/* h316_mi.c- BBN ARPAnet IMP/TIP Modem Interface | |
Based on the SIMH simulator package written by Robert M Supnik. | |
Copyright (c) 2013 Robert Armstrong, bob@jfcl.com. | |
Permission is hereby granted, free of charge, to any person obtaining a | |
copy of this software and associated documentation files (the "Software"), | |
to deal in the Software without restriction, including without limitation | |
the rights to use, copy, modify, merge, publish, distribute, sublicense, | |
and/or sell copies of the Software, and to permit persons to whom the | |
Software is furnished to do so, subject to the following conditions: | |
The above copyright notice and this permission notice shall be included in | |
all copies or substantial portions of the Software. | |
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR | |
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, | |
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL | |
ROBERT ARMSTRONG BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER | |
IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN | |
CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. | |
Except as contained in this notice, the name of Robert Armstrong shall not be | |
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REVISION HISTORY | |
mi modem interface | |
21-May-13 RLA New file | |
OVERVIEW | |
The modem interface is one of the BBN engineered devices unique to the | |
ARPAnet IMP/TIP. The original hardware was a full duplex synchronous serial | |
line interface operating at 56k bps. The hardware was fairly smart and was | |
able to handle line synchronization (SYN), packet start (STX) and end (ETX), | |
and data escape (DLE) autonomously. Data is transferred directly to and | |
from H316 main memory using the DMC mechanism. The modem interface also | |
calculated a 24 bit "parity" (and by that I assume they meant some form of | |
CRC) value. This was automatically appended to the end of the transmitted | |
data and automatically verified by the receiving modem. | |
CONNECTIONS | |
This module provides two basic options for emulating the modem. Option 1 | |
takes the data packets from H316 memory, wraps them in a UDP packet, and | |
sends them to another simh instance. The remote simh then unwraps the data | |
packet and loads it directly into H316 memory. In this instance, | |
synchronization, start of text/end of text, and data escapes are pointless | |
and are not used. The words are simply moved verbatim from one H316 to | |
another. | |
The other option is to logically connect the emulated modem to a physical | |
serial port on this PC. In that case we attempt to emulate the actions | |
of the original modem as closely as possible, including the synchronization, | |
start of text/end of text and data escape characters. Synchronization is | |
pointless on an asynchronous interface, of course, but we do it anyway in | |
the interest of compatability. We also attempt to calculate a 24 bit CRC | |
using (as best I can determine) the same algorithm as the original modems. | |
MULTIPLE INSTANCES | |
Each IMP can support up to five modem lines, and fitting this into simh | |
presents an architectural problem. The temptation is to treat all modems as | |
one device with multiple units (each unit corresponding to one line), but | |
that's a problem. The simh view of units is like a disk or tape - there's | |
a single controller that has one IO address, one interrupt and one DMA/DMC | |
channel. That controller then has multiple units attached to it that are | |
selected by bits in a controller register and all units share the same | |
IO, interrupt and DMA/DMC assignments. | |
The modems aren't like that at all - each of the five cards is completely | |
independent with its own distinct IO address, interrupt and DMC assignments. | |
It's analagous to five instances of the same controller installed in the | |
machine, but simh unfortunately has limited support for multiple instances | |
of the same controller. The few instances of prior art in simh that I can | |
find (e.g. xq, xqb on the PDP11/VAX) have just been done ad hoc by | |
duplicating all the device data. Rather than rewrite simh, that's the | |
approach I took here, even though with five instances it gets awkward. | |
POLLING AND SERVICE | |
