dec_dz.h - emulators/simh - Rivoreo Source Code Repositories

 /* dec_dz.c: DZ11 terminal multiplexor simulator

    Copyright (c) 2001-2002, 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 used in advertising or otherwise to promote the sale, use or other dealings
    in this Software without prior written authorization from Robert M Supnik.

    Based on the original DZ11 simulator by Thord Nilson, as updated by
    Arthur Krewat.

    dz		DZ11 terminal multiplexor

    31-Oct-02	RMS	Added 8b support
    12-Oct-02	RMS	Added autoconfigure support
    29-Sep-02	RMS	Fixed bug in set number of lines routine
 			Added variable vector support
 			New data structures
    22-Apr-02	RMS	Updated for changes in sim_tmxr
    28-Apr-02	RMS	Fixed interrupt acknowledge, fixed SHOW DZ ADDRESS
    14-Jan-02	RMS	Added multiboard support
    30-Dec-01	RMS	Added show statistics, set disconnect
 			Removed statistics registers
    03-Dec-01	RMS	Modified for extended SET/SHOW
    09-Nov-01	RMS	Added VAX support
    20-Oct-01	RMS	Moved getchar from sim_tmxr, changed interrupt
 			logic to use tmxr_rqln
    06-Oct-01	RMS	Fixed bug in carrier detect logic
    03-Oct-01	RMS	Added support for BSD-style "ringless" modems
    27-Sep-01	RMS	Fixed bug in xmte initialization
    17-Sep-01	RMS	Added separate autodisconnect switch
    16-Sep-01	RMS	Fixed modem control bit offsets

    This file is intended to be included in a shell routine that invokes
    a simulator definition file:

    pdp11_dz.c	= pdp11_defs.h + dec_dz.h
    pdp10_dz.c	= pdp10_defs.h + dec_dz.h
    vax_dz.c	= vax_defs.h + dec_dz.h
 */

 #include "sim_sock.h"
 #include "sim_tmxr.h"

 #if !defined (DZ_RDX)
 #define DZ_RDX		8
 #endif
 #if !defined (DZ_MUXES)
 #define DZ_MUXES	1
 #endif
 #if !defined (DZ_LINES)
 #define DZ_LINES	8
 #endif
 #if !defined (DZ_8B_DFLT)
 #define DZ_8B_DFLT	0
 #endif

 #define UNIT_V_8B	(UNIT_V_UF + 0)			/* 8b output */
 #define UNIT_8B		(1 << UNIT_V_8B)

 #define DZ_MNOMASK	(DZ_MUXES - 1)			/* mask for mux no */
 #define DZ_LNOMASK	(DZ_LINES - 1)			/* mask for lineno */
 #define DZ_LMASK	((1 << DZ_LINES) - 1)		/* mask of lines */
 #define DZ_SILO_ALM	16				/* silo alarm level */

 /* DZCSR - 160100 - control/status register */

 #define CSR_MAINT	0000010				/* maint - NI */
 #define CSR_CLR		0000020				/* clear */
 #define CSR_MSE		0000040				/* master scan enb */
 #define CSR_RIE		0000100				/* rcv int enb */
 #define CSR_RDONE	0000200				/* rcv done - RO */
 #define CSR_V_TLINE	8				/* xmit line - RO */
 #define CSR_TLINE	(DZ_LNOMASK << CSR_V_TLINE)
 #define CSR_SAE		0010000				/* silo alm enb */
 #define CSR_SA		0020000				/* silo alm - RO */
 #define CSR_TIE		0040000				/* xmit int enb */
 #define CSR_TRDY	0100000				/* xmit rdy - RO */
 #define CSR_RW		(CSR_MSE | CSR_RIE | CSR_SAE | CSR_TIE)
 #define CSR_MBZ		(0004003 | CSR_CLR | CSR_MAINT)

 #define CSR_GETTL(x)	(((x) >> CSR_V_TLINE) & DZ_LNOMASK)
 #define CSR_PUTTL(x,y)	x = ((x) & ~CSR_TLINE) | (((y) & DZ_LNOMASK) << CSR_V_TLINE)

 /* DZRBUF - 160102 - receive buffer, read only */

 #define RBUF_CHAR	0000377				/* rcv char */
 #define RBUF_V_RLINE	8				/* rcv line */
 #define RBUF_PARE	0010000				/* parity err - NI */
 #define RBUF_FRME	0020000				/* frame err - NI */
 #define RBUF_OVRE	0040000				/* overrun err - NI */
 #define RBUF_VALID	0100000				/* rcv valid */
 #define RBUF_MBZ	0004000

 /* DZLPR - 160102 - line parameter register, write only, word access only */

 #define LPR_V_LINE	0				/* line */
 #define LPR_LPAR	0007770				/* line pars - NI */
 #define LPR_RCVE	0010000				/* receive enb */
 #define LPR_GETLN(x)	(((x) >> LPR_V_LINE) & DZ_LNOMASK)

 /* DZTCR - 160104 - transmission control register */

 #define TCR_V_XMTE	0				/* xmit enables */
 #define TCR_V_DTR	8				/* DTRs */

 /* DZMSR - 160106 - modem status register, read only */

 #define MSR_V_RI	0				/* ring indicators */
 #define MSR_V_CD	8				/* carrier detect */

 /* DZTDR - 160106 - transmit data, write only */

 #define TDR_CHAR	0000377				/* xmit char */
 #define TDR_V_TBR	8				/* xmit break - NI */

 extern int32 IREQ (HLVL);
 extern int32 sim_switches;
 extern FILE *sim_log;
 extern int32 tmxr_poll;					/* calibrated delay */

 uint16 dz_csr[DZ_MUXES] = { 0 };			/* csr */
 uint16 dz_rbuf[DZ_MUXES] = { 0 };			/* rcv buffer */
 uint16 dz_lpr[DZ_MUXES] = { 0 };			/* line param */
 uint16 dz_tcr[DZ_MUXES] = { 0 };			/* xmit control */
 uint16 dz_msr[DZ_MUXES] = { 0 };			/* modem status */
 uint16 dz_tdr[DZ_MUXES] = { 0 };			/* xmit data */
 uint8 dz_sae[DZ_MUXES] = { 0 };				/* silo alarm enabled */
 uint32 dz_rxi = 0;					/* rcv interrupts */
 uint32 dz_txi = 0;					/* xmt interrupts */
 int32 dz_mctl = 0;					/* modem ctrl enabled */
 int32 dz_auto = 0;					/* autodiscon enabled */
 TMLN dz_ldsc[DZ_MUXES * DZ_LINES] = { 0 };		/* line descriptors */
 TMXR dz_desc = { DZ_MUXES * DZ_LINES, 0, 0, NULL };	/* mux descriptor */

 DEVICE dz_dev;
 t_stat dz_rd (int32 *data, int32 PA, int32 access);
 t_stat dz_wr (int32 data, int32 PA, int32 access);
 int32 dz_rxinta (void);
 int32 dz_txinta (void);
 t_stat dz_svc (UNIT *uptr);
 t_stat dz_reset (DEVICE *dptr);
 t_stat dz_attach (UNIT *uptr, char *cptr);
 t_stat dz_detach (UNIT *uptr);
 t_stat dz_clear (int32 dz, t_bool flag);
 int32 dz_getc (int32 dz);
 void dz_update_rcvi (void);
 void dz_update_xmti (void);
 void dz_clr_rxint (int32 dz);
 void dz_set_rxint (int32 dz);
 void dz_clr_txint (int32 dz);
 void dz_set_txint (int32 dz);
 t_stat dz_summ (FILE *st, UNIT *uptr, int32 val, void *desc);
 t_stat dz_show (FILE *st, UNIT *uptr, int32 val, void *desc);
 t_stat dz_show_vec (FILE *st, UNIT *uptr, int32 val, void *desc);
 t_stat dz_setnl (UNIT *uptr, int32 val, char *cptr, void *desc);

