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/* nova_dkp.c: NOVA moving head disk simulator
Copyright (c) 1993-2001, 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.
dkp moving head disk
26-Apr-01 RMS Added device enable/disable support
12-Dec-00 RMS Added Eclipse support from Charles Owen
15-Oct-00 RMS Editorial changes
14-Apr-99 RMS Changed t_addr to unsigned
15-Sep-97 RMS Fixed bug in DIB/DOB for new disks
15-Sep-97 RMS Fixed bug in cylinder extraction (found by Charles Owen)
10-Sep-97 RMS Fixed bug in error reporting (found by Charles Owen)
25-Nov-96 RMS Defaulted to autosize
29-Jun-96 RMS Added unit disable support
*/
#include "nova_defs.h"
#define DKP_NUMDR 4 /* #drives */
#define DKP_NUMWD 256 /* words/sector */
#define UNIT_V_WLK (UNIT_V_UF + 0) /* write locked */
#define UNIT_V_DTYPE (UNIT_V_UF + 1) /* disk type */
#define UNIT_M_DTYPE 017
#define UNIT_V_AUTO (UNIT_V_UF + 5) /* autosize */
#define UNIT_W_UF 7 /* saved flag width */
#define UNIT_WLK (1 << UNIT_V_WLK)
#define UNIT_DTYPE (UNIT_M_DTYPE << UNIT_V_DTYPE)
#define UNIT_AUTO (1 << UNIT_V_AUTO)
#define GET_DTYPE(x) (((x) >> UNIT_V_DTYPE) & UNIT_M_DTYPE)
#define FUNC u3 /* function */
#define CYL u4 /* on cylinder */
/* Unit, surface, sector, count register
Original format: 2b, 6b, 4b, 4b
Revised format: 2b, 5b, 5b, 4b
*/
#define USSC_V_COUNT 0 /* count */
#define USSC_M_COUNT 017
#define USSC_V_OSECTOR 4 /* old: sector */
#define USSC_M_OSECTOR 017
#define USSC_V_OSURFACE 8 /* old: surface */
#define USSC_M_OSURFACE 077
#define USSC_V_NSECTOR 4 /* new: sector */
#define USSC_M_NSECTOR 037
#define USSC_V_NSURFACE 9 /* new: surface */
#define USSC_M_NSURFACE 037
#define USSC_V_UNIT 14 /* unit */
#define USSC_M_UNIT 03
#define USSC_UNIT (USSC_M_UNIT << USSC_V_UNIT)
#define GET_COUNT(x) (((x) >> USSC_V_COUNT) & USSC_M_COUNT)
#define GET_SECT(x,dt) ((drv_tab[dt].new)? \
(((x) >> USSC_V_NSECTOR) & USSC_M_NSECTOR): \
(((x) >> USSC_V_OSECTOR) & USSC_M_OSECTOR) )
#define GET_SURF(x,dt) ((drv_tab[dt].new)? \
(((x) >> USSC_V_NSURFACE) & USSC_M_NSURFACE): \
(((x) >> USSC_V_OSURFACE) & USSC_M_OSURFACE) )
#define GET_UNIT(x) (((x) >> USSC_V_UNIT) & USSC_M_UNIT)
/* Flags, command, cylinder register
Original format: 5b, 2b, 1b + 8b (surrounding command)
Revised format: 5b, 2b, 9b
*/
#define FCCY_V_OCYL 0 /* old: cylinder */
#define FCCY_M_OCYL 0377
#define FCCY_V_OCMD 8 /* old: command */
#define FCCY_M_OCMD 3
#define FCCY_V_OCEX 10 /* old: cyl extend */
#define FCCY_OCEX (1 << FCCY_V_OCEX)
#define FCCY_V_NCYL 0 /* new: cylinder */
#define FCCY_M_NCYL 0777
#define FCCY_V_NCMD 9 /* new: command */
#define FCCY_M_NCMD 3
#define FCCY_READ 0
#define FCCY_WRITE 1
#define FCCY_SEEK 2
#define FCCY_RECAL 3
#define FCCY_FLAGS 0174000 /* flags */
#define GET_CMD(x,dt) ((drv_tab[dt].new)? \
(((x) >> FCCY_V_NCMD) & FCCY_M_NCMD): \
(((x) >> FCCY_V_OCMD) & FCCY_M_OCMD) )
#define GET_CYL(x,dt) ((drv_tab[dt].new)? \
(((x) >> FCCY_V_NCYL) & FCCY_M_NCYL): \
((((x) >> FCCY_V_OCYL) & FCCY_M_OCYL) | \
((dt != TYPE_D44)? 0: \