The IMP software turns out to be extraordinarily sensitive to modem timing. | |
It actually goes to the trouble of measuring the effective line speed by | |
using the RTC to time how long it takes to send a message, and one thing that | |
especially annoys the IMP are variations in the effective line speed. They | |
had a lot of trouble with AT&T Long Lines back in the Old Days, and the IMP | |
has quite a bit of code to monitor line quality. Even fairly minor variations | |
in speed will cause it to mark the line as "down" and sent a trouble report | |
back to BBN. | |
To combat this, we actually let the RTC code time the transmitter interrupts. | |
When the IMP software does a "start modem output" OCP the entire packet will | |
be extracted from H316 memory and transmitted via UDP at that instant, BUT | |
the transmitter done interrupt will be deferred. The delay is computed from | |
the length of the packet and the simulated line speed, and then the RTC is | |
used to count down the interval. When the time expires, the interrupt request | |
is generated. It's unfortunate to have to couple the RTC and the modem in | |
this way, but since the IMP code is using the RTC to measure the line speed | |
AND since the RTC determines when the transmit done occurs, it guarantees | |
that the IMP always sees exactly the same delay. | |
The modem receiver is completely independent of the transmitter and is polled | |
by the usual simh event queue mechanism and mi_service() routine. When the | |
IMP code executes a "start modem input" OCP a read pending flag is set in the | |
modem status but nothing else occurs. Each poll checks the UDP socket for | |
incoming data and, if a packet was received AND a read operation is pending, | |
then the read completes that moment and the interrupt request is asserted. | |
The UDP socket is polled regardless of whether a read is pending and if data | |
arrives without a read then it's discarded. That's exactly what a real modem | |
would do. | |
ERROR HANDLING | |
Transmitter error handling is easy - fatal errors print a message and abort | |
the simulation, but any other errors are simply ignored. The IMP modems had | |
no kind of error dection on the transmitter side and no way to report them | |
anyway so we do the same. Any data packet associated with the error is just | |
discarded. In particular with both UDP and COM ports there's no way to tell | |
whether anybody is on the other end listening, so even packets that are | |
successfully transmitted may disappear into the ether. This isn't a problem | |
for the IMP - the real world was like that too and the IMP is able to handle | |
retransmitting packets without our help. | |
Receiver errors set the error flag in the modem status; this flag can be | |
tested and cleared by the "skip on modem error" SKS instruction. The only | |
receiver error that can be detected is buffer overrun (i.e. the sender's | |
message was longer than the receiver's buffer). With a serial connection | |
checksum errors are also possible, but those never occur with UDP. | |
Transmitting or receiving on a modem that's not attached isn't an error - it | |
simply does nothing. It's analogous to a modem with the phone line unplugged. | |
Hard I/O errors for UDP or COM ports print an error message and then detach | |
the modem connection. It's up to the user to interrupt the simulation and | |
reattach if he wants to try again. | |
STATE | |
Modem state is maintained in the following variables - | |
RXPOLL 24 receiver polling interval | |
RXPEND 1 an input operation is pending | |
RXERR 1 receiver error flag | |
RXIEN 1 receiver interrupt enable | |
RXIRQ 1 receiver interrupt request | |
RXTOT 32 count of total messages received | |
TXDLY 32 RTC ticks until TX done interrupt | |
TXIEN 1 transmitter interrupt enable | |
TXIRQ 1 transmitter interrupt request | |
TXTOT 32 count of total messages transmitted | |
LINKNO 32 link number for h316_udp module | |
BPS 32 simulated bps for UDP delay calculations | |
actual baud rate for physical COM ports | |
ILOOP 1 interface (local) loopback enabled | |
RLOOP 1 remote (line) loopback enabled | |
Most of these values will be found in the Modem Information Data Block (aka | |
"MIDB") but a few are stored elsewhere (e.g. IRQ/IEN are in the CPU's dev_int | |
and dev_enb vectors). | |
TODO | |
Implement checksum handling | |
