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/* pdp11_rk.c: RK11/RKV11 cartridge disk simulator
Copyright (c) 1993-2009, 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.
rk RK11/RKV11/RK05 cartridge disk
23-Oct-13 RMS Revised for new boot setup routine
20-Mar-09 RMS Fixed bug in read header (Walter F Mueller)
16-Aug-05 RMS Fixed C++ declaration and cast problems
07-Jul-05 RMS Removed extraneous externs
30-Sep-04 RMS Revised Unibus interface
24-Jan-04 RMS Added increment inhibit, overrun detection, formatting
29-Dec-03 RMS Added RKV11 support
29-Sep-02 RMS Added variable address support to bootstrap
Added vector change/display support
Revised mapping mnemonics
New data structures
26-Jan-02 RMS Revised bootstrap to conform to M9312
06-Jan-02 RMS Revised enable/disable support
30-Nov-01 RMS Added read only unit, extended SET/SHOW support
24-Nov-01 RMS Converted FLG to array
09-Nov-01 RMS Added bus map support
07-Sep-01 RMS Revised device disable and interrupt mechanisms
26-Apr-01 RMS Added device enable/disable support
25-Mar-01 RMS Fixed block fill calculation
15-Feb-01 RMS Corrected bootstrap string
29-Jun-96 RMS Added unit disable support
The RK11 is an eight drive cartridge disk subsystem. An RK05 drive
consists of 203 cylinders, each with 2 surfaces containing 12 sectors
of 512 bytes.
The most complicated part of the RK11 controller is the concept of
interrupt "polling". While only one read or write can occur at a
time, the controller supports multiple seeks. When a seek completes,
if done is set the drive attempts to interrupt. If an interrupt is
already pending, the interrupt is "queued" until it can be processed.
When an interrupt occurs, RKDS<15:13> is loaded with the number of the
interrupting drive.
To implement this structure, and to assure that read/write interrupts
take priority over seek interrupts, the controller contains an
interrupt queue, rkintq, with a bit for a controller interrupt and
then one for each drive. In addition, the drive number of the last
non-seeking drive is recorded in last_drv.
*/
#include "pdp11_defs.h"
/* Constants */
#define RK_NUMWD 256 /* words/sector */
#define RK_NUMSC 12 /* sectors/surface */
#define RK_NUMSF 2 /* surfaces/cylinder */
#define RK_NUMCY 203 /* cylinders/drive */
#define RK_NUMTR (RK_NUMCY * RK_NUMSF) /* tracks/drive */
#define RK_NUMDR 8 /* drives/controller */
#define RK_M_NUMDR 07
#define RK_SIZE (RK_NUMCY * RK_NUMSF * RK_NUMSC * RK_NUMWD)
/* words/drive */
#define RK_CTLI 1 /* controller int */
#define RK_SCPI(x) (2u << (x)) /* drive int */
#define RK_MAXFR (1 << 16) /* max transfer */
/* Flags in the unit flags word */
#define UNIT_V_HWLK (UNIT_V_UF + 0) /* hwre write lock */
#define UNIT_V_SWLK (UNIT_V_UF + 1) /* swre write lock */
#define UNIT_HWLK (1u << UNIT_V_HWLK)
#define UNIT_SWLK (1u << UNIT_V_SWLK)
#define UNIT_WPRT (UNIT_HWLK|UNIT_SWLK|UNIT_RO) /* write prot */
/* Parameters in the unit descriptor */
#define CYL u3 /* current cylinder */
#define FUNC u4 /* function */
/* RKDS */
BITFIELD rk_ds_bits[] = {
#define RKDS_SC 0000017 /* sector counter */
BITF(SC,4),
#define RKDS_ON_SC 0000020 /* on sector */
BIT(ON_SC),
#define RKDS_WLK 0000040 /* write locked */
BIT(WLK),
