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src.rivoreo.one / emulators / simh / v3.8-2-rc1 / . / Ibm1130 / ibm1130_disk.c
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/* ibm1130_disk.c: IBM 1130 disk IO simulator
NOTE - there is a problem with this code. The Device Status Word (DSW) is
computed from current conditions when requested by an XIO load status
command; the value of DSW available to the simulator's examine & save
commands may NOT be accurate. This should probably be fixed.
Based on the SIMH package written by Robert M Supnik
* (C) Copyright 2002, Brian Knittel.
* You may freely use this program, but: it offered strictly on an AS-IS, AT YOUR OWN
* RISK basis, there is no warranty of fitness for any purpose, and the rest of the
* usual yada-yada. Please keep this notice and the copyright in any distributions
* or modifications.
*
* Revision History
* 05-dec-06 Added cgiwritable mode
*
* 19-Dec-05 We no longer issue an operation complete interrupt if an INITR, INITW
* or CONTROL operation is attemped on a drive that is not online. DATA_ERROR
* is now only indicated in the DSW when
*
* 02-Nov-04 Addes -s option to boot to leave switches alone.
* 15-jun-03 moved actual read on XIO read to end of time interval,
* as the APL boot card required 2 instructions to run between the
* time read was initiated and the time the data was read (a jump and a wait)
*
* 01-sep-02 corrected treatment of -m and -r flags in dsk_attach
* in cgi mode, so that file is opened readonly but emulated
* disk is writable.
*
* This is not a supported product, but I welcome bug reports and fixes.
* Mail to simh@ibm1130.org
*/
#include "ibm1130_defs.h"
#include "memory.h"
#define TRACE_DMS_IO /* define to enable debug of DMS phase IO */
#ifdef TRACE_DMS_IO
extern int32 sim_switches;
extern int32 sim_quiet;
static int trace_dms = 0;
static void tracesector (int iswrite, int nwords, int addr, int sector);
static t_stat where_cmd (int flag, char *ptr);
static t_stat phdebug_cmd (int flag, char *ptr);
static t_stat fdump_cmd (int flags, char *cptr);
static void enable_dms_tracing (int newsetting);
#endif
/* Constants */
#define DSK_NUMWD 321 /* words/sector */
#define DSK_NUMSC 4 /* sectors/surface */
#define DSK_NUMSF 2 /* surfaces/cylinder */
#define DSK_NUMCY 203 /* cylinders/drive */
#define DSK_NUMTR (DSK_NUMCY * DSK_NUMSF) /* tracks/drive */
#define DSK_NUMDR 5 /* drives/controller */
#define DSK_SIZE (DSK_NUMCY * DSK_NUMSF * DSK_NUMSC * DSK_NUMWD) /* words/drive */
#define UNIT_V_RONLY (UNIT_V_UF + 0) /* hwre write lock */
#define UNIT_V_OPERR (UNIT_V_UF + 1) /* operation error flag */
#define UNIT_V_HARDERR (UNIT_V_UF + 2) /* hard error flag (reset on power down) */
#define UNIT_RONLY (1u << UNIT_V_RONLY)
#define UNIT_OPERR (1u << UNIT_V_OPERR)
#define UNIT_HARDERR (1u << UNIT_V_HARDERR)
#define MEM_MAPPED(uptr) (uptr->flags & UNIT_BUF) /* disk buffered in memory */
#define IO_NONE 0 /* last operation, used to ensure fseek between read and write */
#define IO_READ 1
#define IO_WRITE 2
#define DSK_DSW_DATA_ERROR 0x8000 /* device status word bits */
#define DSK_DSW_OP_COMPLETE 0x4000
#define DSK_DSW_NOT_READY 0x2000
#define DSK_DSW_DISK_BUSY 0x1000
#define DSK_DSW_CARRIAGE_HOME 0x0800
#define DSK_DSW_SECTOR_MASK 0x0003
