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prirun.p50em/emdev.h
Jim a063854a5c get16r0 shortcut macros to mean "Ring 0" 
name faults in traces
2007-03-03 00:00:00 -05:00

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/* emdev.h, Jim Wilcoxson, April 17, 2005
Device handlers for pio instructions. Use devnull as a template for
new handlers.
NOTES:
OCP instructions never skip
SKS instructions skip on specified conditions
INA/OTA instructions skip if they succeed (data was read/written)
Device numbers:
'00 = polling (?)
'01 = paper tape reader
'02 = paper tape punch
'03 = #1 MPC/URC (line printer/card reader/card punch)
'04 = SOC/Option A/VCP board (system console/user terminal)
'05 = #2 MPC/URC (line printer/card reader/card punch)
'06 = card punch? (RTOS User Guide, A-1) / IPC (Engr Handbook p.101)
'06 = Interproc. Channel (IPC) (R20 Hacker's Guide)
'07 = #1 PNC
'10 = ICS2 #1 or ICS1
'11 = ICS2 #2 or ICS1
'12 = floppy disk/diskette (magtape controller #3 at rev 22.1?)
'13 = #2 magtape controller
'14 = #1 magtape controller
'15 = #5 AMLC or ICS1
'16 = #6 AMLC or ICS1
'17 = #7 AMLC or ICS1
'20 = control panel / real-time clock
'21 = 1st 4002 (Option B') disk controller
'22 = disk #3
'23 = disk #4
'24 = disk (was Writable Control Store)
'25 = disk (was 4000 disk controller)
'26 = 1st disk controller
'27 = 2nd disk controller
'30-32 = BPIOC #1-3 (RTOS User Guide, A-1)
'32 = AMLC #8 or ICS1
'33 = #1 Versatec (verdim)
'34 = #2 Versatec
'35 = #4 AMLC or ICS1
'36-37 = ELFBUS #1 & 2 (ICS1 #1, ICS1 #2)
'40 = A/D converter type 6000
'41 = digital input type 6020
'42 = digital input #2
'43 = digital output type 6040
'44 = digital output #2
'45 = disk (was D/A converter type 6060 (analog output) - obsolete)
'46 = disk
'47 = #2 PNC
'50 = #1 HSSMLC/MDLC (cs/slcdim.pma)
'51 = #2 HSSMLC/MDLC
'52 = #3 AMLC or ICS1
'53 = #2 AMLC
'54 = #1 AMLC
'55 = MACI autocall unit
'56 = old SMLC (RTOS User Guide, A-1 & Hacker's Guide)
'60-67 = reserved for user devices (GPIB)
'70-'73 = Megatek graphics terminals
'75-'76 = T$GPPI
Devices emulated by Primos in ks/ptrap.ftn for I/O instructions in Ring 3:
'01 = paper tape reader
'02 = paper tape punch
'04 = console
'20 = control panel lights & sense switches
*/
#include <errno.h>
#include <fcntl.h>
#include <sys/time.h>
#include <sys/select.h>
#include <unistd.h>
#include <termios.h>
#include <sys/types.h>
#include <sys/socket.h>
#include <netinet/in.h>
#include <time.h>
/* this macro is used when I/O is successful. In VI modes, it sets
the EQ condition code bit. In SR modes, it does a skip */
#define IOSKIP \
if (crs[KEYS] & 010000) \
crs[KEYS] |= 0100; \
else \
RPL++
/* this macro is used to decide whether blocking should be enabled for
an I/O operation. The rules are:
- if process exchange is enabled, I/O can never block (check modals)
- if the instruction (assumed to be I/O) is followed by JMP *-1 (SR
modes) or BCNE *-2 (VI modes), then it's okay to block
*/
#if 1
#define BLOCKIO \
(!(crs[MODALS] & 010) && (get16(RP) == 03776 || (get16(RP) == 0141603 && get16(RP+1) == RPL-2)))
#else
#define BLOCKIO 0
#endif
/* this is a template for new device handlers */
int devnew (int class, int func, int device) {
switch (class) {
case -1:
return 0;
case 0:
TRACE(T_INST, " OCP '%02o%02o\n", func, device);
if (func == 99) {
;
} else {
printf("Unimplemented OCP device '%02o function '%02o\n", device, func);
fatal(NULL);
}
break;
case 1:
TRACE(T_INST, " SKS '%02o%02o\n", func, device);
if (func == 99)
IOSKIP; /* assume it's always ready */
else {
printf("Unimplemented SKS device '%02o function '%02o\n", device, func);
fatal(NULL);
}
break;
case 2:
TRACE(T_INST, " INA '%02o%02o\n", func, device);
if (func == 99) {
;
} else {
printf("Unimplemented INA device '%02o function '%02o\n", device, func);
fatal(NULL);
}
break;
case 3:
TRACE(T_INST, " OTA '%02o%02o\n", func, device);
if (func == 99) {
IOSKIP;
} else {
printf("Unimplemented OTA device '%02o function '%02o, A='%o\n", device, func, crs[A]);
fatal(NULL);
}
break;
}
}
/* this is a template for null (not present) devices */
int devnone (int class, int func, int device) {
static int seen[64] = {64*0};
switch (class) {
case -1:
return 0;
case 0:
TRACE(T_INST, " OCP '%02o%02o\n", func, device);
break;
case 1:
TRACE(T_INST, " SKS '%02o%02o\n", func, device);
break;
case 2:
TRACE(T_INST, " INA '%02o%02o\n", func, device);
break;
case 3:
TRACE(T_INST, " OTA '%02o%02o\n", func, device);
break;
}
if (!seen[device])
fprintf(stderr, " unimplemented device '%o\n", device);
seen[device] = 1;
}
/* Device '4: system console
NOTES:
- needs to reset tty attributes when emulator shuts down
- Primos only handles ASRATE 110 (10cps), 1010 (30cps), 3410 (960 cps)
- input ID is wrong, causes OCP '0477 on clock interrupt
- instruction counters on output are bogus, need to intercept TNOUA instead
OCP '0004 = initialize for input only, echoplex, 110 baud, 8-bit, no parity
OCP '0104 = same, but for output only
OCP '0204 = set receive interrupt mask
OCP '0304 = enable receive DMA/C
OCP '0404 = reset receive interrupt mask and DMA/C enable
OCP '0504 = set transmit interrupt mask
OCP '0604 = enable transmit DMA/C
OCP '0704 = reset transmit interrupt mask and DMA/C enable
OCP '1004 = Full duplex; software must echo
OCP '1104 = output a sync pulse (diagnostics)
OCP '1204 = Prime normal, independent xmit and recv w/echoplex
OCP '1304 = Self test mode (internally connects transmitter to receiver)
OCP '1504 = Set both xmit & rcv interrupt masks
OCP '1604 = Reset both xmit & rcv interrupt masks
OCP '1704 = same as '0004, but clears interrupt masks and dma/c enables
(this is the state after Master Clear)
SKS '0004 = skip if either receive or xmit ready, whichever are enabled
SKS '0104 = skip if not busy
SKS '0204 = skip if receiver not interrupting
SKS '0304 = skip if control registers valid
SKS '0404 = skip if neither xmit nor recv are interrupting
SKS '0504 = skip if xmit not interrupting
SKS '0604 = skip is xmit ready (can accept a character)
SKS '0704 = skip if recv ready (character present)
SKS '1104-'1404 = skip if input bit 1/2/3/4 marking
SKS '1504 = skip if parity error
SKS '1604 = skip if character overrun
SKS '1704 = skip if framing error
INA '0004 = "or" character into right byte of A, not modifying left byte
INA '0404 = input receive control register 1 (always works)
INA '0504 = input receive control register 2 (always works)
INA '0604 = input xmit control register 1 (always works)
INA '0704 = input xmit control register 2 (always works)
INA '1004 = like '0004, but clear A first
INA '1104 = input device ID
INA '1404 = input recv DMA/C channel address (these last 4 always work)
INA '1504 = input xmit DMA/C channel address
INA '1604 = input recv interrupt vector
INA '1704 = input xmit interrupt vector
OTA '0004 = xmit character from A; fails if inited for recv only
OTA '0404 = output rcv CR 1
OTA '0504 = output rcv CR 2
OTA '0604 = output xmit CR 1
OTA '0704 = output xmit CR 2
OTA '1404 = output recv DMA/C channel address (these last 4 always work)
OTA '1504 = output xmit DMA/C channel address
OTA '1604 = output recv interrupt vector
OTA '1704 = output xmit interrupt vector
*/
int devasr (int class, int func, int device) {
static FILE *conslog;
static int ttydev;
static int ttyflags;
static int needflush; /* true if data has been written but not flushed */
static int atbol=1; /* true if cursor is at bol */
static int atnewl=1; /* true if cursor is on a blank line */
static struct termios terminfo;
static fd_set fds;
struct timeval timeout;
unsigned char ch;
int newflags;
int n;
switch (class) {
case -1:
setsid();
ttydev = open("/dev/tty", O_RDWR, 0);
if (ttydev < 0) {
perror(" error opening /dev/tty");
fatal(NULL);
}
if (fcntl(ttydev, F_GETFL, ttyflags) == -1) {
perror(" unable to get tty flags");
fatal(NULL);
}
FD_ZERO(&fds);
if (tcgetattr(ttydev, &terminfo) == -1) {
perror(" unable to get tty attributes");
fatal(NULL);
}
/* NOTE: some of these are not restored after the emulator
is suspended (VSUSP) then restarted, eg, the VSUSP and
VINTR characters */
terminfo.c_iflag &= ~(INLCR | ICRNL);
terminfo.c_lflag &= ~(ECHOCTL | ICANON);
terminfo.c_oflag &= ~(TOSTOP);
terminfo.c_cc[VINTR] = _POSIX_VDISABLE; /* use ^\ instead */
terminfo.c_cc[VSUSP] = '';
terminfo.c_cc[VMIN] = 0;
terminfo.c_cc[VTIME] = 0;
if (tcsetattr(ttydev, TCSANOW, &terminfo) == -1) {
perror(" unable to set tty attributes");
fatal(NULL);
}
/* ignore SIGTTIN in case the emulator is put in the background */
signal(SIGTTIN, SIG_IGN);
/* open console log file and set to line buffering */
if ((conslog = fopen("console.log", "w")) == NULL) {
perror(" unable to open console log file");
fatal(NULL);
}
setvbuf(conslog, NULL, _IOLBF, 0);
return 0;
case 0:
TRACE(T_INST, " OCP '%02o%02o\n", func, device);
break;
case 1:
