PDP11/pdp11_vh.c

/* pdp11_vh.c: DHQ11 asynchronous terminal multiplexor simulator

   Copyright (c) 2004-2006, John A. Dundas III
   Portions derived from work by 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
   THE AUTHOR 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 the Author shall not be
   used in advertising or otherwise to promote the sale, use or other dealings
   in this Software without prior written authorization from the Author.

   vh		    DHQ11 asynch multiplexor for SIMH

   29-Oct-06    RMS     Synced poll and clock
   07-Jul-05	RMS	    Removed extraneous externs
   15-Jun-05	RMS	    Revised for new autoconfigure interface
			            Fixed bug in vector display routine
   12-Jun-04	RMS	    Repair MS2SIMH macro to avoid divide by	0 bug
   08-Jun-04	JAD	    Repair vh_dev initialization; remove unused
			             variables, cast to avoid conversion confusion
   07-Jun-04	JAD	    Complete function prototypes of forward declarations.
			            Repair broken prototypes of vh_rd() and vh_wr()
			            Explicitly size integer declarations
   4-Jun-04	    JAD     Preliminary code: If operating in a PDP-11 Unibus
			             environment, force DHU mode
   29-May-04	JAD	    Make certain RX.TIMER is within allowable range
   25-May-04	JAD	    All time-based operations are scaled by tmxr_poll units
   23-May-04	JAD	    Change to fifo_get() and dq_tx_report() to avoid
			             gratuitous stack manipulation
   20-May-04	JAD	    Made modem control and auto-hangup unit flags
   19-May-04	JAD	    Fix problem with modem status where the line number
			             was not being included
   12-May-04	JAD	    Revised for updated tmxr interfaces
   28-Jan-04	JAD	    Original creation and testing

I/O Page Registers

CSR	17 760 440 (float)

Vector:	300 (float)

Priority:	BR4

Rank:		32

*/
/* MANY constants needed! */

#if	defined (VM_VAX)
#include "vax_defs.h"
extern int32	int_req[IPL_HLVL];
#endif

#if	defined (VM_PDP11)
#include "pdp11_defs.h"
extern int32	int_req[IPL_HLVL];
extern int32	cpu_opt;
#endif

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

/* imports from pdp11_stddev.c: */
extern int32	tmxr_poll, clk_tps;
/* convert ms to SIMH time units based on tmxr_poll polls per second */
#define	MS2SIMH(ms)	(((ms) * clk_tps) / 1000)
extern FILE	*sim_log;

#ifndef	VH_MUXES
#define	VH_MUXES	(4)
#endif
#define	VH_MNOMASK	(VH_MUXES - 1)

#define	VH_LINES	(8)

#define	UNIT_V_MODEDHU	(UNIT_V_UF + 0)
#define	UNIT_V_FASTDMA	(UNIT_V_UF + 1)
#define	UNIT_V_MODEM	(UNIT_V_UF + 2)
#define	UNIT_V_HANGUP	(UNIT_V_UF + 3)
#define	UNIT_MODEDHU	(1 << UNIT_V_MODEDHU)
#define	UNIT_FASTDMA	(1 << UNIT_V_FASTDMA)
#define	UNIT_MODEM	(1 << UNIT_V_MODEM)
#define	UNIT_HANGUP	(1 << UNIT_V_HANGUP)

/* VHCSR - 160440 - Control and Status Register */

#define	CSR_M_IND_ADDR		(017)
#define	CSR_SKIP		(1 << 4)
#define	CSR_MASTER_RESET	(1 << 5)
#define	CSR_RXIE		(1 << 6)
#define	CSR_RX_DATA_AVAIL	(1 << 7)
#define	CSR_M_TX_LINE		(017)
#define	CSR_V_TX_LINE		(8)
#define	CSR_TX_DMA_ERR		(1 << 12)
#define	CSR_DIAG_FAIL		(1 << 13)
#define	CSR_TXIE		(1 << 14)
#define	CSR_TX_ACTION		(1 << 15)
#define	CSR_GETCHAN(x)	((x) & CSR_M_IND_ADDR)
#define	CSR_RW			\
	(CSR_TXIE|CSR_RXIE|CSR_SKIP|CSR_M_IND_ADDR|CSR_MASTER_RESET)
#define	RESET_ABORT		(052525)

/* Receive Buffer (RBUF) */

#define	FIFO_SIZE		(256)
#define	FIFO_ALARM		(191)
#define	FIFO_HALF		(FIFO_SIZE / 2)
#define	RBUF_M_RX_CHAR		(0377)
#define	RBUF_M_RX_LINE		(07)
#define	RBUF_V_RX_LINE		(8)
#define	RBUF_PARITY_ERR		(1 << 12)
#define	RBUF_FRAME_ERR		(1 << 13)
#define	RBUF_OVERRUN_ERR 	(1 << 14)
#define	RBUF_DATA_VALID		(1 << 15)
#define	RBUF_GETLINE(x)		(((x) >> RBUF_V_RX_LINE) & RBUF_M_RX_LINE)
#define	RBUF_PUTLINE(x)		((x) << RBUF_V_RX_LINE)
#define	RBUF_DIAG		\
	(RBUF_PARITY_ERR|RBUF_FRAME_ERR|RBUF_OVERRUN_ERR)
#define	XON			(021)
#define	XOFF			(023)

/* Transmit Character Register (TXCHAR) */

#define	TXCHAR_M_CHAR		(0377)
#define	TXCHAR_TX_DATA_VALID	(1 << 15)

/* Receive Timer Register (RXTIMER) */

#define	RXTIMER_M_RX_TIMER	(0377)

/* Line-Parameter Register (LPR) */

#define	LPR_DISAB_XRPT		(1 << 0)	/* not impl. in real DHU */
#define	LPR_V_DIAG		(1)
#define	LPR_M_DIAG		(03)
#define	LPR_V_CHAR_LGTH		(3)
#define	LPR_M_CHAR_LGTH		(03)
#define	LPR_PARITY_ENAB		(1 << 5)
#define	LPR_EVEN_PARITY		(1 << 6)
#define	LPR_STOP_CODE		(1 << 7)
#define	LPR_V_RX_SPEED		(8)
#define	LPR_M_RX_SPEED		(017)
#define	LPR_V_TX_SPEED		(12)
#define	LPR_M_TX_SPEED		(017)

#define	RATE_50			(0)
#define	RATE_75			(1)
#define	RATE_110		(2)
#define	RATE_134		(3)
#define	RATE_150		(4)
#define	RATE_300		(5)
#define	RATE_600		(6)
#define	RATE_1200		(7)
#define	RATE_1800		(8)
#define	RATE_2000		(9)
#define	RATE_2400		(10)
#define	RATE_4800		(11)
#define	RATE_7200		(12)
#define	RATE_9600		(13)
#define	RATE_19200		(14)
#define	RATE_38400		(15)