/* device status words */
static int16 dsk_dsw[DSK_NUMDR] = {DSK_DSW_NOT_READY, DSK_DSW_NOT_READY, DSK_DSW_NOT_READY, DSK_DSW_NOT_READY, DSK_DSW_NOT_READY};
static int16 dsk_sec[DSK_NUMDR] = {0}; /* next-sector-up */
static char dsk_lastio[DSK_NUMDR]; /* last stdio operation: IO_READ or IO_WRITE */
int32 dsk_swait = 50; /* seek time -- see how short a delay we can get away with */
int32 dsk_rwait = 50; /* rotate time */
static t_bool raw_disk_debug = FALSE;
static t_stat dsk_svc (UNIT *uptr);
static t_stat dsk_reset (DEVICE *dptr);
static t_stat dsk_attach (UNIT *uptr, char *cptr);
static t_stat dsk_detach (UNIT *uptr);
static t_stat dsk_boot (int unitno, DEVICE *dptr);
static void diskfail (UNIT *uptr, int dswflag, int unitflag, t_bool do_interrupt);
/* DSK data structures
dsk_dev disk device descriptor
dsk_unit unit descriptor
dsk_reg register list
*/
UNIT dsk_unit[] = {
{ UDATA (&dsk_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE, DSK_SIZE) },
{ UDATA (&dsk_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE, DSK_SIZE) },
{ UDATA (&dsk_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE, DSK_SIZE) },
{ UDATA (&dsk_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE, DSK_SIZE) },
{ UDATA (&dsk_svc, UNIT_FIX+UNIT_ATTABLE+UNIT_DISABLE, DSK_SIZE) }
};
#define IS_ONLINE(u) (((u)->flags & (UNIT_ATT|UNIT_DIS)) == UNIT_ATT)
/* Parameters in the unit descriptor */
#define CYL u3 /* current cylinder */
#define FUNC u4 /* current function */
REG dsk_reg[] = {
{ HRDATA (DSKDSW0, dsk_dsw[0], 16) },
{ HRDATA (DSKDSW1, dsk_dsw[1], 16) },
{ HRDATA (DSKDSW2, dsk_dsw[2], 16) },
{ HRDATA (DSKDSW3, dsk_dsw[3], 16) },
{ HRDATA (DSKDSW4, dsk_dsw[4], 16) },
{ DRDATA (STIME, dsk_swait, 24), PV_LEFT },
{ DRDATA (RTIME, dsk_rwait, 24), PV_LEFT },
{ NULL } };
MTAB dsk_mod[] = {
{ UNIT_RONLY, 0, "write enabled", "ENABLED", NULL },
{ UNIT_RONLY, UNIT_RONLY, "write locked", "LOCKED", NULL },
{ 0 } };
DEVICE dsk_dev = {
"DSK", dsk_unit, dsk_reg, dsk_mod,
DSK_NUMDR, 16, 16, 1, 16, 16,
NULL, NULL, &dsk_reset,
dsk_boot, dsk_attach, dsk_detach};
static int32 dsk_ilswbit[DSK_NUMDR] = { /* interrupt level status word bits for the drives */
ILSW_2_1131_DISK,
ILSW_2_2310_DRV_1,
ILSW_2_2310_DRV_2,
ILSW_2_2310_DRV_3,
ILSW_2_2310_DRV_4,
};
static int32 dsk_ilswlevel[DSK_NUMDR] =
{
2, /* interrupt levels for the drives */
2, 2, 2, 2
};
typedef enum {DSK_FUNC_IDLE, DSK_FUNC_READ, DSK_FUNC_VERIFY, DSK_FUNC_WRITE, DSK_FUNC_SEEK, DSK_FUNC_FAILED} DSK_FUNC;
static struct tag_dsk_action { /* stores data needed for pending IO activity */
int32 io_address;
uint32 io_filepos;
int io_nwords;
int io_sector;
} dsk_action[DSK_NUMDR];
/* xio_disk - XIO command interpreter for the disk drives */
/*
* device status word:
*
* 0 data error, occurs when:
* 1. A modulo 4 error is detected during a read, read-check, or write operation.
* 2. The disk storage is in a read or write mode at the leading edge of a sector pulse.
* 3. A seek-incomplete signal is received from the 2311.
* 4. A write select error has occurred in the disk storage drive.
* 5. The power unsafe latch is set in the attachment.
* Conditions 1, 2, and 3 are turned off by a sense device command with modifier bit 15
* set to 1. Conditions 4 and 5 are turned off by powering the drive off and back on.