Implement remote loopback | |
*/ | |
#ifdef VM_IMPTIP | |
#include "h316_defs.h" // H316 emulator definitions | |
#include "h316_imp.h" // ARPAnet IMP/TIP definitions | |
// Externals from other parts of simh ... | |
extern uint16 dev_ext_int, dev_ext_enb; // current IRQ and IEN bit vectors | |
extern int32 PC; // current PC (for debug messages) | |
extern int32 stop_inst; // needed by IOBADFNC() | |
extern int32 sim_switches; // option bitmap for ATTACH/DETACH | |
extern uint16 M[]; // main memory (for DMC access) | |
// Forward declarations ... | |
int32 mi_io (uint16 line, int32 inst, int32 fnc, int32 dat, int32 dev); | |
int32 mi1_io (int32 inst, int32 fnc, int32 dat, int32 dev); | |
int32 mi2_io (int32 inst, int32 fnc, int32 dat, int32 dev); | |
int32 mi3_io (int32 inst, int32 fnc, int32 dat, int32 dev); | |
int32 mi4_io (int32 inst, int32 fnc, int32 dat, int32 dev); | |
int32 mi5_io (int32 inst, int32 fnc, int32 dat, int32 dev); | |
t_stat mi_rx_service (UNIT *uptr); | |
void mi_rx_local (uint16 line, uint16 txnext, uint16 txcount); | |
t_stat mi_reset (DEVICE *dptr); | |
t_stat mi_attach (UNIT *uptr, char *cptr); | |
t_stat mi_detach (UNIT *uptr); | |
t_stat mi_set_loopback (UNIT *uptr, int32 val, char *cptr, void *desc); | |
t_stat mi_show_loopback (FILE *st, UNIT *uptr, int32 val, void *desc); | |
//////////////////////////////////////////////////////////////////////////////// | |
////////////////////// D A T A S T R U C T U R E S ////////////////////// | |
//////////////////////////////////////////////////////////////////////////////// | |
// simh requires several data structures for every device - a DIB, one or more | |
// UNITS, a modifier table, a register list, and a device definition. The sit- | |
// uation here is even more complicated because we have five identical modems to | |
// define, and so lots of clever macros are used to handle the repetition and | |
// save some typing. | |
// Modem Information Data Blocks ... | |
// The MIDB is our own internal data structure for each modem. It keeps data | |
// about the current state, COM port, UDP connection, etc. | |
#define MI_MIDB(N) {FALSE, FALSE, 0, 0, 0, FALSE, FALSE, NOLINK, MI_TXBPS} | |
MIDB mi1_db = MI_MIDB(1), mi2_db = MI_MIDB(2); | |
MIDB mi3_db = MI_MIDB(3), mi4_db = MI_MIDB(4); | |
MIDB mi5_db = MI_MIDB(5); | |
// Modem Device Information Blocks ... | |
// The DIB is the structure simh uses to keep track of the device IO address | |
// and IO service routine. It can also hold the DMC channel, but we don't use | |
// that because it's unit specific. | |
#define MI_DIB(N) {MI##N, 1, MI##N##_RX_DMC, MI##N##_TX_DMC, \ | |
INT_V_MI##N##RX, INT_V_MI##N##TX, &mi##N##_io, N} | |
DIB mi1_dib = MI_DIB(1), mi2_dib = MI_DIB(2); | |
DIB mi3_dib = MI_DIB(3), mi4_dib = MI_DIB(4); | |
DIB mi5_dib = MI_DIB(5); | |
// Modem Device Unit data ... | |
// simh uses the unit data block primarily to schedule device service events. | |
#define mline u3 // our modem line number is stored in user data 3 | |
#define MI_UNIT(N) {UDATA (&mi_rx_service, UNIT_ATTABLE, 0), MI_RXPOLL, N, 0, 0, 0} | |
UNIT mi1_unit = MI_UNIT(1), mi2_unit = MI_UNIT(2); | |
UNIT mi3_unit = MI_UNIT(3), mi4_unit = MI_UNIT(4); | |
UNIT mi5_unit = MI_UNIT(5); | |
// Modem Device Registers ... | |
// These are the simh device "registers" - they c can be viewed with the | |
// "EXAMINE MIn STATE" command and modified by "DEPOSIT MIn ..." | |
#define MI_REG(N) { \ | |
{ DRDATA (RXPOLL, mi##N##_unit.wait, 24), REG_NZ + PV_LEFT }, \ | |
{ FLDATA (RXPEND, mi##N##_db.rxpending, 0), REG_RO + PV_RZRO }, \ | |
{ FLDATA (RXERR, mi##N##_db.rxerror, 0), PV_RZRO }, \ | |
{ FLDATA (RXIEN, dev_ext_enb, INT_V_MI##N##RX-INT_V_EXTD) }, \ | |
{ FLDATA (RXIRQ, dev_ext_int, INT_V_MI##N##RX-INT_V_EXTD) }, \ | |
{ DRDATA (RXTOT, mi##N##_db.rxtotal, 32), REG_RO + PV_LEFT }, \ | |
{ DRDATA (TXDLY, mi##N##_db.txdelay, 32), PV_LEFT }, \ | |
{ FLDATA (TXIEN, dev_ext_enb, INT_V_MI##N##TX-INT_V_EXTD) }, \ | |
{ FLDATA (TXIRQ, dev_ext_int, INT_V_MI##N##TX-INT_V_EXTD) }, \ | |
{ DRDATA (TXTOT, mi##N##_db.txtotal, 32), REG_RO + PV_LEFT }, \ | |
{ DRDATA (LINK, mi##N##_db.link, 32), REG_RO + PV_LEFT }, \ | |
{ DRDATA (BPS, mi##N##_db.bps, 32), REG_NZ + PV_LEFT }, \ | |
{ FLDATA (LLOOP, mi##N##_db.lloop, 0), REG_RO + PV_RZRO }, \ | |
{ FLDATA (ILOOP, mi##N##_db.iloop, 0), REG_RO + PV_RZRO }, \ | |
