/* hp2100_mux.c: HP 2100 12920A terminal multiplexor simulator | |
Copyright (c) 2002-2013, Robert M Supnik | |
Permission is hereby granted, free of charge, to any person obtaining a | |
copy of this software and associated documentation files (the "Software"), | |
to deal in the Software without restriction, including without limitation | |
the rights to use, copy, modify, merge, publish, distribute, sublicense, | |
and/or sell copies of the Software, and to permit persons to whom the | |
Software is furnished to do so, subject to the following conditions: | |
The above copyright notice and this permission notice shall be included in | |
all copies or substantial portions of the Software. | |
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR | |
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, | |
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL | |
ROBERT M SUPNIK BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER | |
IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN | |
CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. | |
Except as contained in this notice, the name of Robert M Supnik shall not be | |
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in this Software without prior written authorization from Robert M Supnik. | |
MUX,MUXL,MUXM 12920A terminal multiplexor | |
10-Jan-13 MP Added DEV_MUX and additional DEVICE field values | |
10-Feb-12 JDB Deprecated DEVNO in favor of SC | |
Removed DEV_NET to allow restoration of listening port | |
28-Mar-11 JDB Tidied up signal handling | |
26-Oct-10 JDB Changed I/O signal handler for revised signal model | |
25-Nov-08 JDB Revised for new multiplexer library SHOW routines | |
09-Oct-08 JDB "muxl_unit" defined one too many units (17 instead of 16) | |
10-Sep-08 JDB SHOW MUX CONN/STAT with SET MUX DIAG is no longer disallowed | |
07-Sep-08 JDB Changed Telnet poll to connect immediately after reset or attach | |
27-Aug-08 JDB Added LINEORDER support | |
12-Aug-08 JDB Added BREAK deferral to allow RTE break-mode to work | |
26-Jun-08 JDB Rewrote device I/O to model backplane signals | |
16-Apr-08 JDB Sync mux poll with console poll for idle compatibility | |
06-Mar-07 JDB Corrected "mux_sta" size from 16 to 21 elements | |
Fixed "muxc_reset" to clear lines 16-20 | |
26-Feb-07 JDB Added debug printouts | |
Fixed control card OTx to set current channel number | |
Fixed to set "muxl_ibuf" in response to a transmit interrupt | |
Changed "mux_xbuf", "mux_rbuf" declarations from 8 to 16 bits | |
Fixed to set "mux_rchp" when a line break is received | |
Fixed incorrect "odd_par" table values | |
Reversed test in "RCV_PAR" to return "LIL_PAR" on odd parity | |
Fixed mux reset (ioCRS) to clear port parameters | |
Fixed to use PUT_DCH instead of PUT_CCH for data channel status | |
10-Feb-07 JDB Added DIAG/TERM modifiers to implement diagnostic mode | |
28-Dec-06 JDB Added ioCRS state to I/O decoders | |
02-Jun-06 JDB Fixed compiler warning for mux_ldsc init | |
22-Nov-05 RMS Revised for new terminal processing routines | |
29-Jun-05 RMS Added SET MUXLn DISCONNECT | |
07-Oct-04 JDB Allow enable/disable from any device | |
26-Apr-04 RMS Fixed SFS x,C and SFC x,C | |
Implemented DMA SRQ (follows FLG) | |
05-Jan-04 RMS Revised for tmxr library changes | |
21-Dec-03 RMS Added invalid character screening for TSB (from Mike Gemeny) | |
09-May-03 RMS Added network device flag | |
01-Nov-02 RMS Added 7B/8B support | |
22-Aug-02 RMS Updated for changes to sim_tmxr | |
Reference: | |
- 12920A Asynchronous Multiplexer Interface Kits Operating and Service Manual | |
(12920-90001, Oct-1972) | |
The 12920A was a 16-channel asynchronous terminal multiplexer. It supported | |
direct-connected terminals as well as modems at speeds up to 2400 baud. It | |
was the primary terminal multiplexer for the HP 2000 series of Time-Shared | |
BASIC systems. | |
The multiplexer was implemented as a three-card set consisting of a lower | |
data card, an upper data card, and a modem control card. Under simulation, | |
these are implemented by three devices: | |
MUXL lower data card (lines) | |
MUX upper data card (scanner) | |
MUXM control card (modem control) | |
The lower and upper data cards must be in adjacent I/O slots. The control | |
card may be placed in any slot, although in practice it was placed in the | |
slot above the upper data card, so that all three cards were physically | |
together. | |
The 12920A supported one or two control cards (two cards were used with | |
801-type automatic dialers). Under simulation, only one control card is | |
supported. | |
Implementation notes: | |
1. If a BREAK is detected during an input poll, and we are not in diagnostic | |
mode, we defer recognition until either a character is output or a second | |
successive input poll occurs. This is necessary for RTE break-mode | |
operation. Without this deferral, a BREAK during output would be ignored | |
by the RTE driver, making it impossible to stop a long listing. | |
The problem is due to timing differences between simulated and real time. | |
The RTE multiplexer driver is a privileged driver. Privileged drivers | |
bypass RTE to provide rapid interrupt handling. To inform RTE that an | |
operation is complete, e.g., that a line has been written, the interrupt | |
section of the driver sets a device timeout of one clock tick (10 | |
milliseconds). When that timeout occurs, RTE is entered normally to | |
complete the I/O transaction. While the completion timeout is pending, | |
the driver ignores any further interrupts from the multiplexer line. | |
The maximum communication rate for the multiplexer is 2400 baud, or | |
approximately 4.2 milliseconds per character transferred. A typical line | |