* 1 operation complete
* 2 not ready, occurs when disk not ready or busy or disabled or off-line or
* power unsafe latch set. Also included in the disk not ready is the write select error,
* which can be a result of power unsafe or write select.
* 3 disk busy
* 4 carriage home (on cyl 0)
* 15-16: number of next sector spinning into position.
*/
extern void void_backtrace (int afrom, int ato);
void xio_disk (int32 iocc_addr, int32 func, int32 modify, int drv)
{
int i, rev, nsteps, newcyl, sec, nwords;
uint32 newpos; /* changed from t_addr to uint32 in anticipation of simh 64-bit development */
char msg[80];
UNIT *uptr = dsk_unit+drv;
int16 buf[DSK_NUMWD];
if (! BETWEEN(drv, 0, DSK_NUMDR-1)) { /* hmmm, invalid drive */
if (func != XIO_SENSE_DEV) { /* tried to use it, too */
/* just do nothing, as if the controller isn't there. NAMCRA at N0116300 tests for drives by attempting reads
sprintf(msg, "Op %x on invalid drive number %d", func, drv);
xio_error(msg);
*/
}
return;
}
CLRBIT(uptr->flags, UNIT_OPERR); /* clear pending error flag from previous op, if any */
switch (func) {
case XIO_INITR:
if (! IS_ONLINE(uptr)) { /* disk is offline */
diskfail(uptr, 0, 0, FALSE);
break;
}
sim_cancel(uptr); /* cancel any pending ops */
dsk_dsw[drv] |= DSK_DSW_DISK_BUSY; /* and mark the disk as busy */
nwords = M[iocc_addr++ & mem_mask]; /* get word count w/o upsetting SAR/SBR */
if (nwords == 0) /* this is bad -- on real 1130, this locks up disk controller ! */
break;
if (! BETWEEN(nwords, 1, DSK_NUMWD)) { /* count bad */
SETBIT(uptr->flags, UNIT_OPERR); /* set data error DSW bit when op complete */
nwords = DSK_NUMWD; /* limit xfer to proper sector size */
}
sec = modify & 0x07; /* get sector on cylinder */
if ((modify & 0x0080) == 0) { /* it's a real read if it's not a read check */
/* ah. We have a problem. The APL boot card counts on there being time for at least one
* more instruction to execute between the XIO read and the time the data starts loading
* into core. So, we have to defer the actual read operation a bit. Might as well wait
* until it's time to issue the operation complete interrupt. This means saving the
* IO information, then performing the actual read in dsk_svc.
*/
newpos = (uptr->CYL*DSK_NUMSC*DSK_NUMSF + sec)*2*DSK_NUMWD;
dsk_action[drv].io_address = iocc_addr;
dsk_action[drv].io_nwords = nwords;
dsk_action[drv].io_sector = sec;
dsk_action[drv].io_filepos = newpos;
uptr->FUNC = DSK_FUNC_READ;
}
else {
trace_io("* DSK%d verify %d.%d (%x)", drv, uptr->CYL, sec, uptr->CYL*8 + sec);
if (raw_disk_debug)
printf("* DSK%d verify %d.%d (%x)", drv, uptr->CYL, sec, uptr->CYL*8 + sec);
uptr->FUNC = DSK_FUNC_VERIFY;
}
sim_activate(uptr, dsk_rwait);
break;
case XIO_INITW:
if (! IS_ONLINE(uptr)) { /* disk is offline */
diskfail(uptr, 0, 0, FALSE);
break;
}
if (uptr->flags & UNIT_RONLY) { /* oops, write to RO disk? permanent error until disk is powered off/on */
diskfail(uptr, DSK_DSW_DATA_ERROR, UNIT_HARDERR, FALSE);
break;
}