(((x) & FCCY_OCEX) >> (FCCY_V_OCEX - FCCY_V_OCMD)))) )
/* Status */
#define STA_ERR 0000001 /* error */
#define STA_DLT 0000002 /* data late */
#define STA_CRC 0000004 /* crc error */
#define STA_UNS 0000010 /* unsafe */
#define STA_XCY 0000020 /* cross cylinder */
#define STA_CYL 0000040 /* nx cylinder */
#define STA_DRDY 0000100 /* drive ready */
#define STA_SEEK3 0000200 /* seeking unit 3 */
#define STA_SEEK2 0000400 /* seeking unit 2 */
#define STA_SEEK1 0001000 /* seeking unit 1 */
#define STA_SEEK0 0002000 /* seeking unit 0 */
#define STA_SKDN3 0004000 /* seek done unit 3 */
#define STA_SKDN2 0010000 /* seek done unit 2 */
#define STA_SKDN1 0020000 /* seek done unit 1 */
#define STA_SKDN0 0040000 /* seek done unit 0 */
#define STA_DONE 0100000 /* operation done */
#define STA_DYN (STA_DRDY | STA_CYL) /* set from unit */
#define STA_EFLGS (STA_ERR | STA_DLT | STA_CRC | STA_UNS | \
STA_XCY | STA_CYL) /* error flags */
#define STA_DFLGS (STA_DONE | STA_SKDN0 | STA_SKDN1 | \
STA_SKDN2 | STA_SKDN3) /* done flags */
#define GET_SA(cy,sf,sc,t) (((((cy)*drv_tab[t].surf)+(sf))* \
drv_tab[t].sect)+(sc))
/* This controller supports many different disk drive types:
type #sectors/ #surfaces/ #cylinders/ new format?
surface cylinder drive
floppy 8 1 77 no
DS/DD floppy 16 2 77 yes
Diablo 31 12 2 203 no
6225 20 2 245 yes
Century 111 6 10 203 no
Diablo 44 12 4 408 no
6099 32 4 192 yes
6227 20 6 245 yes
6070 24 4 408 yes
Century 114 12 20 203 no
6103 32 8 192 yes
4231 23 19 411 yes
In theory, each drive can be a different type. The size field in
each unit selects the drive capacity for each drive and thus the
drive type. DISKS MUST BE DECLARED IN ASCENDING SIZE.
*/
#define TYPE_FLP 0
#define SECT_FLP 8
#define SURF_FLP 1
#define CYL_FLP 77
#define SIZE_FLP (SECT_FLP * SURF_FLP * CYL_FLP * DKP_NUMWD)
#define NFMT_FLP FALSE
#define TYPE_DSDD 1
#define SECT_DSDD 16
#define SURF_DSDD 2
#define CYL_DSDD 77
#define SIZE_DSDD (SECT_DSDD * SURF_DSDD * CYL_DSDD * DKP_NUMWD)
#define NFMT_DSDD TRUE
#define TYPE_D31 2
#define SECT_D31 12
#define SURF_D31 2
#define CYL_D31 203
#define SIZE_D31 (SECT_D31 * SURF_D31 * CYL_D31 * DKP_NUMWD)
#define NFMT_D31 FALSE
#define TYPE_6225 3
#define SECT_6225 20
#define SURF_6225 2
#define CYL_6225 245
#define SIZE_6225 (SECT_6225 * SURF_6225 * CYL_6225 * DKP_NUMWD)
#define NFMT_6225 TRUE
#define TYPE_C111 4
#define SECT_C111 6
#define SURF_C111 10
#define CYL_C111 203
#define SIZE_C111 (SECT_C111 * SURF_C111 * CYL_C111 * DKP_NUMWD)
#define NFMT_C111 FALSE
#define TYPE_D44 5
#define SECT_D44 12
#define SURF_D44 4
#define CYL_D44 408
#define SIZE_D44 (SECT_D44 * SURF_D44 * CYL_D44 * DKP_NUMWD)
#define NFMT_D44 FALSE
#define TYPE_6099 6
#define SECT_6099 32
#define SURF_6099 4
#define CYL_6099 192
#define SIZE_6099 (SECT_6099 * SURF_6099 * CYL_6099 * DKP_NUMWD)
#define NFMT_6099 TRUE
#define TYPE_6227 7
#define SECT_6227 20
#define SURF_6227 6
#define CYL_6227 245
#define SIZE_6227 (SECT_6227 * SURF_6227 * CYL_6227 * DKP_NUMWD)
#define NFMT_6227 TRUE
#define TYPE_6070 8
