NetBSD/sys/dev/ic/clmpcc.c
1999-09-18 09:45:05 +00:00

1593 lines
38 KiB
C

/* $NetBSD: clmpcc.c,v 1.7 1999/09/18 09:45:05 scw Exp $ */
/*-
* Copyright (c) 1999 The NetBSD Foundation, Inc.
* All rights reserved.
*
* This code is derived from software contributed to The NetBSD Foundation
* by Steve C. Woodford.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by the NetBSD
* Foundation, Inc. and its contributors.
* 4. Neither the name of The NetBSD Foundation nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
* ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
* TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
/*
* Cirrus Logic CD2400/CD2401 Four Channel Multi-Protocol Comms. Controller.
*/
#include "opt_ddb.h"
#include <sys/types.h>
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/ioctl.h>
#include <sys/select.h>
#include <sys/tty.h>
#include <sys/proc.h>
#include <sys/user.h>
#include <sys/conf.h>
#include <sys/file.h>
#include <sys/uio.h>
#include <sys/kernel.h>
#include <sys/syslog.h>
#include <sys/device.h>
#include <sys/malloc.h>
#include <machine/bus.h>
#include <machine/param.h>
#include <dev/ic/clmpccreg.h>
#include <dev/ic/clmpccvar.h>
#include <dev/cons.h>
#if defined(CLMPCC_ONLY_BYTESWAP_LOW) && defined(CLMPCC_ONLY_BYTESWAP_HIGH)
#error "CLMPCC_ONLY_BYTESWAP_LOW and CLMPCC_ONLY_BYTESWAP_HIGH are mutually exclusive."
#endif
static int clmpcc_init __P((struct clmpcc_softc *sc));
static void clmpcc_shutdown __P((struct clmpcc_chan *));
static int clmpcc_speed __P((struct clmpcc_softc *, speed_t,
int *, int *));
static int clmpcc_param __P((struct tty *, struct termios *));
static void clmpcc_set_params __P((struct clmpcc_chan *));
static void clmpcc_start __P((struct tty *));
static int clmpcc_modem_control __P((struct clmpcc_chan *, int, int));
cdev_decl(clmpcc);
#define CLMPCCUNIT(x) (minor(x) & 0x7fffc)
#define CLMPCCCHAN(x) (minor(x) & 0x00003)
#define CLMPCCDIALOUT(x) (minor(x) & 0x80000)
/*
* These should be in a header file somewhere...
*/
#define ISSET(v, f) (((v) & (f)) != 0)
#define ISCLR(v, f) (((v) & (f)) == 0)
#define SET(v, f) (v) |= (f)
#define CLR(v, f) (v) &= ~(f)
extern struct cfdriver clmpcc_cd;
/*
* Make this an option variable one can patch.
*/
u_int clmpcc_ibuf_size = CLMPCC_RING_SIZE;
/*
* Things needed when the device is used as a console
*/
static struct clmpcc_softc *cons_sc = NULL;
static int cons_chan;
static int cons_rate;
static int clmpcc_common_getc __P((struct clmpcc_softc *, int));
static void clmpcc_common_putc __P((struct clmpcc_softc *, int, int));
int clmpcccngetc __P((dev_t));
void clmpcccnputc __P((dev_t, int));
/*
* Convenience functions, inlined for speed
*/
#define integrate static inline
integrate u_int8_t clmpcc_rdreg __P((struct clmpcc_softc *, u_int));
integrate void clmpcc_wrreg __P((struct clmpcc_softc *, u_int, u_int));
integrate u_int8_t clmpcc_rdreg_odd __P((struct clmpcc_softc *, u_int));
integrate void clmpcc_wrreg_odd __P((struct clmpcc_softc *, u_int, u_int));
integrate void clmpcc_wrtx_multi __P((struct clmpcc_softc *, u_int8_t *,
u_int));
integrate u_int8_t clmpcc_select_channel __P((struct clmpcc_softc *, u_int));
integrate void clmpcc_channel_cmd __P((struct clmpcc_softc *,int,int));
integrate void clmpcc_enable_transmitter __P((struct clmpcc_chan *));
#define clmpcc_rd_msvr(s) clmpcc_rdreg_odd(s,CLMPCC_REG_MSVR)
#define clmpcc_wr_msvr(s,r,v) clmpcc_wrreg_odd(s,r,v)
#define clmpcc_wr_pilr(s,r,v) clmpcc_wrreg_odd(s,r,v)