sim_cancel(uptr); /* cancel any pending ops */
dsk_dsw[drv] |= DSK_DSW_DISK_BUSY; /* and mark drive as busy */
nwords = M[iocc_addr++ & mem_mask]; /* get word count w/o upsetting SAR/SBR */
if (nwords == 0) /* this is bad -- locks up disk controller ! */
break;
if (! BETWEEN(nwords, 1, DSK_NUMWD)) { /* count bad */
SETBIT(uptr->flags, UNIT_OPERR); /* set data error DSW bit when op complete */
nwords = DSK_NUMWD; /* limit xfer to proper sector size */
}
sec = modify & 0x07; /* get sector on cylinder */
newpos = (uptr->CYL*DSK_NUMSC*DSK_NUMSF + sec)*2*DSK_NUMWD;
trace_io("* DSK%d wrote %d words from M[%04x-%04x] to %d.%d (%x, %x)", drv, nwords, iocc_addr & mem_mask, (iocc_addr + nwords - 1) & mem_mask, uptr->CYL, sec, uptr->CYL*8 + sec, newpos);
if (raw_disk_debug)
printf("* DSK%d XIO @ %04x wrote %d words from M[%04x-%04x] to %d.%d (%x, %x)\n", drv, prev_IAR, nwords, iocc_addr & mem_mask, (iocc_addr + nwords - 1) & mem_mask, uptr->CYL, sec, uptr->CYL*8 + sec, newpos);
#ifdef TRACE_DMS_IO
if (trace_dms)
tracesector(1, nwords, iocc_addr & mem_mask, uptr->CYL*8 + sec);
#endif
for (i = 0; i < nwords; i++)
buf[i] = M[iocc_addr++ & mem_mask];
for (; i < DSK_NUMWD; i++) /* rest of sector gets zeroed */
buf[i] = 0;
i = uptr->CYL*8 + sec;
if (buf[0] != i)
printf("*DSK writing bad sector#\n");
if (MEM_MAPPED(uptr)) {
memcpy((char *) uptr->filebuf + newpos, buf, 2*DSK_NUMWD);
uptr->hwmark = newpos + 2*DSK_NUMWD;
}
else {
if (uptr->pos != newpos || dsk_lastio[drv] != IO_WRITE) {
fseek(uptr->fileref, newpos, SEEK_SET);
dsk_lastio[drv] = IO_WRITE;
}
fxwrite(buf, 2, DSK_NUMWD, uptr->fileref);
uptr->pos = newpos + 2*DSK_NUMWD;
}
uptr->FUNC = DSK_FUNC_WRITE;
sim_activate(uptr, dsk_rwait);
break;
case XIO_CONTROL: /* step fwd/rev */
if (! IS_ONLINE(uptr)) {
diskfail(uptr, 0, 0, FALSE);
break;
}
sim_cancel(uptr);
rev = modify & 4;
nsteps = iocc_addr & 0x00FF;
if (nsteps == 0) /* 0 steps does not cause op complete interrupt */
break;
newcyl = uptr->CYL + (rev ? (-nsteps) : nsteps);
if (newcyl < 0)
newcyl = 0;
else if (newcyl >= DSK_NUMCY)
newcyl = DSK_NUMCY-1;
uptr->FUNC = DSK_FUNC_SEEK;
uptr->CYL = newcyl;
sim_activate(uptr, dsk_swait); /* schedule interrupt */
dsk_dsw[drv] |= DSK_DSW_DISK_BUSY;
trace_io("* DSK%d at cyl %d", drv, newcyl);
break;
case XIO_SENSE_DEV:
CLRBIT(dsk_dsw[drv], DSK_DSW_CARRIAGE_HOME|DSK_DSW_NOT_READY);
if ((uptr->flags & UNIT_HARDERR) || (dsk_dsw[drv] & DSK_DSW_DISK_BUSY) || ! IS_ONLINE(uptr))
SETBIT(dsk_dsw[drv], DSK_DSW_NOT_READY);
else if (uptr->CYL <= 0) {
SETBIT(dsk_dsw[drv], DSK_DSW_CARRIAGE_HOME);
uptr->CYL = 0;
}
dsk_sec[drv] = (int16) ((dsk_sec[drv] + 1) % 4); /* advance the "next sector" count every time */
ACC = dsk_dsw[drv] | dsk_sec[drv];
if (modify & 0x01) { /* reset interrupts */
CLRBIT(dsk_dsw[drv], DSK_DSW_OP_COMPLETE|DSK_DSW_DATA_ERROR);
CLRBIT(ILSW[dsk_ilswlevel[drv]], dsk_ilswbit[drv]);
}
break;
default:
sprintf(msg, "Invalid disk XIO function %x", func);
xio_error(msg);
}
}