#define SECT_6070 24
#define SURF_6070 4
#define CYL_6070 408
#define SIZE_6070 (SECT_6070 * SURF_6070 * CYL_6070 * DKP_NUMWD)
#define NFMT_6070 TRUE
#define TYPE_C114 9
#define SECT_C114 12
#define SURF_C114 20
#define CYL_C114 203
#define SIZE_C114 (SECT_C114 * SURF_C114 * CYL_C114 * DKP_NUMWD)
#define NFMT_C114 FALSE
#define TYPE_6103 10
#define SECT_6103 32
#define SURF_6103 8
#define CYL_6103 192
#define SIZE_6103 (SECT_6103 * SURF_6103 * CYL_6103 * DKP_NUMWD)
#define NFMT_6103 TRUE
#define TYPE_4231 11
#define SECT_4231 23
#define SURF_4231 19
#define CYL_4231 411
#define SIZE_4231 (SECT_4231 * SURF_4231 * CYL_4231 * DKP_NUMWD)
#define NFMT_4231 TRUE
struct drvtyp {
int32 sect; /* sectors */
int32 surf; /* surfaces */
int32 cyl; /* cylinders */
int32 size; /* #blocks */
int32 new; /* new format flag */
};
struct drvtyp drv_tab[] = {
{ SECT_FLP, SURF_FLP, CYL_FLP, SIZE_FLP, NFMT_FLP },
{ SECT_DSDD, SURF_DSDD, CYL_DSDD, SIZE_DSDD, NFMT_DSDD },
{ SECT_D31, SURF_D31, CYL_D31, SIZE_D31, NFMT_D31 },
{ SECT_6225, SURF_6225, CYL_6225, SIZE_6225, NFMT_6225 },
{ SECT_C111, SURF_C111, CYL_C111, SIZE_C111, NFMT_C111 },
{ SECT_D44, SURF_D44, CYL_D44, SIZE_D44, NFMT_D44 },
{ SECT_6099, SURF_6099, CYL_6099, SIZE_6099, NFMT_6099 },
{ SECT_6227, SURF_6227, CYL_6227, SIZE_6227, NFMT_6227 },
{ SECT_6070, SURF_6070, CYL_6070, SIZE_6070, NFMT_6070 },
{ SECT_C114, SURF_C114, CYL_C114, SIZE_C114, NFMT_C114 },
{ SECT_6103, SURF_6103, CYL_6103, SIZE_6103, NFMT_6103 },
{ SECT_4231, SURF_4231, CYL_4231, SIZE_4231, NFMT_4231 },
{ 0 } };
extern uint16 M[];
extern UNIT cpu_unit;
extern int32 int_req, dev_busy, dev_done, dev_disable, iot_enb;
int32 dkp_ma = 0; /* memory address */
int32 dkp_ussc = 0; /* unit/sf/sc/cnt */
int32 dkp_fccy = 0; /* flags/cylinder */
int32 dkp_sta = 0; /* status register */
int32 dkp_swait = 100; /* seek latency */
int32 dkp_rwait = 100; /* rotate latency */
t_stat dkp_svc (UNIT *uptr);
t_stat dkp_reset (DEVICE *dptr);
t_stat dkp_boot (int32 unitno);
t_stat dkp_attach (UNIT *uptr, char *cptr);
t_stat dkp_go (void);
t_stat dkp_set_size (UNIT *uptr, int32 value);
#if defined (ECLIPSE)
extern int32 MapAddr (int32 map, int32 addr);
#else
#define MapAddr(m,a) (a)
#endif
/* DKP data structures
dkp_dev DKP device descriptor
dkp_unit DKP unit list
dkp_reg DKP register list
dkp_mod DKP modifier list
*/
UNIT dkp_unit[] = {
{ UDATA (&dkp_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+UNIT_AUTO+
(TYPE_D31 << UNIT_V_DTYPE), SIZE_D31) },
{ UDATA (&dkp_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+UNIT_AUTO+
(TYPE_D31 << UNIT_V_DTYPE), SIZE_D31) },
{ UDATA (&dkp_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+UNIT_AUTO+
(TYPE_D31 << UNIT_V_DTYPE), SIZE_D31) },
{ UDATA (&dkp_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+UNIT_AUTO+
(TYPE_D31 << UNIT_V_DTYPE), SIZE_D31) } };
REG dkp_reg[] = {
{ ORDATA (FCCY, dkp_fccy, 16) },
{ ORDATA (USSC, dkp_ussc, 16) },
{ ORDATA (STA, dkp_sta, 16) },
{ ORDATA (MA, dkp_ma, 16) },
{ FLDATA (INT, int_req, INT_V_DKP) },