{ NULL } \ | |
} | |
REG mi1_reg[] = MI_REG(1), mi2_reg[] = MI_REG(2); | |
REG mi3_reg[] = MI_REG(3), mi4_reg[] = MI_REG(4); | |
REG mi5_reg[] = MI_REG(5); | |
// Modem Device Modifiers ... | |
// These are the modifiers simh uses for the "SET MIn" and "SHOW MIn" commands. | |
#define MI_MOD(N) { \ | |
{ MTAB_XTD|MTAB_VDV, 0, "LOOPBACK", "LOOPINTERFACE", &mi_set_loopback, &mi_show_loopback, NULL }, \ | |
{ MTAB_XTD|MTAB_VDV, 1, NULL, "NOLOOPINTERFACE", &mi_set_loopback, NULL, NULL }, \ | |
{ MTAB_XTD|MTAB_VDV, 2, NULL, "LOOPLINE", &mi_set_loopback, NULL, NULL }, \ | |
{ MTAB_XTD|MTAB_VDV, 3, NULL, "NOLOOPLINE", &mi_set_loopback, NULL, NULL }, \ | |
{ 0 } \ | |
} | |
MTAB mi1_mod[] = MI_MOD(1), mi2_mod[] = MI_MOD(2); | |
MTAB mi3_mod[] = MI_MOD(3), mi4_mod[] = MI_MOD(4); | |
MTAB mi5_mod[] = MI_MOD(5); | |
// Debug modifiers for "SET MIn DEBUG = xxx" ... | |
DEBTAB mi_debug[] = { | |
{"WARN", IMP_DBG_WARN}, // print warnings that would otherwise be suppressed | |
{"UDP", IMP_DBG_UDP}, // print all UDP messages sent and received | |
{"IO", IMP_DBG_IOT}, // print all program I/O instructions | |
{"MSG", MI_DBG_MSG}, // decode and print all messages | |
{0} | |
}; | |
// Modem Device data ... | |
// This is the primary simh structure that defines each device - it gives the | |
// plain text name, the addresses of the unit, register and modifier tables, and | |
// the addresses of all action routines (e.g. attach, reset, etc). | |
#define MI_DEV(MI,N,F) { \ | |
#MI, &mi##N##_unit, mi##N##_reg, mi##N##_mod, \ | |
1, 10, 31, 1, 8, 8, \ | |
NULL, NULL, &mi_reset, NULL, &mi_attach, &mi_detach, \ | |
&mi##N##_dib, DEV_DISABLE|DEV_DEBUG|(F), 0, mi_debug, NULL, NULL \ | |
} | |
DEVICE mi1_dev = MI_DEV(MI1,1,DEV_DIS), mi2_dev = MI_DEV(MI2,2,DEV_DIS); | |
DEVICE mi3_dev = MI_DEV(MI3,3,DEV_DIS), mi4_dev = MI_DEV(MI4,4,DEV_DIS); | |
DEVICE mi5_dev = MI_DEV(MI5,5,DEV_DIS); | |
// Modem Tables ... | |
// These tables make it easy to locate the data associated with any line. | |
DEVICE *const mi_devices[MI_NUM] = {&mi1_dev, &mi2_dev, &mi3_dev, &mi4_dev, &mi5_dev }; | |
UNIT *const mi_units [MI_NUM] = {&mi1_unit, &mi2_unit, &mi3_unit, &mi4_unit, &mi5_unit}; | |
DIB *const mi_dibs [MI_NUM] = {&mi1_dib, &mi2_dib, &mi3_dib, &mi4_dib, &mi5_dib }; | |
MIDB *const mi_midbs [MI_NUM] = {&mi1_db, &mi2_db, &mi3_db, &mi4_db, &mi5_db }; | |
//////////////////////////////////////////////////////////////////////////////// | |
////////////////// L O W L E V E L F U N C T I O N S /////////////////// | |
//////////////////////////////////////////////////////////////////////////////// | |
// Find a pointer to the DEVICE, UNIT, DIB or MIDB given the line number ... | |
#define PDEVICE(l) mi_devices[(l)-1] | |
#define PUNIT(l) mi_units[(l)-1] | |
#define PDIB(l) mi_dibs[(l)-1] | |
#define PMIDB(l) mi_midbs[(l)-1] | |
// These macros set and clear the interrupt request and enable flags ... | |
#define SET_RX_IRQ(l) SET_EXT_INT((1u << (PDIB(l)->rxint - INT_V_EXTD))) | |
#define SET_TX_IRQ(l) SET_EXT_INT((1u << (PDIB(l)->txint - INT_V_EXTD))) | |
#define CLR_RX_IRQ(l) CLR_EXT_INT((1u << (PDIB(l)->rxint - INT_V_EXTD))) | |
#define CLR_TX_IRQ(l) CLR_EXT_INT((1u << (PDIB(l)->txint - INT_V_EXTD))) | |
#define CLR_RX_IEN(l) CLR_EXT_ENB((1u << (PDIB(l)->rxint - INT_V_EXTD))) | |
#define CLR_TX_IEN(l) CLR_EXT_ENB((1u << (PDIB(l)->txint - INT_V_EXTD))) | |
// TRUE if the line has the specified debugging output enabled ... | |
#define ISLDBG(l,f) ((PDEVICE(l)->dctrl & (f)) != 0) | |
// Reset receiver (clear flags AND initialize all data) ... | |
void mi_reset_rx (uint16 line) | |
{ | |
PMIDB(line)->iloop = PMIDB(line)->lloop = FALSE; | |
udp_set_link_loopback (PDEVICE(line), PMIDB(line)->link, FALSE); | |
PMIDB(line)->rxerror = PMIDB(line)->rxpending = FALSE; | |
PMIDB(line)->rxtotal = 0; | |
CLR_RX_IRQ(line); CLR_RX_IEN(line); | |
} | |
// Reset transmitter (clear flags AND initialize all data) ... | |
void mi_reset_tx (uint16 line) | |
{ | |
PMIDB(line)->iloop = PMIDB(line)->lloop = FALSE; | |
udp_set_link_loopback (PDEVICE(line), PMIDB(line)->link, FALSE); | |
PMIDB(line)->txtotal = PMIDB(line)->txdelay = 0; | |
CLR_TX_IRQ(line); CLR_TX_IEN(line); | |
} | |
// Get the DMC control words (starting address, end and length) for the channel. | |
void mi_get_dmc (uint16 dmc, uint16 *pnext, uint16 *plast, uint16 *pcount) | |