TRACE(T_INST, " SKS '%02o%02o\n", func, device);
if (func == 6) { /* skip if room for a character */
timeout.tv_sec = 0;
timeout.tv_usec = 0;
FD_SET(ttydev, &fds);
n = select(ttydev+1, NULL, &fds, NULL, &timeout);
if (n == -1) {
perror(" unable to do write select on tty");
fatal(NULL);
}
if (n) {
IOSKIP;
}
} else if (func == 7) { /* skip if received a char */
if (crs[MODALS] & 010) /* PX enabled? */
timeout.tv_sec = 0; /* yes, can't delay */
else
timeout.tv_sec = 1; /* single user: okay to delay */
timeout.tv_usec = 0;
FD_SET(ttydev, &fds);
n = select(ttydev+1, &fds, NULL, NULL, &timeout);
if (n == -1) {
perror(" unable to do read select on tty");
fatal(NULL);
}
if (n) {
IOSKIP;
}
} else if (func <= 014)
IOSKIP; /* assume it's always ready */
break;
/* signal SIGTTIN is ignore during initialization, so if the
emulator is put in the background, read() will return EIO */
case 2:
TRACE(T_INST, " INA '%02o%02o\n", func, device);
if (func == 0 || func == 010) {
if (BLOCKIO)
newflags = ttyflags & ~O_NONBLOCK;
else
newflags = ttyflags | O_NONBLOCK;
if (newflags != ttyflags && fcntl(ttydev, F_SETFL, newflags) == -1) {
perror(" unable to set tty flags");
fatal(NULL);
}
ttyflags = newflags;
if (needflush) {
if (fflush(stdout) == 0) {
needflush = 0;
devpoll[device] = 0;
}
fflush(conslog);
}
readasr:
n = read(ttydev, &ch, 1);
if (n < 0) {
if (errno != EAGAIN && errno != EIO) {
perror(" error reading from tty");
fatal(NULL);
}
} else if (n == 1) {
if (ch == '') {
if (savetraceflags == 0) {
TRACEA("\nTRACE ENABLED:\n\n");
savetraceflags = ~TB_MAP;
savetraceflags = ~0;
} else {
TRACEA("\nTRACE DISABLED:\n\n");
dumpsegs();
savetraceflags = 0;
}
fflush(tracefile);
goto readasr;
}
if (func >= 010)
crs[A] = 0;
crs[A] = crs[A] | ch;
TRACE(T_INST, " character read=%o: %c\n", crs[A], crs[A] & 0x7f);
if (ch != 015) { /* log all except carriage returns */
fputc(ch, conslog);
fflush(conslog); /* immediately flush typing echos */
}
IOSKIP;
} else if (n != 0) {
printf("Unexpected error reading from tty, n=%d\n", n);
fatal(NULL);
}
} else if (04 <= func && func <= 07) { /* read control register 1/2 */
crs[A] = 0;
IOSKIP;
} else if (func == 011) { /* read device id? */
crs[A] = 4;
IOSKIP;
} else if (func == 012) { /* read control word */
crs[A] = 04110;
IOSKIP;
} else if (func == 017) { /* read xmit interrupt vector */
crs[A] = 0;
IOSKIP;
} else {
printf("Unimplemented INA '04 function '%02o\n", func);
fatal(NULL);
}
break;
case 3:
TRACE(T_INST, " OTA '%02o%02o\n", func, device);
if (func == 0) {
ch = crs[A] & 0x7f;
TRACE(T_INST, " char to write=%o: %c\n", crs[A], ch);
if (ch == 0 || ch == 0x7f) {
IOSKIP;
return;
}
#if 0
/* could do this here too, but Primos does it with SKS before
doing the OTA for the console, so it isn't really necessary.
Also, if done here, it might confused a program if SKS said
the character could be output, then OTA said it couldn't.
The program might stay in a tight OTA loop and hang the
machine until sys console output clears */
timeout.tv_sec = 0;
timeout.tv_usec = 0;
FD_SET(2, &fds);
n = select(2+1, NULL, &fds, NULL, &timeout);
if (n == -1) {
perror(" unable to do write select on stdout");
fatal(NULL);
}
if (!n)
return;
#endif
#if 0
if (atbol && atnewl)
printf("%10d| ", instcount);
#endif
putchar(ch);
if (ch == 015)
atbol = 1;
else {
putc(ch, conslog);
if (ch == 012)
atnewl = 1;
else {
atbol = 0;
atnewl = 0;
}
}
needflush = 1;
if (devpoll[device] == 0)
devpoll[device] = instpermsec*100;
IOSKIP;
} else if (func == 1) { /* write control word */
IOSKIP;
} else if (04 <= func && func <= 07) { /* write control register 1/2 */
IOSKIP;
} else if (func == 013) {
/* NOTE: does this in rev 20 on settime command (set clock on VCP?) */
IOSKIP;
} else if (func == 017) {
/* NOTE: 9950 does this in rev 20, others don't */
IOSKIP;
} else {
printf("Unimplemented OTA device '%02o function '%02o, A='%o\n", device, func, crs[A]);
fatal(NULL);
}
break;
case 4:
/* tty output is blocking, even under Primos, which means that
writes and fflush can hang the entire system, eg, if XOFF
happens while writing to the console) */
if (needflush) {
if (fflush(stdout) == 0)
needflush = 0;
else
devpoll[device] = instpermsec*100;
fflush(conslog);
}
}
}
/* Device '14 - magtape controller #1
NOTES:
This code only supports 1 tape controller (4 units), but could be
extended to support 2 controllers (eg, see disk controller code)
All tape files are assumed to be in SimH .TAP format:
- 4-bytes (little endian integer) indicating data record length (in bytes)
- n bytes of data
- repeat of the 4-byte data record length
- odd length records have a pad byte inserted
- if MSB of record length is set, there is an error in the record
- record length of zero indicates a file mark (doesn't repeat)
- record length of all 1's indicates end-of-tape mark (doesn't repeat)
Tape files are named according to the device and unit, like disk drives:
- dev14u0, dev14u1, dev14u2, dev14u3
These names are usually just links to the actual tape file.
Tape status word bits (MSB to LSB):
1 = Vertical Parity Error
2 = Runaway
3 = CRC Error
4 = LRCC Error
5 = False Gap or Insufficient DMX Range
6 = Uncorrectable Read Error
7 = Raw Erorr
8 = Illegal Command
9 = Selected Tape Ready (online and not rewinding)
10 = Selected Tape Online
11 = Selected Tape is at End Of Tape (EOT)
12 = Selected Tape is Rewinding
13 = Selected Tape is at Beginning Of Tape (BOT)
14 = Selected Tape is Write Protected
15 = DMX Overrun
16 = Rewind Interrupt
OTA '01 Motion control A-register bits:
1 = Select Tape Only
2 = 0 for File operation, 1 for Record operation
3 = 1 for Space operation
4 = 1 for Read & Correct
5 = 1 for 7-track
6 = 1 for 9-track
7 = unused
8 = 1 for 2 chars/word, 0 for 1 char/word (not supported here)
9-11 = motion: 100 = Forward, 010 = Reverse, 001 = Rewind
12 = 1 for Write
13 = 1 for Unit 0
14 = 1 for Unit 1
15 = 1 for Unit 2
16 = 1 for Unit 3
*/
int mtread (int fd, unsigned short *iobuf, int nw, int fw, int *mtstat) {
unsigned char buf[4];
int n,reclen,reclen2,bytestoread;
TRACE(T_TIO, " mtread, nw=%d, initial tape status is 0x%04x\n", nw, *mtstat);
if (fw) {
if (*mtstat & 0x20) /* already at EOT, can't read */
return 0;
n = read(fd, buf, 4);
TRACE(T_TIO, " mtread read foward, %d bytes for reclen\n", n);
if (n == 0) { /* now we're at EOT */
*mtstat |= 0x20;
return 0;
}
*mtstat &= ~8; /* not at BOT now */
readerr:
if (n == -1) {
perror("Error reading from tape file");
*mtstat = 0; /* take drive offline */
return 0;
}
if (n < 4) {
fprintf(stderr," only read %d bytes for reclen\n", n);
fmterr:
warn("Tape file isn't in .TAP format");
*mtstat = 0;
return 0;
}
reclen = buf[0] | (buf[1]<<8) | (buf[2]<<16) | (buf[3]<<24);
TRACE(T_TIO, " mtread reclen = %d bytes\n", reclen);
if (reclen == 0) { /* hit a file mark */
*mtstat |= 0x100;
return 0;
}
if (reclen == 0xFFFF) { /* hit EOT mark */
/* NOTE: simh says to backup here, probably to wipe out EOT if
more data is written. IMO, EOT should never be written to
simulated tape files. */
if (lseek(fd, -4, SEEK_CUR) == -1) {
perror("em: unable to backspace over EOT");
goto readerr;
}
*mtstat |= 0x20;
return 0;
}
if (reclen & 0x8000) { /* record marked in error */
/* NOTE: simh may have non-zero record length here... */
*mtstat |= 0xB600; /* set all error bits */;
return 0;
}
if (reclen & 1)
warn("odd-length record in tape file!");
if (reclen < 0) {
fprintf(stderr," negative record length %d\n", reclen);
goto fmterr;
}
/* now either position or read forward */
if (nw == 0) { /* spacing only */
if ((n=lseek(fd, reclen, SEEK_CUR)) == -1) {
perror("em: unable to forward space record");
goto fmterr;
} else {
TRACE(T_TIO, " spaced forward %d bytes to position %d\n", reclen, n);
}
} else {
if ((reclen+1)/2 > nw) {
fprintf(stderr,"em: reclen = %d bytes in tape file - too big!\n", reclen);
*mtstat |= 2; /* set DMX overrun status */
bytestoread = nw*2;
} else {
bytestoread = reclen;
}
n = read(fd, iobuf, bytestoread);
TRACE(T_TIO, " mtread read %d/%d bytes of data \n", n, reclen);
if (n == -1) goto readerr;
if (n != bytestoread) goto fmterr;
if (bytestoread != reclen) { /* skip the rest of the record */
if (lseek(fd, reclen-bytestoread, SEEK_CUR) == -1) {
fprintf(stderr,"em: unable to handle large record\n");
goto readerr;
}
}
}
/* now get the trailing record length */
n = read(fd, buf, 4);
TRACE(T_TIO, " mtread read %d bytes for trailer reclen\n", n);
if (n == -1) goto readerr;
if (n != 4) goto fmterr;
reclen2 = buf[0] | (buf[1]<<8) | (buf[2]<<16) | (buf[3]<<24);
if (reclen2 != reclen) goto fmterr;
/* XXX: maybe should pad odd-length record with a zero... */
return (bytestoread+1)/2;
} else {
/* spacing backward, see if we're at BOT */
if ((*mtstat & 8) || (lseek(fd, 0, SEEK_CUR) == 0)) {
*mtstat |= 8; /* yep, at BOT */
return 0;
}
/* backup 4 bytes, read reclen */
if (lseek(fd, -4, SEEK_CUR) == -1)