of 20 characters would therefore take ~85 milliseconds, plus the 10 | |
millisecond completion timeout, or about 95 milliseconds total. BREAK | |
recognition would be ignored for roughly 10% of that time. At lower baud | |
rates, recognition would be ignored for a correspondingly smaller | |
percentage of the time. | |
However, SIMH uses an optimized timing of 500 instructions per character | |
transfer, rather than the ~6600 instructions that a character transfer | |
should take, and so a typical 20-character line will take about 11,000 | |
instructions. On the other hand, the clock tick is calibrated to real | |
time, and 10 milliseconds of real time takes about 420,000 instructions | |
on a 2.0 GHz PC. To be recognized, then, the BREAK key must be pressed | |
in a window that is open for about 2.5% of the time. Therefore, the | |
BREAK key will be ignored about 97.5% of the time, and RTE break-mode | |
effectively will not work. | |
Deferring BREAK recognition until the next character is output ensures | |
that the BREAK interrupt will be accepted (the simulator delivers input | |
interrupts before output interrupts, so the BREAK interrupt arrives | |
before the output character transmit interrupt). If an output operation | |
is not in progress, then the BREAK will be recognized at the next input | |
poll. | |
*/ | |
#include <ctype.h> | |
#include "hp2100_defs.h" | |
#include "sim_tmxr.h" | |
/* Unit references */ | |
#define MUX_LINES 16 /* number of user lines */ | |
#define MUX_ILINES 5 /* number of diag rcv only lines */ | |
/* Service times */ | |
#define MUXL_WAIT 500 | |
/* Unit flags */ | |
#define UNIT_V_MDM (TTUF_V_UF + 0) /* modem control */ | |
#define UNIT_V_DIAG (TTUF_V_UF + 1) /* loopback diagnostic */ | |
#define UNIT_MDM (1 << UNIT_V_MDM) | |
#define UNIT_DIAG (1 << UNIT_V_DIAG) | |
/* Debug flags */ | |
#define DEB_CMDS (1 << 0) /* Command initiation and completion */ | |
#define DEB_CPU (1 << 1) /* CPU I/O */ | |
#define DEB_XFER (1 << 2) /* Socket receive and transmit */ | |
/* Channel number (OTA upper, LIA lower or upper) */ | |
#define MUX_V_CHAN 10 /* channel num */ | |
#define MUX_M_CHAN 037 | |
#define MUX_CHAN(x) (((x) >> MUX_V_CHAN) & MUX_M_CHAN) | |
/* OTA, lower = parameters or data */ | |
#define OTL_P 0100000 /* parameter */ | |
#define OTL_TX 0040000 /* transmit */ | |
#define OTL_ENB 0020000 /* enable */ | |
#define OTL_TPAR 0010000 /* xmt parity */ | |
#define OTL_ECHO 0010000 /* rcv echo */ | |
#define OTL_DIAG 0004000 /* diagnose */ | |
#define OTL_SYNC 0004000 /* sync */ | |
#define OTL_V_LNT 8 /* char length */ | |
#define OTL_M_LNT 07 | |
#define OTL_LNT(x) (((x) >> OTL_V_LNT) & OTL_M_LNT) | |
#define OTL_V_BAUD 0 /* baud rate */ | |
#define OTL_M_BAUD 0377 | |
#define OTL_BAUD(x) (((x) >> OTL_V_BAUD) & OTL_M_BAUD) | |
#define OTL_CHAR 03777 /* char mask */ | |
#define OTL_PAR 0200 /* char parity */ | |
/* LIA, lower = received data */ | |
#define LIL_PAR 0100000 /* parity */ | |
#define PUT_DCH(x) (((x) & MUX_M_CHAN) << MUX_V_CHAN) | |
#define LIL_CHAR 01777 /* character */ | |
/* LIA, upper = status */ | |
#define LIU_SEEK 0100000 /* seeking NI */ | |
#define LIU_DG 0000010 /* diagnose */ | |
#define LIU_BRK 0000004 /* break */ | |
#define LIU_LOST 0000002 /* char lost */ | |
#define LIU_TR 0000001 /* trans/rcv */ | |
/* OTA, control */ | |
#define OTC_SCAN 0100000 /* scan */ | |
#define OTC_UPD 0040000 /* update */ | |
#define OTC_V_CHAN 10 /* channel */ | |
#define OTC_M_CHAN 017 | |
#define OTC_CHAN(x) (((x) >> OTC_V_CHAN) & OTC_M_CHAN) | |
#define OTC_EC2 0000200 /* enable Cn upd */ | |
#define OTC_EC1 0000100 | |
#define OTC_C2 0000040 /* Cn flops */ | |
#define OTC_C1 0000020 | |
#define OTC_V_C 4 /* S1 to C1 */ | |
#define OTC_ES2 0000010 /* enb comparison */ | |
#define OTC_ES1 0000004 | |
#define OTC_V_ES 2 | |
#define OTC_SS2 0000002 /* SSn flops */ | |
#define OTC_SS1 0000001 | |
#define OTC_RW (OTC_ES2|OTC_ES1|OTC_SS2|OTC_SS1) | |
#define RTS OCT_C2 /* C2 = rts */ | |
#define DTR OTC_C1 /* C1 = dtr */ | |
/* LIA, control */ | |
#define LIC_MBO 0140000 /* always set */ | |
#define LIC_V_CHAN 10 /* channel */ | |
#define LIC_M_CHAN 017 | |
#define PUT_CCH(x) (((x) & OTC_M_CHAN) << OTC_V_CHAN) | |
#define LIC_I2 0001000 /* change flags */ | |
#define LIC_I1 0000400 | |
#define LIC_S2 0000002 /* Sn flops */ | |
#define LIC_S1 0000001 | |
#define LIC_V_I 8 /* S1 to I1 */ | |
#define CDET LIC_S2 /* S2 = cdet */ | |
#define DSR LIC_S1 /* S1 = dsr */ | |
#define LIC_TSTI(ch) (((muxc_lia[ch] ^ muxc_ota[ch]) & \ | |
((muxc_ota[ch] & (OTC_ES2|OTC_ES1)) >> OTC_V_ES)) \ | |
<< LIC_V_I) | |
/* Program constants */ | |
static const uint8 odd_par [256] = { | |
1, 0, 0, 1, 0, 1, 1, 0, 0, 1, 1, 0, 1, 0, 0, 1, /* 000-017 */ | |
0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 0, 1, 0, 1, 1, 0, /* 020-037 */ | |
0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 0, 1, 0, 1, 1, 0, /* 040-067 */ | |
1, 0, 0, 1, 0, 1, 1, 0, 0, 1, 1, 0, 1, 0, 0, 1, /* 060-077 */ | |
0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 0, 1, 0, 1, 1, 0, /* 100-117 */ | |
1, 0, 0, 1, 0, 1, 1, 0, 0, 1, 1, 0, 1, 0, 0, 1, /* 120-137 */ | |
1, 0, 0, 1, 0, 1, 1, 0, 0, 1, 1, 0, 1, 0, 0, 1, /* 140-157 */ | |
0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 0, 1, 0, 1, 1, 0, /* 160-177 */ | |
0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 0, 1, 0, 1, 1, 0, /* 200-217 */ | |
1, 0, 0, 1, 0, 1, 1, 0, 0, 1, 1, 0, 1, 0, 0, 1, /* 220-237 */ | |
1, 0, 0, 1, 0, 1, 1, 0, 0, 1, 1, 0, 1, 0, 0, 1, /* 240-267 */ | |
0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 0, 1, 0, 1, 1, 0, /* 260-277 */ | |
1, 0, 0, 1, 0, 1, 1, 0, 0, 1, 1, 0, 1, 0, 0, 1, /* 300-317 */ | |
0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 0, 1, 0, 1, 1, 0, /* 320-337 */ | |
