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/* vax750_stddev.c: VAX 11/750 standard I/O devices
Copyright (c) 2010-2012, Matt Burke
This module incorporates code from SimH, Copyright (c) 1998-2011, 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
THE AUTHOR(S) 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(s) of the author(s) shall not be
used in advertising or otherwise to promote the sale, use or other dealings
in this Software without prior written authorization from the author(s).
tti console input
tto console output
td console TU58
todr TODR clock
tmr interval timer
22-Oct-12 MP Generalized setting TODR for all OSes.
Unbound the TODR value from the 100hz clock tick
interrupt. TODR now behaves like the original
battery backed-up clock and runs with the wall
clock, not the simulated instruction clock.
Two operational modes are available:
- Default VMS mode, which is similar to the previous
behavior in that without initializing the TODR it
would default to the value VMS would set it to if
VMS knew the correct time. This would be correct
almost all the time unless a VMS disk hadn't been
booted from for more than a year. This mode
produces strange time results for non VMS OSes on
each system boot.
- OS Agnostic mode. This mode behaves precisely like
the VAX780 TODR and works correctly for all OSes.
This mode is enabled by attaching the TODR to a
battery backup state file for the TOY clock
(i.e. sim> attach TODR TOY_CLOCK). When operating
in OS Agnostic mode, the TODR will initially start
counting from 0 and be adjusted differently when an
OS specifically writes to the TODR. VMS will prompt
to set the time on each boot (if the TODR value is
less than about 1 month) unless the SYSGEN
parameter TIMEPROMPTWAIT is set to 0.
21-Oct-2012 MB First Version
*/
#include "vax_defs.h"
#include "sim_tmxr.h"
#include <time.h>
#include "pdp11_td.h"
/* Terminal definitions */
#define RXCS_RD (CSR_DONE + CSR_IE) /* terminal input */
#define RXCS_WR (CSR_IE)
#define RXDB_ERR 0x8000 /* error */
#define RXDB_OVR 0x4000 /* overrun */
#define RXDB_FRM 0x2000 /* framing error */
#define TXCS_RD (CSR_DONE + CSR_IE) /* terminal output */
#define TXCS_WR (CSR_IE)
#define TXDB_V_SEL 8 /* unit select */
#define TXDB_M_SEL 0xF
#define TXDB_MISC 0xF /* console misc */
#define MISC_MASK 0xFF /* console data mask */
#define MISC_SWDN 0x1 /* software done */
#define MISC_BOOT 0x2 /* reboot */
#define MISC_CLWS 0x3 /* clear warm start */
#define MISC_CLCS 0x4 /* clear cold start */
#define TXDB_SEL (TXDB_M_SEL << TXDB_V_SEL) /* non-terminal */
#define TXDB_GETSEL(x) (((x) >> TXDB_V_SEL) & TXDB_M_SEL)
static BITFIELD rx_csr_bits[] = {
BITNCF(6), /* unused */
BIT(IE), /* Interrupt Enable */
BIT(DONE), /* Xmit Ready */
BITNCF(8), /* unused */
ENDBITS
};
static BITFIELD rx_buf_bits[] = {
BITF(DAT,8), /* data buffer */
BITNCF(5), /* unused */
BIT(RBRK),
BIT(OVR),
BIT(ERR),
ENDBITS
};
static BITFIELD tx_csr_bits[] = {
BIT(XBR), /* Break */
BITNC, /* unused */
BIT(MAINT), /* Maint */
BITNCF(3), /* unused */
BIT(IE), /* Interrupt Enable */
BIT(DONE), /* Xmit Ready */
BITNCF(8), /* unused */
ENDBITS
};
static BITFIELD tx_buf_bits[] = {
BITF(DAT,8), /* data buffer */
BITNCF(8), /* unused */
ENDBITS
};
/* Clock definitions */
#define TMR_CSR_ERR 0x80000000 /* error W1C */
#define TMR_CSR_DON 0x00000080 /* done W1C */
#define TMR_CSR_IE 0x00000040 /* int enb RW */
#define TMR_CSR_SGL 0x00000020 /* single WO */