#define RKDS_RWS 0000100 /* rd/wr/seek ready */
BIT(RWS),
#define RKDS_RDY 0000200 /* drive ready */
BIT(RDY),
#define RKDS_SC_OK 0000400 /* SC valid */
BIT(SC_OK),
#define RKDS_INC 0001000 /* seek incomplete */
BIT(INC),
#define RKDS_UNSAFE 0002000 /* unsafe */
BIT(UNSAFE),
#define RKDS_RK05 0004000 /* RK05 */
BIT(RK05),
#define RKDS_PWR 0010000 /* power low */
BIT(PWR),
#define RKDS_ID 0160000 /* drive ID */
#define RKDS_V_ID 13
BITF(ID,3),
ENDBITS
};
/* RKER */
BITFIELD rk_er_bits[] = {
#define RKER_WCE 0000001 /* write check */
BIT(WCE),
#define RKER_CSE 0000002 /* checksum */
BIT(CSE),
#define RKER_NXS 0000040 /* nx sector */
BIT(NXS),
#define RKER_NXC 0000100 /* nx cylinder */
BIT(NXC),
#define RKER_NXD 0000200 /* nx drive */
BIT(NXD),
#define RKER_TE 0000400 /* timing error */
BIT(TE),
#define RKER_DLT 0001000 /* data late */
BIT(DLT),
#define RKER_NXM 0002000 /* nx memory */
BIT(NXM),
#define RKER_PGE 0004000 /* programming error */
BIT(PGE),
#define RKER_SKE 0010000 /* seek error */
BIT(SKE),
#define RKER_WLK 0020000 /* write lock */
BIT(WLK),
#define RKER_OVR 0040000 /* overrun */
BIT(OVR),
#define RKER_DRE 0100000 /* drive error */
BIT(DRE),
#define RKER_IMP 0177743 /* implemented */
#define RKER_SOFT (RKER_WCE+RKER_CSE) /* soft errors */
#define RKER_HARD 0177740 /* hard errors */
ENDBITS
};
/* RKCS */
static const char *rk_funcs[] = {
"CTLRESET", "WRITE", "READ", "WCHK", "SEEK", "RCHK", "DRVRESET", "WLK"};
BITFIELD rk_cs_bits[] = {
BIT(GO),
#define RKCS_M_FUNC 0000007 /* function */
#define RKCS_CTLRESET 0
#define RKCS_WRITE 1
#define RKCS_READ 2
#define RKCS_WCHK 3
#define RKCS_SEEK 4
#define RKCS_RCHK 5
#define RKCS_DRVRESET 6
#define RKCS_WLK 7
#define RKCS_V_FUNC 1
BITFNAM(FUNC,3,rk_funcs),
#define RKCS_MEX 0000060 /* memory extension */
#define RKCS_V_MEX 4
BITF(MEX,2),
BIT(IE),
BIT(DONE),
#define RKCS_SSE 0000400 /* stop on soft err */
BIT(SSE),
BITNC,
#define RKCS_FMT 0002000 /* format */
BIT(FMT),
#define RKCS_INH 0004000 /* inhibit increment */
BIT(INH),
BITNC,
#define RKCS_SCP 0020000 /* search complete */
BIT(SCP),
#define RKCS_HERR 0040000 /* hard error */
BIT(HERR),
#define RKCS_ERR 0100000 /* error */
BIT(ERR),
#define RKCS_REAL 0026776 /* kept here */
#define RKCS_RW 0006576 /* read/write */
#define GET_FUNC(x) (((x) >> RKCS_V_FUNC) & RKCS_M_FUNC)
ENDBITS
};
/* RKDA */
BITFIELD rk_da_bits[] = {
#define RKDA_V_SECT 0 /* sector */
#define RKDA_M_SECT 017
BITF(SECT,4),
#define RKDA_V_TRACK 4 /* track */
#define RKDA_M_TRACK 0777
BITF(SURF,1),
#define RKDA_V_CYL 5 /* cylinder */
#define RKDA_M_CYL 0377
BITF(CYL,8),
#define RKDA_V_DRIVE 13 /* drive */
#define RKDA_M_DRIVE 07
#define RKDA_DRIVE (RKDA_M_DRIVE << RKDA_V_DRIVE)
BITF(DRIVE,3),
#define GET_SECT(x) (((x) >> RKDA_V_SECT) & RKDA_M_SECT)
#define GET_CYL(x) (((x) >> RKDA_V_CYL) & RKDA_M_CYL)
#define GET_TRACK(x) (((x) >> RKDA_V_TRACK) & RKDA_M_TRACK)
#define GET_DRIVE(x) (((x) >> RKDA_V_DRIVE) & RKDA_M_DRIVE)
#define GET_DA(x) ((GET_TRACK (x) * RK_NUMSC) + GET_SECT (x))
ENDBITS
};
/* RKWC */
BITFIELD rk_wc_bits[] = {
BITF(WC,16),
ENDBITS
};
/* RKBA */
BITFIELD rk_ba_bits[] = {
#define RKBA_IMP 0177776 /* implemented */
BITF(BA,16),
ENDBITS
};
BITFIELD *rk_reg_bits[] = {