0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 0, 1, 0, 1, 1, 0, /* 340-357 */ | |
1, 0, 0, 1, 0, 1, 1, 0, 0, 1, 1, 0, 1, 0, 0, 1 /* 360-377 */ | |
}; | |
#define RCV_PAR(x) (odd_par[(x) & 0377] ? 0 : LIL_PAR) | |
#define XMT_PAR(x) (odd_par[(x) & 0377] ? 0 : OTL_PAR) | |
/* Multiplexer controller state variables */ | |
struct { | |
FLIP_FLOP control; /* control flip-flop */ | |
FLIP_FLOP flag; /* flag flip-flop */ | |
FLIP_FLOP flagbuf; /* flag buffer flip-flop */ | |
} muxl = { CLEAR, CLEAR, CLEAR }; | |
uint32 muxl_ibuf = 0; /* low in: rcv data */ | |
uint32 muxl_obuf = 0; /* low out: param */ | |
uint32 muxu_ibuf = 0; /* upr in: status */ | |
uint32 muxu_obuf = 0; /* upr out: chan */ | |
struct { | |
FLIP_FLOP control; /* control flip-flop */ | |
FLIP_FLOP flag; /* flag flip-flop */ | |
FLIP_FLOP flagbuf; /* flag buffer flip-flop */ | |
} muxc = { CLEAR, CLEAR, CLEAR }; | |
uint32 muxc_chan = 0; /* ctrl chan */ | |
uint32 muxc_scan = 0; /* ctrl scan */ | |
/* Multiplexer per-line state variables */ | |
uint16 mux_sta [MUX_LINES + MUX_ILINES]; /* line status */ | |
uint16 mux_rpar [MUX_LINES + MUX_ILINES]; /* rcv param */ | |
uint16 mux_xpar [MUX_LINES]; /* xmt param */ | |
uint8 mux_rchp [MUX_LINES + MUX_ILINES]; /* rcv chr pend */ | |
uint8 mux_xdon [MUX_LINES]; /* xmt done */ | |
uint8 muxc_ota [MUX_LINES]; /* ctrl: Cn,ESn,SSn */ | |
uint8 muxc_lia [MUX_LINES]; /* ctrl: Sn */ | |
uint8 mux_defer [MUX_LINES]; /* break deferred flags */ | |
/* Multiplexer per-line buffer variables */ | |
uint16 mux_rbuf[MUX_LINES + MUX_ILINES]; /* rcv buf */ | |
uint16 mux_xbuf[MUX_LINES]; /* xmt buf */ | |
/* Multiplexer local routines */ | |
void mux_receive (int32 ln, int32 c, t_bool diag); | |
void mux_data_int (void); | |
void mux_ctrl_int (void); | |
void mux_diag (int32 c); | |
/* Multiplexer global routines */ | |
IOHANDLER muxlio; | |
IOHANDLER muxuio; | |
IOHANDLER muxcio; | |
t_stat muxi_svc (UNIT *uptr); | |
t_stat muxo_svc (UNIT *uptr); | |
t_stat muxc_reset (DEVICE *dptr); | |
t_stat mux_attach (UNIT *uptr, char *cptr); | |
t_stat mux_detach (UNIT *uptr); | |
t_stat mux_setdiag (UNIT *uptr, int32 val, char *cptr, void *desc); | |
/* MUXL/MUXU device information block. | |
The DIBs of adjacent cards must be contained in an array, so they are defined | |
here and referenced in the lower and upper card device structures. | |
*/ | |
DIB mux_dib[] = { | |
{ &muxlio, MUXL }, | |
{ &muxuio, MUXU } | |
}; | |
#define muxl_dib mux_dib[0] | |
#define muxu_dib mux_dib[1] | |
/* MUXL data structures. | |
muxl_dib MUXL device information block | |
muxl_unit MUXL unit list | |
muxl_reg MUXL register list | |
muxl_mod MUXL modifier list | |
muxl_dev MUXL device descriptor | |
*/ | |
TMXR mux_desc; | |
DEVICE muxl_dev; | |
UNIT muxl_unit[] = { | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT }, | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT }, | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT }, | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT }, | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT }, | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT }, | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT }, | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT }, | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT }, | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT }, | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT }, | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT }, | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT }, | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT }, | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT }, | |
{ UDATA (&muxo_svc, TT_MODE_UC, 0), MUXL_WAIT } | |
}; | |
REG muxl_reg[] = { | |
{ FLDATA (CTL, muxl.control, 0) }, | |
{ FLDATA (FLG, muxl.flag, 0) }, | |
{ FLDATA (FBF, muxl.flagbuf, 0) }, | |
{ BRDATA (STA, mux_sta, 8, 16, MUX_LINES + MUX_ILINES) }, | |
{ BRDATA (RPAR, mux_rpar, 8, 16, MUX_LINES + MUX_ILINES) }, | |
{ BRDATA (XPAR, mux_xpar, 8, 16, MUX_LINES) }, | |
{ BRDATA (RBUF, mux_rbuf, 8, 16, MUX_LINES + MUX_ILINES) }, | |
{ BRDATA (XBUF, mux_xbuf, 8, 16, MUX_LINES) }, | |
{ BRDATA (RCHP, mux_rchp, 8, 1, MUX_LINES + MUX_ILINES) }, | |
{ BRDATA (XDON, mux_xdon, 8, 1, MUX_LINES) }, | |
{ BRDATA (BDFR, mux_defer, 8, 1, MUX_LINES) }, | |
{ URDATA (TIME, muxl_unit[0].wait, 10, 24, 0, | |
MUX_LINES, REG_NZ + PV_LEFT) }, | |
{ ORDATA (SC, muxl_dib.select_code, 6), REG_HRO }, | |
{ ORDATA (DEVNO, muxl_dib.select_code, 6), REG_HRO }, | |
{ NULL } | |
}; | |
MTAB muxl_mod[] = { | |
{ TT_MODE, TT_MODE_UC, "UC", "UC", NULL, NULL, NULL }, | |
{ TT_MODE, TT_MODE_7B, "7b", "7B", NULL, NULL, NULL }, | |
{ TT_MODE, TT_MODE_8B, "8b", "8B", NULL, NULL, NULL }, | |
{ TT_MODE, TT_MODE_7P, "7p", "7P", NULL, NULL, NULL }, | |
{ UNIT_MDM, UNIT_MDM, "dataset", "DATASET", NULL, NULL, NULL }, | |
{ UNIT_MDM, 0, "no dataset", "NODATASET", NULL, NULL, NULL }, | |
{ MTAB_XTD | MTAB_VUN | MTAB_NC, 0, "LOG", "LOG", &tmxr_set_log, &tmxr_show_log, &mux_desc }, | |
{ MTAB_XTD | MTAB_VUN | MTAB_NC, 0, NULL, "NOLOG", &tmxr_set_nolog, NULL, &mux_desc }, | |
{ MTAB_XTD | MTAB_VUN, 0, NULL, "DISCONNECT", &tmxr_dscln, NULL, &mux_desc }, | |
{ MTAB_XTD | MTAB_VDV, 1, "SC", "SC", &hp_setsc, &hp_showsc, &muxl_dev }, | |
{ MTAB_XTD | MTAB_VDV | MTAB_NMO, 1, "DEVNO", "DEVNO", &hp_setdev, &hp_showdev, &muxl_dev }, | |
{ 0 } | |
}; | |
DEVICE muxl_dev = { | |
"MUXL", /* device name */ | |
muxl_unit, /* unit array */ | |
muxl_reg, /* register array */ | |
muxl_mod, /* modifier array */ | |
MUX_LINES, /* number of units */ | |
10, /* address radix */ | |
31, /* address width */ | |
1, /* address increment */ | |
8, /* data radix */ | |
8, /* data width */ | |
NULL, /* examine routine */ | |