{ FLDATA (BUSY, dev_busy, INT_V_DKP) },
{ FLDATA (DONE, dev_done, INT_V_DKP) },
{ FLDATA (DISABLE, dev_disable, INT_V_DKP) },
{ DRDATA (STIME, dkp_swait, 24), PV_LEFT },
{ DRDATA (RTIME, dkp_rwait, 24), PV_LEFT },
{ GRDATA (FLG0, dkp_unit[0].flags, 8, UNIT_W_UF, UNIT_V_UF - 1),
REG_HRO },
{ GRDATA (FLG1, dkp_unit[1].flags, 8, UNIT_W_UF, UNIT_V_UF - 1),
REG_HRO },
{ GRDATA (FLG2, dkp_unit[2].flags, 8, UNIT_W_UF, UNIT_V_UF - 1),
REG_HRO },
{ GRDATA (FLG3, dkp_unit[3].flags, 8, UNIT_W_UF, UNIT_V_UF - 1),
REG_HRO },
{ DRDATA (CAPAC0, dkp_unit[0].capac, 32), PV_LEFT + REG_HRO },
{ DRDATA (CAPAC1, dkp_unit[1].capac, 32), PV_LEFT + REG_HRO },
{ DRDATA (CAPAC2, dkp_unit[2].capac, 32), PV_LEFT + REG_HRO },
{ DRDATA (CAPAC3, dkp_unit[3].capac, 32), PV_LEFT + REG_HRO },
{ FLDATA (*DEVENB, iot_enb, INT_V_DKP), REG_HRO },
{ NULL } };
MTAB dkp_mod[] = {
{ UNIT_WLK, 0, "write enabled", "ENABLED", NULL },
{ UNIT_WLK, UNIT_WLK, "write locked", "LOCKED", NULL },
{ (UNIT_DTYPE+UNIT_ATT), (TYPE_FLP << UNIT_V_DTYPE) + UNIT_ATT,
"6030 (floppy)", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (TYPE_DSDD << UNIT_V_DTYPE) + UNIT_ATT,
"6097 (DS/DD floppy)", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (TYPE_D31 << UNIT_V_DTYPE) + UNIT_ATT,
"4047 (Diablo 31)", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (TYPE_D44 << UNIT_V_DTYPE) + UNIT_ATT,
"4234/6045 (Diablo 44)", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (TYPE_C111 << UNIT_V_DTYPE) + UNIT_ATT,
"4048 (Century 111)", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (TYPE_C114 << UNIT_V_DTYPE) + UNIT_ATT,
"2314/4057 (Century 114)", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (TYPE_6225 << UNIT_V_DTYPE) + UNIT_ATT,
"6225", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (TYPE_6227 << UNIT_V_DTYPE) + UNIT_ATT,
"6227", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (TYPE_6099 << UNIT_V_DTYPE) + UNIT_ATT,
"6099", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (TYPE_6103 << UNIT_V_DTYPE) + UNIT_ATT,
"6103", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (TYPE_6070 << UNIT_V_DTYPE) + UNIT_ATT,
"6070", NULL, NULL },
{ (UNIT_DTYPE+UNIT_ATT), (TYPE_4231 << UNIT_V_DTYPE) + UNIT_ATT,
"4231/3330", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (TYPE_FLP << UNIT_V_DTYPE),
"6030 (floppy)", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (TYPE_DSDD << UNIT_V_DTYPE),
"6097 (DS/DD floppy)", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (TYPE_D31 << UNIT_V_DTYPE),
"4047 (Diablo 31)", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (TYPE_D44 << UNIT_V_DTYPE),
"4234/6045 (Diablo 44)", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (TYPE_C111 << UNIT_V_DTYPE),
"4048 (Century 111)", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (TYPE_C114 << UNIT_V_DTYPE),
"2314/4057 (Century 114)", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (TYPE_6225 << UNIT_V_DTYPE),
"6225", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (TYPE_6227 << UNIT_V_DTYPE),
"6227", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (TYPE_6099 << UNIT_V_DTYPE),