 /* DZ data structures

    dz_dev	DZ device descriptor
    dz_unit	DZ unit list
    dz_reg	DZ register list
 */

 DIB dz_dib = { IOBA_DZ, IOLN_DZ * DZ_MUXES, &dz_rd, &dz_wr,
 		2, IVCL (DZRX), VEC_DZRX, { &dz_rxinta, &dz_txinta } };

 UNIT dz_unit = { UDATA (&dz_svc, UNIT_ATTABLE + DZ_8B_DFLT, 0) };

 REG dz_nlreg = { DRDATA (NLINES, dz_desc.lines, 6), PV_LEFT };

 REG dz_reg[] = {
 	{ BRDATA (CSR, dz_csr, DZ_RDX, 16, DZ_MUXES) },
 	{ BRDATA (RBUF, dz_rbuf, DZ_RDX, 16, DZ_MUXES) },
 	{ BRDATA (LPR, dz_lpr, DZ_RDX, 16, DZ_MUXES) },
 	{ BRDATA (TCR, dz_tcr, DZ_RDX, 16, DZ_MUXES) },
 	{ BRDATA (MSR, dz_msr, DZ_RDX, 16, DZ_MUXES) },
 	{ BRDATA (TDR, dz_tdr, DZ_RDX, 16, DZ_MUXES) },
 	{ BRDATA (SAENB, dz_sae, DZ_RDX, 1, DZ_MUXES) },
 	{ GRDATA (RXINT, dz_rxi, DZ_RDX, DZ_MUXES, 0) },
 	{ GRDATA (TXINT, dz_txi, DZ_RDX, DZ_MUXES, 0) },
 	{ FLDATA (MDMCTL, dz_mctl, 0) },
 	{ FLDATA (AUTODS, dz_auto, 0) },
 	{ GRDATA (DEVADDR, dz_dib.ba, DZ_RDX, 32, 0), REG_HRO },
 	{ GRDATA (DEVVEC, dz_dib.vec, DZ_RDX, 16, 0), REG_HRO },
 	{ NULL }  };

 MTAB dz_mod[] = {
 	{ UNIT_8B, 0, "7b", "7B", NULL },
 	{ UNIT_8B, UNIT_8B, "8b", "8B", NULL },
 	{ MTAB_XTD | MTAB_VDV, 1, NULL, "DISCONNECT",
 		&tmxr_dscln, NULL, &dz_desc },
 	{ UNIT_ATT, UNIT_ATT, "connections", NULL, NULL, &dz_summ },
 	{ MTAB_XTD | MTAB_VDV | MTAB_NMO, 1, "CONNECTIONS", NULL,
 		NULL, &dz_show, NULL },
 	{ MTAB_XTD | MTAB_VDV | MTAB_NMO, 0, "STATISTICS", NULL,
 		NULL, &dz_show, NULL },
 	{ MTAB_XTD|MTAB_VDV, 010, "ADDRESS", "ADDRESS",
 		&set_addr, &show_addr, NULL },
 	{ MTAB_XTD|MTAB_VDV, 0, "VECTOR", "VECTOR",
 		&set_vec, &dz_show_vec, NULL },
 #if !defined (VM_PDP10)
 	{ MTAB_XTD | MTAB_VDV, 0, NULL, "AUTOCONFIGURE",
 		&set_addr_flt, NULL, NULL },
 #endif
 	{ MTAB_XTD | MTAB_VDV | MTAB_VAL, 0, "lines", "LINES",
 		&dz_setnl, NULL, &dz_nlreg },
 	{ 0 }  };

 DEVICE dz_dev = {
 	"DZ", &dz_unit, dz_reg, dz_mod,
 	1, DZ_RDX, 8, 1, DZ_RDX, 8,
 	&tmxr_ex, &tmxr_dep, &dz_reset,
 	NULL, &dz_attach, &dz_detach,
 	&dz_dib, DEV_FLTA | DEV_DISABLE | DEV_UBUS | DEV_QBUS };

 /* IO dispatch routines, I/O addresses 177601x0 - 177601x7 */

 t_stat dz_rd (int32 *data, int32 PA, int32 access)
 {
 int32 dz = ((PA - dz_dib.ba) >> 3) & DZ_MNOMASK;	/* get mux num */

 switch ((PA >> 1) & 03) {				/* case on PA<2:1> */
 case 00:						/* CSR */
 	*data = dz_csr[dz] = dz_csr[dz] & ~CSR_MBZ;
 	break;
 case 01:						/* RBUF */
 	dz_csr[dz] = dz_csr[dz] & ~CSR_SA;		/* clr silo alarm */
 	if (dz_csr[dz] & CSR_MSE) {			/* scanner on? */
 		dz_rbuf[dz] = dz_getc (dz);		/* get top of silo */
 		if (!dz_rbuf[dz]) dz_sae[dz] = 1;	/* empty? re-enable */
 		tmxr_poll_rx (&dz_desc);		/* poll input */
 		dz_update_rcvi ();  }			/* update rx intr */
 	else {	dz_rbuf[dz] = 0;			/* no data */
 		dz_update_rcvi ();  }			/* no rx intr */
 	*data = dz_rbuf[dz];
 	break;
 case 02:						/* TCR */
 	*data = dz_tcr[dz];
 	break;
 case 03:						/* MSR */
 	*data = dz_msr[dz];
 	break;  }
 return SCPE_OK;
 }

 t_stat dz_wr (int32 data, int32 PA, int32 access)
 {
 int32 dz = ((PA - dz_dib.ba) >> 3) & DZ_MNOMASK;	/* get mux num */
 int32 i, line;
 TMLN *lp;