NULL, /* deposit routine */ | |
&muxc_reset, /* reset routine */ | |
NULL, /* boot routine */ | |
NULL, /* attach routine */ | |
NULL, /* detach routine */ | |
&muxl_dib, /* device information block */ | |
DEV_DISABLE, /* device flags */ | |
0, /* debug control flags */ | |
NULL, /* debug flag name table */ | |
NULL, /* memory size change routine */ | |
NULL, /* logical device name */ | |
NULL, /* help routine */ | |
NULL, /* help attach routine*/ | |
NULL /* help context */ | |
}; | |
/* MUXU data structures | |
mux_order MUX line connection order table | |
mux_ldsc MUX terminal multiplexer line descriptors | |
mux_desc MUX terminal multiplexer device descriptor | |
muxu_dib MUXU device information block | |
muxu_unit MUXU unit list | |
muxu_reg MUXU register list | |
muxu_mod MUXU modifier list | |
muxu_deb MUXU debug list | |
muxu_dev MUXU device descriptor | |
*/ | |
DEVICE muxu_dev; | |
int32 mux_order [MUX_LINES] = { -1 }; /* connection order */ | |
TMLN mux_ldsc [MUX_LINES] = { { 0 } }; /* line descriptors */ | |
TMXR mux_desc = { MUX_LINES, 0, 0, mux_ldsc, mux_order }; /* device descriptor */ | |
UNIT muxu_unit = { UDATA (&muxi_svc, UNIT_ATTABLE, 0), POLL_FIRST }; | |
REG muxu_reg[] = { | |
{ ORDATA (IBUF, muxu_ibuf, 16) }, | |
{ ORDATA (OBUF, muxu_obuf, 16) }, | |
{ ORDATA (SC, muxu_dib.select_code, 6), REG_HRO }, | |
{ ORDATA (DEVNO, muxu_dib.select_code, 6), REG_HRO }, | |
{ NULL } | |
}; | |
MTAB muxu_mod[] = { | |
{ UNIT_DIAG, UNIT_DIAG, "diagnostic mode", "DIAG", &mux_setdiag, NULL, NULL }, | |
{ UNIT_DIAG, 0, "terminal mode", "TERM", &mux_setdiag, NULL, NULL }, | |
{ UNIT_ATT, UNIT_ATT, "", NULL, NULL, &tmxr_show_summ, &mux_desc }, | |
{ MTAB_XTD | MTAB_VDV | MTAB_NMO, 0, "LINEORDER", "LINEORDER", &tmxr_set_lnorder, &tmxr_show_lnorder, &mux_desc }, | |
{ MTAB_XTD | MTAB_VDV | MTAB_NMO, 1, "CONNECTIONS", NULL, NULL, &tmxr_show_cstat, &mux_desc }, | |
{ MTAB_XTD | MTAB_VDV | MTAB_NMO, 0, "STATISTICS", NULL, NULL, &tmxr_show_cstat, &mux_desc }, | |
{ MTAB_XTD | MTAB_VDV, 1, NULL, "DISCONNECT", &tmxr_dscln, NULL, &mux_desc }, | |
{ MTAB_XTD | MTAB_VDV, 1, "SC", "SC", &hp_setsc, &hp_showsc, &muxl_dev }, | |
{ MTAB_XTD | MTAB_VDV | MTAB_NMO, 1, "DEVNO", "DEVNO", &hp_setdev, &hp_showdev, &muxl_dev }, | |
{ 0 } | |
}; | |
DEBTAB muxu_deb [] = { | |
{ "CMDS", DEB_CMDS }, | |
{ "CPU", DEB_CPU }, | |
{ "XFER", DEB_XFER }, | |
{ NULL, 0 } | |
}; | |
DEVICE muxu_dev = { | |
"MUX", /* device name */ | |
&muxu_unit, /* unit array */ | |
muxu_reg, /* register array */ | |
muxu_mod, /* modifier array */ | |
1, /* number of units */ | |
10, /* address radix */ | |
31, /* address width */ | |
1, /* address increment */ | |
8, /* data radix */ | |
8, /* data width */ | |
&tmxr_ex, /* examine routine */ | |
&tmxr_dep, /* deposit routine */ | |
&muxc_reset, /* reset routine */ | |
NULL, /* boot routine */ | |
&mux_attach, /* attach routine */ | |
&mux_detach, /* detach routine */ | |
&muxu_dib, /* device information block */ | |
DEV_DISABLE | DEV_DEBUG | DEV_MUX, /* device flags */ | |
0, /* debug control flags */ | |
muxu_deb, /* debug flag name table */ | |
NULL, /* memory size change routine */ | |
NULL, /* logical device name */ | |
NULL, /* help routine */ | |
NULL, /* help attach routine*/ | |
(void *) &mux_desc /* help context */ | |
}; | |
/* MUXC data structures. | |
muxc_dib MUXC device information block | |
muxc_unit MUXC unit list | |
muxc_reg MUXC register list | |
muxc_mod MUXC modifier list | |
muxc_dev MUXC device descriptor | |
*/ | |
DEVICE muxc_dev; | |
DIB muxc_dib = { &muxcio, MUXC }; | |
UNIT muxc_unit = { UDATA (NULL, 0, 0) }; | |
REG muxc_reg[] = { | |
{ FLDATA (CTL, muxc.control, 0) }, | |
{ FLDATA (FLG, muxc.flag, 0) }, | |
{ FLDATA (FBF, muxc.flagbuf, 0) }, | |
{ FLDATA (SCAN, muxc_scan, 0) }, | |
{ ORDATA (CHAN, muxc_chan, 4) }, | |
{ BRDATA (DSO, muxc_ota, 8, 6, MUX_LINES) }, | |
{ BRDATA (DSI, muxc_lia, 8, 2, MUX_LINES) }, | |
{ ORDATA (SC, muxc_dib.select_code, 6), REG_HRO }, | |
{ ORDATA (DEVNO, muxc_dib.select_code, 6), REG_HRO }, | |
{ NULL } | |
}; | |
MTAB muxc_mod[] = { | |
{ MTAB_XTD | MTAB_VDV, 0, "SC", "SC", &hp_setsc, &hp_showsc, &muxc_dev }, | |
{ MTAB_XTD | MTAB_VDV | MTAB_NMO, 0, "DEVNO", "DEVNO", &hp_setdev, &hp_showdev, &muxc_dev }, | |
{ 0 } | |
}; | |
DEVICE muxc_dev = { | |
"MUXM", /* device name */ | |
&muxc_unit, /* unit array */ | |
muxc_reg, /* register array */ | |
muxc_mod, /* modifier array */ | |
1, /* number of units */ | |
10, /* address radix */ | |
31, /* address width */ | |
1, /* address increment */ | |
8, /* data radix */ | |
8, /* data width */ | |
NULL, /* examine routine */ | |
NULL, /* deposit routine */ | |
&muxc_reset, /* reset routine */ | |
NULL, /* boot routine */ | |
NULL, /* attach routine */ | |
NULL, /* detach routine */ | |
&muxc_dib, /* device information block */ | |
DEV_DISABLE, /* device flags */ | |
0, /* debug control flags */ | |
NULL, /* debug flag name table */ | |
NULL, /* memory size change routine */ | |
NULL, /* logical device name */ | |
NULL, /* help routine */ | |
NULL, /* help attach routine*/ | |
NULL /* help context */ | |
}; | |
/* Lower data card I/O signal handler. | |
Implementation notes: | |
1. The operating manual says that "at least 100 milliseconds of CLC 0s must | |
be programmed" by systems employing the multiplexer to ensure that the | |
multiplexer resets. In practice, such systems issue 128K CLC 0 | |
instructions. As we provide debug logging of multiplexer resets, a CRS | |
counter is used to ensure that only one debug line is printed in response | |
to these 128K CRS invocations. | |
*/ | |
uint32 muxlio (DIB *dibptr, IOCYCLE signal_set, uint32 stat_data) | |
{ | |
int32 ln; | |
const char *hold_or_clear = (signal_set & ioCLF ? ",C" : ""); | |