/* diskfail - schedule an operation complete that sets the error bit */
static void diskfail (UNIT *uptr, int dswflag, int unitflag, t_bool do_interrupt)
{
int drv = uptr - dsk_unit;
sim_cancel(uptr); /* cancel any pending ops */
SETBIT(dsk_dsw[drv], dswflag); /* set any specified DSW bits */
SETBIT(uptr->flags, unitflag); /* set any specified unit flag bits */
uptr->FUNC = DSK_FUNC_FAILED; /* tell svc routine why it failed */
if (do_interrupt)
sim_activate(uptr, 1); /* schedule an immediate op complete interrupt */
}
t_stat dsk_svc (UNIT *uptr)
{
int drv = uptr - dsk_unit, i, nwords, sec;
int16 buf[DSK_NUMWD];
uint32 newpos; /* changed from t_addr to uint32 in anticipation of simh 64-bit development */
int32 iocc_addr;
if (uptr->FUNC == DSK_FUNC_IDLE) /* service function called with no activity? not good, but ignore */
return SCPE_OK;
CLRBIT(dsk_dsw[drv], DSK_DSW_DISK_BUSY); /* activate operation complete interrupt */
SETBIT(dsk_dsw[drv], DSK_DSW_OP_COMPLETE);
if (uptr->flags & (UNIT_OPERR|UNIT_HARDERR)) { /* word count error or data error */
SETBIT(dsk_dsw[drv], DSK_DSW_DATA_ERROR);
CLRBIT(uptr->flags, UNIT_OPERR); /* soft error is one time occurrence; don't clear hard error */
}
/* schedule interrupt */
SETBIT(ILSW[dsk_ilswlevel[drv]], dsk_ilswbit[drv]);
switch (uptr->FUNC) { /* take care of business */
case DSK_FUNC_IDLE:
case DSK_FUNC_VERIFY:
case DSK_FUNC_WRITE:
case DSK_FUNC_SEEK:
case DSK_FUNC_FAILED:
break;
case DSK_FUNC_READ: /* actually read the data into core */
iocc_addr = dsk_action[drv].io_address; /* recover saved parameters */
nwords = dsk_action[drv].io_nwords;
newpos = dsk_action[drv].io_filepos;
sec = dsk_action[drv].io_sector;
if (MEM_MAPPED(uptr)) {
memcpy(buf, (char *) uptr->filebuf + newpos, 2*DSK_NUMWD);
}
else {
if (uptr->pos != newpos || dsk_lastio[drv] != IO_READ) {
fseek(uptr->fileref, newpos, SEEK_SET);
dsk_lastio[drv] = IO_READ;
uptr->pos = newpos;
}
fxread(buf, 2, DSK_NUMWD, uptr->fileref); /* read whole sector so we're in position for next read */
uptr->pos = newpos + 2*DSK_NUMWD;
}
void_backtrace(iocc_addr, iocc_addr + nwords - 1); /* mark prev instruction as altered */
trace_io("* DSK%d read %d words from %d.%d (%x, %x) to M[%04x-%04x]", drv, nwords, uptr->CYL, sec, uptr->CYL*8 + sec, newpos, iocc_addr & mem_mask,
(iocc_addr + nwords - 1) & mem_mask);
/* this will help debug the monitor by letting me watch phase loading */
if (raw_disk_debug)
printf("* DSK%d XIO @ %04x read %d words from %d.%d (%x, %x) to M[%04x-%04x]\n", drv, prev_IAR, nwords, uptr->CYL, sec, uptr->CYL*8 + sec, newpos, iocc_addr & mem_mask,
(iocc_addr + nwords - 1) & mem_mask);
i = uptr->CYL*8 + sec;
if (buf[0] != i)
printf("*DSK read bad sector #\n");
for (i = 0; i < nwords; i++)
M[(iocc_addr+i) & mem_mask] = buf[i];
#ifdef TRACE_DMS_IO
if (trace_dms)
tracesector(0, nwords, iocc_addr & mem_mask, uptr->CYL*8 + sec);
#endif
break;
default:
fprintf(stderr, "Unexpected FUNC %x in dsk_svc(%d)\n", uptr->FUNC, drv);
break;
}