 switch ((PA >> 1) & 03) {				/* case on PA<2:1> */
 case 00:						/* CSR */
 	if (access == WRITEB) data = (PA & 1)?		/* byte? merge */
 		(dz_csr[dz] & 0377) | (data << 8):
 		(dz_csr[dz] & ~0377) | data;
 	if (data & CSR_CLR) dz_clear (dz, FALSE);	/* clr? reset */
 	if (data & CSR_MSE) sim_activate (&dz_unit, tmxr_poll);
 	else dz_csr[dz] &= ~(CSR_SA | CSR_RDONE | CSR_TRDY);
 	if ((data & CSR_RIE) == 0) dz_clr_rxint (dz);	/* RIE = 0? */
 	else if (((dz_csr[dz] & CSR_IE) == 0) &&	/* RIE 0->1? */
 	         ((dz_csr[dz] & CSR_SAE)?
 		  (dz_csr[dz] & CSR_SA): (dz_csr[dz] & CSR_RDONE)))
 		dz_set_rxint (dz);
 	if ((data & CSR_TIE) == 0) dz_clr_txint (dz);	/* TIE = 0? */
 	else if (((dz_csr[dz] & CSR_TIE) == 0) && (dz_csr[dz] & CSR_TRDY))
 		dz_set_txint (dz);
 	dz_csr[dz] = (dz_csr[dz] & ~CSR_RW) | (data & CSR_RW);
 	break;
 case 01:						/* LPR */
 	dz_lpr[dz] = data;
 	line = (dz * DZ_LINES) + LPR_GETLN (data);	/* get line num */
 	lp = &dz_ldsc[line];				/* get line desc */
 	if (dz_lpr[dz] & LPR_RCVE) lp->rcve = 1;	/* rcv enb? on */
 	else lp->rcve = 0;				/* else line off */
 	tmxr_poll_rx (&dz_desc);			/* poll input */
 	dz_update_rcvi ();				/* update rx intr */
 	break;
 case 02:						/* TCR */
 	if (access == WRITEB) data = (PA & 1)?		/* byte? merge */
 		(dz_tcr[dz] & 0377) | (data << 8):
 		(dz_tcr[dz] & ~0377) | data;
 	if (dz_mctl) {					/* modem ctl? */
 		dz_msr[dz] |= ((data & 0177400) &	/* dcd |= dtr & ring */
 		    ((dz_msr[dz] & DZ_LMASK) << MSR_V_CD));
 		dz_msr[dz] &=  ~(data >> TCR_V_DTR);	/* ring &= ~dtr */
 		if (dz_auto) {				/* auto disconnect? */
 		    int32 drop;
 		    drop = (dz_tcr[dz] & ~data) >> TCR_V_DTR; /* drop = dtr & ~data */
 		    for (i = 0; i < DZ_LINES; i++) {	/* drop hangups */
 			line = (dz * DZ_LINES) + i;	/* get line num */
 			lp = &dz_ldsc[line];		/* get line desc */
 			if (lp->conn && (drop & (1 << i))) {
 			    tmxr_msg (lp->conn, "\r\nLine hangup\r\n");
 			    tmxr_reset_ln (lp);		/* reset line, cdet */
 			    dz_msr[dz] &= ~(1 << (i + MSR_V_CD));
 			    }				/* end if drop */
 			}				/* end for */
 		    }					/* end if auto */
 		}					/* end if modem */
 	dz_tcr[dz] = data;
 	tmxr_poll_tx (&dz_desc);			/* poll output */
 	dz_update_xmti ();				/* update int */
 	break;
 case 03:						/* TDR */
 	if (PA & 1) {					/* odd byte? */
 		dz_tdr[dz] = (dz_tdr[dz] & 0377) | (data << 8);	/* just save */
 		break;  }
 	dz_tdr[dz] = data;
 	if (dz_csr[dz] & CSR_MSE) {			/* enabled? */
 		line = (dz * DZ_LINES) + CSR_GETTL (dz_csr[dz]);
 		lp = &dz_ldsc[line];			/* get line desc */
 		tmxr_putc_ln (lp, dz_tdr[dz] &		/* store char */
 		    ((dz_unit.flags & UNIT_8B)? 0377: 0177));
 		tmxr_poll_tx (&dz_desc);		/* poll output */
 		dz_update_xmti ();  }			/* update int */
 	break;  }
 return SCPE_OK;
 }

 /* Unit service routine

    The DZ11 polls to see if asynchronous activity has occurred and now
    needs to be processed.  The polling interval is controlled by the clock
    simulator, so for most environments, it is calibrated to real time.
    Typical polling intervals are 50-60 times per second.

    The simulator assumes that software enables all of the multiplexors,
    or none of them.
 */

 t_stat dz_svc (UNIT *uptr)
 {
 int32 dz, t, newln;

 for (dz = t = 0; dz < DZ_MUXES; dz++)			/* check enabled */
 	t = t | (dz_csr[dz] & CSR_MSE);
 if (t) {						/* any enabled? */
 	newln = tmxr_poll_conn (&dz_desc);		/* poll connect */
 	if ((newln >= 0) && dz_mctl) {			/* got a live one? */
 		dz = newln / DZ_LINES;			/* get mux num */
 		if (dz_tcr[dz] & (1 << (newln + TCR_V_DTR)))	/* DTR set? */
 		     dz_msr[dz] |= (1 << (newln + MSR_V_CD));	/* set cdet */
 		else dz_msr[dz] |= (1 << newln);  }		/* set ring */
 	tmxr_poll_rx (&dz_desc);			/* poll input */
 	dz_update_rcvi ();				/* upd rcv intr */
 	tmxr_poll_tx (&dz_desc);			/* poll output */
 	dz_update_xmti ();				/* upd xmt intr */
 	sim_activate (uptr, tmxr_poll);  }		/* reactivate */
 return SCPE_OK;
 }

 /* Get first available character for mux, if any */

 int32 dz_getc (int32 dz)
 {
 uint32 i, line, c;

 for (i = c = 0; (i < DZ_LINES) && (c == 0); i++) { 	/* loop thru lines */
 	line = (dz * DZ_LINES) + i;			/* get line num */
 	c = tmxr_getc_ln (&dz_ldsc[line]);		/* test for input */
 	if (c) c = c | (i << RBUF_V_RLINE);		/* or in line # */
 	}						/* end for */
 return c;
 }

 /* Update receive interrupts */

 void dz_update_rcvi (void)
 {
 int32 i, dz, line, scnt[DZ_MUXES];
 TMLN *lp;

 for (dz = 0; dz < DZ_MUXES; dz++) {			/* loop thru muxes */
     scnt[dz] = 0;					/* clr input count */
     for (i = 0; i < DZ_LINES; i++) {			/* poll lines */
 	line = (dz * DZ_LINES) + i;			/* get line num */
 	lp = &dz_ldsc[line];				/* get line desc */
 	scnt[dz] = scnt[dz] + tmxr_rqln (lp);		/* sum buffers */
 	if (dz_mctl && !lp->conn)			/* if disconn */
 	    dz_msr[dz] &= ~(1 << (i + MSR_V_CD));	/* reset car det */
 	}
     }
 for (dz = 0; dz < DZ_MUXES; dz++) {			/* loop thru muxes */
     if (scnt[dz] && (dz_csr[dz] & CSR_MSE)) {		/* input & enabled? */
 	dz_csr[dz] |= CSR_RDONE;			/* set done */
 	if (dz_sae[dz] && (scnt[dz] >= DZ_SILO_ALM)) {	/* alm enb & cnt hi? */
 	    dz_csr[dz] |= CSR_SA;			/* set status */
 	    dz_sae[dz] = 0;  }  }			/* disable alarm */
     else dz_csr[dz] &= ~CSR_RDONE;			/* no, clear done */
     if ((dz_csr[dz] & CSR_RIE) &&			/* int enable */
 	((dz_csr[dz] & CSR_SAE)?
 	 (dz_csr[dz] & CSR_SA): (dz_csr[dz] & CSR_RDONE)))
 	dz_set_rxint (dz);				/* and alm/done? */
     else dz_clr_rxint (dz);				/* no, clear int */
     }
 return;
 }

 /* Update transmit interrupts */

 void dz_update_xmti (void)
 {
 int32 dz, linemask, i, j, line;

 for (dz = 0; dz < DZ_MUXES; dz++) {			/* loop thru muxes */
     linemask = dz_tcr[dz] & DZ_LMASK;			/* enabled lines */
     dz_csr[dz] &= ~CSR_TRDY;				/* assume not rdy */
     j = CSR_GETTL (dz_csr[dz]);				/* start at current */
     for (i = 0; i < DZ_LINES; i++) {			/* loop thru lines */
 	j = (j + 1) & DZ_LNOMASK;			/* next line */
 	line = (dz * DZ_LINES) + j;			/* get line num */
 	if ((linemask & (1 << j)) && dz_ldsc[line].xmte) {
 		CSR_PUTTL (dz_csr[dz], j);		/* put ln in csr */
 		dz_csr[dz] |= CSR_TRDY;			/* set xmt rdy */
 		break;  }  }
     if ((dz_csr[dz] & CSR_TIE) && (dz_csr[dz] & CSR_TRDY)) /* ready plus int? */
 	 dz_set_txint (dz);
     else dz_clr_txint (dz);				/* no int req */
     }
 return;
 }