/* Line-Status Register (STAT) */

#define	STAT_DHUID		(1 << 8)	/* mode: 0=DHV, 1=DHU */
#define	STAT_MDL		(1 << 9)	/* always 0, has modem support */
#define	STAT_CTS		(1 << 11)	/* CTS from modem */
#define	STAT_DCD		(1 << 12)	/* DCD from modem */
#define	STAT_RI			(1 << 13)	/* RI from modem */
#define	STAT_DSR		(1 << 15)	/* DSR from modem */

/* FIFO Size Register (FIFOSIZE) */

#define	FIFOSIZE_M_SIZE		(0377)

/* FIFO Data Register (FIFODATA) */

#define	FIFODATA_W0		(0377)
#define	FIFODATA_V_W1		(8)
#define	FIFODATA_M_W1		(0377)

/* Line-Control Register (LNCTRL) */

#define	LNCTRL_TX_ABORT		(1 << 0)
#define	LNCTRL_IAUTO		(1 << 1)
#define	LNCTRL_RX_ENA		(1 << 2)
#define	LNCTRL_BREAK		(1 << 3)
#define	LNCTRL_OAUTO		(1 << 4)
#define	LNCTRL_FORCE_XOFF 	(1 << 5)
#define	LNCTRL_V_MAINT		(6)
#define	LNCTRL_M_MAINT		(03)
#define	LNCTRL_LINK_TYPE 	(1 << 8)	/* 0=data leads only, 1=modem */
#define	LNCTRL_DTR		(1 << 9)	/* DTR to modem */
#define	LNCTRL_RTS		(1 << 12)	/* RTS to modem */

/* Transmit Buffer Address Register Number 1 (TBUFFAD1) */

/* Transmit Buffer Address Register Number 2 (TBUFFAD2) */

#define	TB2_M_TBUFFAD		(077)
#define	TB2_TX_DMA_START 	(1 << 7)
#define	TB2_TX_ENA		(1 << 15)

/* Transmit DMA Buffer Counter (TBUFFCT) */

/* Self-Test Error Codes */

#define	SELF_NULL		(0201)
#define	SELF_SKIP		(0203)
#define	SELF_OCT		(0211)
#define	SELF_RAM		(0225)
#define	SELF_RCD		(0231)
#define	SELF_DRD		(0235)

#define	BMP_OK			(0305)
#define	BMP_BAD			(0307)

/* Loopback types */

#define	LOOP_NONE		(0)
#define	LOOP_H325		(1)
#define	LOOP_H3101		(2)	/* p.2-13 DHQ manual */
/* Local storage */

static uint16	vh_csr[VH_MUXES]	= { 0 };	/* CSRs */
static uint16	vh_timer[VH_MUXES]	= { 1 };	/* controller timeout */
static uint16	vh_mcount[VH_MUXES]	= { 0 };
static uint32	vh_timeo[VH_MUXES]	= { 0 };
static uint32	vh_ovrrun[VH_MUXES]	= { 0 };	/* line overrun bits */
/* XOFF'd channels, one bit/channel */
static uint32	vh_stall[VH_MUXES]	= { 0 };
static uint16	vh_loop[VH_MUXES]	= { 0 };	/* loopback status */

/* One bit per controller: */
static uint32	vh_rxi = 0;	/* rcv interrupts */
static uint32	vh_txi = 0;	/* xmt interrupts */
static uint32	vh_crit = 0;	/* FIFO.CRIT */

static const int32 bitmask[4] = { 037, 077, 0177, 0377 };

/* RX FIFO state */

static int32	rbuf_idx[VH_MUXES]		= { 0 };/* index into vh_rbuf */
static uint32   vh_rbuf[VH_MUXES][FIFO_SIZE]    = { 0 };

/* TXQ state */

#define	TXQ_SIZE	(16)
static int32	txq_idx[VH_MUXES]		= { 0 };
static uint32	vh_txq[VH_MUXES][TXQ_SIZE]	= { 0 };

/* Need to extend the TMLN structure */

typedef struct {
	TMLN	*tmln;
	uint16	lpr;		/* line parameters */
	uint16	lnctrl;		/* line control */
	uint16	lstat;		/* line modem status */
	uint16	tbuffct;	/* remaining character count */
	uint16	tbuf1;
	uint16	tbuf2;
	uint16	txchar;		/* single character I/O */
} TMLX;

static TMLN vh_ldsc[VH_MUXES * VH_LINES] = { 0 };
static TMXR vh_desc = { VH_MUXES * VH_LINES, 0, 0, vh_ldsc };
static TMLX vh_parm[VH_MUXES * VH_LINES] = { 0 };

/* Forward references */
static t_stat vh_rd (int32 *data, int32 PA, int32 access);
static t_stat vh_wr (int32 data, int32 PA, int32 access);
static t_stat vh_svc (UNIT *uptr);
static int32 vh_rxinta (void);
static int32 vh_txinta (void);
static t_stat vh_clear (int32 vh, t_bool flag);
static t_stat vh_reset (DEVICE *dptr);
static t_stat vh_attach (UNIT *uptr, char *cptr);
static t_stat vh_detach (UNIT *uptr);       
static t_stat vh_show_vec (FILE *st, UNIT *uptr, int32 val, void *desc); 
static t_stat vh_show (FILE *st, UNIT *uptr, int32 val, void *desc);
static t_stat vh_show_debug (FILE *st, UNIT *uptr, int32 val, void *desc);
static t_stat vh_show_rbuf (FILE *st, UNIT *uptr, int32 val, void *desc);
static t_stat vh_show_txq (FILE *st, UNIT *uptr, int32 val, void *desc);
static t_stat vh_putc (int32 vh, TMLX *lp, int32 chan, int32 data);
static void doDMA (int32 vh, int32 chan);
static t_stat vh_summ (FILE *st, UNIT *uptr, int32 val, void *desc);

int32 tmxr_send_buffered_data (TMLN *lp);