{ | |
uint16 dmcad; | |
if ((dmc<DMC1) || (dmc>(DMC1+DMC_MAX-1))) { | |
*pnext = *plast = *pcount = 0; return; | |
} | |
dmcad = DMC_BASE + (dmc-DMC1)*2; | |
*pnext = M[dmcad] & X_AMASK; *plast = M[dmcad+1] & X_AMASK; | |
*pcount = (*plast - *pnext + 1) & DMASK; | |
} | |
// Update the DMC words to show "count" words transferred. | |
void mi_update_dmc (uint32 dmc, uint32 count) | |
{ | |
uint16 dmcad, next; | |
if ((dmc<DMC1) || (dmc>(DMC1+DMC_MAX-1))) return; | |
dmcad = DMC_BASE + (dmc-DMC1)*2; | |
next = M[dmcad]; | |
M[dmcad] = (next & DMA_IN) | ((next+count) & X_AMASK); | |
} | |
// Link error recovery ... | |
void mi_link_error (uint16 line) | |
{ | |
// Any physical I/O error, either for the UDP link or a COM port, prints a | |
// message and detaches the modem. It's up to the user to decide what to do | |
// after that... | |
fprintf(stderr,"MI%d - UNRECOVERABLE I/O ERROR!\n", line); | |
mi_reset_rx(line); mi_reset_tx(line); | |
sim_cancel(PUNIT(line)); mi_detach(PUNIT(line)); | |
PMIDB(line)->link = NOLINK; | |
} | |
//////////////////////////////////////////////////////////////////////////////// | |
/////////////////// D E B U G G I N G R O U T I N E S //////////////////// | |
//////////////////////////////////////////////////////////////////////////////// | |
// Log a modem input or output including DMC words ... | |
void mi_debug_mio (uint16 line, uint32 dmc, const char *ptext) | |
{ | |
uint16 next, last, count; | |
if (!ISLDBG(line, IMP_DBG_IOT)) return; | |
mi_get_dmc(dmc, &next, &last, &count); | |
sim_debug(IMP_DBG_IOT, PDEVICE(line), | |
"start %s (PC=%06o, next=%06o, last=%06o, count=%d)\n", | |
ptext, PC-1, next, last, count); | |
} | |
// Log the contents of a message sent or received ... | |
void mi_debug_msg (uint16 line, uint16 next, uint16 count, const char *ptext) | |
{ | |
uint16 i; char buf[CBUFSIZE]; int len = 0; | |
if (!ISLDBG(line, MI_DBG_MSG)) return; | |
sim_debug(MI_DBG_MSG, PDEVICE(line), "message %s (length=%d)\n", ptext, count); | |
for (i = 1, len = 0; i <= count; ++i) { | |
len += sprintf(buf+len, "%06o ", M[next+i-1]); | |
if (((i & 7) == 0) || (i == count)) { | |
sim_debug(MI_DBG_MSG, PDEVICE(line), "- %s\n", buf); len = 0; | |
} | |
} | |
} | |
//////////////////////////////////////////////////////////////////////////////// | |
///////////////// T R A N S M I T A N D R E C E I V E ////////////////// | |
//////////////////////////////////////////////////////////////////////////////// | |
// Start the transmitter ... | |
void mi_start_tx (uint16 line) | |
{ | |
// This handles all the work of the "start modem output" OCP, including | |
// extracting the packet from H316 memory, EXCEPT for actually setting the | |
// transmit done interrupt. That's handled by the RTC polling routine after | |
// a delay that we calculate.. | |
uint16 next, last, count; uint32 nbits; t_stat ret; | |
// Get the DMC words for this channel and update the next pointer as if the | |
// transfer actually occurred. | |
mi_get_dmc(PDIB(line)->txdmc, &next, &last, &count); | |
mi_update_dmc(PDIB(line)->txdmc, count); | |
mi_debug_msg (line, next, count, "sent"); | |
// Transmit the data, handling both the interface loopback AND the line loop | |
// back flags in the process. Note that in particular the interface loop back | |
// does NOT require that the modem be attached! | |
if (PMIDB(line)->iloop) { | |
mi_rx_local(line, next, count); | |
} else if (PMIDB(line)->link != NOLINK) { | |
ret = udp_send(PDEVICE(line), PMIDB(line)->link, &M[next], count); | |
if (ret != SCPE_OK) mi_link_error(line); | |
} | |
// Do some fancy math to figure out how long, in RTC ticks, it would actually | |
// take to transmit a packet of this length with a real modem and phone line. | |
// Note that the "+12" is an approximation for the modem overhead, including | |
// DLE, STX, ETX and checksum bytes, that would be added to the packet. | |
nbits = (((uint32) count)*2UL + 12UL) * 8UL; | |
PMIDB(line)->txdelay = (nbits * 1000000UL) / (PMIDB(line)->bps * rtc_interval); | |
//fprintf(stderr,"MI%d - transmit packet, length=%d, bits=%ld, interval=%ld, delay=%ld\n", line, count, nbits, rtc_interval, PMIDB(line)->txdelay); | |
// That's it - we're done until it's time for the TX done interrupt ... | |
CLR_TX_IRQ(line); | |
} | |
// Poll for transmitter done interrupts ... | |