 /* Interrupt routines */

 void dz_clr_rxint (int32 dz)
 {
 dz_rxi = dz_rxi & ~(1 << dz);				/* clr mux rcv int */
 if (dz_rxi == 0) CLR_INT (DZRX);			/* all clr? */
 else SET_INT (DZRX);					/* no, set intr */
 return;
 }

 void dz_set_rxint (int32 dz)
 {
 dz_rxi = dz_rxi | (1 << dz);				/* set mux rcv int */
 SET_INT (DZRX);						/* set master intr */
 return;
 }

 int32 dz_rxinta (void)
 {
 int32 dz;

 for (dz = 0; dz < DZ_MUXES; dz++) {			/* find 1st mux */
 	if (dz_rxi & (1 << dz)) {
 		dz_clr_rxint (dz);			/* clear intr */
 		return (dz_dib.vec + (dz * 010));  }  }	/* return vector */
 return 0;
 }

 void dz_clr_txint (int32 dz)
 {
 dz_txi = dz_txi & ~(1 << dz);				/* clr mux xmt int */
 if (dz_txi == 0) CLR_INT (DZTX);			/* all clr? */
 else SET_INT (DZTX);					/* no, set intr */
 return;
 }

 void dz_set_txint (int32 dz)
 {
 dz_txi = dz_txi | (1 << dz);				/* set mux xmt int */
 SET_INT (DZTX);						/* set master intr */
 return;
 }

 int32 dz_txinta (void)
 {
 int32 dz;

 for (dz = 0; dz < DZ_MUXES; dz++) {			/* find 1st mux */
 	if (dz_txi & (1 << dz)) {
 		dz_clr_txint (dz);			/* clear intr */
 		return (dz_dib.vec + 4 + (dz * 010));  }  }	/* return vector */
 return 0;
 }

 /* Device reset */

 t_stat dz_clear (int32 dz, t_bool flag)
 {
 int32 i, line;

 dz_csr[dz] = 0;						/* clear CSR */
 dz_rbuf[dz] = 0;					/* silo empty */
 dz_lpr[dz] = 0;						/* no params */
 if (flag) dz_tcr[dz] = 0;				/* INIT? clr all */
 else dz_tcr[dz] &= ~0377;				/* else save dtr */
 dz_tdr[dz] = 0;
 dz_sae[dz] = 1;						/* alarm on */
 dz_clr_rxint (dz);					/* clear int */
 dz_clr_txint (dz);
 for (i = 0; i < DZ_LINES; i++) {			/* loop thru lines */
 	line = (dz * DZ_LINES) + i;
 	if (!dz_ldsc[line].conn) dz_ldsc[line].xmte = 1;/* set xmt enb */
 	dz_ldsc[line].rcve = 0;  }			/* clr rcv enb */
 return SCPE_OK;
 }

 t_stat dz_reset (DEVICE *dptr)
 {
 int32 i, ndev;

 for (i = 0; i < (DZ_MUXES * DZ_LINES); i++)		/* init mux desc */
 	dz_desc.ldsc[i] = &dz_ldsc[i];
 for (i = 0; i < DZ_MUXES; i++) dz_clear (i, TRUE);	/* init muxes */
 dz_rxi = dz_txi = 0;					/* clr master int */
 CLR_INT (DZRX);
 CLR_INT (DZTX);
 sim_cancel (&dz_unit);					/* stop poll */
 ndev = ((dptr->flags & DEV_DIS)? 0: (dz_desc.lines / DZ_LINES));
 return auto_config (RANK_DZ, ndev);			/* auto config */
 }

 /* Attach */

 t_stat dz_attach (UNIT *uptr, char *cptr)
 {
 t_stat r;
 extern int32 sim_switches;

 dz_mctl = dz_auto = 0;					/* modem ctl off */
 r = tmxr_attach (&dz_desc, uptr, cptr);			/* attach mux */
 if (r != SCPE_OK) return r;				/* error? */
 if (sim_switches & SWMASK ('M')) {			/* modem control? */
 	dz_mctl = 1;
 	printf ("Modem control activated\n");
 	if (sim_log) fprintf (sim_log, "Modem control activated\n");
 	if (sim_switches & SWMASK ('A')) {		/* autodisconnect? */
 		dz_auto = 1;
 		printf ("Auto disconnect activated\n");
 		if (sim_log) fprintf (sim_log, "Auto disconnect activated\n");
 		}
 	}
 return SCPE_OK;
 }

 /* Detach */

 t_stat dz_detach (UNIT *uptr)
 {
 return tmxr_detach (&dz_desc, uptr);
 }

 /* Show summary processor */

 t_stat dz_summ (FILE *st, UNIT *uptr, int32 val, void *desc)
 {
 int32 i, t;

 for (i = t = 0; i < dz_desc.lines; i++) {		/* get num conn */
     if (dz_ldsc[i].conn) t = t + 1;  }
 if (t == 1) fprintf (st, "1 connection");
 else fprintf (st, "%d connections", t);
 return SCPE_OK;
 }

 /* SHOW CONN/STAT processor */

 t_stat dz_show (FILE *st, UNIT *uptr, int32 val, void *desc)
 {
 int32 i, t;

 for (i = t = 0; i < dz_desc.lines; i++) {		/* loop thru conn */
     if (dz_ldsc[i].conn) {
 	t = 1;
 	if (val) tmxr_fconns (st, &dz_ldsc[i], i);
 	else tmxr_fstats (st, &dz_ldsc[i], i);  }  }
 if (t == 0) fprintf (st, "all disconnected\n");
 return SCPE_OK;
 }

 /* SET LINES processor */

 t_stat dz_setnl (UNIT *uptr, int32 val, char *cptr, void *desc)
 {
 int32 newln, i, t, ndev;
 t_stat r;

 if (cptr == NULL) return SCPE_ARG;
 newln = (int32) get_uint (cptr, 10, (DZ_MUXES * DZ_LINES), &r);
 if ((r != SCPE_OK) || (newln == dz_desc.lines)) return r;
 if ((newln == 0) || (newln % DZ_LINES)) return SCPE_ARG;
 if (newln < dz_desc.lines) {
     for (i = newln, t = 0; i < dz_desc.lines; i++) t = t | dz_ldsc[i].conn;
     if (t && !get_yn ("This will disconnect users; proceed [N]?", FALSE))
 	return SCPE_OK;
     for (i = newln; i < dz_desc.lines; i++) {
 	if (dz_ldsc[i].conn) {
 	    tmxr_msg (dz_ldsc[i].conn, "\r\nOperator disconnected line\r\n");
 	    tmxr_reset_ln (&dz_ldsc[i]);  }		/* reset line */
 	if ((i % DZ_LINES) == (DZ_LINES - 1))
 	    dz_clear (i / DZ_LINES, TRUE);  }		/* reset mux */
     }
 dz_dib.lnt = (newln / DZ_LINES) * IOLN_DZ;		/* set length */
 dz_desc.lines = newln;
 ndev = ((dz_dev.flags & DEV_DIS)? 0: (dz_desc.lines / DZ_LINES));
 return auto_config (RANK_DZ, ndev);			/* auto config */
 }

 /* SHOW VECTOR processor */

 t_stat dz_show_vec (FILE *st, UNIT *uptr, int32 val, void *desc)
 {
 return show_vec (st, uptr, ((dz_desc.lines * 2) / DZ_LINES), desc);
 }
	/* dec_dz.c: DZ11 terminal multiplexor simulator

	Copyright (c) 2001-2002, 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 used in advertising or otherwise to promote the sale, use or other dealings
	in this Software without prior written authorization from Robert M Supnik.