"6099", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (TYPE_6103 << UNIT_V_DTYPE),
"6103", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (TYPE_6070 << UNIT_V_DTYPE),
"6070", NULL, NULL },
{ (UNIT_AUTO+UNIT_DTYPE+UNIT_ATT), (TYPE_4231 << UNIT_V_DTYPE),
"4231/3330", NULL, NULL },
{ (UNIT_AUTO+UNIT_ATT), UNIT_AUTO, "autosize", NULL, NULL },
{ UNIT_AUTO, UNIT_AUTO, NULL, "AUTOSIZE", NULL },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_FLP << UNIT_V_DTYPE),
NULL, "FLOPPY", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_FLP << UNIT_V_DTYPE),
NULL, "6030", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_DSDD << UNIT_V_DTYPE),
NULL, "DSDDFLOPPY", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_DSDD << UNIT_V_DTYPE),
NULL, "6097", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_D31 << UNIT_V_DTYPE),
NULL, "D31", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_D31 << UNIT_V_DTYPE),
NULL, "4047", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_D44 << UNIT_V_DTYPE),
NULL, "D44", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_D44 << UNIT_V_DTYPE),
NULL, "4234", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_D44 << UNIT_V_DTYPE),
NULL, "6045", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_C111 << UNIT_V_DTYPE),
NULL, "C111", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_C111 << UNIT_V_DTYPE),
NULL, "4048", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_C114 << UNIT_V_DTYPE),
NULL, "C114", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_C114 << UNIT_V_DTYPE),
NULL, "2314", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_C114 << UNIT_V_DTYPE),
NULL, "4057", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_6225 << UNIT_V_DTYPE),
NULL, "6225", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_6227 << UNIT_V_DTYPE),
NULL, "6227", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_6099 << UNIT_V_DTYPE),
NULL, "6099", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_6103 << UNIT_V_DTYPE),
NULL, "6103", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_6070 << UNIT_V_DTYPE),
NULL, "6070", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_4231 << UNIT_V_DTYPE),
NULL, "4231", &dkp_set_size },
{ (UNIT_AUTO+UNIT_DTYPE), (TYPE_4231 << UNIT_V_DTYPE),
NULL, "3330", &dkp_set_size },
{ 0 } };
DEVICE dkp_dev = {
"DP", dkp_unit, dkp_reg, dkp_mod,
DKP_NUMDR, 8, 30, 1, 8, 16,
NULL, NULL, &dkp_reset,
&dkp_boot, &dkp_attach, NULL };
/* IOT routine */
int32 dkp (int32 pulse, int32 code, int32 AC)
{
UNIT *uptr;
int32 u, rval, dtype;
rval = 0;
uptr = dkp_dev.units + GET_UNIT (dkp_ussc); /* select unit */
dtype = GET_DTYPE (uptr -> flags); /* get drive type */
switch (code) { /* decode IR<5:7> */
case ioDIA: /* DIA */
dkp_sta = dkp_sta & ~STA_DYN; /* clear dynamic */
if (uptr -> flags & UNIT_ATT) dkp_sta = dkp_sta | STA_DRDY;
if (uptr -> CYL >= drv_tab[dtype].cyl)
dkp_sta = dkp_sta | STA_CYL; /* bad cylinder? */
if (dkp_sta & STA_EFLGS) dkp_sta = dkp_sta | STA_ERR;
rval = dkp_sta;