void mi_poll_tx (uint16 line, uint32 quantum) | |
{ | |
// This routine is called, via the RTC service, to count down the interval | |
// until the transmitter finishes. When it hits zero, an interrupt occurs. | |
if (PMIDB(line)->txdelay == 0) return; | |
if (PMIDB(line)->txdelay <= quantum) { | |
SET_TX_IRQ(line); PMIDB(line)->txdelay = 0; PMIDB(line)->txtotal++; | |
sim_debug(IMP_DBG_IOT, PDEVICE(line), "transmit done (message #%d, intreq=%06o)\n", PMIDB(line)->txtotal, dev_ext_int); | |
} else | |
PMIDB(line)->txdelay -= quantum; | |
} | |
// Start the receiver ... | |
void mi_start_rx (uint16 line) | |
{ | |
// "Starting" the receiver simply sets the RX pending flag. Nothing else | |
// needs to be done (nothing else _can_ be done!) until we actually receive | |
// a real packet. | |
// We check for the case of another receive already pending, but I don't | |
// think the real hardware detected this or considered it an error condition. | |
if (PMIDB(line)->rxpending) { | |
sim_debug(IMP_DBG_WARN,PDEVICE(line),"start input while input already pending\n"); | |
} | |
PMIDB(line)->rxpending = TRUE; PMIDB(line)->rxerror = FALSE; | |
CLR_RX_IRQ(line); | |
} | |
// Poll for receiver data ... | |
void mi_poll_rx (uint16 line) | |
{ | |
// This routine is called by mi_service to poll for any packets received. | |
// This is done regardless of whether a receive is pending on the line. If | |
// a packet is waiting AND a receive is pending then we'll store it and finish | |
// the receive operation. If a packet is waiting but no receive is pending | |
// then the packet is discarded... | |
uint16 next, last, maxbuf; uint16 *pdata; int16 count; | |
// If the modem isn't attached, then the read never completes! | |
if (PMIDB(line)->link == NOLINK) return; | |
// Get the DMC words for this channel, or zeros if no read is pending ... | |
if (PMIDB(line)->rxpending) { | |
mi_get_dmc(PDIB(line)->rxdmc, &next, &last, &maxbuf); | |
pdata = &M[next]; | |
} else { | |
next = last = maxbuf = 0; pdata = NULL; | |
} | |
// Try to read a packet. If we get nothing then just return. | |
count = udp_receive(PDEVICE(line), PMIDB(line)->link, pdata, maxbuf); | |
if (count == 0) return; | |
if (count < 0) {mi_link_error(line); return;} | |
// Now would be a good time to worry about whether a receive is pending! | |
if (!PMIDB(line)->rxpending) { | |
sim_debug(IMP_DBG_WARN, PDEVICE(line), "data received with no input pending\n"); | |
return; | |
} | |
// We really got a packet! Update the DMC pointers to reflect the actual | |
// size of the packet received. If the packet length would have exceeded the | |
// receiver buffer, then that sets the error flag too. | |
if (count > maxbuf) { | |
sim_debug(IMP_DBG_WARN, PDEVICE(line), "receiver overrun (length=%d maxbuf=%d)\n", count, maxbuf); | |
PMIDB(line)->rxerror = TRUE; count = maxbuf; | |
} | |
mi_update_dmc(PDIB(line)->rxdmc, count); | |
mi_debug_msg (line, next, count, "received"); | |
// Assert the interrupt request and we're done! | |
SET_RX_IRQ(line); PMIDB(line)->rxpending = FALSE; PMIDB(line)->rxtotal++; | |
sim_debug(IMP_DBG_IOT, PDEVICE(line), "receive done (message #%d, intreq=%06o)\n", PMIDB(line)->rxtotal, dev_ext_int); | |
} | |
// Receive cross patched data ... | |
void mi_rx_local (uint16 line, uint16 txnext, uint16 txcount) | |
{ | |
// This routine is invoked by the mi_start_tx() function when this modem has | |
// the "interface cross patch" bit set. This flag causes the modem to talk to | |
// to itself, and data sent by the transmitter goes directly to the receiver. | |
// The modem is bypassed completely and in fact need not even be connected. | |
// This is essentially a special case of the mi_poll_rx() routine and it's a | |
// shame they don't share more code, but that's the way it is. | |
// Get the DMC words for this channel, or zeros if no read is pending ... | |
uint16 rxnext, rxlast, maxbuf; | |
// If no read is pending, then just throw away the data ... | |
if (!PMIDB(line)->rxpending) return; | |
// Get the DMC words for the receiver and copy data from one buffer to the other. | |
mi_get_dmc(PDIB(line)->rxdmc, &rxnext, &rxlast, &maxbuf); | |
if (txcount > maxbuf) {txcount = maxbuf; PMIDB(line)->rxerror = TRUE;} | |
memmove(&M[rxnext], &M[txnext], txcount * sizeof(uint16)); | |
// Update the receiver DMC pointers, assert IRQ and we're done! | |