	Based on the original DZ11 simulator by Thord Nilson, as updated by
	Arthur Krewat.

	dz DZ11 terminal multiplexor

	31-Oct-02 RMS Added 8b support
	12-Oct-02 RMS Added autoconfigure support
	29-Sep-02 RMS Fixed bug in set number of lines routine
	Added variable vector support
	New data structures
	22-Apr-02 RMS Updated for changes in sim_tmxr
	28-Apr-02 RMS Fixed interrupt acknowledge, fixed SHOW DZ ADDRESS
	14-Jan-02 RMS Added multiboard support
	30-Dec-01 RMS Added show statistics, set disconnect
	Removed statistics registers
	03-Dec-01 RMS Modified for extended SET/SHOW
	09-Nov-01 RMS Added VAX support
	20-Oct-01 RMS Moved getchar from sim_tmxr, changed interrupt
	logic to use tmxr_rqln
	06-Oct-01 RMS Fixed bug in carrier detect logic
	03-Oct-01 RMS Added support for BSD-style "ringless" modems
	27-Sep-01 RMS Fixed bug in xmte initialization
	17-Sep-01 RMS Added separate autodisconnect switch
	16-Sep-01 RMS Fixed modem control bit offsets

	This file is intended to be included in a shell routine that invokes
	a simulator definition file:

	pdp11_dz.c = pdp11_defs.h + dec_dz.h
	pdp10_dz.c = pdp10_defs.h + dec_dz.h
	vax_dz.c = vax_defs.h + dec_dz.h
	*/

	#include "sim_sock.h"
	#include "sim_tmxr.h"

	#if !defined (DZ_RDX)
	#define DZ_RDX 8
	#endif
	#if !defined (DZ_MUXES)
	#define DZ_MUXES 1
	#endif
	#if !defined (DZ_LINES)
	#define DZ_LINES 8
	#endif
	#if !defined (DZ_8B_DFLT)
	#define DZ_8B_DFLT 0
	#endif

	#define UNIT_V_8B (UNIT_V_UF + 0) /* 8b output */
	#define UNIT_8B (1 << UNIT_V_8B)

	#define DZ_MNOMASK (DZ_MUXES - 1) /* mask for mux no */
	#define DZ_LNOMASK (DZ_LINES - 1) /* mask for lineno */
	#define DZ_LMASK ((1 << DZ_LINES) - 1) /* mask of lines */
	#define DZ_SILO_ALM 16 /* silo alarm level */

	/* DZCSR - 160100 - control/status register */

	#define CSR_MAINT 0000010 /* maint - NI */
	#define CSR_CLR 0000020 /* clear */
	#define CSR_MSE 0000040 /* master scan enb */
	#define CSR_RIE 0000100 /* rcv int enb */
	#define CSR_RDONE 0000200 /* rcv done - RO */
	#define CSR_V_TLINE 8 /* xmit line - RO */
	#define CSR_TLINE (DZ_LNOMASK << CSR_V_TLINE)
	#define CSR_SAE 0010000 /* silo alm enb */
	#define CSR_SA 0020000 /* silo alm - RO */
	#define CSR_TIE 0040000 /* xmit int enb */
	#define CSR_TRDY 0100000 /* xmit rdy - RO */
	#define CSR_RW (CSR_MSE \| CSR_RIE \| CSR_SAE \| CSR_TIE)
	#define CSR_MBZ (0004003 \| CSR_CLR \| CSR_MAINT)

	#define CSR_GETTL(x) (((x) >> CSR_V_TLINE) & DZ_LNOMASK)
	#define CSR_PUTTL(x,y) x = ((x) & ~CSR_TLINE) \| (((y) & DZ_LNOMASK) << CSR_V_TLINE)

	/* DZRBUF - 160102 - receive buffer, read only */

	#define RBUF_CHAR 0000377 /* rcv char */
	#define RBUF_V_RLINE 8 /* rcv line */
	#define RBUF_PARE 0010000 /* parity err - NI */
	#define RBUF_FRME 0020000 /* frame err - NI */
	#define RBUF_OVRE 0040000 /* overrun err - NI */
	#define RBUF_VALID 0100000 /* rcv valid */
	#define RBUF_MBZ 0004000

	/* DZLPR - 160102 - line parameter register, write only, word access only */

	#define LPR_V_LINE 0 /* line */
	#define LPR_LPAR 0007770 /* line pars - NI */
	#define LPR_RCVE 0010000 /* receive enb */
	#define LPR_GETLN(x) (((x) >> LPR_V_LINE) & DZ_LNOMASK)

	/* DZTCR - 160104 - transmission control register */

	#define TCR_V_XMTE 0 /* xmit enables */
	#define TCR_V_DTR 8 /* DTRs */

	/* DZMSR - 160106 - modem status register, read only */

	#define MSR_V_RI 0 /* ring indicators */
	#define MSR_V_CD 8 /* carrier detect */

	/* DZTDR - 160106 - transmit data, write only */

	#define TDR_CHAR 0000377 /* xmit char */
	#define TDR_V_TBR 8 /* xmit break - NI */

	extern int32 IREQ (HLVL);
	extern int32 sim_switches;
	extern FILE *sim_log;
	extern int32 tmxr_poll; /* calibrated delay */

	uint16 dz_csr[DZ_MUXES] = { 0 }; /* csr */
	uint16 dz_rbuf[DZ_MUXES] = { 0 }; /* rcv buffer */
	uint16 dz_lpr[DZ_MUXES] = { 0 }; /* line param */
	uint16 dz_tcr[DZ_MUXES] = { 0 }; /* xmit control */
	uint16 dz_msr[DZ_MUXES] = { 0 }; /* modem status */
	uint16 dz_tdr[DZ_MUXES] = { 0 }; /* xmit data */
	uint8 dz_sae[DZ_MUXES] = { 0 }; /* silo alarm enabled */
	uint32 dz_rxi = 0; /* rcv interrupts */
	uint32 dz_txi = 0; /* xmt interrupts */
	int32 dz_mctl = 0; /* modem ctrl enabled */
	int32 dz_auto = 0; /* autodiscon enabled */
	TMLN dz_ldsc[DZ_MUXES * DZ_LINES] = { 0 }; /* line descriptors */
	TMXR dz_desc = { DZ_MUXES * DZ_LINES, 0, 0, NULL }; /* mux descriptor */