goto fmterr;
n = read(fd, buf, 4);
if (n == -1) goto readerr;
if (n != 4) goto fmterr;
reclen = buf[0] | (buf[1]<<8) | (buf[2]<<16) | (buf[3]<<24);
/* backup reclen+8 bytes unless this is a file mark, error,
or EOT */
if (reclen == 0) {
*mtstat |= 0x100; /* set filemark status */
goto repo;
}
if (reclen & 0x8000) /* error record (don't report) */
goto repo;
if (reclen == 0xFFFF) {
reclen = 0;
goto repo;
}
if (lseek(fd, -(reclen+8), SEEK_CUR) == -1)
goto fmterr;
/* read leading reclen again to make sure we're positioned correctly */
n = read(fd, buf, 4);
if (n == -1) goto readerr;
if (n != 4) goto fmterr;
reclen2 = buf[0] | (buf[1]<<8) | (buf[2]<<16) | (buf[3]<<24);
if (reclen2 != reclen) goto fmterr;
/* finally, backup over the reclen to be positioned for read */
repo:
if ((n = lseek(fd, -4, SEEK_CUR)) == -1)
goto readerr;
if (n == 0)
*mtstat |= 8; /* now at BOT */
return 0;
}
}
int mtwrite (int fd, unsigned short *iobuf, int nw, int *mtstat) {
int n;
n = write(fd, iobuf, nw*2);
if (nw*2 != n) {
perror("Error writing to tape file");
fatal(NULL);
}
*mtstat &= ~8; /* not at BOT now */
}
int devmt (int class, int func, int device) {
static unsigned short mtvec = 0114; /* interrupt vector */
static unsigned short dmxchan = 0; /* dmx channel number */
static unsigned short datareg = 0; /* data holding register */
static unsigned short ready = 0; /* true if datareg valid */
static unsigned short enabled = 0; /* interrupts enabled */
static unsigned short interrupting = 0; /* true if interrupt pending */
static unsigned short usel = 0; /* last unit selected */
static struct {
int fd; /* tape file descriptor */
int mtstat; /* last tape status */
int firstwrite; /* true if next write is the first */
} unit[4];
int u;
char devfile[8];
/* the largest rec size Primos ever supported is 16K bytes, plus 8
bytes for the 4-byte .TAP format record length at the beginning &
end of each record */
#define MAXTAPEWORDS 8*1024
unsigned short iobuf[MAXTAPEWORDS+4]; /* 16-bit WORDS! */
unsigned short *iobufp;
unsigned short dmxreg; /* DMA/C register address */
unsigned short tempdmxchan; /* temp to incr during xfer */
short dmxnch; /* number of DMX channels - 1 */
unsigned short dmxaddr;
unsigned long dmcpair;
short dmxnw, dmxtotnw;
int i,n;
char reclen[4];
switch (class) {
case -1: /* initialize emulator device */
for (u=0; u<4; u++) {
unit[u].fd = -1;
unit[u].mtstat = 0;
unit[u].firstwrite = 1;
}
return 0;
case 0:
TRACE(T_INST|T_TIO, " OCP '%02o%02o\n", func, device);
if (func == 012 || func == 013) { /* set normal/diag mode - ignored */
;
} else if (func == 014) { /* ack interrupt */
/* this is a hack because Primos acks interrupts immediately after
OTA 01 (due to a tape controller bug) */
if (interrupting)
interrupting--;
} else if (func == 015) { /* set interrupt mask */
enabled = 1;
} else if (func == 016) { /* reset interrupt mask */
enabled = 0;
} else if (func == 017) { /* initialize */
mtvec = 014;
dmxchan = 0;
datareg = 0;
interrupting = 0;
ready = 0;
usel = 0;
} else {
printf("Unimplemented OCP device '%02o function '%02o\n", device, func);
fatal(NULL);
}
break;
case 1:
TRACE(T_INST|T_TIO, " SKS '%02o%02o\n", func, device);
if (func == 00) { /* skip if ready */
if (ready)
IOSKIP;
} else if (func == 01) { /* skip if not busy */
IOSKIP;
} else if (func == 04) { /* skip if not interrupting */
if (!interrupting)
IOSKIP;
} else {
printf("Unimplemented SKS device '%02o function '%02o\n", device, func);
fatal(NULL);
}
break;
case 2:
TRACE(T_INST|T_TIO, " INA '%02o%02o\n", func, device);
if (func == 0) {
#if 0
if (!ready) warn("INA 00 on tape device w/o matching OTA!");
#endif
crs[A] = datareg;
datareg = 0;
ready = 0;
IOSKIP;
} else {
printf("Unimplemented INA device '%02o function '%02o\n", device, func);
fatal(NULL);
}
break;
case 3:
TRACE(T_INST|T_TIO, " OTA '%02o%02o, A='%06o %04x\n", func, device, crs[A], crs[A]);
#if 0
/* don't accept any OTA's if we're interrupting */
if (interrupting)
break;
#endif
if (func == 01) {
/* here's the hard part where everything happens... decode unit first */
u = crs[A] & 0xF;
if (u == 1) u = 3;
else if (u == 2) u = 2;
else if (u == 4) u = 1;
else if (u == 8) u = 0;
else
fatal("em: no unit selected on tape OTA '01");
usel = u;
/* XXX: if the tape device file changes (inode changes?), close
and re-open the file (new tape reel). Does offline need to
be reported at least once in this case? Or should it somehow
be related to rewinds? (only do the check at BOT?) */
#if 0
if (unit[u].mtstat & 8 && /* tape device file changed */) {
/* close tape fd if open & set to -1 */
}
#endif
/* if the tape file has never been opened, do it now. */
if (unit[u].fd == -1) {
unit[u].mtstat = 0;
unit[u].firstwrite = 1;
snprintf(devfile,sizeof(devfile),"dev%ou%d", device, u);
TRACE(T_TIO, " filename for tape dev '%o unit %d is %s\n", device, u, devfile);
if ((unit[u].fd = open(devfile, O_RDWR, 0770)) == -1) {
fprintf(stderr,"em: unable to open tape device file %s for device '%o unit %d for read/write\n", devfile, device, u);
IOSKIP;
break;
}
unit[u].mtstat = 0x00C8; /* Ready, Online, BOT */
}
/* "select only" is ignored. On a real tape controller, this
blocks (I think) if the previous tape operation is in progress */
if (crs[A] & 0x8000) {
TRACE(T_TIO, " select only\n");
IOSKIP;
break;
}
/* clear "last operation" error bits in mtstat, but preserve status
things like "at BOT", "at EOT", "write protected" */
unit[u].mtstat &= 0x00EC;
/* for rewind, read, write, & space, setup a completion
interrupt if controller interrupts are enabled. NOTE: there
is a race condition here. Immediately following OTA 01,
Primos clears pending interrupts because of an old tape
controller bug. To get around this, "interrupting" is a
counter and is set to 2 so that when Primos clears
interrupts, the counter is decremented in this driver, but
the interrupt will still occur later */
interrupting = 2;
devpoll[device] = 10;
if ((crs[A] & 0x00E0) == 0x0020) { /* rewind */
//traceflags = ~TB_MAP;
TRACE(T_TIO, " rewind\n");
if (lseek(unit[u].fd, 0, SEEK_SET) == -1) {
perror("Unable to rewind tape drive file");
fatal(NULL);
}
unit[u].mtstat = 0x00C8; /* Ready, Online, BOT */
IOSKIP;
break;
}
/* Now we're reading, writing, or spacing either a record or file:
- space file/record, forward or backward = okay
- read record = okay, read file doesn't make sense
- write record = okay, write file = write file mark */
/* write file mark
NOTE: the tape file should probably be truncated on the first
write, not on each file mark */
if ((crs[A] & 0x4010) == 0x0010) {
TRACE(T_TIO, " write file mark\n");
*(int *)iobuf = 0;
mtwrite(unit[u].fd, iobuf, 2, &unit[u].mtstat);
ftruncate(unit[u].fd, lseek(unit[u].fd, 0, SEEK_CUR));
IOSKIP;
break;
}
/* space forward or backward a record or file at a time */
if (crs[A] & 0x2000) { /* space operation */
if ((crs[A] & 0xC0) == 0)
warn("Motion = 0 for tape spacing operation");
else if (crs[A] & 0x4000) { /* record operation */
TRACE(T_TIO, " space record, dir=%x\n", crs[A] & 0x80);
mtread(unit[u].fd, iobuf, 0, crs[A] & 0x80, &unit[u].mtstat);
} else { /* file spacing operation */
TRACE(T_TIO, " space file, dir=%x\n", crs[A] & 0x80);
do {
mtread(unit[u].fd, iobuf, 0, crs[A] & 0x80, &unit[u].mtstat);
} while (!(unit[u].mtstat & 0x128)); /* FM, EOT, BOT */
}
IOSKIP;
break;
}
/* read/write backward aren't supported */
if (((crs[A] & 0x00E0) == 0x0040) && ((crs[A] & 0x2000) == 0)) {
warn("em: read/write reverse not supported for tapes");
unit[u].mtstat = 0;
IOSKIP;
break;
}
/* for read command, fill the io buffer first. Note that mtread
doesn't store record lengths in iobuf and the return value is
the actual data record length in words. It also ensures that
the return value is never > the # of words requested (MAXTAPEWORDS)
for write commands, the 4-byte .TAP record length IS stored in
iobuf and the length returned by mtwrite reflects that */
if (crs[A] & 0x10) { /* write record */
dmxtotnw = 0;
iobufp = iobuf+2;
} else {
TRACE(T_TIO, " read record\n");
dmxtotnw = mtread(unit[u].fd, iobuf, MAXTAPEWORDS, 1, &unit[u].mtstat);
iobufp = iobuf;
}
/* data transfer from iobuf (read) or to iobuf (write) */
while (1) {
dmxreg = dmxchan & 0x7FF;
if (dmxchan & 0x0800) { /* DMC */
dmcpair = get32r(dmxreg, 0); /* fetch begin/end pair */
dmxaddr = dmcpair>>16;
dmxnw = (dmcpair & 0xffff) - dmxaddr + 1;
TRACE(T_INST|T_TIO, " DMC channels: ['%o]='%o, ['%o]='%o, nwords=%d\n", dmxreg, dmxaddr, dmxreg+1, (dmcpair & 0xffff), dmxnw);
} else { /* DMA */
dmxreg = dmxreg << 1;
dmxnw = regs.sym.regdmx[dmxreg];
if (dmxnw <= 0)
dmxnw = -(dmxnw>>4);
else
dmxnw = -((dmxnw>>4) ^ 0xF000);
dmxaddr = regs.sym.regdmx[dmxreg+1];
TRACE(T_INST|T_TIO, " DMA channels: ['%o]='%o, ['%o]='%o, nwords=%d\n", dmxreg, regs.sym.regdmx[dmxreg], dmxreg+1, dmxaddr, dmxnw);
}