uptr->FUNC = DSK_FUNC_IDLE; /* we're done with this operation */
return SCPE_OK;
}
t_stat dsk_reset (DEVICE *dptr)
{
int drv;
UNIT *uptr;
#ifdef TRACE_DMS_IO
/* add the WHERE command. It finds the phase that was loaded at given address and indicates */
/* the offset in the phase */
register_cmd("WHERE", &where_cmd, 0, "w{here} address find phase and offset of an address\n");
register_cmd("PHDEBUG", &phdebug_cmd, 0, "ph{debug} off|phlo phhi break on phase load\n");
register_cmd("FDUMP", &fdump_cmd, 0, NULL);
#endif
for (drv = 0, uptr = dsk_dev.units; drv < DSK_NUMDR; drv++, uptr++) {
sim_cancel(uptr);
CLRBIT(ILSW[2], dsk_ilswbit[drv]);
CLRBIT(uptr->flags, UNIT_OPERR|UNIT_HARDERR);
uptr->CYL = 0;
uptr->FUNC = DSK_FUNC_IDLE;
dsk_dsw[drv] = (int16) ((uptr->flags & UNIT_ATT) ? DSK_DSW_CARRIAGE_HOME : 0);
}
calc_ints();
return SCPE_OK;
}
static t_stat dsk_attach (UNIT *uptr, char *cptr)
{
int drv = uptr - dsk_unit;
t_stat rval;
sim_cancel(uptr); /* cancel current IO */
dsk_lastio[drv] = IO_NONE;
if (uptr->flags & UNIT_ATT) /* dismount current disk */
if ((rval = dsk_detach(uptr)) != SCPE_OK)
return rval;
uptr->CYL = 0; /* reset the device */
uptr->FUNC = DSK_FUNC_IDLE;
dsk_dsw[drv] = DSK_DSW_CARRIAGE_HOME;
CLRBIT(uptr->flags, UNIT_RO|UNIT_ROABLE|UNIT_BUFABLE|UNIT_BUF|UNIT_RONLY|UNIT_OPERR|UNIT_HARDERR);
CLRBIT(ILSW[2], dsk_ilswbit[drv]);
calc_ints();
if (sim_switches & SWMASK('M')) /* if memory mode (e.g. for CGI), buffer the file */
SETBIT(uptr->flags, UNIT_BUFABLE|UNIT_MUSTBUF);
if (sim_switches & SWMASK('R')) /* read lock mode */
SETBIT(uptr->flags, UNIT_RO|UNIT_ROABLE|UNIT_RONLY);
if (cgi && (sim_switches & SWMASK('M')) && ! cgiwritable) { /* if cgi and memory mode, but writable option not specified */
sim_switches |= SWMASK('R'); /* have attach_unit open file in readonly mode */
SETBIT(uptr->flags, UNIT_ROABLE); /* but don't set the UNIT_RONLY flag so DMS can write to the buffered image */
}
if ((rval = attach_unit(uptr, quotefix(cptr))) != SCPE_OK) { /* mount new disk */
SETBIT(dsk_dsw[drv], DSK_DSW_NOT_READY);
return rval;
}
if (drv == 0) {
disk_ready(TRUE);
disk_unlocked(FALSE);
}
enable_dms_tracing(sim_switches & SWMASK('D'));
raw_disk_debug = sim_switches & SWMASK('G');
return SCPE_OK;
}
static t_stat dsk_detach (UNIT *uptr)
{
t_stat rval;
int drv = uptr - dsk_unit;
sim_cancel(uptr);
if ((rval = detach_unit(uptr)) != SCPE_OK)
return rval;
CLRBIT(ILSW[2], dsk_ilswbit[drv]);
CLRBIT(uptr->flags, UNIT_OPERR|UNIT_HARDERR);
calc_ints();
uptr->CYL = 0;
uptr->FUNC = DSK_FUNC_IDLE;
dsk_dsw[drv] = DSK_DSW_NOT_READY;
if (drv == 0) {
disk_unlocked(TRUE);
disk_ready(FALSE);
}
return SCPE_OK;
}
/* boot routine - if they type BOOT DSK, load the standard boot card. */
static t_stat dsk_boot (int unitno, DEVICE *dptr)
{
t_stat rval;
if ((rval = reset_all(0)) != SCPE_OK)
return rval;
return load_cr_boot(unitno, sim_switches);
}
#ifdef TRACE_DMS_IO
static struct {
int phid;
char *name;
} phase[] = {
# include "dmsr2v12phases.h"
0xFFFF, ""
};
#pragma pack(2)