	DEVICE dz_dev;
	t_stat dz_rd (int32 *data, int32 PA, int32 access);
	t_stat dz_wr (int32 data, int32 PA, int32 access);
	int32 dz_rxinta (void);
	int32 dz_txinta (void);
	t_stat dz_svc (UNIT *uptr);
	t_stat dz_reset (DEVICE *dptr);
	t_stat dz_attach (UNIT uptr, char cptr);
	t_stat dz_detach (UNIT *uptr);
	t_stat dz_clear (int32 dz, t_bool flag);
	int32 dz_getc (int32 dz);
	void dz_update_rcvi (void);
	void dz_update_xmti (void);
	void dz_clr_rxint (int32 dz);
	void dz_set_rxint (int32 dz);
	void dz_clr_txint (int32 dz);
	void dz_set_txint (int32 dz);
	t_stat dz_summ (FILE st, UNIT uptr, int32 val, void *desc);
	t_stat dz_show (FILE st, UNIT uptr, int32 val, void *desc);
	t_stat dz_show_vec (FILE st, UNIT uptr, int32 val, void *desc);
	t_stat dz_setnl (UNIT uptr, int32 val, char cptr, void *desc);

	/* DZ data structures

	dz_dev DZ device descriptor
	dz_unit DZ unit list
	dz_reg DZ register list
	*/

	DIB dz_dib = { IOBA_DZ, IOLN_DZ * DZ_MUXES, &dz_rd, &dz_wr,
	2, IVCL (DZRX), VEC_DZRX, { &dz_rxinta, &dz_txinta } };

	UNIT dz_unit = { UDATA (&dz_svc, UNIT_ATTABLE + DZ_8B_DFLT, 0) };

	REG dz_nlreg = { DRDATA (NLINES, dz_desc.lines, 6), PV_LEFT };

	REG dz_reg[] = {
	{ BRDATA (CSR, dz_csr, DZ_RDX, 16, DZ_MUXES) },
	{ BRDATA (RBUF, dz_rbuf, DZ_RDX, 16, DZ_MUXES) },
	{ BRDATA (LPR, dz_lpr, DZ_RDX, 16, DZ_MUXES) },
	{ BRDATA (TCR, dz_tcr, DZ_RDX, 16, DZ_MUXES) },
	{ BRDATA (MSR, dz_msr, DZ_RDX, 16, DZ_MUXES) },
	{ BRDATA (TDR, dz_tdr, DZ_RDX, 16, DZ_MUXES) },
	{ BRDATA (SAENB, dz_sae, DZ_RDX, 1, DZ_MUXES) },
	{ GRDATA (RXINT, dz_rxi, DZ_RDX, DZ_MUXES, 0) },
	{ GRDATA (TXINT, dz_txi, DZ_RDX, DZ_MUXES, 0) },
	{ FLDATA (MDMCTL, dz_mctl, 0) },
	{ FLDATA (AUTODS, dz_auto, 0) },
	{ GRDATA (DEVADDR, dz_dib.ba, DZ_RDX, 32, 0), REG_HRO },
	{ GRDATA (DEVVEC, dz_dib.vec, DZ_RDX, 16, 0), REG_HRO },
	{ NULL } };

	MTAB dz_mod[] = {
	{ UNIT_8B, 0, "7b", "7B", NULL },
	{ UNIT_8B, UNIT_8B, "8b", "8B", NULL },
	{ MTAB_XTD \| MTAB_VDV, 1, NULL, "DISCONNECT",
	&tmxr_dscln, NULL, &dz_desc },
	{ UNIT_ATT, UNIT_ATT, "connections", NULL, NULL, &dz_summ },
	{ MTAB_XTD \| MTAB_VDV \| MTAB_NMO, 1, "CONNECTIONS", NULL,
	NULL, &dz_show, NULL },
	{ MTAB_XTD \| MTAB_VDV \| MTAB_NMO, 0, "STATISTICS", NULL,
	NULL, &dz_show, NULL },
	{ MTAB_XTD\|MTAB_VDV, 010, "ADDRESS", "ADDRESS",
	&set_addr, &show_addr, NULL },
	{ MTAB_XTD\|MTAB_VDV, 0, "VECTOR", "VECTOR",
	&set_vec, &dz_show_vec, NULL },
	#if !defined (VM_PDP10)
	{ MTAB_XTD \| MTAB_VDV, 0, NULL, "AUTOCONFIGURE",
	&set_addr_flt, NULL, NULL },
	#endif
	{ MTAB_XTD \| MTAB_VDV \| MTAB_VAL, 0, "lines", "LINES",
	&dz_setnl, NULL, &dz_nlreg },
	{ 0 } };

	DEVICE dz_dev = {
	"DZ", &dz_unit, dz_reg, dz_mod,
	1, DZ_RDX, 8, 1, DZ_RDX, 8,
	&tmxr_ex, &tmxr_dep, &dz_reset,
	NULL, &dz_attach, &dz_detach,
	&dz_dib, DEV_FLTA \| DEV_DISABLE \| DEV_UBUS \| DEV_QBUS };

	/* IO dispatch routines, I/O addresses 177601x0 - 177601x7 */

	t_stat dz_rd (int32 *data, int32 PA, int32 access)
	{
	int32 dz = ((PA - dz_dib.ba) >> 3) & DZ_MNOMASK; /* get mux num */

	switch ((PA >> 1) & 03) { /* case on PA<2:1> */
	case 00: /* CSR */
	*data = dz_csr[dz] = dz_csr[dz] & ~CSR_MBZ;
	break;
	case 01: /* RBUF */
	dz_csr[dz] = dz_csr[dz] & ~CSR_SA; /* clr silo alarm */
	if (dz_csr[dz] & CSR_MSE) { /* scanner on? */
	dz_rbuf[dz] = dz_getc (dz); /* get top of silo */
	if (!dz_rbuf[dz]) dz_sae[dz] = 1; /* empty? re-enable */
	tmxr_poll_rx (&dz_desc); /* poll input */
	dz_update_rcvi (); } /* update rx intr */
	else { dz_rbuf[dz] = 0; /* no data */
	dz_update_rcvi (); } /* no rx intr */
	*data = dz_rbuf[dz];
	break;
	case 02: /* TCR */
	*data = dz_tcr[dz];
	break;
	case 03: /* MSR */
	*data = dz_msr[dz];
	break; }
	return SCPE_OK;
	}

	t_stat dz_wr (int32 data, int32 PA, int32 access)
	{
	int32 dz = ((PA - dz_dib.ba) >> 3) & DZ_MNOMASK; /* get mux num */
	int32 i, line;
	TMLN *lp;