static uint32 crs_count = 0; /* cntr for ioCRS repeat */ | |
IOSIGNAL signal; | |
IOCYCLE working_set = IOADDSIR (signal_set); /* add ioSIR if needed */ | |
if (crs_count && !(signal_set & ioCRS)) { /* counting CRSes and not present? */ | |
if (DEBUG_PRI (muxu_dev, DEB_CMDS)) /* report reset count */ | |
fprintf (sim_deb, ">>MUXl cmds: [CRS] Multiplexer reset %d times\n", | |
crs_count); | |
crs_count = 0; /* clear counter */ | |
} | |
while (working_set) { | |
signal = IONEXT (working_set); /* isolate next signal */ | |
switch (signal) { /* dispatch I/O signal */ | |
case ioCLF: /* clear flag flip-flop */ | |
muxl.flag = muxl.flagbuf = CLEAR; | |
if (DEBUG_PRI (muxu_dev, DEB_CMDS)) | |
fputs (">>MUXl cmds: [CLF] Flag cleared\n", sim_deb); | |
mux_data_int (); /* look for new int */ | |
break; | |
case ioSTF: /* set flag flip-flop */ | |
case ioENF: /* enable flag */ | |
muxl.flag = muxl.flagbuf = SET; | |
if (DEBUG_PRI (muxu_dev, DEB_CMDS)) | |
fputs (">>MUXl cmds: [STF] Flag set\n", sim_deb); | |
break; | |
case ioSFC: /* skip if flag is clear */ | |
setstdSKF (muxl); | |
break; | |
case ioSFS: /* skip if flag is set */ | |
setstdSKF (muxl); | |
break; | |
case ioIOI: /* I/O data input */ | |
stat_data = IORETURN (SCPE_OK, muxl_ibuf); /* merge in return status */ | |
if (DEBUG_PRI (muxu_dev, DEB_CPU)) | |
fprintf (sim_deb, ">>MUXl cpu: [LIx%s] Data = %06o\n", hold_or_clear, muxl_ibuf); | |
break; | |
case ioIOO: /* I/O data output */ | |
muxl_obuf = IODATA (stat_data); /* store data */ | |
if (DEBUG_PRI (muxu_dev, DEB_CPU)) | |
if (muxl_obuf & OTL_P) | |
fprintf (sim_deb, ">>MUXl cpu: [OTx%s] Parameter = %06o\n", hold_or_clear, muxl_obuf); | |
else | |
fprintf (sim_deb, ">>MUXl cpu: [OTx%s] Data = %06o\n", hold_or_clear, muxl_obuf); | |
break; | |
case ioPOPIO: /* power-on preset to I/O */ | |
muxl.flag = muxl.flagbuf = SET; /* set flag andflag buffer */ | |
break; | |
case ioCRS: /* control reset */ | |
if (crs_count == 0) { /* first reset? */ | |
muxl.control = CLEAR; /* clear control flip-flop */ | |
for (ln = 0; ln < MUX_LINES; ln++) { /* clear transmit info */ | |
mux_xbuf[ln] = mux_xpar[ln] = 0; | |
muxc_ota[ln] = muxc_lia[ln] = mux_xdon[ln] = 0; | |
} | |
for (ln = 0; ln < (MUX_LINES + MUX_ILINES); ln++) { | |
mux_rbuf[ln] = mux_rpar[ln] = 0; /* clear receive info */ | |
mux_sta[ln] = mux_rchp[ln] = 0; | |
} | |
} | |
crs_count = crs_count + 1; /* increment count */ | |
break; | |
case ioCLC: /* clear control flip-flop */ | |
muxl.control = CLEAR; | |
if (DEBUG_PRI (muxu_dev, DEB_CMDS)) | |
fprintf (sim_deb, ">>MUXl cmds: [CLC%s] Data interrupt inhibited\n", hold_or_clear); | |
break; | |
case ioSTC: /* set control flip-flop */ | |
muxl.control = SET; /* set control */ | |
ln = MUX_CHAN (muxu_obuf); /* get chan # */ | |
if (muxl_obuf & OTL_TX) { /* transmit? */ | |
if (ln < MUX_LINES) { /* line valid? */ | |
if (muxl_obuf & OTL_P) { /* parameter? */ | |
mux_xpar[ln] = muxl_obuf; /* store param value */ | |
if (DEBUG_PRI (muxu_dev, DEB_CMDS)) | |
fprintf (sim_deb, | |
">>MUXl cmds: [STC%s] Transmit channel %d parameter %06o stored\n", | |
hold_or_clear, ln, muxl_obuf); | |
} | |
else { /* data */ | |
if (mux_xpar[ln] & OTL_TPAR) /* parity requested? */ | |
muxl_obuf = /* add parity bit */ | |
muxl_obuf & ~OTL_PAR | | |
XMT_PAR(muxl_obuf); | |
mux_xbuf[ln] = muxl_obuf; /* load buffer */ | |
if (sim_is_active (&muxl_unit[ln])) { /* still working? */ | |
mux_sta[ln] = mux_sta[ln] | LIU_LOST; /* char lost */ | |
if (DEBUG_PRI (muxu_dev, DEB_CMDS)) | |
fprintf (sim_deb, ">>MUXl cmds: [STC%s] Transmit channel %d data overrun\n", | |
hold_or_clear, ln); | |
} | |
else { | |
if (muxu_unit.flags & UNIT_DIAG) /* loopback? */ | |
mux_ldsc[ln].conn = 1; /* connect this line */ | |
sim_activate (&muxl_unit[ln], muxl_unit[ln].wait); | |
if (DEBUG_PRI (muxu_dev, DEB_CMDS)) | |
fprintf (sim_deb, ">>MUXl cmds: [STC%s] Transmit channel %d data %06o scheduled\n", | |
hold_or_clear, ln, muxl_obuf); | |
} | |
} | |
} | |
else if (DEBUG_PRI (muxu_dev, DEB_CMDS)) /* line invalid */ | |
fprintf (sim_deb, ">>MUXl cmds: [STC%s] Transmit channel %d invalid\n", hold_or_clear, ln); | |
} | |
else /* receive */ | |
if (ln < (MUX_LINES + MUX_ILINES)) { /* line valid? */ | |
if (muxl_obuf & OTL_P) { /* parameter? */ | |
mux_rpar[ln] = muxl_obuf; /* store param value */ | |
if (DEBUG_PRI (muxu_dev, DEB_CMDS)) | |
fprintf (sim_deb, | |
">>MUXl cmds: [STC%s] Receive channel %d parameter %06o stored\n", | |
hold_or_clear, ln, muxl_obuf); | |
} | |
else if (DEBUG_PRI (muxu_dev, DEB_CMDS)) /* data (invalid action) */ | |
fprintf (sim_deb, | |
">>MUXl cmds: [STC%s] Receive channel %d parameter %06o invalid action\n", | |
hold_or_clear, ln, muxl_obuf); | |
} | |
else if (DEBUG_PRI (muxu_dev, DEB_CMDS)) /* line invalid */ | |
fprintf (sim_deb, ">>MUXl cmds: [STC%s] Receive channel %d invalid\n", hold_or_clear, ln); | |
break; | |
case ioSIR: /* set interrupt request */ | |
setstdPRL (muxl); /* set standard PRL signal */ | |
setstdIRQ (muxl); /* set standard IRQ signal */ | |
setstdSRQ (muxl); /* set standard SRQ signal */ | |
break; | |
case ioIAK: /* interrupt acknowledge */ | |
muxl.flagbuf = CLEAR; | |
break; | |
default: /* all other signals */ | |
break; /* are ignored */ | |
} | |
working_set = working_set & ~signal; /* remove current signal from set */ | |
} | |
return stat_data; | |
} | |
/* Upper data card I/O signal handler. | |
The upper data card does not have a control, flag, or flag buffer flip-flop. | |
It does not drive the IRQ or SRQ lines, so the I/O dispatcher does not handle | |
the ioSIR signal. | |
Implementation notes: | |
1. The upper and lower data card hardware takes a number of actions in | |
response to the CRS signal. Under simulation, these actions are taken by | |
the lower data card CRS handler. | |