break;
case ioDOA: /* DOA */
if ((dev_busy & INT_DKP) == 0) {
dkp_fccy = AC; /* save cmd, cyl */
dkp_sta = dkp_sta & ~(AC & FCCY_FLAGS); }
break;
case ioDIB: /* DIB */
rval = dkp_ma; /* return buf addr */
break;
case ioDOB: /* DOB */
if ((dev_busy & INT_DKP) == 0) dkp_ma =
AC & (drv_tab[dtype].new? DMASK: AMASK);
break;
case ioDIC: /* DIC */
rval = dkp_ussc; /* return unit, sect */
break;
case ioDOC: /* DOC */
if ((dev_busy & INT_DKP) == 0) dkp_ussc = AC; /* save unit, sect */
break; } /* end switch code */
/* IOT, continued */
u = GET_UNIT(dkp_ussc); /* select unit */
switch (pulse) { /* decode IR<8:9> */
case iopS: /* start */
dev_busy = dev_busy | INT_DKP; /* set busy */
dev_done = dev_done & ~INT_DKP; /* clear done */
int_req = int_req & ~INT_DKP; /* clear int */
if (dkp_go ()) break; /* new cmd, error? */
dev_busy = dev_busy & ~INT_DKP; /* clear busy */
dev_done = dev_done | INT_DKP; /* set done */
int_req = (int_req & ~INT_DEV) | (dev_done & ~dev_disable);
dkp_sta = dkp_sta | STA_DONE;
break;
case iopC: /* clear */
dev_busy = dev_busy & ~INT_DKP; /* clear busy */
dev_done = dev_done & ~INT_DKP; /* clear done */
int_req = int_req & ~INT_DKP; /* clear int */
dkp_sta = dkp_sta & ~(STA_DFLGS + STA_EFLGS);
if (dkp_unit[u].FUNC != FCCY_SEEK) sim_cancel (&dkp_unit[u]);
break;
case iopP: /* pulse */
dev_done = dev_done & ~INT_DKP; /* clear done */
if (dkp_go ()) break; /* new seek command */
dev_done = dev_done | INT_DKP; /* set done */
int_req = (int_req & ~INT_DEV) | (dev_done & ~dev_disable);
dkp_sta = dkp_sta | (STA_SKDN0 >> u); /* set seek done */
break; } /* end case pulse */
return rval;
}
/* New command, start vs pulse handled externally
Returns true if command ok, false if error
*/
t_stat dkp_go (void)
{
UNIT *uptr;
int32 newcyl, func, u, dtype;
dkp_sta = dkp_sta & ~STA_EFLGS; /* clear errors */
u = GET_UNIT (dkp_ussc); /* get unit number */
uptr = dkp_dev.units + u; /* get unit */
if (((uptr -> flags & UNIT_ATT) == 0) || sim_is_active (uptr)) {
dkp_sta = dkp_sta | STA_ERR; /* attached or busy? */
return FALSE; }
dtype = GET_DTYPE (uptr -> flags); /* get drive type */
func = GET_CMD (dkp_fccy, dtype); /* get function */
newcyl = GET_CYL (dkp_fccy, dtype); /* get cylinder */
switch (func) { /* decode command */
case FCCY_READ: case FCCY_WRITE:
sim_activate (uptr, dkp_rwait); /* schedule */
break;
case FCCY_RECAL: /* recalibrate */
newcyl = 0;
func = FCCY_SEEK;
case FCCY_SEEK: /* seek */
sim_activate (uptr, dkp_swait * abs (newcyl - uptr -> CYL));
dkp_sta = dkp_sta | (STA_SEEK0 >> u); /* set seeking */
uptr -> CYL = newcyl; /* on cylinder */
break; } /* end case command */
uptr -> FUNC = func; /* save command */
return TRUE; /* no error */
}
/* Unit service
If seek done, put on cylinder;
else, do read or write
If controller was busy, clear busy, set done, interrupt
Memory access: sectors are read into/written from an intermediate
buffer to allow word-by-word mapping of memory addresses on the
Eclipse. This allows each word written to memory to be tested
for out of range.