if (dmxnw < 0) { /* but is legal for >32K DMC transfer... */
printf("devmt: requested negative DMX of size %d\n", dmxnw);
fatal(NULL);
}
if (crs[A] & 0x10) { /* write record */
if (dmxtotnw+dmxnw > MAXTAPEWORDS)
fatal("Tape write is too big");
for (n=dmxnw; n > 0; n--) {
*iobufp++ = get16r(dmxaddr+i, 0);
}
dmxtotnw = dmxtotnw + dmxnw;
} else {
if (dmxnw > dmxtotnw)
dmxnw = dmxtotnw;
for (n=dmxnw; n > 0; n--) {
put16r(*iobufp++, dmxaddr+i, 0);
}
dmxtotnw = dmxtotnw - dmxnw;
}
TRACE(T_TIO, " read/wrote %d words\n", dmxnw);
if (dmxchan & 0x0800) { /* DMC */
put16r(dmxaddr+dmxnw, dmxreg, 0); /* update starting address */
} else {
regs.sym.regdmx[dmxreg] += dmxnw<<4; /* increment # words */
regs.sym.regdmx[dmxreg+1] += dmxnw; /* increment address */
}
/* if chaining, bump channel number and decrement # channels */
if (dmxchan & 0xF000)
dmxchan = dmxchan + 2 - (1<<12);
else
break;
}
/* for write record, do the write */
if (crs[A] & 0x10) { /* write record */
TRACE(T_TIO, " write record\n");
n = dmxtotnw*2;
reclen[0] = n & 0xFF;
reclen[1] = n>>8 & 0xFF;
reclen[2] = n>>16 & 0xFF;
reclen[3] = n>>24 & 0xFF;
*(int *)iobuf = *(int *)reclen;
*(int *)(iobuf+2+dmxtotnw) = *(int *)reclen;
mtwrite(unit[u].fd, iobuf, dmxtotnw+4, &unit[u].mtstat);
} else { /* read record */
if (dmxtotnw > 0) {
TRACE(T_TIO, " DMA Overrun, lost %d words\n", dmxtotnw);
unit[u].mtstat |= 0x800;
}
}
IOSKIP;
break;
} else if (func == 02) {
TRACE(T_TIO, " setup INA, A='%06o, 0x%04x\n", crs[A], crs[A]);
if (crs[A] & 0x8000)
datareg = unit[usel].mtstat;
else if (crs[A] & 0x4000)
datareg = 0114; /* device ID */
else if (crs[A] & 0x2000)
datareg = dmxchan;
else if (crs[A] & 0x1000)
datareg = mtvec;
else {
TRACE(T_TIO, " Bad OTA '02 to tape drive, A='%06o, 0x$04x\n", crs[A], crs[A]);
if (enabled) {
interrupting = 1;
devpoll[device] = 10;
}
}
TRACE(T_TIO, " datareg='%06o, 0x%04x\n", datareg, datareg);
IOSKIP;
} else if (func == 03) { /* power on */
TRACE(T_TIO, " power on\n");
IOSKIP;
} else if (func == 05) { /* illegal - DIAG */
TRACE(T_TIO, " illegal DIAG OTA '05\n");
if (enabled) {
interrupting = 1;
devpoll[device] = 10;
IOSKIP;
}
} else if (func == 014) { /* set DMX channel */
dmxchan = crs[A];
TRACE(T_TIO, " dmx channel '%o, 0x%04x\n", dmxchan, dmxchan);
IOSKIP;
} else if (func == 016) { /* set interrupt vector */
mtvec = crs[A];
TRACE(T_TIO, " interrupt vector '%o\n", mtvec);
IOSKIP;
} else {
printf("Unimplemented OTA device '%02o function '%02o, A='%o\n", device, func, crs[A]);
fatal(NULL);
}
break;
case 4:
TRACE(T_TIO, " POLL device '%02o, enabled=%d, interrupting=%d\n", device, enabled, interrupting);
if (enabled && interrupting) {
if (intvec == -1) {
TRACE(T_TIO, " CPU interrupt to vector '%o\n", mtvec);
intvec = mtvec;
}
/* HACK: keep interrupting because of Primos race bug */
devpoll[device] = 100;
}
}
}
/* Device '20: control panel switches and lights, and realtime clock
OCP '0020 = start Line Frequency Clock, enable mem increment, ack previous overflow (something else on VCP?)
OCP '0120 = ack PIC interrupt
OCP '0220 = stop LFC, disable mem increment, ack previous overflow
OCP '0420 = select LFC for memory increment (something else on VCP?)
OCP '0520 = select external clock for memory increment
OCP '0620 = starts a new 50-ms watchdog timeout interval
OCP '0720 = stops the watchdog timer
OCP '1520 = set interrupt mask
OCP '1620 = reset interrupt mask
OCP '1720 = initialize as in Master Clear
SKS '0020 = skip if clock IS interrupting
SKS '0220 = skip if clock IS NOT interrupting
SKS '0520 = skip if WDT timed out
SKS '0720 = skip if WDT caused external interrupt (loc '60)
OTA '0220 = set PIC Interval register (negative, interrupts on incr to zero)
OTA '0720 = set control register
OTA '1220 = set Memory Increment Cell address
OTA '1320 = set interrupt vector address
OTA '1720 = write to lights (sets CP fetch address)
INA '0220 = read PIC Interval register
INA '1120 = read device ID, don't clear A first
INA '1220 = read Memory Increment Cell address
INA '1320 = read interrupt vector address
INA '1420 = read location from CP ROM (not implemented, used to boot)
INA '1620 = read control panel up switches
INA '1720 = read control panel down switches
IMPORTANT NOTE 1: this device ('20) never skips!
IMPORTANT NOTE 2: if the host system suspends, then when it awakes,
devcp will make the clock tick faster until it catches up to where
it should be. Fake clock interrupts are injected every 100 Prime
instructions to catch up. These fast interrupts can't occur too
quickly (like every 10 Prime instructions), because CLKDIM can't
execute completely in 10 instructions and the repeated interrupts
will eventually cause the clock semaphore to overflow.
*/
/* initclock sets Primos' real-time clock variable */
initclock(datnowea) {
int datnow, i;
time_t unixtime;
struct tm *tms;
unixtime = time(NULL);
tms = localtime(&unixtime);
datnow = tms->tm_year<<25 | (tms->tm_mon+1)<<21 | tms->tm_mday<<16 | ((tms->tm_hour*3600 + tms->tm_min*60 + tms->tm_sec)/4);
put32r(datnow, datnowea, 0);
}
int devcp (int class, int func, int device) {
static short enabled = 0;
static unsigned short clkvec;
static short clkpic = 0;
static unsigned long ticks = -1;
static unsigned long absticks = -1;
static struct timeval start_tv;
static ea_t datnowea = 0;
static struct timeval prev_tv;
static unsigned long previnstcount=0; /* value of instcount corresponding to above */
struct timeval tv;
unsigned long elapsedms,targetticks;
int i;
#define SETCLKPOLL devpoll[device] = instpermsec*(-clkpic*3.2)/1000;
switch (class) {
case -1:
/* if -map is used, lookup DATNOW symbol and set the 32-bit
Primos time value (DATNOW+TIMNOW) */
datnowea = 0;
for (i=0; i<numsyms; i++) {
if (strcmp(mapsym[i].symname, "DATNOW") == 0)
datnowea = mapsym[i].address;
}
return 0;
case 0:
TRACE(T_INST, " OCP '%02o%02o\n", func, device);
if (func == 00) { /* does something on VCP after OCP '0420 */
;
} else if (func == 01) { /* ack PIC interrupt */
;
} else if (func == 02) { /* stop LFC (IO.PNC DIAG) */
;
} else if (func == 04) { /* does something on VCP during boot */
;
} else if (func == 015) { /* set interrupt mask */
/* this enables tracing when the clock process initializes */
//traceflags = ~TB_MAP;
//TRACEA("Clock interrupt enabled!\n");
enabled = 1;
SETCLKPOLL;
ticks = -1;
} else if (func == 016 || func == 017) {
enabled = 0;
devpoll[device] = 0;
} else {
printf("Unimplemented OCP device '%02o function '%02o\n", device, func);
fatal(NULL);
}
break;
case 1:
TRACE(T_INST, " SKS '%02o%02o\n", func, device);
printf("Unimplemented SKS device '%02o function '%02o\n", device, func);
fatal(NULL);
break;
case 2:
TRACE(T_INST, " INA '%02o%02o\n", func, device);
if (func == 011) { /* input ID */
crs[A] = 020; /* this is the Option-A board */
crs[A] = 0220; /* VCP board? */
crs[A] = 0120; /* this is the SOC board */
//traceflags = ~TB_MAP;
} else if (func == 016) {
crs[A] = sswitch;
} else if (func == 017) { /* read switches pushed down */
crs[A] = 0;
} else {
printf("Unimplemented INA device '%02o function '%02o\n", device, func);
fatal(NULL);
}
break;
case 3:
TRACE(T_INST, " OTA '%02o%02o\n", func, device);
if (func == 02) { /* set PIC interval */
clkpic = *(short *)(crs+A);
SETCLKPOLL;
TRACE(T_INST, "Clock PIC interval set to %d\n", clkpic);
} else if (func == 07) {
TRACE(T_INST, "Clock control register set to '%o\n", crs[A]);
} else if (func == 013) {
clkvec = crs[A];
TRACE(T_INST, "Clock interrupt vector address = '%o\n", clkvec);
} else if (func == 017) { /* write lights */
} else {
printf("Unimplemented OTA device '%02o function '%02o, A='%o\n", device, func, crs[A]);
fatal(NULL);
}
break;
/* Clock poll important considerations are:
1. ticks = -1 initially; this triggers initialization here
2. start_tv corresponds to the time where ticks = 0
3. if the clock gets out of sync, it ticks faster or slower until
it is right
4. if the clock is WAY out of sync, try to jump to the correct time
5. once the clock is in sync, reset start_tv if ticks gets too big
(uh, after 5 months!) to prevent overflows in time calculations
*/
case 4:
/* interrupt if enabled and no interrupt active */
if (enabled) {
if (intvec == -1) {
intvec = clkvec;
SETCLKPOLL;
ticks++;
if (gettimeofday(&tv, NULL) != 0)
fatal("em: gettimeofday 3 failed");
if (ticks == 0) {
start_tv = tv;
prev_tv = tv;
previnstcount = instcount;
if (datnowea != 0)
initclock(datnowea);
}
elapsedms = (tv.tv_sec-start_tv.tv_sec-1)*1000 + (tv.tv_usec+1000000-start_tv.tv_usec)/1000;
targetticks = elapsedms/(-clkpic*3.2/1000);
#if 0
absticks++;
if (absticks%1000 == 0)
printf("Clock check: target=%d, ticks=%d\n", targetticks, ticks);
#endif
/* if the clock gets way out of whack (eg, because of a host
suspend or time change (eg, DST), reset it IFF datnowea is
known. This causes an immediate jump to the correct time.