#define TMR_CSR_XFR 0x00000010 /* xfer WO */
#define TMR_CSR_RUN 0x00000001 /* run RW */
#define TMR_CSR_RD (TMR_CSR_W1C | TMR_CSR_WR)
#define TMR_CSR_W1C (TMR_CSR_ERR | TMR_CSR_DON)
#define TMR_CSR_WR (TMR_CSR_IE | TMR_CSR_RUN)
#define TMR_INC 10000 /* usec/interval */
#define CLK_DELAY 5000 /* 100 Hz */
#define TMXR_MULT 1 /* 100 Hz */
static BITFIELD tmr_iccs_bits [] = {
BIT(RUN), /* Run */
BITNCF(3), /* unused */
BIT(XFR), /* Transfer */
BIT(SGL), /* Single */
BIT(IE), /* Interrupt Enable */
BIT(DON), /* Done */
BITNCF(23), /* unused */
BIT(ERR), /* Error */
ENDBITS
};
/* TU58 definitions */
#define UNIT_V_WLK (UNIT_V_UF) /* write locked */
#define UNIT_WLK (1u << UNIT_V_UF)
#define UNIT_WPRT (UNIT_WLK | UNIT_RO) /* write protect */
#define TD_NUMBLK 512 /* blocks/tape */
#define TD_NUMBY 512 /* bytes/block */
#define TD_SIZE (TD_NUMBLK * TD_NUMBY) /* bytes/tape */
int32 tti_csr = 0; /* control/status */
uint32 tti_buftime; /* time input character arrived */
int32 tti_buf = 0; /* buffer */
int32 tti_int = 0; /* interrupt */
int32 tto_csr = 0; /* control/status */
int32 tto_buf = 0; /* buffer */
int32 tto_int = 0; /* interrupt */
int32 csi_int = 0; /* interrupt */
int32 cso_int = 0; /* interrupt */
int32 tmr_iccs = 0; /* interval timer csr */
uint32 tmr_icr = 0; /* curr interval */
uint32 tmr_nicr = 0; /* next interval */
uint32 tmr_inc = 0; /* timer increment */
int32 tmr_int = 0; /* interrupt */
int32 clk_tps = 100; /* ticks/second */
int32 tmxr_poll = CLK_DELAY * TMXR_MULT; /* term mux poll */
int32 tmr_poll = CLK_DELAY; /* pgm timer poll */
struct todr_battery_info {
uint32 toy_gmtbase; /* GMT base of set value */
uint32 toy_gmtbasemsec; /* The milliseconds of the set value */
uint32 toy_endian_plus2; /* 2 -> Big Endian, 3 -> Little Endian, invalid otherwise */
};
typedef struct todr_battery_info TOY;
int32 td_regval; /* temp location used in reg declarations */
t_stat tti_svc (UNIT *uptr);
t_stat tto_svc (UNIT *uptr);
t_stat tmr_svc (UNIT *uptr);
t_stat tti_reset (DEVICE *dptr);
t_stat tto_reset (DEVICE *dptr);
t_stat clk_reset (DEVICE *dptr);
const char *tti_description (DEVICE *dptr);
const char *tto_description (DEVICE *dptr);
const char *clk_description (DEVICE *dptr);
t_stat tti_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr);
t_stat tto_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr);
t_stat clk_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr);
t_stat clk_attach (UNIT *uptr, CONST char *cptr);
t_stat clk_detach (UNIT *uptr);
t_stat tmr_reset (DEVICE *dptr);
const char *tmr_description (DEVICE *dptr);
t_stat td_reset (DEVICE *dptr);
const char *td_description (DEVICE *dptr);
int32 icr_rd (void);
void tmr_incr (uint32 inc);
void tmr_sched (uint32 incr);
t_stat todr_resync (void);
t_stat txdb_misc_wr (int32 data);
extern int32 con_halt (int32 code, int32 cc);
/* TTI data structures
tti_dev TTI device descriptor
tti_unit TTI unit descriptor
tti_reg TTI register list
*/
UNIT tti_unit = { UDATA (&tti_svc, UNIT_IDLE|TT_MODE_8B, 0), TMLN_SPD_9600_BPS };
REG tti_reg[] = {
{ HRDATAD (RXDB, tti_buf, 16, "last data item processed") },
{ HRDATAD (RXCS, tti_csr, 16, "control/status register") },
{ FLDATAD (INT, tti_int, 0, "interrupt pending flag") },
{ FLDATAD (DONE, tti_csr, CSR_V_DONE, "device done flag (CSR<7>)") },
{ FLDATAD (IE, tti_csr, CSR_V_IE, "interrupt enable flag (CSR<6>)") },
{ DRDATAD (POS, tti_unit.pos, T_ADDR_W, "number of characters input"), PV_LEFT },