mi_update_dmc(PDIB(line)->rxdmc, txcount); | |
mi_debug_msg (line, rxnext, txcount, "received"); | |
SET_RX_IRQ(line); PMIDB(line)->rxpending = FALSE; PMIDB(line)->rxtotal++; | |
sim_debug(IMP_DBG_IOT, PDEVICE(line), "receive done (message #%d, intreq=%06o)\n", PMIDB(line)->rxtotal, dev_ext_int); | |
} | |
//////////////////////////////////////////////////////////////////////////////// | |
//////////// I / O I N S T R U C T I O N E M U L A T I O N ///////////// | |
//////////////////////////////////////////////////////////////////////////////// | |
// Line specific I/O routines ... | |
// Unfortunately simh doesn't pass the I/O emulation routine any data about the | |
// device except for its device address. In particular, it doesn't pass a pointer | |
// to the device or unit data blocks, so we're on our own to find those. Rather | |
// than a search on the device address, we just provide a separate I/O routine | |
// for each modem line. All they do is call the common I/O routine with an extra | |
// parameter - problem solved! | |
int32 mi1_io(int32 inst, int32 fnc, int32 dat, int32 dev) {return mi_io(1, inst, fnc, dat, dev);} | |
int32 mi2_io(int32 inst, int32 fnc, int32 dat, int32 dev) {return mi_io(2, inst, fnc, dat, dev);} | |
int32 mi3_io(int32 inst, int32 fnc, int32 dat, int32 dev) {return mi_io(3, inst, fnc, dat, dev);} | |
int32 mi4_io(int32 inst, int32 fnc, int32 dat, int32 dev) {return mi_io(4, inst, fnc, dat, dev);} | |
int32 mi5_io(int32 inst, int32 fnc, int32 dat, int32 dev) {return mi_io(5, inst, fnc, dat, dev);} | |
// Common I/O simulation routine ... | |
int32 mi_io (uint16 line, int32 inst, int32 fnc, int32 dat, int32 dev) | |
{ | |
// This routine is invoked by the CPU module whenever the code executes any | |
// I/O instruction (OCP, SKS, INA or OTA) with one of our modem's device | |
// address. | |
// OCP (output control pulse) initiates various modem operations ... | |
if (inst == ioOCP) { | |
switch (fnc) { | |
case 000: | |
// MnOUT - start modem output ... | |
mi_debug_mio(line, PDIB(line)->txdmc, "output"); | |
mi_start_tx(line); return dat; | |
case 001: | |
// MnUNXP - un-cross patch modem ... | |
sim_debug(IMP_DBG_IOT,PDEVICE(line),"un-cross patch modem (PC=%06o)\n", PC-1); | |
PMIDB(line)->iloop = PMIDB(line)->lloop = FALSE; | |
udp_set_link_loopback (PDEVICE(line), PMIDB(line)->link, FALSE); | |
return dat; | |
case 002: | |
// MnLXP - enable line cross patch ... | |
sim_debug(IMP_DBG_IOT,PDEVICE(line),"enable line cross patch (PC=%06o)\n", PC-1); | |
PMIDB(line)->lloop = TRUE; | |
udp_set_link_loopback (PDEVICE(line), PMIDB(line)->link, TRUE); | |
PMIDB(line)->iloop = FALSE; return dat; | |
case 003: | |
// MnIXP - enable interface cross patch ... | |
sim_debug(IMP_DBG_IOT,PDEVICE(line),"enable interface cross patch (PC=%06o)\n", PC-1); | |
PMIDB(line)->iloop = TRUE; PMIDB(line)->lloop = FALSE; | |
udp_set_link_loopback (PDEVICE(line), PMIDB(line)->link, FALSE); | |
return dat; | |
case 004: | |
// MnIN - start modem input ... | |
mi_debug_mio(line, PDIB(line)->rxdmc, "input"); | |
mi_start_rx(line); return dat; | |
} | |
// SKS (skip) tests various modem conditions ... | |
} else if (inst == ioSKS) { | |
switch (fnc) { | |
case 004: | |
// MnERR - skip on modem error ... | |
sim_debug(IMP_DBG_IOT,PDEVICE(line),"skip on error (PC=%06o, %s)\n", | |
PC-1, PMIDB(line)->rxerror ? "SKIP" : "NOSKIP"); | |
return PMIDB(line)->rxerror ? IOSKIP(dat) : dat; | |
// NOTE - the following skip, MnRXDONE, isn't actually part of the | |
// original IMP design. As far as I can tell the IMP had no way to | |
// explicitly poll this flags; the only way to tell when a modem finished | |
// was to catch the associated interrupt. I've added one for testing | |
// purposes, using an unimplemented SKS instruction. | |
case 002: | |
// MnRXDONE - skip on receive done ... | |
return PMIDB(line)->rxpending ? dat : IOSKIP(dat); | |
} | |
} | |
// Anything else is an error... | |
sim_debug(IMP_DBG_WARN,PDEVICE(line),"UNIMPLEMENTED I/O (PC=%06o, instruction=%o, function=%02o)\n", PC-1, inst, fnc); | |
return IOBADFNC(dat); | |
} | |
// Receiver service ... | |
t_stat mi_rx_service (UNIT *uptr) | |
{ | |
// This is the standard simh "service" routine that's called when an event | |
// queue entry expires. It just polls the receiver and reschedules itself. | |