/* SIMH I/O Structures */

static DIB vh_dib = {
	IOBA_VH,
	IOLN_VH * VH_MUXES,
	&vh_rd,		/* read */
	&vh_wr,		/* write */
	2,		/* # of vectors */
	IVCL (VHRX),
	VEC_VHRX,
	{ &vh_rxinta, &vh_txinta }	/* int. ack. routines */
};

static UNIT vh_unit[VH_MUXES] = {
	{ UDATA (&vh_svc, UNIT_ATTABLE, 0) },
	{ UDATA (&vh_svc, UNIT_ATTABLE, 0) },
	{ UDATA (&vh_svc, UNIT_ATTABLE, 0) },
	{ UDATA (&vh_svc, UNIT_ATTABLE, 0) },
};

static const REG vh_nlreg = { DRDATA (NLINES, vh_desc.lines, 6), PV_LEFT };

static const REG vh_reg[] = {
	{ BRDATA (CSR,     vh_csr, DEV_RDX, 16, VH_MUXES) },
	{ GRDATA (DEVADDR, vh_dib.ba, DEV_RDX, 32, 0), REG_HRO },
	{ GRDATA (DEVVEC,  vh_dib.vec, DEV_RDX, 16, 0), REG_HRO },
	{ NULL }
};

static const MTAB vh_mod[] = {
	{ UNIT_MODEDHU, 0, "DHV mode", "DHV", NULL },
	{ UNIT_MODEDHU, UNIT_MODEDHU, "DHU mode", "DHU", NULL },
	{ UNIT_FASTDMA, 0, NULL, "NORMAL", NULL },
	{ UNIT_FASTDMA, UNIT_FASTDMA, "fast DMA", "FASTDMA", NULL },
	{ UNIT_MODEM, 0, NULL, "NOMODEM", NULL },
	{ UNIT_MODEM, UNIT_MODEM, "modem", "MODEM", NULL },
	{ UNIT_HANGUP, 0, NULL, "NOHANGUP", NULL },
	{ UNIT_HANGUP, UNIT_HANGUP, "hangup", "HANGUP", NULL },
	{ MTAB_XTD|MTAB_VDV, 020, "ADDRESS", "ADDRESS",
		&set_addr, &show_addr, NULL },
	{ MTAB_XTD|MTAB_VDV, 0, "VECTOR", "VECTOR",
		&set_vec, &vh_show_vec, NULL },
	{ MTAB_XTD|MTAB_VDV, 0, NULL, "AUTOCONFIGURE",
		&set_addr_flt, NULL, NULL },
	/* this one is dangerous, don't use yet */
	{ MTAB_XTD|MTAB_VDV|MTAB_VAL, 0, "lines", "LINES",
		NULL, NULL, (REG *)&vh_nlreg },
	{ UNIT_ATT, UNIT_ATT, "connections", NULL, NULL, &vh_summ },
	{ MTAB_XTD | MTAB_VDV | MTAB_NMO, 1, "CONNECTIONS", NULL,
		NULL, &vh_show, NULL },
	{ MTAB_XTD | MTAB_VDV | MTAB_NMO, 0, "STATISTICS", NULL,
		NULL, &vh_show, NULL },
	{ MTAB_XTD | MTAB_VDV, 1, NULL, "DISCONNECT",
		&tmxr_dscln, NULL, &vh_desc },
	{ MTAB_XTD | MTAB_VDV | MTAB_NMO, 0, "DEBUG", NULL,
		NULL, &vh_show_debug, NULL },
	{ MTAB_XTD | MTAB_VDV | MTAB_NMO, 0, "RBUF", NULL,
		NULL, &vh_show_rbuf, NULL },
	{ MTAB_XTD | MTAB_VDV | MTAB_NMO, 0, "TXQ", NULL,
		NULL, &vh_show_txq, NULL },
	{ 0 }
};

DEVICE vh_dev = {
	"VH",		/* name */
	vh_unit,	/* units */
	(REG *)vh_reg,	/* registers */
	(MTAB *)vh_mod,	/* modifiers */
	VH_MUXES,	/* # units */
	DEV_RDX,	/* address radix */
	8,		/* address width */
	1,		/* address increment */
	DEV_RDX,	/* data radix */
	8,		/* data width */
	NULL,		/* examine routine */
	NULL,		/* deposit routine */
	&vh_reset,	/* reset routine */
	NULL,		/* boot routine */
	&vh_attach,	/* attach routine */
	&vh_detach,	/* detach routine */
	(void *)&vh_dib,	/* context */
	DEV_FLTA | DEV_DISABLE | DEV_DIS |DEV_NET | DEV_QBUS | DEV_UBUS,	/* flags */
};

/* Interrupt routines */

static void vh_clr_rxint (	int32	vh	)
{
	vh_rxi &= ~(1 << vh);
	if (vh_rxi == 0)
		CLR_INT (VHRX);
	else
		SET_INT (VHRX);
}

static void vh_set_rxint (	int32	vh	)
{
	vh_rxi |= (1 << vh);
	SET_INT (VHRX);
}

/* RX interrupt ack. (bus cycle) */

static int32 vh_rxinta (void)
{
	int32	vh;

	for (vh = 0; vh < VH_MUXES; vh++) {
		if (vh_rxi & (1 << vh)) {
			vh_clr_rxint (vh);
			return (vh_dib.vec + (vh * 010));
		}
	}
	return (0);
}

static void vh_clr_txint (	int32	vh	)
{
	vh_txi &= ~(1 << vh);
	if (vh_txi == 0)
		CLR_INT (VHTX);
	else
		SET_INT (VHTX);
}

static void vh_set_txint (	int32	vh	)
{
	vh_txi |= (1 << vh);
	SET_INT (VHTX);
}

/* TX interrupt ack. (bus cycle) */

static int32 vh_txinta (void)
{
	int32	vh;

	for (vh = 0; vh < VH_MUXES; vh++) {
		if (vh_txi & (1 << vh)) {
			vh_clr_txint (vh);
			return (vh_dib.vec + 4 + (vh * 010));
		}
	}
	return (0);
}
/* RX FIFO get/put routines */

/* return 0 on success, -1 on FIFO overflow */

static int32 fifo_put (	int32	vh,
			TMLX	*lp,
			int32	data	)
{
	int32	status = 0;