*/ | |
uint32 muxuio (DIB *dibptr, IOCYCLE signal_set, uint32 stat_data) | |
{ | |
IOSIGNAL signal; | |
IOCYCLE working_set = IOADDSIR (signal_set); /* add ioSIR if needed */ | |
while (working_set) { | |
signal = IONEXT (working_set); /* isolate next signal */ | |
switch (signal) { /* dispatch I/O signal */ | |
case ioIOI: /* I/O data input */ | |
stat_data = IORETURN (SCPE_OK, muxu_ibuf); /* merge in return status */ | |
if (DEBUG_PRI (muxu_dev, DEB_CPU)) | |
fprintf (sim_deb, ">>MUXu cpu: [LIx] Status = %06o, channel = %d\n", | |
muxu_ibuf, MUX_CHAN(muxu_ibuf)); | |
break; | |
case ioIOO: /* I/O data output */ | |
muxu_obuf = IODATA (stat_data); /* store data */ | |
if (DEBUG_PRI (muxu_dev, DEB_CPU)) | |
fprintf (sim_deb, ">>MUXu cpu: [OTx] Data channel = %d\n", MUX_CHAN(muxu_obuf)); | |
break; | |
default: /* all other signals */ | |
break; /* are ignored */ | |
} | |
working_set = working_set & ~signal; /* remove current signal from set */ | |
} | |
return stat_data; | |
} | |
/* Control card I/O signal handler. | |
In diagnostic mode, the control signals C1 and C2 are looped back to status | |
signals S1 and S2. Changing the control signals may cause an interrupt, so a | |
test is performed after IOO processing. | |
*/ | |
uint32 muxcio (DIB *dibptr, IOCYCLE signal_set, uint32 stat_data) | |
{ | |
const char *hold_or_clear = (signal_set & ioCLF ? ",C" : ""); | |
uint16 data; | |
int32 ln, old; | |
IOSIGNAL signal; | |
IOCYCLE working_set = IOADDSIR (signal_set); /* add ioSIR if needed */ | |
while (working_set) { | |
signal = IONEXT (working_set); /* isolate next signal */ | |
switch (signal) { /* dispatch I/O signal */ | |
case ioCLF: /* clear flag flip-flop */ | |
muxc.flag = muxc.flagbuf = CLEAR; | |
if (DEBUG_PRI (muxu_dev, DEB_CMDS)) | |
fputs (">>MUXc cmds: [CLF] Flag cleared\n", sim_deb); | |
mux_ctrl_int (); /* look for new int */ | |
break; | |
case ioSTF: /* set flag flip-flop */ | |
case ioENF: /* enable flag */ | |
muxc.flag = muxc.flagbuf = SET; | |
if (DEBUG_PRI (muxu_dev, DEB_CMDS)) | |
fputs (">>MUXc cmds: [STF] Flag set\n", sim_deb); | |
break; | |
case ioSFC: /* skip if flag is clear */ | |
setstdSKF (muxc); | |
break; | |
case ioSFS: /* skip if flag is set */ | |
setstdSKF (muxc); | |
break; | |
case ioIOI: /* I/O data input */ | |
data = LIC_MBO | PUT_CCH (muxc_chan) | /* mbo, chan num */ | |
LIC_TSTI (muxc_chan) | /* I2, I1 */ | |
(muxc_ota[muxc_chan] & (OTC_ES2 | OTC_ES1)) | /* ES2, ES1 */ | |
(muxc_lia[muxc_chan] & (LIC_S2 | LIC_S1)); /* S2, S1 */ | |
if (DEBUG_PRI (muxu_dev, DEB_CPU)) | |
fprintf (sim_deb, ">>MUXc cpu: [LIx%s] Status = %06o, channel = %d\n", | |
hold_or_clear, data, muxc_chan); | |
muxc_chan = (muxc_chan + 1) & LIC_M_CHAN; /* incr channel */ | |
stat_data = IORETURN (SCPE_OK, data); /* merge in return status */ | |
break; | |
case ioIOO: /* I/O data output */ | |
data = IODATA (stat_data); /* clear supplied status */ | |
ln = muxc_chan = OTC_CHAN (data); /* set channel */ | |
if (data & OTC_SCAN) muxc_scan = 1; /* set scan flag */ | |
else muxc_scan = 0; | |
if (data & OTC_UPD) { /* update? */ | |
old = muxc_ota[ln]; /* save prior val */ | |
muxc_ota[ln] = /* save ESn,SSn */ | |
(muxc_ota[ln] & ~OTC_RW) | (data & OTC_RW); | |
if (data & OTC_EC2) /* if EC2, upd C2 */ | |
muxc_ota[ln] = | |
(muxc_ota[ln] & ~OTC_C2) | (data & OTC_C2); | |
if (data & OTC_EC1) /* if EC1, upd C1 */ | |
muxc_ota[ln] = | |
(muxc_ota[ln] & ~OTC_C1) | (data & OTC_C1); | |
if (muxu_unit.flags & UNIT_DIAG) /* loopback? */ | |
muxc_lia[ln ^ 1] = /* set S1, S2 to C1, C2 */ | |
(muxc_lia[ln ^ 1] & ~(LIC_S2 | LIC_S1)) | | |
(muxc_ota[ln] & (OTC_C1 | OTC_C2)) >> OTC_V_C; | |
else if ((muxl_unit[ln].flags & UNIT_MDM) && /* modem ctrl? */ | |
(old & DTR) && /* DTR drop? */ | |
!(muxc_ota[ln] & DTR)) { | |
tmxr_linemsg (&mux_ldsc[ln], "\r\nLine hangup\r\n"); | |
tmxr_reset_ln (&mux_ldsc[ln]); /* reset line */ | |
muxc_lia[ln] = 0; /* dataset off */ | |
} | |
} /* end update */ | |
if (DEBUG_PRI (muxu_dev, DEB_CPU)) | |
fprintf (sim_deb, ">>MUXc cpu: [OTx%s] Parameter = %06o, channel = %d\n", | |
hold_or_clear, data, ln); | |
if ((muxu_unit.flags & UNIT_DIAG) && (!muxc.flag)) /* loopback and flag clear? */ | |
mux_ctrl_int (); /* status chg may interrupt */ | |
break; | |
case ioPOPIO: /* power-on preset to I/O */ | |
muxc.flag = muxc.flagbuf = SET; /* set flag and flag buffer */ | |
break; | |
case ioCRS: /* control reset */ | |
case ioCLC: /* clear control flip-flop */ | |
muxc.control = CLEAR; | |
break; | |
case ioSTC: /* set control flip-flop */ | |
muxc.control = SET; | |
break; | |
case ioSIR: /* set interrupt request */ | |
setstdPRL (muxc); /* set standard PRL signal */ | |
setstdIRQ (muxc); /* set standard IRQ signal */ | |
setstdSRQ (muxc); /* set standard SRQ signal */ | |
break; | |
case ioIAK: /* interrupt acknowledge */ | |
muxc.flagbuf = CLEAR; | |
break; | |
default: /* all other signals */ | |
break; /* are ignored */ | |
} | |
working_set = working_set & ~signal; /* remove current signal from set */ | |
} | |
return stat_data; | |
} | |
/* Unit service - receive side | |
Poll for new connections | |
Poll all active lines for input | |
*/ | |
t_stat muxi_svc (UNIT *uptr) | |
{ | |
int32 ln, c; | |
t_bool loopback; | |
loopback = ((muxu_unit.flags & UNIT_DIAG) != 0); /* diagnostic mode? */ | |
if (!loopback) { /* terminal mode? */ | |
if (uptr->wait == POLL_FIRST) /* first poll? */ | |
uptr->wait = sync_poll (INITIAL); /* initial synchronization */ | |
else /* not first */ | |
uptr->wait = sync_poll (SERVICE); /* continue synchronization */ | |
sim_activate (uptr, uptr->wait); /* continue polling */ | |
ln = tmxr_poll_conn (&mux_desc); /* look for connect */ | |
if (ln >= 0) { /* got one? */ | |
if ((muxl_unit[ln].flags & UNIT_MDM) && /* modem ctrl? */ | |
