || (cptr != NULL)) return SCPE_ARG;
for (i = 0; i < DP_NUMDRV; i++) {
if (dpc_unit[i].flags & UNIT_ATT) return SCPE_ALATT;
}
for (i = 0; i < DP_NUMDRV; i++)
dpc_unit[i].capac = (val? DP_SIZE3: DP_SIZE2);
dp_ctype = val;
return SCPE_OK;
}
/* Show controller type */
t_stat dp_showtype (FILE *st, UNIT *uptr, int32 val, void *desc)
{
if (dp_ctype == A13210) fprintf (st, "13210A");
else fprintf (st, "12557A");
return SCPE_OK;
}
/* 7900/7901 bootstrap routine (HP 12992F ROM) */
const BOOT_ROM dp_rom = {
0106710, /*ST CLC DC ; clr dch */
0106711, /* CLC CC ; clr cch */
0017757, /* JSB STAT ; get status */
0067746, /*SK LDB SKCMD ; seek cmd */
0106610, /* OTB DC ; cyl # */
0103710, /* STC DC,C ; to dch */
0106611, /* OTB CC ; seek cmd */
0103711, /* STC CC,C ; to cch */
0102310, /* SFS DC ; addr wd ok? */
0027710, /* JMP *-1 ; no, wait */
0006400, /* CLB */
0102501, /* LIA 1 ; read switches */
0002011, /* SLA,RSS ; <0> set? */
0047747, /* ADB BIT9 ; head 2 = removable */
0106610, /* OTB DC ; head/sector */
0103710, /* STC DC,C ; to dch */
0102311, /* SFS CC ; seek done? */
0027720, /* JMP *-1 ; no, wait */
0017757, /* JSB STAT ; get status */
0067776, /* LDB DMACW ; DMA control */
0106606, /* OTB 6 */
0067750, /* LDB ADDR1 ; memory addr */
0106602, /* OTB 2 */
0102702, /* STC 2 ; flip DMA ctrl */
0067752, /* LDB CNT ; word count */
0106602, /* OTB 2 */
0063745, /* LDB RDCMD ; read cmd */
0102611, /* OTA CC ; to cch */
0103710, /* STC DC,C ; start dch */
0103706, /* STC 6,C ; start DMA */
0103711, /* STC CC,C ; start cch */
0102311, /* SFS CC ; done? */
0027737, /* JMP *-1 ; no, wait */
0017757, /* JSB STAT ; get status */
0027775, /* JMP XT ; done */
0037766, /*FSMSK 037766 ; status mask */
0004000, /*STMSK 004000 ; unsafe mask */
0020000, /*RDCMD 020000 ; read cmd */
0030000, /*SKCMD 030000 ; seek cmd */
0001000, /*BIT9 001000 ; head 2 select */
0102011, /*ADDR1 102011 */
0102055, /*ADDR2 102055 */
0164000, /*CNT -6144. */
0, 0, 0, 0, /* unused */
0000000, /*STAT 0 */
0002400, /* CLA ; status request */
0102611, /* OTC CC ; to cch */
0103711, /* STC CC,C ; start cch */
0102310, /* SFS DC ; done? */
0027763, /* JMP *-1 */
0102510, /* LIA DC ; get status */
0013743, /* AND FSMSK ; mask 15,14,3,0 */
0002003, /* SZA,RSS ; drive ready? */
0127757, /* JMP STAT,I ; yes */
0013744, /* AND STMSK ; fault? */
0002002, /* SZA */
0102030, /* HLT 30 ; yes */
0027700, /* JMP ST ; no, retry */
0117751, /*XT JSB ADDR2,I ; start program */
0120010, /*DMACW 120000+DC */
0000000 /* -ST */
};
t_stat dpc_boot (int32 unitno, DEVICE *dptr)
{
int32 dev;
if (unitno != 0) return SCPE_NOFNC; /* only unit 0 */
dev = dpd_dib.devno; /* get data chan dev */
if (ibl_copy (dp_rom, dev)) return SCPE_IERR; /* copy boot to memory */
SR = (SR & IBL_OPT) | IBL_DP | (dev << IBL_V_DEV); /* set SR */
if (sim_switches & SWMASK ('R')) SR = SR | IBL_DP_REM; /* boot from removable? */
return SCPE_OK;
}