	if (lp == NULL)
		goto override;
	/* this might have to move to vh_getc() */
	if ((lp->lnctrl & LNCTRL_OAUTO) && ((data & RBUF_DIAG) == 0)) {
		TMLX	*l0p;
		/* implement transmitted data flow control */
		switch (data & 0377) {
		case XON:
			lp->tbuf2 |= TB2_TX_ENA;
			goto common;
		case XOFF:
			lp->tbuf2 &= ~TB2_TX_ENA;
		common:
			/* find line 0 for this controller */
			l0p = &vh_parm[vh * VH_LINES];
			if (l0p->lpr & LPR_DISAB_XRPT)
				return (0);
			break;
		default:
			break;
		}
	}
/* BUG: which of the following 2 is correct? */
	/* if ((data & RBUF_DIAG) == RBUF_DIAG) */
	if (data & RBUF_DIAG)
		goto override;
	if (((lp->lnctrl >> LNCTRL_V_MAINT) & LNCTRL_M_MAINT) == 2)
		goto override;
	if (!(lp->lnctrl & LNCTRL_RX_ENA))
		return (0);	
override:
	vh_csr[vh] |= CSR_RX_DATA_AVAIL;
	if (rbuf_idx[vh] < FIFO_SIZE) {
		vh_rbuf[vh][rbuf_idx[vh]] = data;
		rbuf_idx[vh] += 1;
	} else {
		vh_ovrrun[vh] |= (1 << RBUF_GETLINE (data));
		status = -1;
	}
	if (vh_csr[vh] & CSR_RXIE) {
		if (vh_unit[vh].flags & UNIT_MODEDHU) {
			/* was it a modem status change? */
			if ((data & RBUF_DIAG) == RBUF_DIAG)
				vh_set_rxint (vh);
			/* look for FIFO alarm @ 3/4 full */
			else if (rbuf_idx[vh] == FIFO_ALARM)
				vh_set_rxint (vh);
			else if (vh_timer[vh] == 0)
				; /* nothing, infinite timeout */
			else if (vh_timer[vh] == 1)
				vh_set_rxint (vh);
			else if (vh_timeo[vh] == 0)
				vh_timeo[vh] = MS2SIMH (vh_timer[vh]) + 1;
		} else {
			/* Interrupt on transition _from_ an empty FIFO */
			if (rbuf_idx[vh] == 1)
				vh_set_rxint (vh);
		}
	}
	if (rbuf_idx[vh] > FIFO_ALARM)
		vh_crit |= (1 << vh);
	/* Implement RX FIFO-level flow control */
	if (lp != NULL) {
		if ((lp->lnctrl & LNCTRL_FORCE_XOFF) || 
		      ((vh_crit & (1 << vh)) && (lp->lnctrl & LNCTRL_IAUTO))) {
			int32	chan = RBUF_GETLINE(data);
			vh_stall[vh] ^= (1 << chan);
			/* send XOFF every other character received */
			if (vh_stall[vh] & (1 << chan))
				vh_putc (vh, lp, chan, XOFF);
		}
	}
	return (status);
}

static int32 fifo_get (	int32	vh	)
{
	int32	data, i;

	if (rbuf_idx[vh] == 0) {
		vh_csr[vh] &= ~CSR_RX_DATA_AVAIL;
		return (0);
	}
	/* pick off the first character, mark valid */
	data = vh_rbuf[vh][0] | RBUF_DATA_VALID;
	/* move the remainder up */
	rbuf_idx[vh] -= 1;
	for (i = 0; i < rbuf_idx[vh]; i++)
		vh_rbuf[vh][i] = vh_rbuf[vh][i + 1];
	/* rbuf_idx[vh] -= 1; */
	/* look for any previous overruns */
	if (vh_ovrrun[vh]) {
		for (i = 0; i < VH_LINES; i++) {
			if (vh_ovrrun[vh] & (1 << i)) {
				fifo_put (vh, NULL, RBUF_OVERRUN_ERR |
					  RBUF_PUTLINE (i));
				vh_ovrrun[vh] &= ~(1 << i);
				break;
			}
		}
	}
	/* recompute FIFO alarm condition */
	if ((rbuf_idx[vh] < FIFO_HALF) && (vh_crit & (1 << vh))) {
		vh_crit &= ~(1 << vh);
		/* send XON to all XOFF'd channels on this controller */
		for (i = 0; i < VH_LINES; i++) {
			TMLX	*lp = &vh_parm[(vh * VH_LINES) + i];
			if (lp->lnctrl & LNCTRL_FORCE_XOFF)
				continue;
			if (vh_stall[vh] & (1 << i)) {
				vh_putc (vh, NULL, i, XON);
				vh_stall[vh] &= ~(1 << i);
			}
		}
	}
	return (data & 0177777);
}
/* TX Q manipulation */

static int32 dq_tx_report (	int32	vh	)
{
	int32	data, i;

	if (txq_idx[vh] == 0)
		return (0);
	data = vh_txq[vh][0];
	txq_idx[vh] -= 1;
	for (i = 0; i < txq_idx[vh]; i++)
		vh_txq[vh][i] = vh_txq[vh][i + 1];
	/* txq_idx[vh] -= 1; */
	return (data & 0177777);
}

static void q_tx_report (	int32	vh,
				int32	data	)
{
	if (vh_csr[vh] & CSR_TXIE)
		vh_set_txint (vh);
	if (txq_idx[vh] >= TXQ_SIZE) {
/* BUG: which of the following 2 is correct? */
		dq_tx_report (vh);
		/* return; */
	}
	vh_txq[vh][txq_idx[vh]] = CSR_TX_ACTION | data;
	txq_idx[vh] += 1;
}
/* Channel get/put routines */

static void HangupModem (	int32	vh,
				TMLX	*lp,
				int32	chan	)
{
	if (vh_unit[vh].flags & UNIT_MODEM)
		lp->lstat &= ~(STAT_DCD|STAT_DSR|STAT_CTS|STAT_RI);
	if (lp->lnctrl & LNCTRL_LINK_TYPE)
		/* RBUF<0> = 0 for modem status */
		fifo_put (vh, lp, RBUF_DIAG |
				  RBUF_PUTLINE (chan) |
				  ((lp->lstat >> 8) & 0376));
		/* BUG: check for overflow above */
}

/* TX a character on a line, regardless of the TX enable state */

static t_stat vh_putc (	int32	vh,
			TMLX	*lp,
			int32	chan,
			int32	data	)
{
	int32	val;
	t_stat	status = SCPE_OK;

	/* truncate to desired character length */
	data &= bitmask[(lp->lpr >> LPR_V_CHAR_LGTH) & LPR_M_CHAR_LGTH];
	switch ((lp->lnctrl >> LNCTRL_V_MAINT) & LNCTRL_M_MAINT) {
	case 0:		/* normal */
#if	0
		/* check for (external) loopback setting */
		switch (vh_loop[vh]) {
		default:
		case LOOP_NONE:
			break;
		}
#endif
		status = tmxr_putc_ln (lp->tmln, data);
		if (status == SCPE_LOST) {
			tmxr_reset_ln (lp->tmln);
			HangupModem (vh, lp, chan);
		} else if (status == SCPE_STALL) {
			/* let's flush and try again */
			tmxr_send_buffered_data (lp->tmln);
			status = tmxr_putc_ln (lp->tmln, data);
		}
		break;
	case 1:		/* auto echo */
		break;
	case 2:		/* local loopback */
		if (lp->lnctrl & LNCTRL_BREAK)
			val = fifo_put (vh, lp,
				RBUF_FRAME_ERR | RBUF_PUTLINE (chan));
		else
			val = fifo_put (vh, lp,
				RBUF_PUTLINE (chan) | data);
		status = (val < 0) ? SCPE_TTMO : SCPE_OK;
		break;
	default:	/* remote loopback */
		break;
	}
	return (status);
}