If datnowea is not available (no Primos maps), then we have
to tick our way to the correct time */
if (abs(ticks-targetticks) > 5000 && datnowea != 0)
ticks = -1;
else if (ticks < targetticks)
devpoll[device] = 100; /* behind, so catch-up */
else if (ticks > targetticks)
devpoll[device] = devpoll[device]*2; /* ahead, so slow down */
else { /* just right! */
if (ticks > 1000000000) { /* after a long time, */
start_tv = tv; /* reset tick vars */
ticks = 0;
}
}
/* update instpermsec every 5 seconds
NB: this should probably be done whether the clock is running
or not */
if (instcount-previnstcount > instpermsec*1000*5) {
instpermsec = (instcount-previnstcount) /
((tv.tv_sec-prev_tv.tv_sec-1)*1000 + (tv.tv_usec+1000000-prev_tv.tv_usec)/1000);
//printf("instcount = %d, previnstcount = %d, diff=%d, instpermsec=%d\n", instcount, previnstcount, instcount-previnstcount, instpermsec);
//printf("instpermsec=%d\n", instpermsec);
previnstcount = instcount;
prev_tv = tv;
}
} else {
devpoll[device] = 100; /* couldn't interrupt, try again soon */
}
}
break;
}
}
/* disk controller at '26 and '27
NOTES:
- in the DSEL disk channel program command, unit number is a 4-bit field,
with these binary values:
0001 = unit 0 (pdev 460/461)
0010 = unit 1 (pdev 462/463)
0100 = unit 2 (pdev 464/465)
1000 = unit 3 (pdev 466/467)
OCP '1626 = reset interrupt
OCP '1726 = reset controller
INA '0626 = ??
INA '1126 = input ID, don't clear A first, fails if no controller
- bits 1,2,8-16 are significant, bits 8-9 are type, 10-16 are ID
- 4004 controller responds '26 (type=0)
- 4005 controller responds '126 (type=1)
- 2382 controller responds '040100 (type=1)
- LCDTC controller responds '226 (type=2)
- 10019 controller responds '040100 (type=1)
- 6590 controller responds '040100 (type=1)
INA '1726 = read oar, fails if controller is not halted
OTA '1726 = load OAR (Order Address Register), ie, run channel
program, address is in A
*/
int devdisk (int class, int func, int device) {
#define S_HALT 0
#define S_RUN 1
#define S_INT 2
/* this should be 8, but not sure how it is supported on controllers */
#define MAXDRIVES 4
#define HASHMAX 4451
#if 0
#define CID4005 0100
#else
#define CID4005 0
#endif
static struct {
unsigned short oar;
unsigned short state; /* channel program state: S_XXXX */
unsigned short status; /* controller status */
short usel; /* unit selected (0-3, -1=none) */
short dmachan; /* dma channel selected */
short dmanch; /* number of dma channels-1 */
struct {
int rtfd; /* read trace file descriptor */
unsigned short theads; /* total heads (cfg file) */
unsigned short spt; /* sectors per track */
unsigned short curtrack; /* current head position */
int devfd; /* Unix device file descriptor */
int readnum; /* increments on each read */
unsigned char** modrecs; /* hash table of modified records */
} unit[MAXDRIVES];
} dc[64];
short i,u;
/* temps for running channel programs */
unsigned short order;
unsigned short m,m1,m2;
short head, track, rec, recsize, nwords;
unsigned short dmareg, dmaaddr;
unsigned char *hashp;
/* NOTE: this iobuf size looks suspicious; probably should be 2080 bytes,
the largest disk record size, and there probably should be some checks
that no individual DMA exceeds this size, that no individual disk
read or write exceeds 1040 words. Maybe it's 4096 bytes because this
is the largest DMA transfer request size... */
unsigned short iobuf[4096]; /* local I/O buf (for mapped I/O) */
unsigned short *iobufp;
unsigned short access;
short dmanw, dmanw1, dmanw2;
unsigned int utempl;
char ordertext[8];
int theads, spt, phyra, phyra2;
int nb; /* number of bytes returned from read/write */
char devfile[8];
char rtfile[16]; /* read trace file name */
int rtnw; /* total number of words read (all channels) */
//traceflags |= TB_DIO;
switch (class) {
case -1:
#ifdef DISKSAFE
printf("em: Running in DISKSAFE mode; no changes will be permanent\n");
#endif
for (i=0; i<64; i++) {
dc[i].state = S_HALT;
dc[i].status = 0100000;
dc[i].usel = -1;
for (u=0; u<MAXDRIVES; u++) {
dc[i].unit[u].rtfd = -1;
dc[i].unit[u].theads = 40;
dc[i].unit[u].spt = 9;
dc[i].unit[u].curtrack = 0;
dc[i].unit[u].devfd = -1;
dc[i].unit[u].readnum = -1;
dc[i].unit[u].modrecs = NULL;
}
}
return 0;
case 0:
TRACE(T_INST|T_DIO, " OCP '%2o%2o\n", func, device);
if (func == 016) { /* reset interrupt */
if (dc[device].state == S_INT) {
dc[device].state = S_RUN;
devpoll[device] = 1;
}
} else if (func == 017) { /* reset controller */
dc[device].state = S_HALT;
dc[device].status = 0100000;
dc[device].usel = -1;
} else {
printf(" Unrecognized OCP '%2o%2o\n", func, device);
fatal(NULL);
}
break;
case 1:
TRACE(T_INST|T_DIO, " SKS '%2o%2o\n", func, device);
if (func == 04) { /* skip if not interrupting */
if (dc[device].state != S_INT)
IOSKIP;
} else {
printf(" Unrecognized SKS '%2o%2o\n", func, device);
fatal(NULL);
}
break;
case 2:
TRACE(T_INST|T_DIO, " INA '%2o%2o\n", func, device);
/* this turns tracing on when the Primos disk processes initialize */
//traceflags = ~TB_MAP;
/* INA's are only accepted when the controller is not busy */
if (dc[device].state != S_HALT)
return;
if (func == 01) /* read device id, clear A first */
crs[A] = CID4005 + device;
else if (func == 011) /* read device id, don't clear A */
crs[A] |= (CID4005 + device);
else if (func == 017) { /* read OAR */
crs[A] = dc[device].oar;
} else {
printf("Unimplemented INA device '%02o function '%02o\n", device, func);
fatal(NULL);
}
IOSKIP;
break;
case 3:
TRACE(T_INST|T_DIO, " OTA '%02o%02o\n", func, device);
if (func == 017) { /* set OAR (order address register) */
dc[device].state = S_RUN;
dc[device].oar = crs[A];
devpoll[device] = 1;
} else {
printf("Unimplemented OTA device '%02o function '%02o, A='%o\n", device, func, crs[A]);
fatal(NULL);
}
IOSKIP;
break;
case 4: /* poll (run channel program) */
while (dc[device].state == S_RUN) {
m = get16r(dc[device].oar, 0);
m1 = get16r(dc[device].oar+1, 0);
TRACE(T_INST|T_DIO, "\nDIOC %o: %o %o %o\n", dc[device].oar, m, m1, get16r(dc[device].oar+2, 0));
dc[device].oar += 2;
order = m>>12;
/* this is for conditional execution, and needs some work... */
if (m & 04000) { /* "execute if ..." */
if (order == 2 || order == 5 || order == 6)
dc[device].oar++;
continue;
}
switch (order) {
case 0: /* DHLT = Halt */
dc[device].state = S_HALT;
devpoll[device] = 0;
TRACE(T_INST|T_DIO, " channel halted at '%o\n", dc[device].oar);
break;
case 2: /* SFORM = Format */
case 5: /* SREAD = Read */
case 6: /* SWRITE = Write */
dc[device].status &= ~076000; /* clear bits 2-6 */
m2 = get16r(dc[device].oar++, 0);
recsize = m & 017;
track = m1 & 01777;
rec = m2 >> 8; /* # records for format, rec # for R/W */
head = m2 & 077;
u = dc[device].usel;
if (order == 2)
strcpy(ordertext,"Format");
else if (order == 5)
strcpy(ordertext,"Read");
else if (order == 6)
strcpy(ordertext,"Write");
TRACE(T_INST|T_DIO, "%s, head=%d, track=%d, rec=%d, recsize=%d\n", ordertext, head, track, rec, recsize);
if (u == -1) {
fprintf(stderr," Device '%o, order %d with no unit selected\n", device, order);
dc[device].status |= 2; /* select error (right?)... */
break;
}
if (recsize != 0) {
fprintf(stderr," Device '%o, order %d, recsize=%d\n", device, order, recsize);
dc[device].status |= 02000; /* header check (right error?) */
break;
}
if (track != dc[device].unit[u].curtrack) {
fprintf(stderr," Device '%o, order %d at track %d, but already positioned to track %d\n", device, order, track, dc[device].unit[u].curtrack);
dc[device].status |= 4; /* illegal seek */
break;
}
if (dc[device].unit[u].devfd == -1) {
TRACE(T_INST|T_DIO, " Device '%o unit %d not ready\n", device, u);
dc[device].status = 0100001;
} else if (order == 2) {
TRACE(T_INST|T_DIO, " Format order\n");
//fatal("DFORMAT channel order not implemented");
} else { /* order = 5 (read) or 6 (write) */
/* translate head/track/sector to drive record address */
phyra = (track*dc[device].unit[u].theads*dc[device].unit[u].spt) + head*9 + rec;
TRACE(T_INST|T_DIO, " Unix ra=%d, byte offset=%d\n", phyra, phyra*2080);
/* does this record exist in the disk unit hash table? If it does,