#define MAXSLET ((3*320)/4)
struct tag_slet {
int16 phid;
int16 addr;
int16 nwords;
int16 sector;
} slet[MAXSLET] = {
# include "dmsr2v12slet.h" /* without RPG, use this info until overwritten by actual data from disk */
};
#pragma pack()
#define MAXMSEG 100
struct tag_mseg {
char *name;
int addr, offset, len, phid;
} mseg[MAXMSEG];
int nseg = 0;
static void enable_dms_tracing (int newsetting)
{
nseg = 0; /* clear the segment map */
if ((newsetting && trace_dms) || ! (newsetting || trace_dms))
return;
trace_dms = newsetting;
if (! sim_quiet)
printf("DMS disk tracing is now %sabled\n", trace_dms ? "en" : "dis");
}
char * saywhere (int addr)
{
int i;
static char buf[150];
for (i = 0; i < nseg; i++) {
if (addr >= mseg[i].addr && addr < (mseg[i].addr+mseg[i].len)) {
sprintf(buf, "/%04x = /%04x + /%x in ", addr, mseg[i].addr - mseg[i].offset, addr-mseg[i].addr + mseg[i].offset);
if (mseg[i].phid > 0)
sprintf(buf+strlen(buf), "phase %02x (%s)", mseg[i].phid, mseg[i].name);
else
sprintf(buf+strlen(buf), "%s", mseg[i].name);
return buf;
}
}
return NULL;
}
static int phdebug_lo = -1, phdebug_hi = -1;
static t_stat phdebug_cmd (int flag, char *ptr)
{
int val1, val2;
if (strcmpi(ptr, "off") == 0)
phdebug_lo = phdebug_hi = -1;
else {
switch(sscanf(ptr, "%x%x", &val1, &val2)) {
case 1:
phdebug_lo = phdebug_hi = val1;
enable_dms_tracing(TRUE);
break;
case 2:
phdebug_lo = val1;
phdebug_hi = val2;
enable_dms_tracing(TRUE);
break;
default:
printf("Usage: phdebug off | phdebug phfrom [phto]\n");
break;
}
}
return SCPE_OK;
}
static t_stat where_cmd (int flag, char *ptr)
{
int addr;
char *where;
if (! trace_dms) {
printf("Tracing is disabled. To enable, attach disk with -d switch\n");
return SCPE_OK;
}
if (sscanf(ptr, "%x", &addr) != 1)
return SCPE_ARG;
if ((where = saywhere(addr)) == NULL)
printf("/%04x not found\n", addr);
else
printf("%s\n", where);
return SCPE_OK;
}
/* savesector - save info on a sector just read. THIS IS NOT YET TESTED */
static void addseg (int i)
{
if (! trace_dms)
return;
if (nseg >= MAXMSEG) {
printf("(Memory map full, disabling tracing)\n");
trace_dms = 0;
nseg = -1;
return;
}
memcpy(mseg+i+1, mseg+i, (nseg-i)*sizeof(mseg[0]));
nseg++;
}
static void delseg (int i)
{
if (! trace_dms)
return;
if (nseg > 0) {
nseg--;
memcpy(mseg+i, mseg+i+1, (nseg-i)*sizeof(mseg[0]));
}
}
static void savesector (int addr, int offset, int len, int phid, char *name)
{
int i;
if (! trace_dms)
return;
addr++; /* first word is sector address, so account for that */
len--;
for (i = 0; i < nseg; i++) {
if (addr >= (mseg[i].addr+mseg[i].len)) /* entirely after this entry */
continue;
if (mseg[i].addr < addr) { /* old one starts before this. split it */
addseg(i);
mseg[i].len = addr-mseg[i].addr;
i++;
mseg[i].addr = addr;
mseg[i].len -= mseg[i-1].len;
}
break;
}
addseg(i); /* add new segment. Old one ends up after this */
if (i >= MAXMSEG)
return;
mseg[i].addr = addr;
mseg[i].offset = offset;
mseg[i].phid = phid;
mseg[i].len = len;