rk_ds_bits,
rk_er_bits,
rk_cs_bits,
rk_wc_bits,
rk_ba_bits,
rk_da_bits,
NULL,
NULL,
};
/* Debug detail levels */
#define RKDEB_OPS 001 /* transactions */
#define RKDEB_RRD 002 /* reg reads */
#define RKDEB_RWR 004 /* reg writes */
#define RKDEB_TRC 010 /* trace */
#define RKDEB_INT 020 /* interrupts */
#define RK_MIN 10
#define MAX(x,y) (((x) > (y))? (x): (y))
extern uint16 *M; /* memory */
extern int32 int_req[IPL_HLVL];
uint16 *rkxb = NULL; /* xfer buffer */
int32 rkcs = 0; /* control/status */
int32 rkds = 0; /* drive status */
int32 rkba = 0; /* memory address */
int32 rkda = 0; /* disk address */
int32 rker = 0; /* error status */
int32 rkwc = 0; /* word count */
int32 rkintq = 0; /* interrupt queue */
int32 last_drv = 0; /* last r/w drive */
int32 rk_stopioe = 1; /* stop on error */
int32 rk_swait = 10; /* seek time */
int32 rk_rwait = 10; /* rotate time */
const char *rk_regnames[] = {
"RKDS",
"RKER",
"RKCS",
"RKWC",
"RKBA",
"RKDA",
"unused",
"RKDB",
};
int32 *rk_regs[] = {
&rkds,
&rker,
&rkcs,
&rkwc,
&rkba,
&rkda,
};
t_stat rk_rd (int32 *data, int32 PA, int32 access);
t_stat rk_wr (int32 data, int32 PA, int32 access);
int32 rk_inta (void);
t_stat rk_svc (UNIT *uptr);
t_stat rk_reset (DEVICE *dptr);
void rk_go (void);
void rk_set_done (int32 error);
void rk_clr_done (void);
t_stat rk_boot (int32 unitno, DEVICE *dptr);
t_stat rk_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr);
const char *rk_description (DEVICE *dptr);
DEBTAB rk_deb[] = {
{ "OPS", RKDEB_OPS },
{ "RRD", RKDEB_RRD },
{ "RWR", RKDEB_RWR },
{ "INTERRUPT", RKDEB_INT },
{ "TRACE", RKDEB_TRC },
{ NULL, 0 }
};
/* RK11 data structures
rk_dev RK device descriptor
rk_unit RK unit list
rk_reg RK register list
rk_mod RK modifier list
*/
#define IOLN_RK 020
DIB rk_dib = {
IOBA_AUTO, IOLN_RK, &rk_rd, &rk_wr,
1, IVCL (RK), VEC_AUTO, { &rk_inta }, IOLN_RK,
};
UNIT rk_unit[] = {
{ UDATA (&rk_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+
UNIT_ROABLE, RK_SIZE) },
{ UDATA (&rk_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+
UNIT_ROABLE, RK_SIZE) },
{ UDATA (&rk_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+
UNIT_ROABLE, RK_SIZE) },
{ UDATA (&rk_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+
UNIT_ROABLE, RK_SIZE) },
{ UDATA (&rk_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+
UNIT_ROABLE, RK_SIZE) },
{ UDATA (&rk_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+
UNIT_ROABLE, RK_SIZE) },
{ UDATA (&rk_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+
UNIT_ROABLE, RK_SIZE) },
{ UDATA (&rk_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE+
UNIT_ROABLE, RK_SIZE) }
};
REG rk_reg[] = {
{ ORDATADF (RKCS, rkcs, 16, "control/status", rk_cs_bits) },
{ ORDATADF (RKDA, rkda, 16, "disk address", rk_da_bits) },
{ ORDATADF (RKBA, rkba, 16, "memory address", rk_ba_bits) },
{ ORDATADF (RKWC, rkwc, 16, "word count", rk_wc_bits) },
{ ORDATADF (RKDS, rkds, 16, "drive status", rk_ds_bits) },
{ ORDATADF (RKER, rker, 16, "error status", rk_er_bits) },
{ ORDATAD (INTQ, rkintq, 9, "interrupt queue") },
{ ORDATAD (DRVN, last_drv, 3, "last r/w drive") },
{ FLDATAD (INT, IREQ (RK), INT_V_RK, "interrupt pending flag") },
{ FLDATAD (ERR, rkcs, CSR_V_ERR, "error flag (CSR<15>)") },