we'll do I/O to the hash entry. If it doesn't, then for read,
go to the disk file; for write, make a new hash entry */
hashp = NULL;
#ifdef DISKSAFE
//fprintf(stderr," R/W, modrecs=%p\n", dc[device].unit[u].modrecs);
for (hashp = dc[device].unit[u].modrecs[phyra%HASHMAX]; hashp != NULL; hashp = *((unsigned char **)hashp)) {
//fprintf(stderr," lookup, hashp=%p\n", hashp);
if (phyra == *((int *)(hashp+sizeof(void *))))
break;
}
//fprintf(stderr,"After search, hashp=%p\n", hashp);
if (hashp == NULL)
if (order == 5) { /* read */
#endif
if (lseek(dc[device].unit[u].devfd, phyra*2080, SEEK_SET) == -1) {
perror("Unable to seek drive file");
fatal(NULL);
}
#ifdef DISKSAFE
} else { /* write */
hashp = malloc(1040*2 + sizeof(void*) + sizeof(int));
*(unsigned char **)hashp = dc[device].unit[u].modrecs[phyra%HASHMAX];
*((int *)(hashp+sizeof(void *))) = phyra;
//fprintf(stderr," Write, new hashp = %p, old bucket head = %p\n", hashp, *(unsigned char **)hashp);
dc[device].unit[u].modrecs[phyra%HASHMAX] = hashp;
hashp = hashp + sizeof(void*) + sizeof(int);
}
else
hashp = hashp + sizeof(void*) + sizeof(int);
//fprintf(stderr," Before disk op %d, hashp=%p\n", order, hashp);
#endif
#if 0
if (order == 6) {
dmareg = dc[device].dmachan << 1;
dmanw = regs.sym.regdmx[dmareg];
dmanw = -(dmanw>>4);
dmaaddr = regs.sym.regdmx[dmareg+1];
phyra2 = get16r(dmaaddr+0, 0);
phyra2 = phyra2<<16 | get16r(dmaaddr+1, 0);
if (phyra2 != phyra)
fprintf(stderr,"devdisk: phyra=%d, phyra2=%d; CRA mismatch (dmanw = %d)!\n", phyra, phyra2, dmanw);
}
#endif
while (dc[device].dmanch >= 0) {
dmareg = dc[device].dmachan << 1;
dmanw = regs.sym.regdmx[dmareg];
dmanw = -(dmanw>>4);
dmaaddr = regs.sym.regdmx[dmareg+1];
TRACE(T_INST|T_DIO, " DMA channels: nch-1=%d, ['%o]='%o, ['%o]='%o, nwords=%d\n", dc[device].dmanch, dc[device].dmachan, regs.sym.regdmx[dmareg], dc[device].dmachan+1, dmaaddr, dmanw);
if (order == 5) {
if (crs[MODALS] & 020)
if ((dmaaddr & 01777) || dmanw > 1024)
iobufp = iobuf;
else
iobufp = mem+mapva(dmaaddr, WACC, &access, 0);
else
iobufp = mem+dmaaddr;
if (hashp != NULL) {
memcpy((char *)iobufp, hashp, dmanw*2);
hashp += dmanw*2;
} else if ((nb=read(dc[device].unit[u].devfd, (char *)iobufp, dmanw*2)) != dmanw*2) {
fprintf(stderr, "Disk read error: device='%o, u=%d, fd=%d, nb=%d\n", device, u, dc[device].unit[u].devfd, nb);
if (nb == -1) perror("Unable to read drive file");
memset((char *)iobufp, 0, dmanw*2);
}
if (iobufp == iobuf)
for (i=0; i<dmanw; i++)
put16r(iobuf[i], dmaaddr+i, 0);
} else {
if (crs[MODALS] & 020) {
iobufp = iobuf;
for (i=0; i<dmanw; i++)
iobuf[i] = get16r(dmaaddr+i, 0);
} else
iobufp = mem+dmaaddr;
if (hashp != NULL) {
memcpy(hashp, (char *)iobufp, dmanw*2);
hashp += dmanw*2;
} else if (write(dc[device].unit[u].devfd, (char *)iobufp, dmanw*2) != dmanw*2) {
perror("Unable to write drive file");
fatal(NULL);
}
}
regs.sym.regdmx[dmareg] = 0;
regs.sym.regdmx[dmareg+1] += dmanw;
dc[device].dmachan += 2;
dc[device].dmanch--;
}
}
break;
case 3: /* SSEEK = Seek */
u = dc[device].usel;
if (u == -1) {
fprintf(stderr," Device '%o, order %d with no unit selected\n", device, order);
dc[device].status |= 2; /* select error (right?)... */
break;
}
if (m1 & 0100000) {
track = 0;
dc[device].status &= ~4; /* clear bit 14: seek error */
} else {
track = m1 & 01777;
}
TRACE(T_INST|T_DIO, " seek track %d, restore=%d, clear=%d\n", track, (m1 & 0100000) != 0, (m1 & 040000) != 0);
dc[device].unit[u].curtrack = track;
break;
case 4: /* DSEL = Select unit */
u = (m1 & 017); /* get unit bits */
if (u == 0) {
dc[device].usel = -1; /* de-select */
TRACE(T_INST|T_DIO, " de-select\n");
break;
}
dc[device].status &= ~3; /* clear 15-16: select err + unavailable */
if (u != 1 && u != 2 && u != 4 && u != 8) {
fprintf(stderr," Device '%o, bad select '%o\n", device, u);
dc[device].usel = -1; /* de-select */
dc[device].status != 2; /* set bit 15: select error */
break;
}
u = u >> 1; /* unit => 0/1/2/4 */
if (u == 4) u = 3; /* unit => 0/1/2/3 */
TRACE(T_INST|T_DIO, " select unit %d\n", u);
dc[device].usel = u;
if (dc[device].unit[u].devfd == -1) {
snprintf(devfile,sizeof(devfile),"dev%ou%d", device, u);
TRACE(T_INST|T_DIO, " filename for dev '%o unit %d is %s\n", device, u, devfile);
/* NOTE: add O_CREAT to allow creating new drives on the fly */
if ((dc[device].unit[u].devfd = open(devfile, O_RDWR, 0770)) == -1) {
fprintf(stderr,"em: unable to open disk device file %s for device '%o unit %d; flagging \n", devfile, device, u);
dc[device].status = 0100001; /* not ready */
} else {
#ifdef DISKSAFE
dc[device].unit[u].modrecs = calloc(HASHMAX, sizeof(void *));
//fprintf(stderr," Device '%o, unit %d, modrecs=%p\n", device, u, dc[device].unit[u].modrecs);
#endif
}
}
break;
case 7: /* DSTALL = Stall */
TRACE(T_INST|T_DIO, " stall\n");
/* NOTE: technically, the stall command is supposed to wait
210 usecs, so that the disk controller doesn't hog the I/O
bus by looping in a channel program waiting for I/O to
complete. With the emulator, this delay isn't necessary,
although it will cause DIAG tests to fail if the delay is
omitted. Hence the PX test. Ignoring stall gives a 25%
increase in I/O's per second on a 2GHz Mac (8MB emulator). */
if (crs[MODALS] & 010) /* PX enabled? */
break; /* yes, no stall */
devpoll[device] = instpermsec/5; /* 200 microseconds, sb 210 */
return;
case 9: /* DSTAT = Store status to memory */
TRACE(T_INST|T_DIO, " store status='%o to '%o\n", dc[device].status, m1);
put16r(dc[device].status,m1,0);
break;
case 11: /* DOAR = Store OAR to memory (2 words) */
TRACE(T_INST|T_DIO, " store OAR='%o to '%o\n", dc[device].oar, m1);
put16r(dc[device].oar,m1,0);
break;
case 13: /* SDMA = select DMA channel(s) to use */
dc[device].dmanch = m & 017;
dc[device].dmachan = m1;
TRACE(T_INST|T_DIO, " set DMA channels, nch-1=%d, channel='%o\n", dc[device].dmanch, dc[device].dmachan);
break;
case 14: /* DINT = generate interrupt through vector address */
TRACE(T_INST|T_DIO, " interrupt through '%o\n", m1);
if (intvec >= 0 || !(crs[MODALS] & 0100000) || inhcount > 0)
dc[device].oar -= 2; /* can't take interrupt right now */
else {
intvec = m1;
dc[device].state = S_INT;
}
//traceflags = ~TB_MAP;
devpoll[device] = 10;
return;
case 15: /* DTRAN = channel program jump */
dc[device].oar = m1;
TRACE(T_INST|T_DIO, " jump to '%o\n", m1);
break;
default:
/* NOTE: orders 1 & 8 are supposed to halt the channel program
but leave the controller busy (model 4004).
Orders 10 & 12 (Store/Load) are not implemented */
printf("Unrecognized channel order = %d\n", order);
fatal(NULL);
}
}
}
}
/*
AMLC I/O operations:
OCP '0054 - stop clock
OCP '0154 - single step clock
OCP '1234 - set normal/DMT mode
OCP '1354 - set diagnostic/DMQ mode
OCP '1554 - enable interrupts
OCP '1654 - disable interrupts
OCP '1754 - initialize AMLC
SKS '0454 - skip if NOT interrupting
INA '0054 - input data set sense bit for all lines (read clear to send)
INA '0754 - input AMLC status and clear (always skips)
INA '1154 - input AMLC controller ID
INA '1454 - input DMA/C channel number
INA '1554 - input DMT/DMQ base address
INA '1654 - input interrupt vector address
OTA '0054 - output line number for INA '0054 (older models only)
OTA '0154 - output line configuration for 1 line
OTA '0254 - output line control for 1 line
OTA '1454 - output DMA/C channel number
OTA '1554 - output DMT/DMQ base address
OTA '1654 - output interrupt vector address
OTA '1754 - output programmable clock constant
Primos AMLC usage:
OCP '17xx
- initialize controller
- clear all registers and flip-flops
- start line clock
- clear all line control bits during the 1st line scan
- responds not ready until 1 line scan is complete
INA '11xx
- read AMLC ID
- emulator always returns '20054 (DMQ, 16 lines)
OTA '17xx
- set AMLC programmable clock constant
- ignored by the emulator
OTA '14xx
- set DMC channel address for double input buffers
- emulator stores in a structure
OCP '13xx
- set dmq mode (used to be "set diagnostic mode")
- ignored by the emulator
OTA '15xx
- set DMT Base Address
- also used for DMQ address?
