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/* pdp11_pclk.c: KW11P programmable clock simulator
Copyright (c) 1993-2002, Robert M Supnik
Written by John Dundas, used with his gracious permission
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.
pclk KW11P line frequency clock
*/
/* KW11-P Programmable Clock
I/O Page Registers:
CSR 17 772 540
CSB 17 772 542
CNT 17 772 544
Vector: 0104
Priority: BR6
** Theory of Operation **
A real KW11-P is built around the following major components:
- 16-bit up/down counter
- 16-bit count set buffer
- 9-bit control and status register
- clocks: crystal controlled (1) 100 kHz and (2) 10 kHz clocks,
(3) a 50/60 Hz line frequency clock, and (4) an analog signal
input trigger
This software emulator for SIMH implements all of the above with
the exception of the external input trigger, which is arbitrarily
wired to 10Hz.
Operation of this emulator is rather simplistic as compared to the
actual device. The register read and write routines are responsible
for copying internal state from the simulated device to the operating
program. Clock state variables are altered in the write routine
as well as the desired clock ticking rate. Possible rates are
given in the table below.
Rate Bit 2 Bit 1
100 kHz 0 0
10 kHz 0 1
Line frequency 1 0
External 1 1
I think SIMH would have a hard time actually keeping up with a 100
kHz ticking rate. I haven't tried this to verify, though.
The clock service routine (pclk_svc) is responsible for ticking
the clock. The routine does implement up/down, repeat vs.
single-interrupt, and single clocking (maintenance). The routine
updates the internal state according to the options selected and
signals interrupts when appropriate.
For a complete description of the device, please see DEC-11-HPWB-D
KW11-P Programmable Real-Time Clock Manual.
** Notes **
1. The device is disabled by default.
2. Use XXDP V2.5 test program ZKWBJ1.BIC; loads at 1000, starts at
1100? Seems to execute the first few tests correctly then waits
for input from the console. I don't have a description of how this
diagnostic works and thus don't know how to proceed from that point.
3. The read and write routines don't do anything with odd address
accesses. The manual says that byte writes don't work.
4. RSTS can use this clock in place of the standard KW11-L line
frequency clock. In order to do this, use the DEFAULT response in
the OPTION: dialog. To the Preferred clock prompt answer "P".
Then you have the option of line frequency "L" or some multiple of
50 between 50 and 1000 to use the programmable portion of the clock.
5. This is really a Unibus peripheral and thus doesn't actually make
sense within a J-11 system as there never was a Qbus version of
this to the best of my knowledge. However the OSs I have tried
don't appear to exhibit any dissonance between this option and the
processor/bus emulation. I think the options that would make
somewhat more sense in a Qbus environment the KWV11-C and/or KWV11-S.
I don't know if any of the -11 OSs contained support for using
these as the system clock, though.
*/
#include "pdp11_defs.h"
#define PCLKCSR_RDMASK 0100377 /* readable */
#define PCLKCSR_WRMASK 0000137 /* writeable */
#define UNIT_V_LINE50HZ (UNIT_V_UF + 0)
#define UNIT_LINE50HZ (1 << UNIT_V_LINE50HZ)
/* CSR - 17772540 */
#define CSR_V_FIX 5 /* single tick */
#define CSR_V_UPDN 4 /* down/up */
#define CSR_V_MODE 3 /* single/repeat */
#define CSR_FIX (1u << CSR_V_FIX)
#define CSR_UPDN (1u << CSR_V_UPDN)
#define CSR_MODE (1u << CSR_V_MODE)
#define CSR_V_RATE 1 /* rate */
#define CSR_M_RATE 03
#define CSR_GETRATE(x) (((x) >> CSR_V_RATE) & CSR_M_RATE)
extern int32 int_req[IPL_HLVL];
extern int32 int_vec[IPL_HLVL][32];
uint32 pclk_csr = 0; /* control/status */
uint32 pclk_csb = 0; /* count set buffer */
uint32 pclk_ctr = 0; /* counter */
static uint32 rate[4] = { 100000, 10000, 60, 10 }; /* ticks per second */
static uint32 xtim[4] = { 10, 100, 16000, 100000 }; /* nominal time delay */
DEVICE pclk_dev;
t_stat pclk_rd (int32 *data, int32 PA, int32 access);
t_stat pclk_wr (int32 data, int32 PA, int32 access);
t_stat pclk_svc (UNIT *uptr);
t_stat pclk_reset (DEVICE *dptr);