{ DRDATAD (TIME, tti_unit.wait, 24, "input polling interval"), PV_LEFT },
{ NULL }
};
MTAB tti_mod[] = {
{ TT_MODE, TT_MODE_7B, "7b", "7B", NULL, NULL, NULL, "Set 7 bit mode" },
{ TT_MODE, TT_MODE_8B, "8b", "8B", NULL, NULL, NULL, "Set 8 bit mode" },
{ 0 }
};
DEVICE tti_dev = {
"TTI", &tti_unit, tti_reg, tti_mod,
1, 10, 31, 1, 16, 8,
NULL, NULL, &tti_reset,
NULL, NULL, NULL,
NULL, 0, 0, NULL, NULL, NULL, &tti_help, NULL, NULL,
&tti_description
};
/* TTO data structures
tto_dev TTO device descriptor
tto_unit TTO unit descriptor
tto_reg TTO register list
*/
UNIT tto_unit = { UDATA (&tto_svc, TT_MODE_8B, 0), SERIAL_OUT_WAIT };
REG tto_reg[] = {
{ HRDATAD (TXDB, tto_buf, 16, "last data item processed") },
{ HRDATAD (TXCS, tto_csr, 16, "control/status register") },
{ FLDATAD (INT, tto_int, 0, "interrupt pending flag") },
{ FLDATAD (DONE, tto_csr, CSR_V_DONE, "device done flag (CSR<7>)") },
{ FLDATAD (IE, tto_csr, CSR_V_IE, "interrupt enable flag (CSR<6>)") },
{ DRDATAD (POS, tto_unit.pos, T_ADDR_W, "number of characters output"), PV_LEFT },
{ DRDATAD (TIME, tto_unit.wait, 24, "time from I/O initiation to interrupt"), PV_LEFT + REG_NZ },
{ NULL }
};
MTAB tto_mod[] = {
{ TT_MODE, TT_MODE_7B, "7b", "7B", NULL, NULL, NULL, "Set 7 bit mode" },
{ TT_MODE, TT_MODE_8B, "8b", "8B", NULL, NULL, NULL, "Set 8 bit mode" },
{ TT_MODE, TT_MODE_7P, "7p", "7P", NULL, NULL, NULL, "Set 7 bit mode (suppress non printing)" },
{ 0 }
};
DEVICE tto_dev = {
"TTO", &tto_unit, tto_reg, tto_mod,
1, 10, 31, 1, 16, 8,
NULL, NULL, &tto_reset,
NULL, NULL, NULL,
NULL, 0, 0, NULL, NULL, NULL, &tto_help, NULL, NULL,
&tto_description
};
/* TODR and TMR data structures */
UNIT clk_unit = { UDATA (NULL, UNIT_IDLE+UNIT_FIX, sizeof(TOY))};
REG clk_reg[] = {
{ DRDATAD (TIME, clk_unit.wait, 24, "initial poll interval"), REG_NZ + PV_LEFT },
{ DRDATAD (POLL, tmr_poll, 24, "calibrated poll interval"), REG_NZ + PV_LEFT + REG_HRO },
#if defined (SIM_ASYNCH_IO)
{ DRDATAD (ASYNCH, sim_asynch_enabled, 1, "asynch I/O enabled flag"), PV_LEFT },
{ DRDATAD (LATENCY, sim_asynch_latency, 32, "desired asynch interrupt latency"), PV_LEFT },
{ DRDATAD (INST_LATENCY, sim_asynch_inst_latency, 32, "calibrated instruction latency"), PV_LEFT },
#endif
{ NULL }
};
DEVICE clk_dev = {
"TODR", &clk_unit, clk_reg, NULL,
1, 0, 8, 4, 0, 32,
NULL, NULL, &clk_reset,
NULL, &clk_attach, &clk_detach,
NULL, 0, 0, NULL, NULL, NULL, &clk_help, NULL, NULL,
&clk_description
};
UNIT tmr_unit = { UDATA (&tmr_svc, 0, 0) }; /* timer */
REG tmr_reg[] = {
{ HRDATADF (ICCS, tmr_iccs, 32, "interval timer control and status", tmr_iccs_bits) },
{ HRDATAD (ICR, tmr_icr, 32, "interval count register") },
{ HRDATAD (NICR, tmr_nicr, 32, "next interval count register") },
{ FLDATAD (INT, tmr_int, 0, "interrupt request") },
{ DRDATAD (TPS, clk_tps, 8, "ticks per second"), REG_NZ + PV_LEFT },
{ HRDATA (INCR, tmr_inc, 32), REG_HIDDEN },
{ NULL }
};
#define TMR_DB_REG 0x01 /* Register Access */
#define TMR_DB_TICK 0x02 /* Ticks */
#define TMR_DB_SCHED 0x04 /* Scheduling */
#define TMR_DB_INT 0x08 /* Interrupts */
#define TMR_DB_TODR 0x10 /* TODR */
DEBTAB tmr_deb[] = {
{ "REG", TMR_DB_REG, "Register Access"},
{ "TICK", TMR_DB_TICK, "Ticks"},
{ "SCHED", TMR_DB_SCHED, "Scheduling"},
{ "INT", TMR_DB_INT, "Interrupts"},
{ "TODR", TMR_DB_TODR, "TODR activities"},
{ NULL, 0 }
};
DEVICE tmr_dev = {
"TMR", &tmr_unit, tmr_reg, NULL,
1, 0, 0, 0, 0, 0,
NULL, NULL, &tmr_reset,