	switch ((PA >> 1) & 03) { /* case on PA<2:1> */
	case 00: /* CSR */
	if (access == WRITEB) data = (PA & 1)? /* byte? merge */
	(dz_csr[dz] & 0377) \| (data << 8):
	(dz_csr[dz] & ~0377) \| data;
	if (data & CSR_CLR) dz_clear (dz, FALSE); /* clr? reset */
	if (data & CSR_MSE) sim_activate (&dz_unit, tmxr_poll);
	else dz_csr[dz] &= ~(CSR_SA \| CSR_RDONE \| CSR_TRDY);
	if ((data & CSR_RIE) == 0) dz_clr_rxint (dz); /* RIE = 0? */
	else if (((dz_csr[dz] & CSR_IE) == 0) && /* RIE 0->1? */
	((dz_csr[dz] & CSR_SAE)?
	(dz_csr[dz] & CSR_SA): (dz_csr[dz] & CSR_RDONE)))
	dz_set_rxint (dz);
	if ((data & CSR_TIE) == 0) dz_clr_txint (dz); /* TIE = 0? */
	else if (((dz_csr[dz] & CSR_TIE) == 0) && (dz_csr[dz] & CSR_TRDY))
	dz_set_txint (dz);
	dz_csr[dz] = (dz_csr[dz] & ~CSR_RW) \| (data & CSR_RW);
	break;
	case 01: /* LPR */
	dz_lpr[dz] = data;
	line = (dz * DZ_LINES) + LPR_GETLN (data); /* get line num */
	lp = &dz_ldsc[line]; /* get line desc */
	if (dz_lpr[dz] & LPR_RCVE) lp->rcve = 1; /* rcv enb? on */
	else lp->rcve = 0; /* else line off */
	tmxr_poll_rx (&dz_desc); /* poll input */
	dz_update_rcvi (); /* update rx intr */
	break;
	case 02: /* TCR */
	if (access == WRITEB) data = (PA & 1)? /* byte? merge */
	(dz_tcr[dz] & 0377) \| (data << 8):
	(dz_tcr[dz] & ~0377) \| data;
	if (dz_mctl) { /* modem ctl? */
	dz_msr[dz] \|= ((data & 0177400) & /* dcd \|= dtr & ring */
	((dz_msr[dz] & DZ_LMASK) << MSR_V_CD));
	dz_msr[dz] &= ~(data >> TCR_V_DTR); /* ring &= ~dtr */
	if (dz_auto) { /* auto disconnect? */
	int32 drop;
	drop = (dz_tcr[dz] & ~data) >> TCR_V_DTR; /* drop = dtr & ~data */
	for (i = 0; i < DZ_LINES; i++) { /* drop hangups */
	line = (dz * DZ_LINES) + i; /* get line num */
	lp = &dz_ldsc[line]; /* get line desc */
	if (lp->conn && (drop & (1 << i))) {
	tmxr_msg (lp->conn, "\r\nLine hangup\r\n");
	tmxr_reset_ln (lp); /* reset line, cdet */
	dz_msr[dz] &= ~(1 << (i + MSR_V_CD));
	} /* end if drop */
	} /* end for */
	} /* end if auto */
	} /* end if modem */
	dz_tcr[dz] = data;
	tmxr_poll_tx (&dz_desc); /* poll output */
	dz_update_xmti (); /* update int */
	break;
	case 03: /* TDR */
	if (PA & 1) { /* odd byte? */
	dz_tdr[dz] = (dz_tdr[dz] & 0377) \| (data << 8); /* just save */
	break; }
	dz_tdr[dz] = data;
	if (dz_csr[dz] & CSR_MSE) { /* enabled? */
	line = (dz * DZ_LINES) + CSR_GETTL (dz_csr[dz]);
	lp = &dz_ldsc[line]; /* get line desc */
	tmxr_putc_ln (lp, dz_tdr[dz] & /* store char */
	((dz_unit.flags & UNIT_8B)? 0377: 0177));
	tmxr_poll_tx (&dz_desc); /* poll output */
	dz_update_xmti (); } /* update int */
	break; }
	return SCPE_OK;
	}

	/* Unit service routine

	The DZ11 polls to see if asynchronous activity has occurred and now
	needs to be processed. The polling interval is controlled by the clock
	simulator, so for most environments, it is calibrated to real time.
	Typical polling intervals are 50-60 times per second.

	The simulator assumes that software enables all of the multiplexors,
	or none of them.
	*/

	t_stat dz_svc (UNIT *uptr)
	{
	int32 dz, t, newln;

	for (dz = t = 0; dz < DZ_MUXES; dz++) /* check enabled */
	t = t \| (dz_csr[dz] & CSR_MSE);
	if (t) { /* any enabled? */
	newln = tmxr_poll_conn (&dz_desc); /* poll connect */
	if ((newln >= 0) && dz_mctl) { /* got a live one? */
	dz = newln / DZ_LINES; /* get mux num */
	if (dz_tcr[dz] & (1 << (newln + TCR_V_DTR))) /* DTR set? */
	dz_msr[dz] \|= (1 << (newln + MSR_V_CD)); /* set cdet */
	else dz_msr[dz] \|= (1 << newln); } /* set ring */
	tmxr_poll_rx (&dz_desc); /* poll input */
	dz_update_rcvi (); /* upd rcv intr */
	tmxr_poll_tx (&dz_desc); /* poll output */
	dz_update_xmti (); /* upd xmt intr */
	sim_activate (uptr, tmxr_poll); } /* reactivate */
	return SCPE_OK;
	}

	/* Get first available character for mux, if any */

	int32 dz_getc (int32 dz)
	{
	uint32 i, line, c;

	for (i = c = 0; (i < DZ_LINES) && (c == 0); i++) { /* loop thru lines */
	line = (dz * DZ_LINES) + i; /* get line num */
	c = tmxr_getc_ln (&dz_ldsc[line]); /* test for input */
	if (c) c = c \| (i << RBUF_V_RLINE); /* or in line # */
	} /* end for */
	return c;
	}

	/* Update receive interrupts */

	void dz_update_rcvi (void)
	{
	int32 i, dz, line, scnt[DZ_MUXES];
	TMLN *lp;

	for (dz = 0; dz < DZ_MUXES; dz++) { /* loop thru muxes */
	scnt[dz] = 0; /* clr input count */
	for (i = 0; i < DZ_LINES; i++) { /* poll lines */
	line = (dz * DZ_LINES) + i; /* get line num */
	lp = &dz_ldsc[line]; /* get line desc */
	scnt[dz] = scnt[dz] + tmxr_rqln (lp); /* sum buffers */
	if (dz_mctl && !lp->conn) /* if disconn */
	dz_msr[dz] &= ~(1 << (i + MSR_V_CD)); /* reset car det */
	}
	}
	for (dz = 0; dz < DZ_MUXES; dz++) { /* loop thru muxes */
	if (scnt[dz] && (dz_csr[dz] & CSR_MSE)) { /* input & enabled? */
	dz_csr[dz] \|= CSR_RDONE; /* set done */
	if (dz_sae[dz] && (scnt[dz] >= DZ_SILO_ALM)) { /* alm enb & cnt hi? */
	dz_csr[dz] \|= CSR_SA; /* set status */
	dz_sae[dz] = 0; } } /* disable alarm */
	else dz_csr[dz] &= ~CSR_RDONE; /* no, clear done */
	if ((dz_csr[dz] & CSR_RIE) && /* int enable */
	((dz_csr[dz] & CSR_SAE)?
	(dz_csr[dz] & CSR_SA): (dz_csr[dz] & CSR_RDONE)))
	dz_set_rxint (dz); /* and alm/done? */
	else dz_clr_rxint (dz); /* no, clear int */
	}
	return;
	}

	/* Update transmit interrupts */

	void dz_update_xmti (void)
	{
	int32 dz, linemask, i, j, line;

	for (dz = 0; dz < DZ_MUXES; dz++) { /* loop thru muxes */
	linemask = dz_tcr[dz] & DZ_LMASK; /* enabled lines */
	dz_csr[dz] &= ~CSR_TRDY; /* assume not rdy */
	j = CSR_GETTL (dz_csr[dz]); /* start at current */
	for (i = 0; i < DZ_LINES; i++) { /* loop thru lines */
	j = (j + 1) & DZ_LNOMASK; /* next line */
	line = (dz * DZ_LINES) + j; /* get line num */
	if ((linemask & (1 << j)) && dz_ldsc[line].xmte) {
	CSR_PUTTL (dz_csr[dz], j); /* put ln in csr */
	dz_csr[dz] \|= CSR_TRDY; /* set xmt rdy */
	break; } }
	if ((dz_csr[dz] & CSR_TIE) && (dz_csr[dz] & CSR_TRDY)) /* ready plus int? */
	dz_set_txint (dz);
	else dz_clr_txint (dz); /* no int req */
	}
	return;
	}