// That's it! | |
uint16 line = uptr->mline; | |
mi_poll_rx(line); | |
sim_activate(uptr, uptr->wait); | |
return SCPE_OK; | |
} | |
// Transmitter service ... | |
t_stat mi_tx_service (uint32 quantum) | |
{ | |
// This is the special transmitter service routine that's called by the RTC | |
// service every time the RTC is updated. This routine polls ALL the modem | |
// transmitters (or at least any which are active) and figures out whether it | |
// is time for an interrupt. | |
uint32 i; | |
for (i = 1; i <= MI_NUM; ++i) mi_poll_tx(i, quantum); | |
return SCPE_OK; | |
} | |
//////////////////////////////////////////////////////////////////////////////// | |
/////////////// D E V I C E A C T I O N C O M M A N D S //////////////// | |
//////////////////////////////////////////////////////////////////////////////// | |
// Reset device ... | |
t_stat mi_reset (DEVICE *dptr) | |
{ | |
// simh calls this routine for the RESET command ... | |
UNIT *uptr = dptr->units; | |
uint16 line = uptr->mline; | |
// Reset the devices AND clear the interrupt enable bits ... | |
mi_reset_rx(line); mi_reset_tx(line); | |
// If the unit is attached, then make sure we restart polling because some | |
// simh commands (e.g. boot) dump the pending event queue! | |
sim_cancel(uptr); | |
if ((uptr->flags & UNIT_ATT) != 0) sim_activate(uptr, uptr->wait); | |
return SCPE_OK; | |
} | |
// Attach device ... | |
t_stat mi_attach (UNIT *uptr, char *cptr) | |
{ | |
// simh calls this routine for (what else?) the ATTACH command. There are | |
// three distinct formats for ATTACH - | |
// | |
// ATTACH -p MIn COMnn - attach MIn to a physical COM port | |
// ATTACH MIn llll:w.x.y.z:rrrr - connect via UDP to a remote simh host | |
// | |
t_stat ret; char *pfn; uint16 line = uptr->mline; | |
t_bool fport = sim_switches & SWMASK('P'); | |
// If we're already attached, then detach ... | |
if ((uptr->flags & UNIT_ATT) != 0) detach_unit(uptr); | |
// The physical (COM port) attach isn't implemented yet ... | |
if (fport) { | |
fprintf(stderr,"MI%d - physical COM support is not yet implemented\n", line); | |
return SCPE_ARG; | |
} | |
// Make a copy of the "file name" argument. udp_create() actually modifies | |
// the string buffer we give it, so we make a copy now so we'll have something | |
// to display in the "SHOW MIn ..." command. | |
pfn = (char *) calloc (CBUFSIZE, sizeof (char)); | |
if (pfn == NULL) return SCPE_MEM; | |
strncpy (pfn, cptr, CBUFSIZE); | |
// Create the UDP connection. | |
ret = udp_create(PDEVICE(line), cptr, &(PMIDB(line)->link)); | |
if (ret != SCPE_OK) {free(pfn); return ret;}; | |
// Reset the flags and start polling ... | |
uptr->flags |= UNIT_ATT; uptr->filename = pfn; | |
return mi_reset(find_dev_from_unit(uptr)); | |
} | |
// Detach device ... | |
t_stat mi_detach (UNIT *uptr) | |
{ | |
// simh calls this routine for (you guessed it!) the DETACH command. This | |
// disconnects the modem from any UDP connection or COM port and effectively | |
// makes the modem "off line". A disconnected modem acts like a real modem | |
// with its phone line unplugged. | |
t_stat ret; uint16 line = uptr->mline; | |
if ((uptr->flags & UNIT_ATT) == 0) return SCPE_OK; | |
ret = udp_release(PDEVICE(line), PMIDB(line)->link); | |
if (ret != SCPE_OK) return ret; | |
PMIDB(line)->link = NOLINK; uptr->flags &= ~UNIT_ATT; | |
free (uptr->filename); uptr->filename = NULL; | |
return mi_reset(PDEVICE(line)); | |
} | |
t_stat mi_set_loopback (UNIT *uptr, int32 val, char *cptr, void *desc) | |
{ | |
t_stat ret = SCPE_OK; uint16 line = uptr->mline; | |
switch (val) { | |
case 0: // LOOPINTERFACE | |
case 1: // NOLOOPINTERFACE | |
PMIDB(line)->iloop = (val == 0) ? 1 : 0; | |
break; | |
case 2: // LOOPLINE | |
case 3: // NOLOOPLINE | |
if (PMIDB(line)->link == NOLINK) | |
return SCPE_UNATT; | |
val = (val == 2) ? 1 : 0; | |
ret = udp_set_link_loopback (PDEVICE(line), PMIDB(line)->link, val); | |
if (ret == SCPE_OK) | |
PMIDB(line)->lloop = val; | |
break; | |
} | |
return ret; | |
} | |
t_stat mi_show_loopback (FILE *st, UNIT *uptr, int32 val, void *desc) | |
{ | |
uint16 line = uptr->mline; | |
if (PMIDB(line)->iloop) | |
fprintf (st, "Interface (local) Loopback"); | |
if (PMIDB(line)->lloop) | |
fprintf (st, "Line (remote) Loopback"); | |
return SCPE_OK; | |
} | |
#endif // #ifdef VM_IMPTIP from the very top |