{ FLDATAD (DONE, rkcs, CSR_V_DONE, "device done flag (CSR<7>)") },
{ FLDATAD (IE, rkcs, CSR_V_IE, "interrupt enable flag (CSR<6>)") },
{ DRDATAD (STIME, rk_swait, 24, "seek time, per cylinder"), PV_LEFT },
{ DRDATAD (RTIME, rk_rwait, 24, "rotational delay"), PV_LEFT },
{ FLDATAD (STOP_IOE, rk_stopioe, 0, "stop on I/O error flag") },
{ ORDATA (DEVADDR, rk_dib.ba, 32), REG_HRO },
{ ORDATA (DEVVEC, rk_dib.vec, 16), REG_HRO },
{ NULL }
};
MTAB rk_mod[] = {
{ UNIT_HWLK, 0, "write enabled", "WRITEENABLED",
NULL, NULL, NULL, "Write enable disk drive" },
{ UNIT_HWLK, UNIT_HWLK, "write locked", "LOCKED",
NULL, NULL, NULL, "Write lock disk drive" },
{ MTAB_XTD|MTAB_VDV|MTAB_VALR, 010, "ADDRESS", "ADDRESS",
&set_addr, &show_addr, NULL, "Bus address" },
{ MTAB_XTD|MTAB_VDV|MTAB_VALR, 0, "VECTOR", "VECTOR",
&set_vec, &show_vec, NULL, "Interrupt vector" },
{ 0 }
};
DEVICE rk_dev = {
"RK", rk_unit, rk_reg, rk_mod,
RK_NUMDR, 8, 24, 1, 8, 16,
NULL, NULL, &rk_reset,
&rk_boot, NULL, NULL,
&rk_dib, DEV_DISABLE | DEV_UBUS | DEV_Q18 | DEV_DEBUG, 0,
rk_deb, NULL, NULL, &rk_help, NULL, NULL,
&rk_description
};
/* I/O dispatch routine, I/O addresses 17777400 - 17777416
17777400 RKDS read only, constructed from "id'd drive"
plus current drive status flags
17777402 RKER read only, set as operations progress,
cleared by INIT or CONTROL RESET
17777404 RKCS read/write
17777406 RKWC read/write
17777410 RKBA read/write
17777412 RKDA read/write
17777414 RKMR read/write, unimplemented
17777416 RKDB read only, unimplemented
*/
t_stat rk_rd (int32 *data, int32 PA, int32 access)
{
UNIT *uptr;
switch ((PA >> 1) & 07) { /* decode PA<3:1> */
case 0: /* RKDS: read only */
rkds = rkds & RKDS_ID; /* identified unit */
uptr = rk_dev.units + GET_DRIVE (rkda); /* selected unit */
if (!(uptr->flags & UNIT_DIS)) { /* not disabled? */
rkds = rkds | RKDS_RK05 | RKDS_SC_OK | /* random sector */
(rand () % RK_NUMSC);
if (uptr->flags & UNIT_ATT) /* attached? */
rkds = rkds | RKDS_RDY;
if (!sim_is_active (uptr)) /* idle? */
rkds = rkds | RKDS_RWS;
if (uptr->flags & UNIT_WPRT) /* write locked? */
rkds = rkds | RKDS_WLK;
if (GET_SECT (rkda) == (rkds & RKDS_SC))
rkds = rkds | RKDS_ON_SC;
}
*data = rkds;
break;
case 1: /* RKER: read only */
*data = rker & RKER_IMP;
break;
case 2: /* RKCS */
rkcs = rkcs & RKCS_REAL;
if (rker) /* update err flags */
rkcs = rkcs | RKCS_ERR;
if (rker & RKER_HARD)
rkcs = rkcs | RKCS_HERR;
*data = rkcs;
break;
case 3: /* RKWC */
*data = rkwc;
break;
case 4: /* RKBA */
*data = rkba & RKBA_IMP;
break;
case 5: /* RKDA */
*data = rkda;
break;
default:
*data = 0;
return SCPE_OK;
} /* end switch */
sim_debug (RKDEB_RRD, &rk_dev, ">>RK read: %s=0%o\n", rk_regnames[(PA >> 1) & 07], *data);
sim_debug_bits (RKDEB_RRD, &rk_dev, rk_reg_bits[(PA >> 1) & 07], *data, *data, 1);
return SCPE_OK;
}
t_stat rk_wr (int32 data, int32 PA, int32 access)
{
int32 old_val = *rk_regs[(PA >> 1) & 07];
switch ((PA >> 1) & 07) { /* decode PA<3:1> */
case 0: /* RKDS: read only */
break;
case 1: /* RKER: read only */
break;
case 2: /* RKCS */
rkcs = rkcs & RKCS_REAL;
if (access == WRITEB)
data = (PA & 1)? (rkcs & 0377) | (data << 8): (rkcs & ~0377) | data;
if ((data & CSR_IE) == 0) { /* int disable? */