mseg[i].name = name;
i++; /* delete any segments completely covered */
while (i < nseg && (mseg[i].addr+mseg[i].len) <= (addr+len))
delseg(i);
if (i < nseg && mseg[i].addr < (addr+len)) { /* old one extends past this. Retain the end */
mseg[i].len = (mseg[i].addr+mseg[i].len) - (addr+len);
mseg[i].addr = addr+len;
}
}
static void tracesector (int iswrite, int nwords, int addr, int sector)
{
int i, phid = 0, offset = 0;
char *name = NULL;
if (nwords < 3 || ! trace_dms)
return;
switch (sector) { /* explicitly known sector name */
case 0: name = "ID/COLD START"; break;
case 1: name = "DCOM"; break;
case 2: name = "RESIDENT IMAGE"; break;
case 3:
case 4:
case 5: name = "SLET"; /* save just-read or written SLET info */
memmove(&slet[(320/4)*(sector-3)], &M[addr+1], nwords*2);
break;
case 6: name = "RELOAD TABLE"; break;
case 7: name = "PAGE HEADER"; break;
}
printf("* %04x: %3d /%04x %c %3d.%d ",
prev_IAR, nwords, addr, iswrite ? 'W' : 'R', sector/8, sector%8);
if (name == NULL) { /* look up sector in SLET */
for (i = 0; i < MAXSLET; i++) {
if (slet[i].phid == 0) /* not found */
goto done;
else if (slet[i].sector > sector) {
if (--i >= 0) {
if (sector >= slet[i].sector && sector <= (slet[i].sector + slet[i].nwords/320)) {
phid = slet[i].phid;
offset = (sector-slet[i].sector)*320;
break;
}
}
goto done;
}
if (slet[i].sector == sector) {
phid = slet[i].phid; /* we found the starting sector */
break;
}
}
if (i >= MAXSLET) /* was not found */
goto done;
name = "?";
for (i = sizeof(phase)/sizeof(phase[0]); --i >= 0; ) {
if (phase[i].phid == phid) { /* look up name */
name = phase[i].name;
break;
}
}
printf("%02x %s", phid, name);
}
else
printf("%s", name);
done:
putchar('\n');
if (phid >= phdebug_lo && phid <= phdebug_hi && offset == 0)
break_simulation(STOP_PHASE_BREAK); /* break on read of first sector of indicated phases */
if (name != NULL && *name != '?' && ! iswrite)
savesector(addr, offset, nwords, phid, name);
}
static t_stat fdump_cmd (int flags, char *cptr)
{
int addr = 0x7a24; /* address of next statement */
int sofst = 0x7a26, symaddr;
int cword, nwords, stype, has_stnum, strel = 1, laststno = 0;
addr = M[addr & mem_mask] & mem_mask; /* get address of first statement */
sofst = M[sofst & mem_mask] & mem_mask ; /* get address of symbol table */
for (;;) {
cword = M[addr];
nwords = (cword >> 2) & 0x01FF;
stype = (cword >> 1) & 0x7C00;
has_stnum = (cword & 1);
if (has_stnum) {
laststno++;
strel = 0;
}
printf("/%04x [%4d +%3d] %3d - %04x", addr, laststno, strel, nwords, stype);
if (has_stnum) {
addr++;
nwords--;
symaddr = sofst - (M[addr] & 0x7FF)*3 + 3;
printf(" [%04x %04x %04x]", M[symaddr], M[symaddr+1], M[symaddr+2]);
}
if (stype == 0x5000) { /* error record */
printf(" (err %d)", M[addr+1]);
}
if (stype == 0x0800)
break;
addr += nwords;
putchar('\n');
if (nwords == 0) {
printf("0 words?\n");
break;
}
strel++;
}
printf("\nEnd found at /%04x, EOFS = /%04x\n", addr, M[0x7a25 & mem_mask]);
return SCPE_OK;
}
#endif /* TRACE_DMS_IO */