NULL, NULL, NULL,
NULL, DEV_DEBUG, 0,
tmr_deb, NULL, NULL, NULL, NULL, NULL,
&tmr_description
};
/* TU58 data structures
td_dev RX device descriptor
td_unit RX unit list
td_reg RX register list
td_mod RX modifier list
*/
UNIT td_unit;
REG td_reg[] = {
{ HRDATAD (ECODE, td_regval, 8, "end packet success code") },
{ HRDATAD (BLOCK, td_regval, 8, "current block number") },
{ HRDATAD (RX_CSR, td_regval,16, "input control/status register") },
{ HRDATAD (RX_BUF, td_regval,16, "input buffer register") },
{ HRDATAD (TX_CSR, td_regval,16, "output control/status register") },
{ HRDATAD (TX_BUF, td_regval,16, "output buffer register") },
{ DRDATAD (P_STATE,td_regval, 4, "protocol state"), REG_RO },
{ DRDATAD (O_STATE,td_regval, 4, "output state"), REG_RO },
{ DRDATAD (IBPTR, td_regval, 9, "input buffer pointer") },
{ DRDATAD (OBPTR, td_regval, 9, "output buffer pointer") },
{ DRDATAD (ILEN, td_regval, 9, "input length") },
{ DRDATAD (OLEN, td_regval, 9, "output length") },
{ DRDATAD (TXSIZE, td_regval, 9, "remaining transfer size") },
{ DRDATAD (OFFSET, td_regval, 9, "offset into current transfer") },
{ DRDATAD (CTIME, td_regval,24, "command time"), PV_LEFT },
{ DRDATAD (STIME, td_regval,24, "seek, per block"), PV_LEFT },
{ DRDATAD (XTIME, td_regval,24, "tr set time"), PV_LEFT },
{ DRDATAD (ITIME, td_regval,24, "init time"), PV_LEFT },
{ BRDATAD (IBUF, &td_regval,16, 8, 512, "input buffer"), },
{ BRDATAD (OBUF, &td_regval,16, 8, 512, "output buffer"), },
{ NULL }
};
MTAB td_mod[] = {
{ UNIT_WLK, 0, "write enabled", "WRITEENABLED", NULL, NULL, NULL, "Write enable TU58 drive" },
{ UNIT_WLK, UNIT_WLK, "write locked", "LOCKED", NULL, NULL, NULL, "Write lock TU58 drive" },
{ 0 }
};
DEVICE td_dev = {
"TD", &td_unit, td_reg, td_mod,
1, DEV_RDX, 20, 1, DEV_RDX, 8,
NULL, NULL, &td_reset,
NULL, NULL, NULL,
NULL, DEV_DEBUG, 0, td_deb, NULL, NULL, NULL, NULL, NULL,
&td_description
};
static void set_csi_int (int32 ctlr, t_bool val)
{
if (csi_int ^ val) {
csi_int = val;
sim_debug (TDDEB_INT, &td_dev, "CSI_INT(%d)\n", val);
}
}
static void set_cso_int (int32 ctlr, t_bool val)
{
if (cso_int ^ val) {
cso_int = val;
sim_debug (TDDEB_INT, &td_dev, "CSO_INT(%d)\n", val);
}
}
/* Console storage MxPR routines
csrs_rd/wr input control/status
csrd_rd input buffer
csts_rd/wr output control/status
cstd_wr output buffer
*/
#define ctlr up7
int32 csrs_rd (void)
{
int32 data;
sim_debug (TDDEB_IRD, &td_dev, "csrs_rd()\n");
td_rd_i_csr ((CTLR *)td_unit.ctlr, &data);
return data;
}
void csrs_wr (int32 data)
{
sim_debug (TDDEB_IWR, &td_dev, "csrs_wr()\n");
td_wr_i_csr ((CTLR *)td_unit.ctlr, data);
}
int32 csrd_rd (void)
{
int32 data;
sim_debug (TDDEB_IRD, &td_dev, "csrd_rd()\n");
td_rd_i_buf ((CTLR *)td_unit.ctlr, &data);
return data;
}
int32 csts_rd (void)
{
int32 data;
sim_debug (TDDEB_ORD, &td_dev, "csts_rd()\n");
td_rd_o_csr ((CTLR *)td_unit.ctlr, &data);
return data;
}
void csts_wr (int32 data)
{
sim_debug (TDDEB_OWR, &td_dev, "csts_wr()\n");
td_wr_o_csr ((CTLR *)td_unit.ctlr, data);
}
void cstd_wr (int32 data)
{
sim_debug (TDDEB_OWR, &td_dev, "cstd_wr()\n");
td_wr_o_buf ((CTLR *)td_unit.ctlr, data);
}
/* Terminal MxPR routines
rxcs_rd/wr input control/status
rxdb_rd input buffer
txcs_rd/wr output control/status
txdb_wr output buffer
*/
int32 rxcs_rd (void)
{
return (tti_csr & RXCS_RD);
}
void rxcs_wr (int32 data)
{
if ((data & CSR_IE) == 0)
tti_int = 0;
else {
if ((tti_csr & (CSR_DONE + CSR_IE)) == CSR_DONE)
tti_int = 1;