/* Retrieve all stored input from TMXR and place in RX FIFO */

static void vh_getc (	int32	vh	)
{
	uint32	i, c;
	TMLX	*lp;

	for (i = 0; i < VH_LINES; i++) {
		lp = &vh_parm[(vh * VH_LINES) + i];
		while (c = tmxr_getc_ln (lp->tmln)) {
			if (c & SCPE_BREAK) {
				fifo_put (vh, lp,
					RBUF_FRAME_ERR | RBUF_PUTLINE (i));
				/* BUG: check for overflow above */
			} else {
				c &= bitmask[(lp->lpr >> LPR_V_CHAR_LGTH) &
					LPR_M_CHAR_LGTH];
				fifo_put (vh, lp, RBUF_PUTLINE (i) | c);
				/* BUG: check for overflow above */
			}
		}
	}
}

/* I/O dispatch routines */

static t_stat vh_rd (	int32	*data,
			int32	PA,
			int32	access	)
{
	int32	vh = ((PA - vh_dib.ba) >> 4) & VH_MNOMASK, line;
	TMLX	*lp;

	switch ((PA >> 1) & 7) {
	case 0:		/* CSR */
		*data = vh_csr[vh] | dq_tx_report (vh);
		vh_csr[vh] &= ~0117400;	/* clear the read-once bits */
		break;
	case 1:		/* RBUF */
		*data = fifo_get (vh);
		break;
	case 2:		/* LPR */
		if (CSR_GETCHAN (vh_csr[vh]) >= VH_LINES) {
			*data = 0;
			break;
		}
		line = (vh * VH_LINES) + CSR_GETCHAN (vh_csr[vh]);
		lp = &vh_parm[line];
		*data = lp->lpr;
		break;
	case 3:		/* STAT/FIFOSIZE */
		if (CSR_GETCHAN (vh_csr[vh]) >= VH_LINES) {
			*data = 0;
			break;
		}
		line = (vh * VH_LINES) + CSR_GETCHAN (vh_csr[vh]);
		lp = &vh_parm[line];
		*data = (lp->lstat & ~0377) |		/* modem status */
#if	0
			(64 - tmxr_tqln (lp->tmln));
fprintf (stderr, "\rtqln %d\n", 64 - tmxr_tqln (lp->tmln));
#else
			64;
#endif
		break;
	case 4:		/* LNCTRL */
		if (CSR_GETCHAN (vh_csr[vh]) >= VH_LINES) {
			*data = 0;
			break;
		}
		line = (vh * VH_LINES) + CSR_GETCHAN (vh_csr[vh]);
		lp = &vh_parm[line];
		*data = lp->lnctrl;
		break;
	case 5:		/* TBUFFAD1 */
		if (CSR_GETCHAN (vh_csr[vh]) >= VH_LINES) {
			*data = 0;
			break;
		}
		line = (vh * VH_LINES) + CSR_GETCHAN (vh_csr[vh]);
		lp = &vh_parm[line];
		*data = lp->tbuf1;
		break;
	case 6:		/* TBUFFAD2 */
		if (CSR_GETCHAN (vh_csr[vh]) >= VH_LINES) {
			*data = 0;
			break;
		}
		line = (vh * VH_LINES) + CSR_GETCHAN (vh_csr[vh]);
		lp = &vh_parm[line];
		*data = lp->tbuf2;
		break;
	case 7:		/* TBUFFCT */
		if (CSR_GETCHAN (vh_csr[vh]) >= VH_LINES) {
			*data = 0;
			break;
		}
		line = (vh * VH_LINES) + CSR_GETCHAN (vh_csr[vh]);
		lp = &vh_parm[line];
		*data = lp->tbuffct;
		break;
	default:
		/* can't happen */
		break;
	}
	return (SCPE_OK);
}

static t_stat vh_wr (	int32	data,
			int32	PA,
			int32	access	)
{
	int32	vh = ((PA - vh_dib.ba) >> 4) & VH_MNOMASK, line;
	TMLX	*lp;