	/* Interrupt routines */

	void dz_clr_rxint (int32 dz)
	{
	dz_rxi = dz_rxi & ~(1 << dz); /* clr mux rcv int */
	if (dz_rxi == 0) CLR_INT (DZRX); /* all clr? */
	else SET_INT (DZRX); /* no, set intr */
	return;
	}

	void dz_set_rxint (int32 dz)
	{
	dz_rxi = dz_rxi \| (1 << dz); /* set mux rcv int */
	SET_INT (DZRX); /* set master intr */
	return;
	}

	int32 dz_rxinta (void)
	{
	int32 dz;

	for (dz = 0; dz < DZ_MUXES; dz++) { /* find 1st mux */
	if (dz_rxi & (1 << dz)) {
	dz_clr_rxint (dz); /* clear intr */
	return (dz_dib.vec + (dz * 010)); } } /* return vector */
	return 0;
	}

	void dz_clr_txint (int32 dz)
	{
	dz_txi = dz_txi & ~(1 << dz); /* clr mux xmt int */
	if (dz_txi == 0) CLR_INT (DZTX); /* all clr? */
	else SET_INT (DZTX); /* no, set intr */
	return;
	}

	void dz_set_txint (int32 dz)
	{
	dz_txi = dz_txi \| (1 << dz); /* set mux xmt int */
	SET_INT (DZTX); /* set master intr */
	return;
	}

	int32 dz_txinta (void)
	{
	int32 dz;

	for (dz = 0; dz < DZ_MUXES; dz++) { /* find 1st mux */
	if (dz_txi & (1 << dz)) {
	dz_clr_txint (dz); /* clear intr */
	return (dz_dib.vec + 4 + (dz * 010)); } } /* return vector */
	return 0;
	}

	/* Device reset */

	t_stat dz_clear (int32 dz, t_bool flag)
	{
	int32 i, line;

	dz_csr[dz] = 0; /* clear CSR */
	dz_rbuf[dz] = 0; /* silo empty */
	dz_lpr[dz] = 0; /* no params */
	if (flag) dz_tcr[dz] = 0; /* INIT? clr all */
	else dz_tcr[dz] &= ~0377; /* else save dtr */
	dz_tdr[dz] = 0;
	dz_sae[dz] = 1; /* alarm on */
	dz_clr_rxint (dz); /* clear int */
	dz_clr_txint (dz);
	for (i = 0; i < DZ_LINES; i++) { /* loop thru lines */
	line = (dz * DZ_LINES) + i;
	if (!dz_ldsc[line].conn) dz_ldsc[line].xmte = 1;/* set xmt enb */
	dz_ldsc[line].rcve = 0; } /* clr rcv enb */
	return SCPE_OK;
	}

	t_stat dz_reset (DEVICE *dptr)
	{
	int32 i, ndev;

	for (i = 0; i < (DZ_MUXES * DZ_LINES); i++) /* init mux desc */
	dz_desc.ldsc[i] = &dz_ldsc[i];
	for (i = 0; i < DZ_MUXES; i++) dz_clear (i, TRUE); /* init muxes */
	dz_rxi = dz_txi = 0; /* clr master int */
	CLR_INT (DZRX);
	CLR_INT (DZTX);
	sim_cancel (&dz_unit); /* stop poll */
	ndev = ((dptr->flags & DEV_DIS)? 0: (dz_desc.lines / DZ_LINES));
	return auto_config (RANK_DZ, ndev); /* auto config */
	}

	/* Attach */

	t_stat dz_attach (UNIT uptr, char cptr)
	{
	t_stat r;
	extern int32 sim_switches;

	dz_mctl = dz_auto = 0; /* modem ctl off */
	r = tmxr_attach (&dz_desc, uptr, cptr); /* attach mux */
	if (r != SCPE_OK) return r; /* error? */
	if (sim_switches & SWMASK ('M')) { /* modem control? */
	dz_mctl = 1;
	printf ("Modem control activated\n");
	if (sim_log) fprintf (sim_log, "Modem control activated\n");
	if (sim_switches & SWMASK ('A')) { /* autodisconnect? */
	dz_auto = 1;
	printf ("Auto disconnect activated\n");
	if (sim_log) fprintf (sim_log, "Auto disconnect activated\n");
	}
	}
	return SCPE_OK;
	}

	/* Detach */

	t_stat dz_detach (UNIT *uptr)
	{
	return tmxr_detach (&dz_desc, uptr);
	}

	/* Show summary processor */

	t_stat dz_summ (FILE st, UNIT uptr, int32 val, void *desc)
	{
	int32 i, t;

	for (i = t = 0; i < dz_desc.lines; i++) { /* get num conn */
	if (dz_ldsc[i].conn) t = t + 1; }
	if (t == 1) fprintf (st, "1 connection");
	else fprintf (st, "%d connections", t);
	return SCPE_OK;
	}

	/* SHOW CONN/STAT processor */

	t_stat dz_show (FILE st, UNIT uptr, int32 val, void *desc)
	{
	int32 i, t;

	for (i = t = 0; i < dz_desc.lines; i++) { /* loop thru conn */
	if (dz_ldsc[i].conn) {
	t = 1;
	if (val) tmxr_fconns (st, &dz_ldsc[i], i);
	else tmxr_fstats (st, &dz_ldsc[i], i); } }
	if (t == 0) fprintf (st, "all disconnected\n");
	return SCPE_OK;
	}

	/* SET LINES processor */

	t_stat dz_setnl (UNIT uptr, int32 val, char cptr, void *desc)
	{
	int32 newln, i, t, ndev;
	t_stat r;

	if (cptr == NULL) return SCPE_ARG;
	newln = (int32) get_uint (cptr, 10, (DZ_MUXES * DZ_LINES), &r);
	if ((r != SCPE_OK) \|\| (newln == dz_desc.lines)) return r;
	if ((newln == 0) \|\| (newln % DZ_LINES)) return SCPE_ARG;
	if (newln < dz_desc.lines) {
	for (i = newln, t = 0; i < dz_desc.lines; i++) t = t \| dz_ldsc[i].conn;
	if (t && !get_yn ("This will disconnect users; proceed [N]?", FALSE))
	return SCPE_OK;
	for (i = newln; i < dz_desc.lines; i++) {
	if (dz_ldsc[i].conn) {
	tmxr_msg (dz_ldsc[i].conn, "\r\nOperator disconnected line\r\n");
	tmxr_reset_ln (&dz_ldsc[i]); } /* reset line */
	if ((i % DZ_LINES) == (DZ_LINES - 1))
	dz_clear (i / DZ_LINES, TRUE); } /* reset mux */
	}
	dz_dib.lnt = (newln / DZ_LINES) * IOLN_DZ; /* set length */
	dz_desc.lines = newln;
	ndev = ((dz_dev.flags & DEV_DIS)? 0: (dz_desc.lines / DZ_LINES));
	return auto_config (RANK_DZ, ndev); /* auto config */
	}

	/* SHOW VECTOR processor */

	t_stat dz_show_vec (FILE st, UNIT uptr, int32 val, void *desc)
	{
	return show_vec (st, uptr, ((dz_desc.lines * 2) / DZ_LINES), desc);
	}