- emulator stores in a structure
OTA '16xx
- set interrupt vector address
- emulator stores in a structure
OTA '01xx
- set line configuration
- emulator ignores: all lines are 8-bit raw
OTA '02xx
- set line control
- emulator ignores: all lines are enabled
OCP '15xx/'16xx
- enable/disable interrupts
- emulator stores in a structure
*/
int devamlc (int class, int func, int device) {
#define MAXLINES 128
#define MAXFD MAXLINES+20
#define MAXBOARDS 8
/* AMLC poll rate in milliseconds */
#define AMLCPOLL 50
#if 1
#define QAMLC 020000 /* this is to enable QAMLC/DMQ functionality */
#else
#define QAMLC 0
#endif
static short inited = 0;
static short devices[MAXBOARDS]; /* list of AMLC devices initialized */
static int tsfd; /* socket fd for terminal server */
static struct { /* maps socket fd to device & line */
int device;
int line;
} socktoline[MAXLINES];
static struct {
char dmqmode; /* 0=DMT, 1=DMQ */
char bufnum; /* 0=1st input buffer, 1=2nd */
char eor; /* 1=End of Range on input */
unsigned short dmcchan; /* DMC channel (for input) */
unsigned short baseaddr; /* DMT/Q base address (for output) */
unsigned short intvector; /* interrupt vector */
char intenable; /* interrupts enabled? */
char interrupting; /* am I interrupting? */
unsigned short xmitenabled; /* 1 bit per line */
unsigned short recvenabled; /* 1 bit per line */
unsigned short ctinterrupt; /* 1 bit per line */
unsigned short dss; /* 1 bit per line */
unsigned short sockfd[16]; /* Unix socket fd, 1 per line */
} dc[64];
int lx;
unsigned short utempa;
unsigned int utempl;
ea_t qcbea, dmcea, dmcbufbegea, dmcbufendea;
unsigned short dmcnw;
int dmcpair;
int optval;
int tsflags;
struct sockaddr_in addr;
int fd;
unsigned int addrlen;
unsigned char buf[1024];
int i, n, nw, newdevice;
switch (class) {
case -1:
/* this part of initialization only occurs once, no matter how many
AMLC boards are configured */
if (!inited) {
for (i=0; i<MAXBOARDS; i++)
devices[i] = 0;
if (tport != 0) {
tsfd = socket(AF_INET, SOCK_STREAM, 0);
if (tsfd == -1) {
perror("socket failed for AMLC");
fatal(NULL);
}
optval = 1;
if (setsockopt(tsfd, SOL_SOCKET, SO_REUSEADDR, &optval, sizeof(optval))) {
perror("setsockopt failed for AMLC");
fatal(NULL);
}
addr.sin_family = AF_INET;
addr.sin_port = htons(tport);
addr.sin_addr.s_addr = INADDR_ANY;
if(bind(tsfd, (struct sockaddr *)&addr, sizeof(addr))) {
perror("bind: unable to bind for AMLC");
fatal(NULL);
}
if(listen(tsfd, 10)) {
perror("listen failed for AMLC");
fatal(NULL);
}
if (fcntl(tsfd, F_GETFL, tsflags) == -1) {
perror("unable to get ts flags for AMLC");
fatal(NULL);
}
tsflags |= O_NONBLOCK;
if (fcntl(tsfd, F_SETFL, tsflags) == -1) {
perror("unable to set ts flags for AMLC");
fatal(NULL);
}
} else
printf("-tport is zero, can't start AMLC devices");
inited = 1;
}
/* this part of initialization occurs for every AMLC board */
if (!inited)
return -1;
/* add this device to the devices array, in the proper slot
so we can tell what order the boards should be in */
switch (device) {
case 054: devices[0] = device; break;
case 053: devices[1] = device; break;
case 052: devices[2] = device; break;
case 035: devices[3] = device; break;
case 015: devices[4] = device; break;
case 016: devices[5] = device; break;
case 017: devices[6] = device; break;
case 032: devices[7] = device; break;
}
return 0;
case 0:
TRACE(T_INST, " OCP '%02o%02o\n", func, device);
//printf(" OCP '%02o%02o\n", func, device);
if (func == 012) { /* set normal (DMT) mode */
dc[device].dmqmode = 0;
} else if (func == 013 && QAMLC) { /* set diagnostic (DMQ) mode */
dc[device].dmqmode = 1;
} else if (func == 015) { /* enable interrupts */
dc[device].intenable = 1;
} else if (func == 016) { /* disable interrupts */
dc[device].intenable = 0;
} else if (func == 017) { /* initialize AMLC */
dc[device].dmqmode = 0;
dc[device].bufnum = 0;
dc[device].dmcchan = 0;
dc[device].baseaddr = 0;
dc[device].intvector = 0;
dc[device].intenable = 0;
dc[device].interrupting = 0;
dc[device].xmitenabled = 0;
dc[device].recvenabled = 0;
dc[device].ctinterrupt = 0;
dc[device].dss = 0; /* NOTE: this is stored inverted: 1=connected */
dc[device].eor = 0;
} else {
printf("Unimplemented OCP device '%02o function '%02o\n", device, func);
fatal(NULL);
}
break;
case 1:
TRACE(T_INST, " SKS '%02o%02o\n", func, device);
if (func == 04) { /* skip if not interrupting */
if (!dc[device].interrupting)
IOSKIP;
} else {
printf("Unimplemented SKS device '%02o function '%02o\n", device, func);
fatal(NULL);
}
break;
case 2:
TRACE(T_INST, " INA '%02o%02o\n", func, device);
if (func == 00) { /* input Data Set Sense (carrier) */
crs[A] = ~dc[device].dss; /* to the outside world, 1 = no carrier*/
IOSKIP;
} else if (func == 07) { /* input AMLC status */
crs[A] = 040000 | (dc[device].bufnum<<8) | (dc[device].intenable<<5) || (dc[device].dmqmode<<4);
if (dc[device].eor) {
crs[A] |= 0100000;
dc[device].eor = 0;
}
if (dc[device].ctinterrupt)
if (dc[device].ctinterrupt & 0xfffe)
crs[A] |= 0xcf; /* multiple char time interrupt */
else
crs[A] |= 0x8f; /* last line cti */
dc[device].interrupting = 0;
//printf("INA '07%02o returns 0x%x\n", device, crs[A]);
IOSKIP;
} else if (func == 011) { /* input ID */
crs[A] = QAMLC | 054;
IOSKIP;
} else {
printf("Unimplemented INA device '%02o function '%02o\n", device, func);
fatal(NULL);
}
break;
case 3:
TRACE(T_INST, " OTA '%02o%02o\n", func, device);
if (func == 01) { /* set line configuration */
lx = crs[A] >> 12;
//printf("OTA '01%02o: AMLC line %d config = %x\n", device, lx, crs[A]);
/* if DTR drops on a connected line, disconnect */
if (!(crs[A] & 0x400) && (dc[device].dss & bitmask16[lx+1])) {
/* see similar code below */
write(dc[device].sockfd[lx], "\r\nDisconnecting logged out session\r\n", 36);
close(dc[device].sockfd[lx]);
dc[device].dss &= ~bitmask16[lx+1];
printf("em: closing AMLC line %d on device '%o\n", lx, device);
}
IOSKIP;
} else if (func == 02) { /* set line control */
//printf("OTA '02%02o: AMLC line control = %x\n", device, crs[A]);
lx = (crs[A]>>12);
if (crs[A] & 040) /* character time interrupt enable/disable */
dc[device].ctinterrupt |= bitmask16[lx+1];
else
dc[device].ctinterrupt &= ~bitmask16[lx+1];
if (crs[A] & 010) /* transmit enable/disable */
dc[device].xmitenabled |= bitmask16[lx+1];
else
dc[device].xmitenabled &= ~bitmask16[lx+1];
if (crs[A] & 01) /* receive enable/disable */
dc[device].recvenabled |= bitmask16[lx+1];
else
dc[device].recvenabled &= ~bitmask16[lx+1];
if ((dc[device].ctinterrupt || dc[device].xmitenabled || dc[device].recvenabled) && devpoll[device] == 0)
devpoll[device] = AMLCPOLL*instpermsec; /* setup another poll */
IOSKIP;
} else if (func == 014) { /* set DMA/C channel (for input) */
dc[device].dmcchan = crs[A] & 0x7ff;
//printf("OTA '14%02o: AMLC chan = %o\n", device, dc[device].dmcchan);
if (!(crs[A] & 0x800))
fatal("Can't run AMLC in DMA mode!");
IOSKIP;
} else if (func == 015) { /* set DMT/DMQ base address (for output) */
dc[device].baseaddr = crs[A];
IOSKIP;
} else if (func == 016) { /* set interrupt vector */
dc[device].intvector = crs[A];
IOSKIP;
} else if (func == 017) { /* set programmable clock constant */
IOSKIP;
} else {
printf("Unimplemented OTA device '%02o function '%02o, A='%o\n", device, func, crs[A]);
fatal(NULL);
}
break;
case 4:
//printf("poll device '%o, cti=%x, xmit=%x, recv=%x, dss=%x\n", device, dc[device].ctinterrupt, dc[device].xmitenabled, dc[device].recvenabled, dc[device].dss);
/* check for new connections */
conloop:
while ((fd = accept(tsfd, (struct sockaddr *)&addr, &addrlen)) == -1 && errno == EINTR)
;
if (fd == -1) {
if (errno != EWOULDBLOCK) {
perror("accept error for AMLC");
fatal("accept error for AMLC");
}
} else {
if (fd >= MAXFD)
fatal("New connection fd is too big");
newdevice = 0;
for (i=0; !newdevice && i<MAXBOARDS; i++)
if (devices[i])
for (lx=0; lx<16; lx++)
if (!(dc[devices[i]].dss & bitmask16[lx+1])) {
newdevice = devices[i];
socktoline[fd].device = newdevice;
socktoline[fd].line = lx;
dc[newdevice].dss |= bitmask16[lx+1];
dc[newdevice].sockfd[lx] = fd;
printf("em: AMLC connection, fd=%d, device='%o, line=%d\n", fd, newdevice, lx);
break;
}
if (!newdevice) {
warn("No free AMLC connection");
write(fd, "\rAll AMLC lines are in use!\r\n", 29);
close(fd);
}
goto conloop;
}
/* do a receive/transmit scan loop for every line
NOTE: should probably do a read & write select to find lines to
process */
for (lx = 0; lx < 16; lx++) {
/* Transmit is first. Lots of opportunity to optimize this
by doing one or two mapva calls, directly examining the queue,
doing the write (which may be partial), then updating the queue
for however many characters were actually sent. */
if (dc[device].xmitenabled & bitmask16[lx+1]) {
n = 0;
if (dc[device].dmqmode) {
qcbea = dc[device].baseaddr + lx*4;
if (dc[device].dss & bitmask16[lx+1]) {
while (n < sizeof(buf) && rtq(qcbea, &utempa, 0)) {
if (utempa & 0x8000) { /* valid character */
//printf("Device %o, line %d, entry=%o (%c)\n", device, lx, utempa, utempa & 0x7f);
buf[n++] = utempa & 0x7F;
}
}
} else { /* no line connected, just drain queue */
//printf("Draining output queue on line %d\n", lx);
put16r(get16r(qcbea, 0), qcbea+1, 0);
}
} else { /* DMT */
utempa = get16r(dc[device].baseaddr + lx, 0);
if (utempa != 0) {
if ((utempa & 0x8000) && (dc[device].dss & bitmask16[lx+1])) {
//printf("Device %o, line %d, entry=%o (%c)\n", device, lx, utempa, utempa & 0x7f);
buf[n++] = utempa & 0x7F;
}
put16r(0, dc[device].baseaddr + lx, 0);
}
/* need to setup DMT xmit poll here, and/or look for char
time interrupt */
}
/* NOTE: probably need to check for partial writes here, or put the
socket in blocking mode. Would be best to know how many characters
to remove from the queue in the loop above. */
if (n > 0)
if ((nw = write(dc[device].sockfd[lx], buf, n)) != n) {
perror("Writing to AMLC");
fatal("Writing to AMLC");
}
}
/* process input, but only as much as will fit into the DMC buffer */
if ((dc[device].dss & dc[device].recvenabled & bitmask16[lx+1]) && !dc[device].eor) {
if (dc[device].bufnum)
dmcea = dc[device].dmcchan ^ 2;
else
dmcea = dc[device].dmcchan;
dmcpair = get32r(dmcea, 0);
dmcbufbegea = dmcpair>>16;
dmcbufendea = dmcpair & 0xffff;
dmcnw = dmcbufendea - dmcbufbegea + 1;
if (dmcnw <= 0)
continue;
if (dmcnw > sizeof(buf))
dmcnw = sizeof(buf);
while ((n = read(dc[device].sockfd[lx], buf, dmcnw)) == -1 && errno == EINTR)
;
//printf("processing recv on device %o, line %d, b#=%d, dmcnw=%d, n=%d\n", device, lx, dc[device].bufnum, dmcnw, n);
/* zero length read means the socket has been closed */
if (n == 0) {
n = -1;
errno = EPIPE;
}
if (n == -1) {
n = 0;
if (errno == EAGAIN || errno == EWOULDBLOCK)
;
else if (errno == EPIPE) {
/* see similar code above */
close(dc[device].sockfd[lx]);
dc[device].dss &= ~bitmask16[lx+1];
printf("Closing AMLC line %d on device '%o\n", lx, device);
} else {
perror("Reading AMLC");
fatal("Reading AMLC");
}
}
if (n > 0) {
for (i=0; i<n; i++) {
utempa = lx<<12 | 0x0200 | buf[i];
put16r(utempa, dmcbufbegea, 0);
//printf("******* stored character %o (%c) at %o\n", utempa, utempa&0x7f, dmcbufbegea);
dmcbufbegea = INCVA(dmcbufbegea, 1);
}
put16r(dmcbufbegea, dmcea, 0);
if (dmcbufbegea > dmcbufendea) { /* end of range has occurred */
dc[device].bufnum = 1-dc[device].bufnum;
dc[device].eor = 1;
}
}
}
}
if (intvec == -1 && dc[device].intenable && (dc[device].ctinterrupt || dc[device].eor)) {
intvec = dc[device].intvector;
dc[device].interrupting = 1;
}
if ((dc[device].ctinterrupt || dc[device].xmitenabled || dc[device].recvenabled) && devpoll[device] == 0)
devpoll[device] = AMLCPOLL*instpermsec; /* setup another poll */
break;
}
}
/* PNC (ring net) device handler
PNC ring buffers are 256 words (later version appear to support 256,
512, and 1024 word packets). "nbkini" (rev 18) allocates 12 ring
buffers + 1 for every 2 nodes in the ring. Both the 1-to-2 queue
for received packets, and 2-to-1 queue for xmit packets have 63
entries. PNC ring buffers are wired and do not cross page
boundaries.