*/
t_stat dkp_svc (UNIT *uptr)
{
int32 sc, sa, xcsa, awc, bda;
int32 sx, dx, pa;
int32 dtype, u, err, newsect, newsurf;
t_stat rval;
static uint16 tbuf[DKP_NUMWD]; /* transfer buffer */
rval = SCPE_OK;
dtype = GET_DTYPE (uptr -> flags); /* get drive type */
if (uptr -> FUNC == FCCY_SEEK) { /* seek? */
if (uptr -> CYL >= drv_tab[dtype].cyl) /* bad cylinder? */
dkp_sta = dkp_sta | STA_ERR | STA_CYL;
dev_done = dev_done | INT_DKP; /* set done */
int_req = (int_req & ~INT_DEV) | (dev_done & ~dev_disable);
u = uptr - dkp_dev.units; /* get unit number */
dkp_sta = (dkp_sta | (STA_SKDN0 >> u)) /* set seek done */
& ~(STA_SEEK0 >> u); /* clear seeking */
return SCPE_OK; }
if (((uptr -> flags & UNIT_ATT) == 0) || /* not attached? */
((uptr -> flags & UNIT_WLK) && (uptr -> FUNC == FCCY_WRITE)))
dkp_sta = dkp_sta | STA_DONE | STA_ERR; /* error */
else if ((uptr -> CYL >= drv_tab[dtype].cyl) || /* bad cylinder */
(GET_SURF (dkp_ussc, dtype) >= drv_tab[dtype].surf) || /* bad surface */
(GET_SECT (dkp_ussc, dtype) >= drv_tab[dtype].sect)) /* or bad sector? */
dkp_sta = dkp_sta | STA_DONE | STA_ERR | STA_UNS;
else if (GET_CYL (dkp_fccy, dtype) != uptr -> CYL) /* address error? */
dkp_sta = dkp_sta | STA_DONE | STA_ERR | STA_UNS;
else { sc = 16 - GET_COUNT (dkp_ussc); /* get sector count */
sa = GET_SA (uptr -> CYL, GET_SURF (dkp_ussc, dtype),
GET_SECT (dkp_ussc, dtype), dtype); /* get disk block */
xcsa = GET_SA (uptr -> CYL + 1, 0, 0, dtype); /* get next cyl addr */
if ((sa + sc) > xcsa ) { /* across cylinder? */
sc = xcsa - sa; /* limit transfer */
dkp_sta = dkp_sta | STA_XCY; } /* xcyl error */
bda = sa * DKP_NUMWD * sizeof (short); /* to words, bytes */
err = fseek (uptr -> fileref, bda, SEEK_SET); /* position drive */
if (uptr -> FUNC == FCCY_READ) { /* read? */
for (sx = 0; sx < sc; sx++) { /* loop thru sectors */
awc = fxread (tbuf, sizeof(uint16), DKP_NUMWD, uptr -> fileref);
for ( ; awc < DKP_NUMWD; awc++) tbuf[awc] = 0;
if (err = ferror (uptr -> fileref)) break;
for (dx = 0; dx < DKP_NUMWD; dx++) { /* loop thru buffer */
pa = MapAddr (0, dkp_ma);
if (MEM_ADDR_OK (pa)) M[pa] = tbuf[dx];
dkp_ma = (dkp_ma + 1) & AMASK; } } }
if (uptr -> FUNC == FCCY_WRITE) { /* write? */
for (sx = 0; sx < sc; sx++) { /* loop thru sectors */
for (dx = 0; dx < DKP_NUMWD; dx++) { /* loop into buffer */
pa = MapAddr (0, dkp_ma);
tbuf[dx] = M[pa];
dkp_ma = (dkp_ma + 1) & AMASK; }
fxwrite (tbuf, sizeof(int16), DKP_NUMWD, uptr -> fileref);
if (err = ferror (uptr -> fileref)) break; } }
if (err != 0) {
perror ("DKP I/O error");
rval = SCPE_IOERR; }
clearerr (uptr -> fileref);
sa = sa + sc; /* update sector addr */
newsect = sa % drv_tab[dtype].sect;
newsurf = (sa / drv_tab[dtype].sect) % drv_tab[dtype].surf;
dkp_ussc = (dkp_ussc & USSC_UNIT) | ((dkp_ussc + sc) & USSC_M_COUNT) |
((drv_tab[dtype].new)?