}
tti_csr = (tti_csr & ~RXCS_WR) | (data & RXCS_WR);
}
int32 rxdb_rd (void)
{
int32 t = tti_buf; /* char + error */
if (tti_csr & CSR_DONE) { /* Input pending ? */
tti_csr = tti_csr & ~CSR_DONE; /* clr done */
tti_buf = tti_buf & BMASK; /* clr errors */
tti_int = 0;
sim_activate_after_abs (&tti_unit, tti_unit.wait); /* check soon for more input */
}
return t;
}
int32 txcs_rd (void)
{
return (tto_csr & TXCS_RD);
}
void txcs_wr (int32 data)
{
if ((data & CSR_IE) == 0)
tto_int = 0;
else {
if ((tto_csr & (CSR_DONE + CSR_IE)) == CSR_DONE)
tto_int = 1;
}
tto_csr = (tto_csr & ~TXCS_WR) | (data & TXCS_WR);
}
void txdb_wr (int32 data)
{
tto_buf = data & WMASK; /* save data */
tto_csr = tto_csr & ~CSR_DONE; /* clear flag */
tto_int = 0; /* clear int */
if (tto_buf & TXDB_SEL) /* console? */
txdb_misc_wr (tto_buf);
else
sim_activate (&tto_unit, tto_unit.wait); /* no, console terminal */
}
/* Terminal input service (poll for character) */
t_stat tti_svc (UNIT *uptr)
{
int32 c;
sim_clock_coschedule (uptr, tmxr_poll); /* continue poll */
if ((tti_csr & CSR_DONE) && /* input still pending and < 500ms? */
((sim_os_msec () - tti_buftime) < 500))
return SCPE_OK;
if ((c = sim_poll_kbd ()) < SCPE_KFLAG) /* no char or error? */
return c;
if (c & SCPE_BREAK) /* break? */
tti_buf = RXDB_ERR | RXDB_FRM;
else
tti_buf = sim_tt_inpcvt (c, TT_GET_MODE (uptr->flags));
tti_buftime = sim_os_msec ();
uptr->pos = uptr->pos + 1;
tti_csr = tti_csr | CSR_DONE;
if (tti_csr & CSR_IE)
tti_int = 1;
return SCPE_OK;
}
/* Terminal input reset */
t_stat tti_reset (DEVICE *dptr)
{
tmxr_set_console_units (&tti_unit, &tto_unit);
tti_buf = 0;
tti_csr = 0;
tti_int = 0;
sim_activate (&tti_unit, KBD_WAIT (tti_unit.wait, tmr_poll));
return SCPE_OK;
}
t_stat tti_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr)
{
fprintf (st, "Console Terminal Input (TTI)\n\n");
fprintf (st, "The terminal input (TTI) polls the console keyboard for input.\n\n");
fprint_set_help (st, dptr);
fprint_show_help (st, dptr);
fprint_reg_help (st, dptr);
return SCPE_OK;
}
const char *tti_description (DEVICE *dptr)
{
return "console terminal input";
}
/* Terminal output service (output character) */
t_stat tto_svc (UNIT *uptr)
{
int32 c;
t_stat r;
if ((tto_buf & TXDB_SEL) == 0) { /* for console? */
c = sim_tt_outcvt (tto_buf, TT_GET_MODE (uptr->flags));
if (c >= 0) {
if ((r = sim_putchar_s (c)) != SCPE_OK) { /* output; error? */
sim_activate (uptr, uptr->wait); /* retry */
return ((r == SCPE_STALL)? SCPE_OK: r); /* !stall? report */
}
}
uptr->pos = uptr->pos + 1;
}
tto_csr = tto_csr | CSR_DONE;
if (tto_csr & CSR_IE)
tto_int = 1;
return SCPE_OK;
}
/* Terminal output reset */
t_stat tto_reset (DEVICE *dptr)
{
tto_buf = 0;
tto_csr = CSR_DONE;
tto_int = 0;
sim_cancel (&tto_unit); /* deactivate unit */
return SCPE_OK;
}
t_stat tto_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr)
{
fprintf (st, "Console Terminal Output (TTO)\n\n");
fprintf (st, "The terminal output (TTO) writes to the simulator console.\n\n");
fprint_set_help (st, dptr);
fprint_show_help (st, dptr);
fprint_reg_help (st, dptr);
return SCPE_OK;
}
const char *tto_description (DEVICE *dptr)
{
return "console terminal output";
}
/* Programmable timer
The architected VAX timer, which increments at 1Mhz, cannot be
accurately simulated due to the overhead that would be required
for 1M clock events per second. Instead 1Mhz intervals are
derived from the calibrated instruction execution rate.