rkintq = 0; /* clr int queue */
sim_debug (RKDEB_INT, &rk_dev, "rk_wr(CLR_INT)\n");
CLR_INT (RK); /* clr int request */
}
else if ((rkcs & (CSR_DONE + CSR_IE)) == CSR_DONE) {
rkintq = rkintq | RK_CTLI; /* queue ctrl int */
sim_debug (RKDEB_INT, &rk_dev, "rk_wr(SET_INT)\n");
SET_INT (RK); /* set int request */
}
rkcs = (rkcs & ~RKCS_RW) | (data & RKCS_RW);
if ((rkcs & CSR_DONE) && (data & CSR_GO)) /* new function? */
rk_go ();
break;
case 3: /* RKWC */
if (access == WRITEB)
data = (PA & 1)? (rkwc & 0377) | (data << 8): (rkwc & ~0377) | data;
rkwc = data;
break;
case 4: /* RKBA */
if (access == WRITEB)
data = (PA & 1)? (rkba & 0377) | (data << 8): (rkba & ~0377) | data;
rkba = data & RKBA_IMP;
break;
case 5: /* RKDA */
if ((rkcs & CSR_DONE) == 0)
return SCPE_OK;
if (access == WRITEB)
data = (PA & 1)? (rkda & 0377) | (data << 8): (rkda & ~0377) | data;
rkda = data;
break;
default:
return SCPE_OK;
} /* end switch */
sim_debug (RKDEB_RWR, &rk_dev, ">>RK write: %s=0%o\n", rk_regnames[(PA >> 1) & 07], data);
sim_debug_bits (RKDEB_RWR, &rk_dev, rk_reg_bits[(PA >> 1) & 07], old_val, *rk_regs[(PA >> 1) & 07], 1);
return SCPE_OK;
}
/* Initiate new function */
void rk_go (void)
{
int32 i, sect, cyl, func;
UNIT *uptr;
func = GET_FUNC (rkcs); /* get function */
if (func == RKCS_CTLRESET) { /* control reset? */
rker = 0; /* clear errors */
rkda = 0;
rkba = 0;
rkcs = CSR_DONE;
rkintq = 0; /* clr int queue */
sim_debug (RKDEB_INT, &rk_dev, "rk_go(CLR_INT)\n");
CLR_INT (RK); /* clr int request */
return;
}
rker = rker & ~RKER_SOFT; /* clear soft errors */
if (rker == 0) /* redo summary */
rkcs = rkcs & ~RKCS_ERR;
rkcs = rkcs & ~RKCS_SCP; /* clear sch compl*/
rk_clr_done (); /* clear done */
last_drv = GET_DRIVE (rkda); /* get drive no */
uptr = rk_dev.units + last_drv; /* select unit */
if (uptr->flags & UNIT_DIS) { /* not present? */
rk_set_done (RKER_NXD);
return;
}
if (((uptr->flags & UNIT_ATT) == 0) || /* not att or busy? */
sim_is_active (uptr)) {
rk_set_done (RKER_DRE);
return;
}
if ((rkcs & RKCS_FMT) && /* format and */
(func != RKCS_READ) && (func != RKCS_WRITE)) { /* not read or write? */
rk_set_done (RKER_PGE);
return;
}
if ((func == RKCS_WRITE) && /* write and locked? */
(uptr->flags & UNIT_WPRT)) {
rk_set_done (RKER_WLK);
return;
}
if (func == RKCS_WLK) { /* write lock? */
uptr->flags = uptr->flags | UNIT_SWLK;
rk_set_done (0);
return;
}
if (func == RKCS_DRVRESET) { /* drive reset? */
uptr->flags = uptr->flags & ~UNIT_SWLK;
cyl = sect = 0;
func = RKCS_SEEK;
}
else {
sect = GET_SECT (rkda);
cyl = GET_CYL (rkda);
}
if (sect >= RK_NUMSC) { /* bad sector? */
rk_set_done (RKER_NXS);
return;
}
if (cyl >= RK_NUMCY) { /* bad cyl? */
rk_set_done (RKER_NXC);
return;
}
i = abs (cyl - uptr->CYL) * rk_swait; /* seek time */
if (func == RKCS_SEEK) { /* seek? */
rk_set_done (0); /* set done */
sim_activate (uptr, MAX (RK_MIN, i)); /* schedule */
}
else sim_activate (uptr, i + rk_rwait);
uptr->FUNC = func; /* save func */
uptr->CYL = cyl; /* put on cylinder */
return;
}
/* Service unit timeout
If seek in progress, complete seek command
Else complete data transfer command
The unit control block contains the function and disk address for
the current command.