((newsurf << USSC_V_NSURFACE) | (newsect << USSC_V_NSECTOR)):
((newsurf << USSC_V_OSURFACE) | (newsect << USSC_V_OSECTOR)) );
dkp_sta = dkp_sta | STA_DONE; } /* set status */
dev_busy = dev_busy & ~INT_DKP; /* clear busy */
dev_done = dev_done | INT_DKP; /* set done */
int_req = (int_req & ~INT_DEV) | (dev_done & ~dev_disable);
return rval;
}
/* Reset routine */
t_stat dkp_reset (DEVICE *dptr)
{
int32 u;
UNIT *uptr;
dev_busy = dev_busy & ~INT_DKP; /* clear busy */
dev_done = dev_done & ~INT_DKP; /* clear done, int */
int_req = int_req & ~INT_DKP;
dkp_fccy = dkp_ussc = dkp_ma = dkp_sta = 0; /* clear registers */
for (u = 0; u < DKP_NUMDR; u++) { /* loop thru units */
uptr = dkp_dev.units + u;
sim_cancel (uptr); /* cancel activity */
uptr -> CYL = uptr -> FUNC = 0; }
return SCPE_OK;
}
/* Attach routine (with optional autosizing) */
t_stat dkp_attach (UNIT *uptr, char *cptr)
{
int32 i, p;
t_stat r;
uptr -> capac = drv_tab[GET_DTYPE (uptr -> flags)].size;
r = attach_unit (uptr, cptr);
if ((r != SCPE_OK) || ((uptr -> flags & UNIT_AUTO) == 0)) return r;
if (fseek (uptr -> fileref, 0, SEEK_END)) return SCPE_OK;
if ((p = ftell (uptr -> fileref)) == 0) return SCPE_OK;
for (i = 0; drv_tab[i].sect != 0; i++) {
if (p <= (drv_tab[i].size * (int) sizeof (short))) {
uptr -> flags = (uptr -> flags & ~UNIT_DTYPE) | (i << UNIT_V_DTYPE);
uptr -> capac = drv_tab[i].size;
return SCPE_OK; } }
return SCPE_OK;
}
/* Set size command validation routine */
t_stat dkp_set_size (UNIT *uptr, int32 value)
{
if (uptr -> flags & UNIT_ATT) return SCPE_ALATT;
uptr -> capac = drv_tab[GET_DTYPE (value)].size;
return SCPE_OK;
}
/* Bootstrap routine */
#define BOOT_START 02000
#define BOOT_UNIT 02021
#define BOOT_SEEK 02022
#define BOOT_LEN (sizeof (boot_rom) / sizeof (int))
static const int32 boot_rom[] = {
060233, /* NIOC 0,DKP ; clear disk */
020420, /* LDA 0,USSC ; unit, sfc, sec, cnt */
063033, /* DOC 0,DKP ; select disk */
020417, /* LDA 0,SEKCMD ; command, cylinder */
061333, /* DOAP 0,DKP ; start seek */
024415, /* LDA 1,SEKDN */
060433, /* DIA 0,DKP ; get status */
0123415, /* AND# 1,0,SZR ; skip if done */
000776, /* JMP .-2 */
0102400, /* SUB 0,0 ; mem addr = 0 */
062033, /* DOB 0,DKP */
020411, /* LDA 0,REDCMD ; command, cylinder */
061133, /* DOAS 0,DKP ; start read */
060433, /* DIA 0, DKP ; get status */
0101113, /* MOVL# 0,0,SNC ; skip if done */
000776, /* JMP .-2 */
000377, /* JMP 377 */
000016, /* USSC: 0.B1+0.B7+0.B11+16 */
0175000, /* SEKCMD: 175000 */
074000, /* SEKDN: 074000 */
0174000 /* REDCMD: 174000 */
};
t_stat dkp_boot (int32 unitno)
{
int32 i, dtype;
extern int32 saved_PC;
for (i = 0; i < BOOT_LEN; i++) M[BOOT_START + i] = boot_rom[i];
unitno = unitno & USSC_M_UNIT;
dtype = GET_DTYPE (dkp_unit[unitno].flags);
M[BOOT_UNIT] = M[BOOT_UNIT] | (unitno << USSC_V_UNIT);
if (drv_tab[dtype].new) M[BOOT_SEEK] = 0176000;
saved_PC = BOOT_START;
return SCPE_OK;
}