	switch ((PA >> 1) & 7) {   
	case 0:		/* CSR, but no read-modify-write */
		if (access == WRITEB)
			data = (PA & 1) ?
				(vh_csr[vh] & 0377) | (data << 8) :
				(vh_csr[vh] & ~0377) | data & 0377;
		if (data & CSR_MASTER_RESET) {
			if ((vh_unit[vh].flags & UNIT_MODEDHU) && (data & CSR_SKIP))
				data &= ~CSR_MASTER_RESET;
			sim_activate (&vh_unit[vh], clk_cosched (tmxr_poll));
			/* vh_mcount[vh] = 72; */ /* 1.2 seconds */
			vh_mcount[vh] = MS2SIMH (1200);	/* 1.2 seconds */
		}
		if ((data & CSR_RXIE) == 0)
			vh_clr_rxint (vh);
		/* catch the RXIE transition if the FIFO is not empty */
		else if (((vh_csr[vh] & CSR_RXIE) == 0) &&
			  (rbuf_idx[vh] != 0)) {
			if (vh_unit[vh].flags & UNIT_MODEDHU) {
				if (rbuf_idx[vh] > FIFO_ALARM)
					vh_set_rxint (vh);
				else if (vh_timer[vh] == 0)
					;
				else if (vh_timer[vh] == 1)
					vh_set_rxint (vh);
				else if (vh_timeo[vh] == 0)
					vh_timeo[vh] = MS2SIMH (vh_timer[vh]) + 1;
			} else {
				vh_set_rxint (vh);
			}
		}
		if ((data & CSR_TXIE) == 0)
			vh_clr_txint (vh);
		else if (((vh_csr[vh] & CSR_TXIE) == 0) &&
			  (txq_idx[vh] != 0))
			vh_set_txint (vh);
		vh_csr[vh] = (vh_csr[vh] & ~((uint16) CSR_RW)) | (data & (uint16) CSR_RW);
		break;
	case 1:		/* TXCHAR/RXTIMER */
		if (CSR_GETCHAN (vh_csr[vh]) >= VH_LINES)
			break;
		if ((data == RESET_ABORT) && (vh_csr[vh] & CSR_MASTER_RESET)) {
			vh_mcount[vh] = 1;
			break;
		}
		if (vh_unit[vh].flags & UNIT_MODEDHU) {
			if (CSR_GETCHAN (vh_csr[vh]) != 0)
				break;
			if (access == WRITEB)
				data = (PA & 1) ?
					(vh_timer[vh] & 0377) | (data << 8) :
					(vh_timer[vh] & ~0377) | (data & 0377);
			vh_timer[vh] = data & 0377;
#if	0
			if (vh_csr[vh] & CSR_RXIE) {
				if (rbuf_idx[vh] > FIFO_ALARM)
					vh_set_rxint (vh);
				else if (vh_timer[vh] == 0)
					;
				else if (vh_timer[vh] == 1)
					vh_set_rxint (vh);
				else if (vh_timeo[vh] == 0)
					vh_timeo[vh] = MS2SIMH (vh_timer[vh]) + 1;
			}
#endif
		} else {
			line = (vh * VH_LINES) + CSR_GETCHAN (vh_csr[vh]);
			lp = &vh_parm[line];
			if (access == WRITEB)
				data = (PA & 1) ?   
					(lp->txchar & 0377) | (data << 8) :
					(lp->txchar & ~0377) | (data & 0377);
			lp->txchar = data;	/* TXCHAR */
			if (lp->txchar & TXCHAR_TX_DATA_VALID) {
				if (lp->tbuf2 & TB2_TX_ENA)
					vh_putc (vh, lp,
						CSR_GETCHAN (vh_csr[vh]),
						lp->txchar);
				q_tx_report (vh,
					CSR_GETCHAN (vh_csr[vh]) << CSR_V_TX_LINE);
				lp->txchar &= ~TXCHAR_TX_DATA_VALID;
			}
		}
		break;
	case 2:		/* LPR */
		if ((data == RESET_ABORT) && (vh_csr[vh] & CSR_MASTER_RESET)) {
			vh_mcount[vh] = 1;
			break;
		}
		if (CSR_GETCHAN (vh_csr[vh]) >= VH_LINES)
			break;
		line = (vh * VH_LINES) + CSR_GETCHAN (vh_csr[vh]);
		lp = &vh_parm[line];
		if (access == WRITEB)
			data = (PA & 1) ?
				(lp->lpr & 0377) | (data << 8) :
				(lp->lpr & ~0377) | data & 0377;
		/* Modify only if CSR<3:0> == 0 */
		if (CSR_GETCHAN (vh_csr[vh]) != 0)
			data &= ~LPR_DISAB_XRPT;
		lp->lpr = data;
		if (((lp->lpr >> LPR_V_DIAG) & LPR_M_DIAG) == 1) {
			fifo_put (vh, lp,
				RBUF_DIAG |
				RBUF_PUTLINE (CSR_GETCHAN (vh_csr[vh])) |
				BMP_OK);
			/* BUG: check for overflow above */
			lp->lpr &= ~(LPR_M_DIAG << LPR_V_DIAG);
		}
		break;
	case 3:		/* STAT/FIFODATA */
		if ((data == RESET_ABORT) && (vh_csr[vh] & CSR_MASTER_RESET)) {
			vh_mcount[vh] = 1;
			break;
		}
		if (CSR_GETCHAN (vh_csr[vh]) >= VH_LINES)
			break;
		line = (vh * VH_LINES) + CSR_GETCHAN (vh_csr[vh]);
		lp = &vh_parm[line];
		if (vh_unit[vh].flags & UNIT_MODEDHU) {
			/* high byte writes not allowed */
			if (PA & 1)
				break;
			/* transmit 1 or 2 characters */
			if (!(lp->tbuf2 & TB2_TX_ENA))
				break;
			vh_putc (vh, lp, CSR_GETCHAN (vh_csr[vh]), data);
			q_tx_report (vh, CSR_GETCHAN (vh_csr[vh]) << CSR_V_TX_LINE);
			if (access != WRITEB)
				vh_putc (vh, lp, CSR_GETCHAN (vh_csr[vh]),
					data >> 8);
		}
		break;
	case 4:		/* LNCTRL */
		if ((data == RESET_ABORT) && (vh_csr[vh] & CSR_MASTER_RESET)) {
			vh_mcount[vh] = 1;
			break;
		}
		if (CSR_GETCHAN (vh_csr[vh]) >= VH_LINES)   
			break;
		line = (vh * VH_LINES) + CSR_GETCHAN (vh_csr[vh]);
		lp = &vh_parm[line];
		if (access == WRITEB)
			data = (PA & 1) ?
				(lp->lnctrl & 0377) | (data << 8) :
				(lp->lnctrl & ~0377) | data & 0377;
		/* catch the abort TX transition */
		if (!(lp->lnctrl & LNCTRL_TX_ABORT) &&
		     (data & LNCTRL_TX_ABORT)) {
			if ((lp->tbuf2 & TB2_TX_ENA) &&
			    (lp->tbuf2 & TB2_TX_DMA_START)) {
				lp->tbuf2 &= ~TB2_TX_DMA_START;
				q_tx_report (vh, CSR_GETCHAN (vh_csr[vh]) << CSR_V_TX_LINE);
			}
		}
		/* Implement program-initiated flow control */
		if ( (data & LNCTRL_FORCE_XOFF) &&
		     !(lp->lnctrl & LNCTRL_FORCE_XOFF) ) {
			if (!(lp->lnctrl & LNCTRL_IAUTO))
				vh_putc (vh, lp, CSR_GETCHAN (vh_csr[vh]), XOFF);
		} else if ( !(data & LNCTRL_FORCE_XOFF) &&
			    (lp->lnctrl & LNCTRL_FORCE_XOFF) ) {
			if (!(lp->lnctrl & LNCTRL_IAUTO))
				vh_putc (vh, lp, CSR_GETCHAN (vh_csr[vh]), XON);
			else if (!(vh_crit & (1 << vh)) &&
				 (vh_stall[vh] & (1 << CSR_GETCHAN (vh_csr[vh]))))
				vh_putc (vh, lp, CSR_GETCHAN (vh_csr[vh]), XON);
		}
		if ( (data & LNCTRL_IAUTO) &&		/* IAUTO 0->1 */
		     !(lp->lnctrl & LNCTRL_IAUTO) ) {
			if (!(lp->lnctrl & LNCTRL_FORCE_XOFF)) {
				if (vh_crit & (1 << vh)) {
					vh_putc (vh, lp,
						CSR_GETCHAN (vh_csr[vh]), XOFF);
					vh_stall[vh] |= (1 << CSR_GETCHAN (vh_csr[vh]));
				}
			} else {
				/* vh_stall[vh] |= (1 << CSR_GETCHAN (vh_csr[vh])) */;
			}
		} else if ( !(data & LNCTRL_IAUTO) &&
			    (lp->lnctrl & LNCTRL_IAUTO) ) {
			if (!(lp->lnctrl & LNCTRL_FORCE_XOFF))
				vh_putc (vh, lp, CSR_GETCHAN (vh_csr[vh]), XON);
		}
		/* check modem control bits */
		if ( !(data & LNCTRL_DTR) &&	/* DTR 1->0 */
		      (lp->lnctrl & LNCTRL_DTR)) {
			if ((lp->tmln->conn) && (vh_unit[vh].flags & UNIT_HANGUP)) {
				tmxr_linemsg (lp->tmln, "\r\nLine hangup\r\n");
				tmxr_reset_ln (lp->tmln);
			}
			HangupModem (vh, lp, CSR_GETCHAN (vh_csr[vh]));
		}
		lp->lnctrl = data;
		lp->tmln->rcve = (data & LNCTRL_RX_ENA) ? 1 : 0;
		tmxr_poll_rx (&vh_desc);
		vh_getc (vh);
		if (lp->lnctrl & LNCTRL_BREAK)
			vh_putc (vh, lp, CSR_GETCHAN (vh_csr[vh]), 0);
		break;
	case 5:		/* TBUFFAD1 */
		if ((data == RESET_ABORT) && (vh_csr[vh] & CSR_MASTER_RESET)) {
			vh_mcount[vh] = 1;
			break;
		}
		if (CSR_GETCHAN (vh_csr[vh]) >= VH_LINES)   
			break;
		line = (vh * VH_LINES) + CSR_GETCHAN (vh_csr[vh]);
		lp = &vh_parm[line];
		if (access == WRITEB)
			data = (PA & 1) ?
				(lp->tbuf1 & 0377) | (data << 8) :
				(lp->tbuf1 & ~0377) | data & 0377;
		lp->tbuf1 = data;
		break;
	case 6:		/* TBUFFAD2 */
		if ((data == RESET_ABORT) && (vh_csr[vh] & CSR_MASTER_RESET)) {
			vh_mcount[vh] = 1;
			break;
		}
		if (CSR_GETCHAN (vh_csr[vh]) >= VH_LINES)
			break;
		line = (vh * VH_LINES) + CSR_GETCHAN (vh_csr[vh]);
		lp = &vh_parm[line];
		if (access == WRITEB)
			data = (PA & 1) ?
				(lp->tbuf2 & 0377) | (data << 8) :
				(lp->tbuf2 & ~0377) | data & 0377;
		lp->tbuf2 = data;
		/* if starting a DMA, clear DMA_ERR */
		if (vh_unit[vh].flags & UNIT_FASTDMA) {
			doDMA (vh, CSR_GETCHAN (vh_csr[vh]));
			tmxr_send_buffered_data (lp->tmln);
		}
		break;
	case 7:		/* TBUFFCT */
		if ((data == RESET_ABORT) && (vh_csr[vh] & CSR_MASTER_RESET)) {
			vh_mcount[vh] = 1;
			break;
		}
		if (CSR_GETCHAN (vh_csr[vh]) >= VH_LINES)
			break;
		line = (vh * VH_LINES) + CSR_GETCHAN (vh_csr[vh]);
		lp = &vh_parm[line];
		if (access == WRITEB)
			data = (PA & 1) ?
				(lp->tbuffct & 0377) | (data << 8) :
				(lp->tbuffct & ~0377) | data & 0377;
		lp->tbuffct = data;
		break;
	default:
		/* can't happen */
		break;
	}
	return (SCPE_OK);
}