(muxc_ota[ln] & DTR)) /* DTR? */ | |
muxc_lia[ln] = muxc_lia[ln] | CDET; /* set cdet */ | |
muxc_lia[ln] = muxc_lia[ln] | DSR; /* set dsr */ | |
mux_ldsc[ln].rcve = 1; /* rcv enabled */ | |
} | |
tmxr_poll_rx (&mux_desc); /* poll for input */ | |
} | |
for (ln = 0; ln < MUX_LINES; ln++) { /* loop thru lines */ | |
if (mux_ldsc[ln].conn) { /* connected? */ | |
if (loopback) { /* diagnostic mode? */ | |
c = mux_xbuf[ln ^ 1] & OTL_CHAR; /* get char from xmit line */ | |
if (c == 0) /* all char bits = 0? */ | |
c = c | SCPE_BREAK; /* set break flag */ | |
mux_ldsc[ln].conn = 0; /* clear connection */ | |
} | |
else if (mux_defer[ln]) /* break deferred? */ | |
c = SCPE_BREAK; /* supply it now */ | |
else | |
c = tmxr_getc_ln (&mux_ldsc[ln]); /* get char from Telnet */ | |
if (c) /* valid char? */ | |
mux_receive (ln, c, loopback); /* process it */ | |
} | |
else /* not connected */ | |
if (!loopback) /* terminal mode? */ | |
muxc_lia[ln] = 0; /* line disconnected */ | |
} | |
if (!muxl.flag) mux_data_int (); /* scan for data int */ | |
if (!muxc.flag) mux_ctrl_int (); /* scan modem */ | |
return SCPE_OK; | |
} | |
/* Unit service - transmit side */ | |
t_stat muxo_svc (UNIT *uptr) | |
{ | |
int32 c, fc, ln, altln; | |
t_bool loopback; | |
ln = uptr - muxl_unit; /* line # */ | |
altln = ln ^ 1; /* alt. line for diag mode */ | |
fc = mux_xbuf[ln] & OTL_CHAR; /* full character data */ | |
c = fc & 0377; /* Telnet character data */ | |
loopback = ((muxu_unit.flags & UNIT_DIAG) != 0); /* diagnostic mode? */ | |
if (mux_ldsc[ln].conn) { /* connected? */ | |
if (mux_ldsc[ln].xmte) { /* xmt enabled? */ | |
if (loopback) /* diagnostic mode? */ | |
mux_ldsc[ln].conn = 0; /* clear connection */ | |
else if (mux_defer[ln]) /* break deferred? */ | |
mux_receive (ln, SCPE_BREAK, loopback); /* process it now */ | |
if ((mux_xbuf[ln] & OTL_SYNC) == 0) { /* start bit 0? */ | |
TMLN *lp = &mux_ldsc[ln]; /* get line */ | |
c = sim_tt_outcvt (c, TT_GET_MODE (muxl_unit[ln].flags)); | |
if (mux_xpar[ln] & OTL_DIAG) /* xmt diagnose? */ | |
mux_diag (fc); /* before munge */ | |
if (loopback) { /* diagnostic mode? */ | |
mux_ldsc[altln].conn = 1; /* set recv connection */ | |
sim_activate (&muxu_unit, 1); /* schedule receive */ | |
} | |
else { /* no loopback */ | |
if (c >= 0) /* valid? */ | |
tmxr_putc_ln (lp, c); /* output char */ | |
tmxr_poll_tx (&mux_desc); /* poll xmt */ | |
} | |
} | |
mux_xdon[ln] = 1; /* set for xmit irq */ | |
if (DEBUG_PRI (muxu_dev, DEB_XFER) && (loopback | (c >= 0))) | |
fprintf (sim_deb, ">>MUXl xfer: Line %d character %s sent\n", | |
ln, fmt_char ((uint8) (loopback ? fc : c))); | |
} | |
else { /* buf full */ | |
tmxr_poll_tx (&mux_desc); /* poll xmt */ | |
sim_activate (uptr, muxl_unit[ln].wait); /* wait */ | |
return SCPE_OK; | |
} | |
} | |
if (!muxl.flag) mux_data_int (); /* scan for int */ | |
return SCPE_OK; | |
} | |
/* Process a character received from a multiplexer port */ | |
void mux_receive (int32 ln, int32 c, t_bool diag) | |
{ | |
if (c & SCPE_BREAK) { /* break? */ | |
if (mux_defer[ln] || diag) { /* break deferred or diagnostic mode? */ | |
mux_defer[ln] = 0; /* process now */ | |
mux_rbuf[ln] = 0; /* break returns NUL */ | |
mux_sta[ln] = mux_sta[ln] | LIU_BRK; /* set break status */ | |
if (DEBUG_PRI (muxu_dev, DEB_XFER)) | |
if (diag) | |
fputs (">>MUXl xfer: Break detected\n", sim_deb); | |
else | |
fputs (">>MUXl xfer: Deferred break processed\n", sim_deb); | |
} | |
else { | |
mux_defer[ln] = 1; /* defer break */ | |
if (DEBUG_PRI (muxu_dev, DEB_XFER)) | |
fputs (">>MUXl xfer: Break detected and deferred\n", sim_deb); | |
return; | |
} | |
} | |
else { /* normal */ | |
if (mux_rchp[ln]) /* char already pending? */ | |
mux_sta[ln] = mux_sta[ln] | LIU_LOST; | |
if (!diag) { /* terminal mode? */ | |
c = sim_tt_inpcvt (c, TT_GET_MODE (muxl_unit[ln].flags)); | |
if (mux_rpar[ln] & OTL_ECHO) { /* echo? */ | |
TMLN *lp = &mux_ldsc[ln]; /* get line */ | |
tmxr_putc_ln (lp, c); /* output char */ | |
tmxr_poll_tx (&mux_desc); /* poll xmt */ | |
} | |
} | |
mux_rbuf[ln] = c; /* save char */ | |
} | |
mux_rchp[ln] = 1; /* char pending */ | |
if (DEBUG_PRI (muxu_dev, DEB_XFER)) | |
fprintf (sim_deb, ">>MUXl xfer: Line %d character %s received\n", | |
ln, fmt_char ((uint8) c)); | |
if (mux_rpar[ln] & OTL_DIAG) /* diagnose this line? */ | |
mux_diag (c); /* do diagnosis */ | |
return; | |
} | |
/* Look for data interrupt */ | |
void mux_data_int (void) | |
{ | |
int32 i; | |
for (i = 0; i < MUX_LINES; i++) { /* rcv lines */ | |
if ((mux_rpar[i] & OTL_ENB) && mux_rchp[i]) { /* enabled, char? */ | |
muxl_ibuf = PUT_DCH (i) | /* lo buf = char */ | |
mux_rbuf[i] & LIL_CHAR | | |
RCV_PAR (mux_rbuf[i]); | |
muxu_ibuf = PUT_DCH (i) | mux_sta[i]; /* hi buf = stat */ | |
mux_rchp[i] = 0; /* clr char, stat */ | |
mux_sta[i] = 0; | |
if (DEBUG_PRI (muxu_dev, DEB_CMDS)) | |
fprintf (sim_deb, ">>MUXl cmds: Receive channel %d interrupt requested\n", i); | |
muxlio (&muxl_dib, ioENF, 0); /* interrupt */ | |
return; | |
} | |
} | |
for (i = 0; i < MUX_LINES; i++) { /* xmt lines */ | |
if ((mux_xpar[i] & OTL_ENB) && mux_xdon[i]) { /* enabled, done? */ | |
muxl_ibuf = PUT_DCH (i) | /* lo buf = last rcv char */ | |
mux_rbuf[i] & LIL_CHAR | | |
RCV_PAR (mux_rbuf[i]); | |
muxu_ibuf = PUT_DCH (i) | mux_sta[i] | LIU_TR; /* hi buf = stat */ | |
mux_xdon[i] = 0; /* clr done, stat */ | |
mux_sta[i] = 0; | |
if (DEBUG_PRI (muxu_dev, DEB_CMDS)) | |
fprintf (sim_deb, ">>MUXl cmds: Transmit channel %d interrupt requested\n", i); | |
muxlio (&muxl_dib, ioENF, 0); /* interrupt */ | |
return; | |
} | |
} | |
for (i = MUX_LINES; i < (MUX_LINES + MUX_ILINES); i++) { /* diag lines */ | |
if ((mux_rpar[i] & OTL_ENB) && mux_rchp[i]) { /* enabled, char? */ | |