The actual xmit/recv buffers for PNC are 256 words, and each buffer
has an associated "block header", stored in a different location in
system memory, that is 8 words.
The BH fields are (16-bit words):
0: type field (1)
1: free pool id (3 for ring buffers)
2-3: pointer to data block
4-7 are available for use by the drivers. For PNC:
4: number of words received (calculated by pncdim based on DMA regs)
or number of
5: receive status word
6: data 1
7: data 2
The PNC data buffer has a 2-word header:
0: To (left) and From (right) bytes containing node-id
1: "Type" word.
Bit 1 set = odd number of bytes
Bit 8 set = normal data messages (otherwise, a timer message)
Primos PNC usage:
OCP '0007
- disconnect from ring
OCP '0207
- inject a token into the ring
OCP '0507
- set PNC into "delay" mode (token recovery BS)
OCP '1007
- stop any xmit in progress
INA '1707
- read PNC status word
- does this in a loop until "connected" bit is clear after disconnect above
- PNC status word:
bit 1 set if receive interrupt (rcv complete)
bit 2 set if xmit interrupt (xmit complete)
bit 3 set if "PNC booster" (repeater?)
bit 4-5 not used
bit 6 set if connected to ring
bit 7 set if multiple tokens detected (only after xmit EOR)
bit 8 set if token detected (only after xmit EOR)
bits 9-16 controller node ID
INA '1207
- read receive status word (byte?)
bit 1 set for previous ACK
bit 2 set for multiple previous ACK
bit 3 set for previous WACK
bit 4 set for previous NACK
bits 5-6 unused
bit 7 ACK byte parity error
bit 8 ACK byte check error (parity on bits 1-6)
bit 9 recv buffer parity error
bit 10 recv busy
bit 11 end of range before end of message
INA '1407
- read xmit status word
bit 1 set for ACK
bit 2 set for multiple ACK (more than 1 node accepted packet)
bit 3 set for WACK
bit 4 set for NACK (bad CRC)
bit 5 unused
bit 6 parity bit of ACK (PNC only)
bit 7 ACK byte parity error
bit 8 ACK byte check error (parity on bits 1-6)
bit 9 xmit buffer parity error
bit 10 xmit busy
bit 11 packet did not return
bit 12 packet returned with bits 6-8 nonzero
bits 13-16 retry count (booster only, zero on PNC)
OCP '1707
- initialize
OTA '1707
- set my node ID (in A register)
- if this fails, no PNC present
OTA '1607
- set interrupt vector (in A reg)
OTA '1407
- initiate receive, dma channel in A
OTA '1507
- initiate xmit, dma channel in A
OCP '0107
- connect to the ring
- (Primos follows this with INA '1707 until "connected" bit is set)
OCP '1407
- ack receive (clears recv interrupt request)
OCP '0407
- ack xmit (clears xmit interrupt request)
OCP '1507
- set interrupt mask (enable interrupts)
OCP '1107
- rev 20 does this, not sure what it does
*/
int devpnc (int class, int func, int device) {
/* PNC controller status bits */
#define PNCRCVINT 0x8000 /* bit 1 rcv interrupt (rcv complete) */
#define PNCXMITINT 0x4000 /* bit 2 xmit interrupt (xmit complete) */
#define PNCBOOSTER 0x2000 /* bit 3 */
#define PNCINTENAB 0x1000 /* bit 4 (JW usage) */
#define PNCCONNECTED 0x400 /* bit 6 */
#define PNCTWOTOKENS 0x200 /* bit 7, only set after xmit EOR */
#define PNCTOKDETECT 0x100 /* bit 8, only set after xmit EOR */
static short pncstat; /* controller status word */
static short recvstat; /* receive status word */
static short xmitstat; /* xmit status word */
static short intvec; /* PNC interrupt vector */
unsigned short dmachan, dmareg, dmaaddr, dmaword;
short i, dmanw;
//traceflags = ~TB_MAP;
switch (class) {
case -1:
return 0;
case 0:
TRACE(T_INST, " OCP '%02o%02o\n", func, device);
if (func == 00) { /* disconnect from ring */
pncstat &= ~PNCCONNECTED;
} else if (func == 01) { /* connect to the ring */
pncstat |= PNCCONNECTED;
} else if (func == 02) { /* inject a token */
;
} else if (func == 04) { /* ack xmit (clear xmit int) */
pncstat &= ~PNCXMITINT;
xmitstat = 0; /* right? */
} else if (func == 05) { /* set PNC into "delay" mode */
printf("Set PNC to delay mode\n");
} else if (func == 010) { /* stop xmit in progress */
xmitstat = 0;
} else if (func == 011) { /* dunno what this is - rev 20 startup */
;
} else if (func == 012) { /* set normal mode */
;
} else if (func == 013) { /* set diagnostic mode */
;
} else if (func == 014) { /* ack receive (clear rcv int) */
pncstat &= ~PNCRCVINT;
recvstat = 0; /* right? */
} else if (func == 015) { /* set interrupt mask (enable int) */
pncstat |= PNCINTENAB;
} else if (func == 016) { /* clear interrupt mask (disenable int) */
pncstat &= ~PNCINTENAB;
} else if (func == 017) { /* initialize */
pncstat = 0;
recvstat = 0;
xmitstat = 0;
intvec = 0;
} else {
printf("Unimplemented OCP device '%02o function '%02o\n", device, func);
fatal(NULL);
}
break;
case 1:
TRACE(T_INST, " SKS '%02o%02o\n", func, device);
if (func == 99)
IOSKIP; /* assume it's always ready */
else {
printf("Unimplemented SKS device '%02o function '%02o\n", device, func);
fatal(NULL);
}
break;
case 2:
TRACE(T_INST, " INA '%02o%02o\n", func, device);
if (func == 011) { /* input ID */
crs[A] = 07;
IOSKIP;
} else if (func == 012) { /* read receive status word */
crs[A] = recvstat;
IOSKIP;
} else if (func == 014) { /* read xmit status word */
crs[A] = xmitstat;
IOSKIP;
} else if (func == 017) { /* read controller status word */
crs[A] = pncstat;
IOSKIP;
} else {
printf("Unimplemented INA device '%02o function '%02o\n", device, func);
fatal(NULL);
}
break;
case 3:
TRACE(T_INST, " OTA '%02o%02o\n", func, device);
if (func == 014) { /* initiate recv, dma chan in A */
dmachan = crs[A];
dmareg = dmachan << 1;
dmanw = regs.sym.regdmx[dmareg];
dmanw = -(dmanw>>4);
dmaaddr = regs.sym.regdmx[dmareg+1];
printf("PNC recv: dmachan=%o, dmareg=%o, dmaaddr=%o, dmanw=%d\n", dmachan, dmareg, dmaaddr, dmanw);
IOSKIP;
} else if (func == 015) { /* initiate xmit, dma chan in A */
dmachan = crs[A];
dmareg = dmachan<<1;
dmanw = regs.sym.regdmx[dmareg];
dmanw = -(dmanw>>4);
dmaaddr = regs.sym.regdmx[dmareg+1];
printf("PNC xmit: dmachan=%o, dmareg=%o, dmaaddr=%o, dmanw=%d\n", dmachan, dmareg, dmaaddr, dmanw);
for (i=0; i<dmanw; i++) {
dmaword = get16(dmaaddr+i);
printf("PNC xmit: word %d = '%o/%d [%o %o]\n", i, dmaword, *(short *)&dmaword, dmaword>>8, dmaword&0xff);
}
IOSKIP;
} else if (func == 016) { /* set interrupt vector */
intvec = crs[A];
IOSKIP;
} else if (func == 017) { /* set my node ID */
pncstat = (pncstat & 0xFF00) | (crs[A] & 0xFF);
IOSKIP;
} else {
printf("Unimplemented OTA device '%02o function '%02o, A='%o\n", device, func, crs[A]);
fatal(NULL);
}
break;
}
}
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