*/
t_stat rk_svc (UNIT *uptr)
{
int32 i, drv, err, awc, wc, cma, cda, t;
int32 da, cyl, track, sect;
uint32 ma;
uint16 comp;
drv = (int32) (uptr - rk_dev.units); /* get drv number */
if (uptr->FUNC == RKCS_SEEK) { /* seek */
rkcs = rkcs | RKCS_SCP; /* set seek done */
if (rkcs & CSR_IE) { /* ints enabled? */
rkintq = rkintq | RK_SCPI (drv); /* queue request */
if (rkcs & CSR_DONE) {
sim_debug (RKDEB_INT, &rk_dev, "rk_svc(SET_INT)\n");
SET_INT (RK);
}
}
else {
rkintq = 0; /* clear queue */
sim_debug (RKDEB_INT, &rk_dev, "rk_svc(CLR_INT)\n");
CLR_INT (RK); /* clear interrupt */
}
return SCPE_OK;
}
if ((uptr->flags & UNIT_ATT) == 0) { /* attached? */
rk_set_done (RKER_DRE);
return IORETURN (rk_stopioe, SCPE_UNATT);
}
sect = GET_SECT (rkda); /* get sector, cyl */
cyl = GET_CYL (rkda);
if (sect >= RK_NUMSC) { /* bad sector? */
rk_set_done (RKER_NXS);
return SCPE_OK;
}
if (cyl >= RK_NUMCY) { /* bad cyl? */
rk_set_done (RKER_NXC);
return SCPE_OK;
}
ma = ((rkcs & RKCS_MEX) << (16 - RKCS_V_MEX)) | rkba; /* get mem addr */
da = GET_DA (rkda) * RK_NUMWD; /* get disk addr */
wc = 0200000 - rkwc; /* get wd cnt */
if ((da + wc) > (int32) uptr->capac) { /* overrun? */
wc = uptr->capac - da; /* trim transfer */
rker = rker | RKER_OVR; /* set overrun err */
}
err = fseek (uptr->fileref, da * sizeof (int16), SEEK_SET);
if (wc && (err == 0)) { /* seek ok? */
switch (uptr->FUNC) { /* case on function */
case RKCS_READ: /* read */
if (rkcs & RKCS_FMT) { /* format? */
for (i = 0, cda = da; i < wc; i++) { /* fill buffer with cyl #s */
if (cda >= (int32) uptr->capac) { /* overrun? */
rker = rker | RKER_OVR; /* set overrun err */
wc = i; /* trim transfer */
break;
}
rkxb[i] = (uint16)(((cda / RK_NUMWD) / (RK_NUMSF * RK_NUMSC)) << RKDA_V_CYL);
cda = cda + RK_NUMWD; /* next sector */
} /* end for wc */
} /* end if format */
else { /* normal read */
i = fxread (rkxb, sizeof (int16), wc, uptr->fileref);
err = ferror (uptr->fileref); /* read file */
for ( ; i < wc; i++) /* fill buf */
rkxb[i] = 0;
}
if (rkcs & RKCS_INH) { /* incr inhibit? */
if ((t = Map_WriteW (ma, 2, &rkxb[wc - 1]))) {/* store last */
rker = rker | RKER_NXM; /* NXM? set flag */
wc = 0; /* no transfer */
}
}
else { /* normal store */
if ((t = Map_WriteW (ma, wc << 1, rkxb))) { /* store buf */
rker = rker | RKER_NXM; /* NXM? set flag */
wc = wc - t; /* adj wd cnt */
}
}
break; /* end read */
case RKCS_WRITE: /* write */
if (rkcs & RKCS_INH) { /* incr inhibit? */
if ((t = Map_ReadW (ma, 2, &comp))) { /* get 1st word */
rker = rker | RKER_NXM; /* NXM? set flag */
wc = 0; /* no transfer */
}
for (i = 0; i < wc; i++) /* all words same */
rkxb[i] = comp;
}
else { /* normal fetch */
if ((t = Map_ReadW (ma, wc << 1, rkxb))) { /* get buf */
rker = rker | RKER_NXM; /* NXM? set flg */
wc = wc - t; /* adj wd cnt */
}
}
if (wc) { /* any xfer? */
awc = (wc + (RK_NUMWD - 1)) & ~(RK_NUMWD - 1); /* clr to */
for (i = wc; i < awc; i++) /* end of blk */
rkxb[i] = 0;
fxwrite (rkxb, sizeof (int16), awc, uptr->fileref);
err = ferror (uptr->fileref);
}
break; /* end write */
case RKCS_WCHK: /* write check */
i = fxread (rkxb, sizeof (int16), wc, uptr->fileref);
if ((err = ferror (uptr->fileref))) { /* read error? */
wc = 0; /* no transfer */
break;
}
for ( ; i < wc; i++) /* fill buf */
rkxb[i] = 0;
awc = wc; /* save wc */
for (wc = 0, cma = ma; wc < awc; wc++) { /* loop thru buf */