If the interval register is read, then its value between events
is interpolated relative to the elapsed instruction count.
*/
int32 iccs_rd (void)
{
sim_debug (TMR_DB_REG, &tmr_dev, "iccs_rd() = 0x%08X\n", tmr_iccs & TMR_CSR_RD);
return tmr_iccs & TMR_CSR_RD;
}
void iccs_wr (int32 val)
{
sim_debug_bits_hdr (TMR_DB_REG, &tmr_dev, "iccs_wr()", tmr_iccs_bits, tmr_iccs, val, TRUE);
if ((val & TMR_CSR_RUN) == 0) { /* clearing run? */
sim_cancel (&tmr_unit); /* cancel timer */
if (tmr_iccs & TMR_CSR_RUN) { /* run 1 -> 0? */
tmr_icr = icr_rd (); /* update itr */
sim_rtcn_calb (0, TMR_CLK); /* stop timer */
}
}
if (val & CSR_DONE) /* Interrupt Acked? */
sim_rtcn_tick_ack (20, TMR_CLK); /* Let timers know */
tmr_iccs = tmr_iccs & ~(val & TMR_CSR_W1C); /* W1C csr */
tmr_iccs = (tmr_iccs & ~TMR_CSR_WR) | /* new r/w */
(val & TMR_CSR_WR);
if (val & TMR_CSR_XFR) /* xfr set? */
tmr_icr = tmr_nicr;
if (val & TMR_CSR_RUN) { /* run? */
if (val & TMR_CSR_XFR) /* new tir? */
sim_cancel (&tmr_unit); /* stop prev */
if (!sim_is_active (&tmr_unit)) { /* not running? */
sim_rtcn_init_unit (&tmr_unit, CLK_DELAY, TMR_CLK); /* init timer */
tmr_sched (tmr_icr); /* activate */
}
}
else {
if (val & TMR_CSR_XFR) /* xfr set? */
tmr_icr = tmr_nicr;
if (val & TMR_CSR_SGL) { /* single step? */
tmr_icr = tmr_icr + 1; /* incr tmr */
if (tmr_icr == 0) { /* if ovflo, */
if (tmr_iccs & TMR_CSR_DON) /* done? set err */
tmr_iccs = tmr_iccs | TMR_CSR_ERR;
else
tmr_iccs = tmr_iccs | TMR_CSR_DON; /* set done */
if (tmr_iccs & TMR_CSR_IE) { /* ie? */
tmr_int = 1; /* set int req */
sim_debug (TMR_DB_INT, &tmr_dev, "tmr_incr() - INT=1\n");
}
tmr_icr = tmr_nicr; /* reload tir */
}
}
}
if ((tmr_iccs & (TMR_CSR_DON | TMR_CSR_IE)) != /* update int */
(TMR_CSR_DON | TMR_CSR_IE)) {
if (tmr_int) {
tmr_int = 0;
sim_debug (TMR_DB_INT, &tmr_dev, "iccs_wr() - INT=0\n");
}
}
}
int32 icr_rd (void)
{
int32 result;
if (tmr_iccs & TMR_CSR_RUN) { /* running? */
uint32 usecs_remaining = (uint32)sim_activate_time_usecs (&tmr_unit);
result = (int32)(~usecs_remaining + 1);
}
else
result = (int32)tmr_icr;
sim_debug (TMR_DB_REG, &tmr_dev, "icr_rd() = 0x%08X%s\n", result, (tmr_iccs & TMR_CSR_RUN) ? " - interpolated" : "");
return result;
}
int32 nicr_rd (void)
{
sim_debug (TMR_DB_REG, &tmr_dev, "nicr_rd() = 0x%08X\n", tmr_nicr);
return tmr_nicr;
}
void nicr_wr (int32 val)
{
sim_debug (TMR_DB_REG, &tmr_dev, "nicr_wr(0x%08X)\n", val);
tmr_nicr = val;
}
/* Interval timer unit service */
t_stat tmr_svc (UNIT *uptr)
{
sim_debug (TMR_DB_TICK, &tmr_dev, "tmr_svc()\n");
tmxr_poll = tmr_poll * TMXR_MULT; /* set mux poll */
if (tmr_iccs & TMR_CSR_DON) /* done? set err */
tmr_iccs = tmr_iccs | TMR_CSR_ERR;
else
tmr_iccs = tmr_iccs | TMR_CSR_DON; /* set done */
if (tmr_iccs & TMR_CSR_RUN) /* run? */
tmr_sched (tmr_nicr); /* reactivate */
if (tmr_iccs & TMR_CSR_IE) { /* ie? set int req */
tmr_int = 1;
sim_debug (TMR_DB_INT, &tmr_dev, "tmr_svc() - INT=1\n");
}
else
tmr_int = 0;
AIO_SET_INTERRUPT_LATENCY(tmr_poll*clk_tps); /* set interrrupt latency */
return SCPE_OK;
}
/* Timer scheduling */
void tmr_sched (uint32 nicr)
{
uint32 usecs = (nicr) ? (~nicr + 1) : 0xFFFFFFFF;
clk_tps = 1000000 / usecs;
sim_debug (TMR_DB_SCHED, &tmr_dev, "tmr_sched(nicr=0x%08X-usecs=0x%08X) - tps=%d\n", nicr, usecs, clk_tps);
tmr_poll = sim_rtcn_calb (clk_tps, TMR_CLK);