t_stat pclk_set_line (UNIT *uptr, int32 val, char *cptr, void *desc);
void pclk_tick (void);
/* PCLK data structures
pclk_dev PCLK device descriptor
pclk_unit PCLK unit descriptor
pclk_reg PCLK register list
*/
DIB pclk_dib = { IOBA_PCLK, IOLN_PCLK, &pclk_rd, &pclk_wr,
1, IVCL (PCLK), VEC_PCLK, { NULL } };
UNIT pclk_unit = { UDATA (&pclk_svc, 0, 0) };
REG pclk_reg[] = {
{ ORDATA (CSR, pclk_csr, 16) },
{ ORDATA (CSB, pclk_csb, 16) },
{ ORDATA (CNT, pclk_ctr, 16) },
{ FLDATA (INT, IREQ (PCLK), INT_V_PCLK) },
{ FLDATA (OVFL, pclk_csr, CSR_V_ERR) },
{ FLDATA (DONE, pclk_csr, CSR_V_DONE) },
{ FLDATA (IE, pclk_csr, CSR_V_IE) },
{ FLDATA (UPDN, pclk_csr, CSR_V_UPDN) },
{ FLDATA (MODE, pclk_csr, CSR_V_MODE) },
{ FLDATA (RUN, pclk_csr, CSR_V_GO) },
{ BRDATA (TIME, xtim, 10, 32, 4), REG_NZ + PV_LEFT },
{ BRDATA (TPS, rate, 10, 32, 4), REG_NZ + PV_LEFT },
{ DRDATA (CURTIM, pclk_unit.wait, 32), REG_HRO },
{ ORDATA (DEVADDR, pclk_dib.ba, 32), REG_HRO },
{ ORDATA (DEVVEC, pclk_dib.vec, 16), REG_HRO },
{ NULL } };
MTAB pclk_mod[] = {
{ UNIT_LINE50HZ, UNIT_LINE50HZ, "50 Hz", "50HZ", &pclk_set_line },
{ UNIT_LINE50HZ, 0, "60 Hz", "60HZ", &pclk_set_line },
{ MTAB_XTD|MTAB_VDV, 0, "ADDRESS", NULL,
NULL, &show_addr, NULL },
{ MTAB_XTD|MTAB_VDV, 0, "VECTOR", "VECTOR",
&set_vec, &show_vec, NULL },
{ 0 } };
DEVICE pclk_dev = {
"PCLK", &pclk_unit, pclk_reg, pclk_mod,
1, 0, 0, 0, 0, 0,
NULL, NULL, &pclk_reset,
NULL, NULL, NULL,
&pclk_dib, DEV_DISABLE | DEV_DIS | DEV_UBUS | DEV_QBUS };
/* Clock I/O address routines */
t_stat pclk_rd (int32 *data, int32 PA, int32 access)
{
switch ((PA >> 1) & 03) {
case 00: /* CSR */
*data = pclk_csr & PCLKCSR_RDMASK; /* return CSR */
pclk_csr = pclk_csr & ~(CSR_ERR | CSR_DONE); /* clr err, done */
CLR_INT (PCLK); /* clr intr */
break;
case 01: /* buffer */
*data = 0; /* read only */
break;
case 02: /* counter */
*data = pclk_ctr & DMASK; /* return counter */
break; }
return SCPE_OK;
}
t_stat pclk_wr (int32 data, int32 PA, int32 access)
{
int32 old_csr = pclk_csr;
int32 rv;
switch ((PA >> 1) & 03) {
case 00: /* CSR */
pclk_csr = data & PCLKCSR_WRMASK; /* clear and write */
CLR_INT (PCLK); /* clr intr */
rv = CSR_GETRATE (pclk_csr); /* new rate */
pclk_unit.wait = xtim[rv]; /* new delay */
if ((pclk_csr & CSR_GO) == 0) { /* stopped? */
sim_cancel (&pclk_unit); /* cancel */
if (data & CSR_FIX) pclk_tick (); } /* fix? tick */
else if (((old_csr & CSR_GO) == 0) || /* run 0 -> 1? */
(rv != CSR_GETRATE (old_csr))) { /* rate change? */
sim_cancel (&pclk_unit); /* cancel */
sim_activate (&pclk_unit, /* start clock */
sim_rtcn_init (pclk_unit.wait, TMR_PCLK));
}
break;
case 01: /* buffer */
pclk_csb = pclk_ctr = data; /* store ctr */
pclk_csr = pclk_csr & ~(CSR_ERR | CSR_DONE); /* clr err, done */
CLR_INT (PCLK); /* clr intr */
break;
case 02: /* counter */
break; } /* read only */
return SCPE_OK;
}
/* Clock tick (automatic or manual) */
void pclk_tick (void)
{
if (pclk_csr & CSR_UPDN) /* up or down? */
pclk_ctr = (pclk_ctr + 1) & DMASK; /* 1 = up */
else pclk_ctr = (pclk_ctr - 1) & DMASK; /* 0 = down */
if (pclk_ctr == 0) { /* reached zero? */
if (pclk_csr & CSR_DONE) /* done already set? */
pclk_csr = pclk_csr | CSR_ERR; /* set error */
else pclk_csr = pclk_csr | CSR_DONE; /* else set done */
if (pclk_csr & CSR_IE) SET_INT (PCLK); /* if IE, set int */
if (pclk_csr & CSR_MODE) pclk_ctr = pclk_csb; /* if rpt, reload */
else {
pclk_csb = 0; /* else clr ctr */
pclk_csr = pclk_csr & ~CSR_GO; } } /* and clr go */
return;
}
/* Clock service */
t_stat pclk_svc (UNIT *uptr)
{
int32 rv;
pclk_tick (); /* tick clock */
if ((pclk_csr & CSR_GO) == 0) return SCPE_OK; /* done? */
rv = CSR_GETRATE (pclk_csr); /* get rate */
sim_activate (&pclk_unit, sim_rtcn_calb (rate[rv], TMR_PCLK));
return SCPE_OK;
}
/* Clock reset */
t_stat pclk_reset (DEVICE *dptr)
{
pclk_csr = 0; /* clear reg */
pclk_csb = 0;
pclk_ctr = 0;
CLR_INT (PCLK); /* clear int */
sim_cancel (&pclk_unit); /* cancel */
pclk_unit.wait = xtim[0]; /* reset delay */
return SCPE_OK;
}
/* Set line frequency */
t_stat pclk_set_line (UNIT *uptr, int32 val, char *cptr, void *desc)
{
if (val == UNIT_LINE50HZ) rate[2] = 50;
else rate[2] = 60;
return SCPE_OK;
}