static void doDMA (	int32	vh,
			int32	chan	)
{
	int32	line, status;
	uint32	pa;
	TMLX	*lp;

	line = (vh * VH_LINES) + chan;
	lp = &vh_parm[line];
	if ((lp->tbuf2 & TB2_TX_ENA) && (lp->tbuf2 & TB2_TX_DMA_START)) {
/* BUG: should compare against available xmit buffer space */
		pa = lp->tbuf1;
		pa |= (lp->tbuf2 & TB2_M_TBUFFAD) << 16;
		status = chan << CSR_V_TX_LINE;
		while (lp->tbuffct) {
			uint8	buf;
			if (Map_ReadB (pa, 1, &buf)) {
				status |= CSR_TX_DMA_ERR;
				lp->tbuffct = 0;
				break;
			}
			if (vh_putc (vh, lp, chan, buf) != SCPE_OK)
				break;
			/* pa = (pa + 1) & PAMASK; */
			pa = (pa + 1) & ((1 << 22) - 1);
			lp->tbuffct--;
		}
		lp->tbuf1 = pa & 0177777;
		lp->tbuf2 = (lp->tbuf2 & ~TB2_M_TBUFFAD) |
			    ((pa >> 16) & TB2_M_TBUFFAD);
		if (lp->tbuffct == 0) {
			lp->tbuf2 &= ~TB2_TX_DMA_START;
			q_tx_report (vh, status);
		}
	}
}

/* Perform many of the functions of PROC2 */

static t_stat vh_svc (	UNIT	*uptr	)
{
	int32	vh, newln, i;

	/* scan all muxes for countdown reset */
	for (vh = 0; vh < VH_MUXES; vh++) {
		if (vh_csr[vh] & CSR_MASTER_RESET) {
			if (vh_mcount[vh] != 0)
				vh_mcount[vh] -= 1;
			else
				vh_clear (vh, FALSE);
		}
	}
	/* sample every 10ms for modem changes (new connections) */
	newln = tmxr_poll_conn (&vh_desc);
	if (newln >= 0) {
		TMLX	*lp;
		int32	line;
		vh = newln / VH_LINES;	/* determine which mux */
		line = newln - (vh * VH_LINES);
		lp = &vh_parm[newln];
		lp->lstat |= STAT_DSR | STAT_DCD | STAT_CTS;
		if (!(lp->lnctrl & LNCTRL_DTR))
			lp->lstat |= STAT_RI;
		if (lp->lnctrl & LNCTRL_LINK_TYPE)
			fifo_put (vh, lp, RBUF_DIAG |
					  RBUF_PUTLINE (line) |
					  ((lp->lstat >> 8) & 0376));
			/* BUG: should check for overflow above */
	}
	/* scan all muxes, lines for DMA to complete; start every 3.12ms */
	for (vh = 0; vh < VH_MUXES; vh++) {
		for (i = 0; i < VH_LINES; i++)
			doDMA (vh, i);
	}
	/* interrupt driven in a real DHQ */
	tmxr_poll_rx (&vh_desc);
	for (vh = 0; vh < VH_MUXES; vh++)
		vh_getc (vh);
	tmxr_poll_tx (&vh_desc);
	/* scan all DHU-mode muxes for RX FIFO timeout */
	for (vh = 0; vh < VH_MUXES; vh++) {
		if (vh_unit[vh].flags & UNIT_MODEDHU) {
			if (vh_timeo[vh] && (vh_csr[vh] & CSR_RXIE)) {
				vh_timeo[vh] -= 1;
				if ((vh_timeo[vh] == 0) && rbuf_idx[vh])
					vh_set_rxint (vh);
			}
		}
	}
	sim_activate (uptr, tmxr_poll);	/* requeue ourselves */
	return (SCPE_OK);
}