sim_activate_after (&tmr_unit, usecs);
}
/* 100Hz TODR reset */
t_stat clk_reset (DEVICE *dptr)
{
if (clk_unit.filebuf == NULL) { /* make sure the TODR is initialized */
clk_unit.filebuf = calloc(sizeof(TOY), 1);
if (clk_unit.filebuf == NULL)
return SCPE_MEM;
}
todr_resync ();
return SCPE_OK;
}
t_stat clk_help (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag, const char *cptr)
{
fprintf (st, "Real-Time Clock (%s)\n\n", dptr->name);
fprintf (st, "The real-time clock autocalibrates; the clock interval is adjusted up or down\n");
fprintf (st, "so that the clock tracks actual elapsed time.\n\n");
fprintf (st, "There are two modes of TODR operation:\n\n");
fprintf (st, " Default VMS mode. Without initializing the TODR it returns the current\n");
fprintf (st, " time of year offset which VMS would set the clock to\n");
fprintf (st, " if VMS knew the correct time (i.e. by manual input).\n");
fprintf (st, " This is correct almost all the time unless a VMS disk\n");
fprintf (st, " hadn't been booted from in the current year. This mode\n");
fprintf (st, " produces strange time results for non VMS OSes on each\n");
fprintf (st, " system boot.\n");
fprintf (st, " OS Agnostic mode. This mode behaves precisely like the VAX780 TODR and\n");
fprintf (st, " works correctly for all OSes. This mode is enabled by\n");
fprintf (st, " attaching the %s to a battery backup state file for the\n", dptr->name);
fprintf (st, " TOY clock (i.e. sim> attach %s TOY_CLOCK). When\n", dptr->name);
fprintf (st, " operating in OS Agnostic mode, the TODR will initially\n");
fprintf (st, " start counting from 0 and be adjusted differently when\n");
fprintf (st, " an OS specifically writes to the TODR. VMS determines\n");
fprintf (st, " if the TODR currently contains a valid time if the value\n");
fprintf (st, " it sees is less than about 1 month. If the time isn't\n");
fprintf (st, " valid VMS will prompt to set the time during the system\n");
fprintf (st, " boot. While prompting for the time it will wait for an\n");
fprintf (st, " answer to the prompt for up to the SYSGEN parameter\n");
fprintf (st, " TIMEPROMPTWAIT seconds. A value of 0 for TIMEPROMPTWAIT\n");
fprintf (st, " will disable the clock setting prompt.\n");
fprint_reg_help (st, dptr);
return SCPE_OK;
}
const char *clk_description (DEVICE *dptr)
{
return "time of year clock";
}
static uint32 sim_byteswap32 (uint32 data)
{
uint8 *bdata = (uint8 *)&data;
uint8 tmp;
tmp = bdata[0];
bdata[0] = bdata[3];
bdata[3] = tmp;
tmp = bdata[1];
bdata[1] = bdata[2];
bdata[2] = tmp;
return data;
}
/* CLK attach */
t_stat clk_attach (UNIT *uptr, CONST char *cptr)
{
t_stat r;
uptr->flags = uptr->flags | (UNIT_ATTABLE | UNIT_BUFABLE);
memset (uptr->filebuf, 0, (size_t)uptr->capac);
r = attach_unit (uptr, cptr);
if (r != SCPE_OK)
uptr->flags = uptr->flags & ~(UNIT_ATTABLE | UNIT_BUFABLE);
else {
TOY *toy = (TOY *)uptr->filebuf;
uptr->hwmark = (uint32) uptr->capac;
if ((toy->toy_endian_plus2 < 2) || (toy->toy_endian_plus2 > 3))
memset (uptr->filebuf, 0, (size_t)uptr->capac);
else {
if (toy->toy_endian_plus2 != sim_end + 2) { /* wrong endian? */
toy->toy_gmtbase = sim_byteswap32 (toy->toy_gmtbase);
toy->toy_gmtbasemsec = sim_byteswap32 (toy->toy_gmtbasemsec);
}
}
toy->toy_endian_plus2 = sim_end + 2;
todr_resync ();
}
return r;
}
/* CLK detach */