if (Map_ReadW (cma, 2, &comp)) { /* mem wd */
rker = rker | RKER_NXM; /* NXM? set flg */
break;
}
if (comp != rkxb[wc]) { /* match to disk? */
rker = rker | RKER_WCE; /* no, err */
if (rkcs & RKCS_SSE)
break;
}
if (!(rkcs & RKCS_INH)) /* next mem addr */
cma = cma + 2;
} /* end for */
break; /* end wcheck */
default: /* read check */
break;
} /* end switch */
} /* end else */
rkwc = (rkwc + wc) & 0177777; /* final word count */
if (!(rkcs & RKCS_INH)) /* final byte addr */
ma = ma + (wc << 1);
rkba = ma & RKBA_IMP; /* lower 16b */
rkcs = (rkcs & ~RKCS_MEX) | ((ma >> (16 - RKCS_V_MEX)) & RKCS_MEX);
if ((uptr->FUNC == RKCS_READ) && (rkcs & RKCS_FMT)) /* read format? */
da = da + (wc * RK_NUMWD); /* count by sectors */
else da = da + wc + (RK_NUMWD - 1); /* count by words */
track = (da / RK_NUMWD) / RK_NUMSC;
sect = (da / RK_NUMWD) % RK_NUMSC;
rkda = (rkda & RKDA_DRIVE) | (track << RKDA_V_TRACK) | (sect << RKDA_V_SECT);
rk_set_done (0);
if (err != 0) { /* error? */
sim_perror ("RK I/O error");
clearerr (uptr->fileref);
return SCPE_IOERR;
}
return SCPE_OK;
}
/* Interrupt state change routines
rk_set_done set done and possibly errors
rk_clr_done clear done
rk_inta acknowledge intererupt
*/
void rk_set_done (int32 error)
{
rkcs = rkcs | CSR_DONE; /* set done */
if (error != 0) {
rker = rker | error; /* update error */
if (rker) /* update err flags */
rkcs = rkcs | RKCS_ERR;
if (rker & RKER_HARD)
rkcs = rkcs | RKCS_HERR;
}
if (rkcs & CSR_IE) { /* int enable? */
rkintq = rkintq | RK_CTLI; /* set ctrl int */
sim_debug (RKDEB_INT, &rk_dev, "rk_set_done(SET_INT)\n");
SET_INT (RK); /* request int */
}
else {
rkintq = 0; /* clear queue */
sim_debug (RKDEB_INT, &rk_dev, "rk_set_done(CLR_INT)\n");
CLR_INT (RK);
}
return;
}
void rk_clr_done (void)
{
rkcs = rkcs & ~CSR_DONE; /* clear done */
rkintq = rkintq & ~RK_CTLI; /* clear ctl int */
sim_debug (RKDEB_INT, &rk_dev, "rk_clr_done(CLR_INT)\n");
CLR_INT (RK); /* clear int req */
return;
}
int32 rk_inta (void)
{
int32 i;
for (i = 0; i <= RK_NUMDR; i++) { /* loop thru intq */
if (rkintq & (1u << i)) { /* bit i set? */
rkintq = rkintq & ~(1u << i); /* clear bit i */
if (rkintq) { /* queue next */
sim_debug (RKDEB_INT, &rk_dev, "rk_inta(SET_INT)\n");
SET_INT (RK);
}
rkds = (rkds & ~RKDS_ID) | /* id drive */
(((i == 0)? last_drv: i - 1) << RKDS_V_ID);
sim_debug (RKDEB_INT, &rk_dev, "rk_inta(vec=0%o)\n", rk_dib.vec);
return rk_dib.vec; /* return vector */
}
}
rkintq = 0; /* clear queue */
return 0; /* passive release */
}
/* Device reset */
t_stat rk_reset (DEVICE *dptr)
{
int32 i;
UNIT *uptr;
rkcs = CSR_DONE;
rkda = rkba = rker = rkds = 0;
rkintq = last_drv = 0;
sim_debug (RKDEB_INT, &rk_dev, "rk_reset(CLR_INT)\n");
CLR_INT (RK);
for (i = 0; i < RK_NUMDR; i++) {
uptr = rk_dev.units + i;
sim_cancel (uptr);
uptr->CYL = uptr->FUNC = 0;
uptr->flags = uptr->flags & ~UNIT_SWLK;
}
if (rkxb == NULL)
rkxb = (uint16 *) calloc (RK_MAXFR, sizeof (uint16));
if (rkxb == NULL)
return SCPE_MEM;
return auto_config (0, 0);
}
/* Device bootstrap */
#define BOOT_START 02000 /* start */
#define BOOT_ENTRY (BOOT_START + 002) /* entry */
#define BOOT_UNIT (BOOT_START + 010) /* unit number */
#define BOOT_CSR (BOOT_START + 032) /* CSR */
#define BOOT_LEN (sizeof (boot_rom) / sizeof (int16))
static const uint16 boot_rom[] = {
0042113, /* "KD" */