muxl_ibuf = PUT_DCH (i) | /* lo buf = char */ | |
mux_rbuf[i] & LIL_CHAR | | |
RCV_PAR (mux_rbuf[i]); | |
muxu_ibuf = PUT_DCH (i) | mux_sta[i] | LIU_DG; /* hi buf = stat */ | |
mux_rchp[i] = 0; /* clr char, stat */ | |
mux_sta[i] = 0; | |
if (DEBUG_PRI (muxu_dev, DEB_CMDS)) | |
fprintf (sim_deb, ">>MUXl cmds: Receive channel %d interrupt requested\n", i); | |
muxlio (&muxl_dib, ioENF, 0); /* interrupt */ | |
return; | |
} | |
} | |
return; | |
} | |
/* Look for control interrupt | |
If either of the incoming status bits does not match the stored status, and | |
the corresponding mismatch is enabled, a control interrupt request is | |
generated. Depending on the scan flag, we check either all 16 lines or just | |
the current line. If an interrupt is requested, the channel counter | |
indicates the interrupting channel. | |
*/ | |
void mux_ctrl_int (void) | |
{ | |
int32 i, line_count; | |
line_count = (muxc_scan ? MUX_LINES : 1); /* check one or all lines */ | |
for (i = 0; i < line_count; i++) { | |
if (muxc_scan) /* scanning? */ | |
muxc_chan = (muxc_chan + 1) & LIC_M_CHAN; /* step channel */ | |
if (LIC_TSTI (muxc_chan)) { /* status change? */ | |
if (DEBUG_PRI (muxu_dev, DEB_CMDS)) | |
fprintf (sim_deb, | |
">>MUXc cmds: Control channel %d interrupt requested (poll = %d)\n", | |
muxc_chan, i + 1); | |
muxcio (&muxc_dib, ioENF, 0); /* set flag */ | |
break; | |
} | |
} | |
return; | |
} | |
/* Set diagnostic lines for given character */ | |
void mux_diag (int32 c) | |
{ | |
int32 i; | |
for (i = MUX_LINES; i < (MUX_LINES + MUX_ILINES); i++) { | |
if (c & SCPE_BREAK) { /* break? */ | |
mux_sta[i] = mux_sta[i] | LIU_BRK; | |
mux_rbuf[i] = 0; /* no char */ | |
} | |
else { | |
if (mux_rchp[i]) mux_sta[i] = mux_sta[i] | LIU_LOST; | |
mux_rchp[i] = 1; | |
mux_rbuf[i] = c; | |
} | |
} | |
return; | |
} | |
/* Reset an individual line */ | |
void mux_reset_ln (int32 i) | |
{ | |
mux_rbuf[i] = mux_xbuf[i] = 0; /* clear state */ | |
mux_rpar[i] = mux_xpar[i] = 0; | |
mux_rchp[i] = mux_xdon[i] = 0; | |
mux_sta[i] = mux_defer[i] = 0; | |
muxc_ota[i] = muxc_lia[i] = 0; /* clear modem */ | |
if (mux_ldsc[i].conn && /* connected? */ | |
((muxu_unit.flags & UNIT_DIAG) == 0)) /* term mode? */ | |
muxc_lia[i] = muxc_lia[i] | DSR | /* cdet, dsr */ | |
(muxl_unit[i].flags & UNIT_MDM? CDET: 0); | |
sim_cancel (&muxl_unit[i]); | |
return; | |
} | |
/* Reset routine for lower data, upper data, and control cards */ | |
t_stat muxc_reset (DEVICE *dptr) | |
{ | |
int32 i; | |
DIB *dibptr = (DIB *) dptr->ctxt; /* DIB pointer */ | |
if (dptr == &muxc_dev) { /* make all consistent */ | |
hp_enbdis_pair (dptr, &muxl_dev); | |
hp_enbdis_pair (dptr, &muxu_dev); | |
} | |
else if (dptr == &muxl_dev) { | |
hp_enbdis_pair (dptr, &muxc_dev); | |
hp_enbdis_pair (dptr, &muxu_dev); | |
} | |
else { | |
hp_enbdis_pair (dptr, &muxc_dev); | |
hp_enbdis_pair (dptr, &muxl_dev); | |
} | |
IOPRESET (dibptr); /* PRESET device (does not use PON) */ | |
muxc_chan = muxc_scan = 0; /* init modem scan */ | |
if (muxu_unit.flags & UNIT_ATT) { /* master att? */ | |
muxu_unit.wait = POLL_FIRST; /* set up poll */ | |
sim_activate (&muxu_unit, muxu_unit.wait); /* start Telnet poll immediately */ | |
} | |
else | |
sim_cancel (&muxu_unit); /* else stop */ | |
for (i = 0; i < MUX_LINES; i++) | |
mux_reset_ln (i); /* reset lines 0-15 */ | |
for (i = MUX_LINES; i < (MUX_LINES + MUX_ILINES); i++) /* reset lines 16-20 */ | |
mux_rbuf[i] = mux_rpar[i] = mux_sta[i] = mux_rchp[i] = 0; | |
return SCPE_OK; | |
} | |
/* Attach master unit */ | |
t_stat mux_attach (UNIT *uptr, char *cptr) | |
{ | |
t_stat status = SCPE_OK; | |
if (muxu_unit.flags & UNIT_DIAG) /* diag mode? */ | |
return SCPE_NOFNC; /* command not allowed */ | |
status = tmxr_attach (&mux_desc, uptr, cptr); /* attach */ | |
if (status == SCPE_OK) { | |
muxu_unit.wait = POLL_FIRST; /* set up poll */ | |
sim_activate (&muxu_unit, muxu_unit.wait); /* start Telnet poll immediately */ | |
} | |
return status; | |
} | |
/* Detach master unit */ | |
t_stat mux_detach (UNIT *uptr) | |
{ | |
int32 i; | |
t_stat r; | |
r = tmxr_detach (&mux_desc, uptr); /* detach */ | |
for (i = 0; i < MUX_LINES; i++) mux_ldsc[i].rcve = 0; /* disable rcv */ | |
sim_cancel (uptr); /* stop poll */ | |
return r; | |
} | |
/* Diagnostic/normal mode routine, | |
Diagnostic testing wants to exercise as much of the regular simulation code | |
as possible to ensure good test coverage. Normally, input polling and output | |
transmission only occurs on connected lines. In diagnostic mode, line | |
connection flags are set selectively to enable processing on the lines under | |
test. The alternative to this would require duplicating the send/receive | |
code; the diagnostic would then test the copy but not the actual code used | |
for normal character transfers, which is undesirable. | |
Therefore, to enable diagnostic mode, we must force a disconnect of the | |
master socket and any connected Telnet lines, which clears the connection | |
flags on all lines. Then we set the "transmission enabled" flags on all | |
lines to enable output character processing for the diagnostic. (Normally, | |
all of the flags are set when the multiplexer is first attached. Until then, | |
the enable flags default to "not enabled," so we enable them explicitly | |
here.) | |
*/ | |
t_stat mux_setdiag (UNIT *uptr, int32 val, char *cptr, void *desc) | |
{ | |
int32 ln; | |
if (val) { /* set diag? */ | |
mux_detach (uptr); /* detach lines */ | |
for (ln = 0; ln < MUX_LINES; ln++) /* enable transmission */ | |
mux_ldsc[ln].xmte = 1; /* on all lines */ | |
} | |
else { /* set term */ | |
for (ln = 0; ln < MUX_LINES; ln++) /* clear connections */ | |
mux_ldsc[ln].conn = 0; /* on all lines */ | |
} | |
return SCPE_OK; | |
} |