t_stat clk_detach (UNIT *uptr)
{
t_stat r;
r = detach_unit (uptr);
if ((uptr->flags & UNIT_ATT) == 0)
uptr->flags = uptr->flags & ~(UNIT_ATTABLE | UNIT_BUFABLE);
return r;
}
/* Interval timer reset */
t_stat tmr_reset (DEVICE *dptr)
{
tmr_poll = sim_rtcn_init_unit (&tmr_unit, CLK_DELAY, TMR_CLK); /* init timer */
tmxr_poll = tmr_poll * TMXR_MULT; /* set mux poll */
tmr_iccs = 0;
tmr_nicr = 0;
tmr_int = 0;
sim_cancel (&tmr_unit); /* cancel timer */
return SCPE_OK;
}
const char *tmr_description (DEVICE *dptr)
{
return "interval timer";
}
/* TODR routines */
int32 todr_rd (void)
{
TOY *toy = (TOY *)clk_unit.filebuf;
struct timespec base, now, val;
/* Maximum number of seconds which can be represented as 10ms ticks
in the 32bit TODR. This is the 33bit value 0x100000000/100 to get seconds */
#define TOY_MAX_SECS (0x40000000/25)
sim_rtcn_get_time(&now, TMR_CLK); /* get curr time */
base.tv_sec = toy->toy_gmtbase;
base.tv_nsec = toy->toy_gmtbasemsec * 1000000;
sim_timespec_diff (&val, &now, &base);
if ((val.tv_sec >= TOY_MAX_SECS) || (!toy->toy_gmtbase))/* todr overflowed? */
return 0; /* stop counting */
sim_debug (TMR_DB_TODR, &tmr_dev, "todr_rd() - TODR=0x%X\n", (int32)(val.tv_sec*100 + val.tv_nsec/10000000));
return (int32)(val.tv_sec*100 + val.tv_nsec/10000000); /* 100hz Clock Ticks */
}
void todr_wr (int32 data)
{
TOY *toy = (TOY *)clk_unit.filebuf;
struct timespec now, val, base;
sim_debug (TMR_DB_TODR, &tmr_dev, "todr_wr(0x%X)\n", data);
if (data) {
/* Save the GMT time when set value was not 0 to record the base for
future read operations in "battery backed-up" state */
sim_rtcn_get_time(&now, TMR_CLK); /* get curr time */
val.tv_sec = ((uint32)data) / 100;
val.tv_nsec = (((uint32)data) % 100) * 10000000;
sim_timespec_diff (&base, &now, &val); /* base = now - data */
toy->toy_gmtbase = (uint32)base.tv_sec;
toy->toy_gmtbasemsec = base.tv_nsec/1000000;
}
else { /* stop the clock */
toy->toy_gmtbase = 0;
toy->toy_gmtbasemsec = 0;
}
}
t_stat todr_resync (void)
{
TOY *toy = (TOY *)clk_unit.filebuf;
if (clk_unit.flags & UNIT_ATT) { /* Attached means behave like real VAX780 */
if (!toy->toy_gmtbase) /* Never set? */
todr_wr (0); /* Start ticking from 0 */
}
else { /* Not-Attached means */
uint32 base; /* behave like simh VMS default */
time_t curr;
struct tm *ctm;
curr = time (NULL); /* get curr time */
if (curr == (time_t) -1) /* error? */
return SCPE_NOFNC;
ctm = localtime (&curr); /* decompose */
if (ctm == NULL) /* error? */
return SCPE_NOFNC;
base = (((((ctm->tm_yday * 24) + /* sec since 1-Jan */
ctm->tm_hour) * 60) +
ctm->tm_min) * 60) +
ctm->tm_sec;
todr_wr ((base * 100) + 0x10000000); /* use VMS form */
}
return SCPE_OK;
}
/* Console write, txdb<11:8> != 0 (console unit) */
t_stat txdb_misc_wr (int32 data)
{
int32 sel = TXDB_GETSEL (data); /* get selection */
sim_activate (&tto_unit, tto_unit.wait); /* set up timeout */
if (sel == TXDB_MISC) { /* misc function? */
switch (data & MISC_MASK) { /* case on function */
case MISC_CLWS:
case MISC_CLCS:
break;
case MISC_SWDN:
ABORT (STOP_SWDN);
break;
case MISC_BOOT:
con_halt (0, 0); /* set up reboot */
break;
}
}
return SCPE_OK;
}
/* Reset */
t_stat td_reset (DEVICE *dptr)
{
return td_connect_console_device (&td_dev, set_csi_int, set_cso_int);
}
const char *td_description (DEVICE *dptr)
{
return "Console TU58 cartridge";
}