0012706, BOOT_START, /* MOV #boot_start, SP */
0012700, 0000000, /* MOV #unit, R0 ; unit number */
0010003, /* MOV R0, R3 */
0000303, /* SWAB R3 */
0006303, /* ASL R3 */
0006303, /* ASL R3 */
0006303, /* ASL R3 */
0006303, /* ASL R3 */
0006303, /* ASL R3 */
0012701, 0177412, /* MOV #RKDA, R1 ; csr */
0010311, /* MOV R3, (R1) ; load da */
0005041, /* CLR -(R1) ; clear ba */
0012741, 0177000, /* MOV #-256.*2, -(R1) ; load wc */
0012741, 0000005, /* MOV #READ+GO, -(R1) ; read & go */
0005002, /* CLR R2 */
0005003, /* CLR R3 */
0012704, BOOT_START+020, /* MOV #START+20, R4 */
0005005, /* CLR R5 */
0105711, /* TSTB (R1) */
0100376, /* BPL .-2 */
0105011, /* CLRB (R1) */
0005007 /* CLR PC */
};
t_stat rk_boot (int32 unitno, DEVICE *dptr)
{
size_t i;
for (i = 0; i < BOOT_LEN; i++)
M[(BOOT_START >> 1) + i] = boot_rom[i];
M[BOOT_UNIT >> 1] = unitno & RK_M_NUMDR;
M[BOOT_CSR >> 1] = (rk_dib.ba & DMASK) + 012;
cpu_set_boot (BOOT_ENTRY);
return SCPE_OK;
}
t_stat rk_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr)
{
const char *const text =
/*567901234567890123456789012345678901234567890123456789012345678901234567890*/
" RK11/RKV11 cartridge disk (RK05) controller (RK)\n"
"\n"
" This simulation only simulates the RK05 disk drive.\n"
" After 1973, you couldn't have an RK02 in a system. Except for an early\n"
" version of DOS11, no PDP11 operating system supported it.\n"
"\n"
" DEC did two versions of the RK11 controller for the PDP11: the RK11-C and\n"
" the RK11-D (There's also a -E for the PDP-15.). The -C is described in\n"
" the 1972 PDP11 Peripherals handbook. In that controller, RKDS<11>\n"
" distinguishes an RK02 (low density, 128 words/sector) drive from an RK03\n"
" (high density, 256 words/drive).\n"
"\n"
" By 1973, the RK11-C had been superseded by the RK11-D. The RK11-D only\n"
" supports high density drives: the RK03 Diablo drive, and the RK05 DEC\n"
" drive. In the RK11-D, RKDS<11> distinguishes between an RK03 (Diablo)\n"
" and an RK05 (DEC) drive.\n"
/*567901234567890123456789012345678901234567890123456789012345678901234567890*/
"\n"
" From the point of view of software, the RK03/RK05 distinction is cosmetic.\n"
" At the hardware level, RK05s had to be daisy-chained in front of RK03s,\n"
" because RK03s did not receive/propagate the power fail signals. Daisy-chain\n"
" order is different than unit-number order and cannot be detected from\n"
" software.\n"
"\n"
" There is no known way to test an RK11-C, as none of the existing software\n"
" sets support it. RT, RSTS/E, and M/M+ were all released after the RK11-D\n"
" and do not support the RK11-C.\n"
"\n"
" Options include the ability to set units write enabled or write locked.\n";
fprintf (st, "%s", text);
fprint_set_help (st, dptr);
fprint_show_help (st, dptr);
fprintf (st, "\nThe RK11 supports the BOOT command. The RK11 is disabled in a Qbus\n");
fprintf (st, "system with more than 256KB of memory.\n");
fprint_reg_help (st, dptr);
fprintf (st, "\nError handling is as follows:\n\n");
fprintf (st, " error STOP_IOE processed as\n");
fprintf (st, " not attached 1 report error and stop\n");
fprintf (st, " 0 disk not ready\n\n");
fprintf (st, " end of file x assume rest of disk is zero\n");
fprintf (st, " OS I/O error x report error and stop\n");
return SCPE_OK;
}
const char *rk_description (DEVICE *dptr)
{
return "RK11/RKV11 cartridge disk controller";
}