/* init a channel on a controller */

/* set for:
send/receive 9600
8 data bits
1 stop bit
no parity
parity odd
auto-flow off
RX disabled
TX enabled
no break on line
no loopback
link type set to data-leads only
DTR & RTS off
DMA character counter 0
DMA start address registers 0
TX_DMA_START 0
TX_ABORT 0
auto-flow reports enabled
FIFO size set to 64
*/

static void vh_init_chan (	int32	vh,
				int32	chan	)
{
	int32	line;
	TMLX	*lp;

	line = (vh * VH_LINES) + chan;
	lp = &vh_parm[line];
	lp->lpr = (RATE_9600 << LPR_V_TX_SPEED) |
		  (RATE_9600 << LPR_V_RX_SPEED) |
		  (03 << LPR_V_CHAR_LGTH);
	lp->lnctrl = 0;
	lp->lstat &= ~(STAT_MDL | STAT_DHUID | STAT_RI);
	if (vh_unit[vh].flags & UNIT_MODEDHU)
		lp->lstat |= STAT_DHUID | 64;
	if (!(vh_unit[vh].flags & UNIT_MODEM))
		lp->lstat |= STAT_DSR | STAT_DCD | STAT_CTS;
	lp->tmln->xmte = 1;
	lp->tmln->rcve = 0;
	lp->tbuffct = 0;
	lp->tbuf1 = 0;
	lp->tbuf2 = TB2_TX_ENA;
	lp->txchar = 0;
}

/* init a controller; flag true if BINIT, false if master.reset */

static t_stat vh_clear (	int32	vh,
				t_bool	flag	)
{
	int32	i;

	txq_idx[vh] = 0;
	rbuf_idx[vh] = 0;
	/* put 8 diag bytes in FIFO: 6 SELF_x, 2 circuit revision codes */
	if (vh_csr[vh] & CSR_SKIP) {
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(0) | SELF_SKIP);
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(1) | SELF_SKIP);
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(2) | SELF_SKIP);
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(3) | SELF_SKIP);
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(4) | SELF_SKIP);
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(5) | SELF_SKIP);
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(6) | 0107);
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(7) | 0105);
	} else {
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(0) | SELF_NULL);
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(1) | SELF_NULL);
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(2) | SELF_NULL);
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(3) | SELF_NULL);
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(4) | SELF_NULL);
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(5) | SELF_NULL);
		/* PROC2 ver. 1 */
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(6) | 0107);
		/* PROC1 ver. 1 */
		fifo_put (vh, NULL, RBUF_DIAG | RBUF_PUTLINE(7) | 0105);
	}
	vh_csr[vh] &= ~(CSR_TX_ACTION|CSR_DIAG_FAIL|CSR_MASTER_RESET);
	if (flag)
		vh_csr[vh] &= ~(CSR_TXIE|CSR_RXIE|CSR_SKIP);
	vh_csr[vh] |= CSR_TX_DMA_ERR | (CSR_M_TX_LINE << CSR_V_TX_LINE);
	vh_clr_rxint (vh);
	vh_clr_txint (vh);
	vh_timer[vh] = 1;
	vh_timeo[vh] = 0;
	vh_ovrrun[vh] = 0;
	for (i = 0; i < VH_LINES; i++)
		vh_init_chan (vh, i);
	vh_crit &= ~(1 << vh);
	vh_stall[vh] = 0;
	vh_loop[vh] = LOOP_NONE;
	return (SCPE_OK);
}

/* Reset all controllers.  Used by BINIT and RESET. */

static t_stat vh_reset (	DEVICE	*dptr	)
{
	int32	i;

	for (i = 0; i < (VH_MUXES * VH_LINES); i++)
		vh_parm[i].tmln = &vh_ldsc[i];
        for (i = 0; i < VH_MUXES; i++) {
#if     defined (VM_PDP11)
		/* if Unibus, force DHU mode */
		if (UNIBUS)
			vh_unit[i].flags |= UNIT_MODEDHU;
#endif
		vh_clear (i, TRUE);
	}
	vh_rxi = vh_txi = 0;
	CLR_INT (VHRX);
	CLR_INT (VHTX);
	for (i = 0; i < VH_MUXES; i++)
		sim_cancel (&vh_unit[i]);
	return (auto_config (dptr->name, (dptr->flags & DEV_DIS) ? 0 : VH_MUXES));
}


static t_stat vh_attach (	UNIT	*uptr,
				char	*cptr	)
{
	if (uptr == &vh_unit[0])
		return (tmxr_attach (&vh_desc, uptr, cptr));
	return (SCPE_NOATT);
}

static t_stat vh_detach (	UNIT	*uptr	)
{
	return (tmxr_detach (&vh_desc, uptr));
}

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

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

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

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

static t_stat vh_show_vec (	FILE	*st,
				UNIT	*uptr,
				int32	val,
				void	*desc	)
{
	return (show_vec (st, uptr, ((vh_desc.lines * 2) / VH_LINES), desc));
}

static void debug_line (	FILE	*st,
				int32	vh,
				int32	chan	)
{
	int32	line;
	TMLX	*lp;

	line = (vh * VH_LINES) + chan;
	lp = &vh_parm[line];
	fprintf (st, "\tline %d\tlpr %06o, lnctrl %06o, lstat %06o\n",
		chan, lp->lpr, lp->lnctrl, lp->lstat);
	fprintf (st, "\t\ttbuffct %06o, tbuf1 %06o, tbuf2 %06o, txchar %06o\n",
		lp->tbuffct, lp->tbuf1, lp->tbuf2, lp->txchar);
	fprintf (st, "\t\ttmln rcve %d xmte %d\n",
		lp->tmln->rcve, lp->tmln->xmte);
}

static t_stat vh_show_debug (	FILE	*st,
				UNIT	*uptr,
				int32	val,
				void	*desc	)
{
	int32	i, j;

	fprintf (st, "VH:\trxi %d, txi %d\n", vh_rxi, vh_txi);
	for (i = 0; i < VH_MUXES; i++) {
		fprintf (st, "VH%d:\tmode %s, crit %d\n", i,
			vh_unit[i].flags & UNIT_MODEDHU ? "DHU" : "DHV",
			vh_crit & (1 << i));
		fprintf (st, "\tCSR %06o, mcount %d, rbuf_idx %d, txq_idx %d\n",
			vh_csr[i], vh_mcount[i], rbuf_idx[i], txq_idx[i]);
		for (j = 0; j < VH_LINES; j++)
			debug_line (st, i, j);
	}
	return (SCPE_OK);
}

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

	for (i = 0; i < rbuf_idx[0]; i++)
		fprintf (st, "%03d: %06o\n", i, vh_rbuf[0][i]);
	return (SCPE_OK);
}

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

	for (i = 0; i < txq_idx[0]; i++)
		fprintf (st, "%02d: %06o\n\r", i, vh_txq[0][i]);
	return (SCPE_OK);
}