#define clmpcc_rd_rxdata(s) clmpcc_rdreg_odd(s,CLMPCC_REG_RDR)
#define clmpcc_wr_txdata(s,v) clmpcc_wrreg_odd(s,CLMPCC_REG_TDR,v)
integrate u_int8_t
clmpcc_rdreg(sc, offset)
struct clmpcc_softc *sc;
u_int offset;
{
#if !defined(CLMPCC_ONLY_BYTESWAP_LOW) && !defined(CLMPCC_ONLY_BYTESWAP_HIGH)
offset ^= sc->sc_byteswap;
#elif defined(CLMPCC_ONLY_BYTESWAP_HIGH)
offset ^= CLMPCC_BYTESWAP_HIGH;
#endif
return bus_space_read_1(sc->sc_iot, sc->sc_ioh, offset);
}
integrate void
clmpcc_wrreg(sc, offset, val)
struct clmpcc_softc *sc;
u_int offset;
u_int val;
{
#if !defined(CLMPCC_ONLY_BYTESWAP_LOW) && !defined(CLMPCC_ONLY_BYTESWAP_HIGH)
offset ^= sc->sc_byteswap;
#elif defined(CLMPCC_ONLY_BYTESWAP_HIGH)
offset ^= CLMPCC_BYTESWAP_HIGH;
#endif
bus_space_write_1(sc->sc_iot, sc->sc_ioh, offset, val);
}
integrate u_int8_t
clmpcc_rdreg_odd(sc, offset)
struct clmpcc_softc *sc;
u_int offset;
{
#if !defined(CLMPCC_ONLY_BYTESWAP_LOW) && !defined(CLMPCC_ONLY_BYTESWAP_HIGH)
offset ^= (sc->sc_byteswap & 2);
#elif defined(CLMPCC_ONLY_BYTESWAP_HIGH)
offset ^= (CLMPCC_BYTESWAP_HIGH & 2);
#endif
return bus_space_read_1(sc->sc_iot, sc->sc_ioh, offset);
}
integrate void
clmpcc_wrreg_odd(sc, offset, val)
struct clmpcc_softc *sc;
u_int offset;
u_int val;
{
#if !defined(CLMPCC_ONLY_BYTESWAP_LOW) && !defined(CLMPCC_ONLY_BYTESWAP_HIGH)
offset ^= (sc->sc_byteswap & 2);
#elif defined(CLMPCC_ONLY_BYTESWAP_HIGH)
offset ^= (CLMPCC_BYTESWAP_HIGH & 2);
#endif
bus_space_write_1(sc->sc_iot, sc->sc_ioh, offset, val);
}
integrate void
clmpcc_wrtx_multi(sc, buff, count)
struct clmpcc_softc *sc;
u_int8_t *buff;
u_int count;
{
u_int offset = CLMPCC_REG_TDR;
#if !defined(CLMPCC_ONLY_BYTESWAP_LOW) && !defined(CLMPCC_ONLY_BYTESWAP_HIGH)
offset ^= (sc->sc_byteswap & 2);
#elif defined(CLMPCC_ONLY_BYTESWAP_HIGH)
offset ^= (CLMPCC_BYTESWAP_HIGH & 2);
#endif
bus_space_write_multi_1(sc->sc_iot, sc->sc_ioh, offset, buff, count);
}
integrate u_int8_t
clmpcc_select_channel(sc, new_chan)
struct clmpcc_softc *sc;
u_int new_chan;
{
u_int old_chan = clmpcc_rdreg_odd(sc, CLMPCC_REG_CAR);
clmpcc_wrreg_odd(sc, CLMPCC_REG_CAR, new_chan);
return old_chan;
}
integrate void
clmpcc_channel_cmd(sc, chan, cmd)
struct clmpcc_softc *sc;
int chan;
int cmd;
{
int i;
for (i = 5000; i; i--) {
if ( clmpcc_rdreg(sc, CLMPCC_REG_CCR) == 0 )
break;
delay(1);
}
if ( i == 0 )
printf("%s: channel %d command timeout (idle)\n",
sc->sc_dev.dv_xname, chan);
clmpcc_wrreg(sc, CLMPCC_REG_CCR, cmd);
}
integrate void
clmpcc_enable_transmitter(ch)
struct clmpcc_chan *ch;
{
u_int old;
int s;
old = clmpcc_select_channel(ch->ch_sc, ch->ch_car);
s = splserial();
clmpcc_wrreg(ch->ch_sc, CLMPCC_REG_IER,
clmpcc_rdreg(ch->ch_sc, CLMPCC_REG_IER) | CLMPCC_IER_TX_EMPTY);
SET(ch->ch_tty->t_state, TS_BUSY);
splx(s);
clmpcc_select_channel(ch->ch_sc, old);
}
static int
clmpcc_speed(sc, speed, cor, bpr)
struct clmpcc_softc *sc;
speed_t speed;
int *cor, *bpr;
{
int c, co, br;
for (co = 0, c = 8; c <= 2048; co++, c *= 4) {
br = ((sc->sc_clk / c) / speed) - 1;
if ( br < 0x100 ) {
*cor = co;
*bpr = br;
return 0;
}
}
return -1;
}
void
clmpcc_attach(sc)
struct clmpcc_softc *sc;
{
struct clmpcc_chan *ch;
struct tty *tp;
int chan;
if ( cons_sc != NULL &&
sc->sc_iot == cons_sc->sc_iot && sc->sc_ioh == cons_sc->sc_ioh )
cons_sc = sc;
/* Initialise the chip */
clmpcc_init(sc);
printf(": Cirrus Logic CD240%c Serial Controller\n",
(clmpcc_rd_msvr(sc) & CLMPCC_MSVR_PORT_ID) ? '0' : '1');
sc->sc_soft_running = 0;
memset(&(sc->sc_chans[0]), 0, sizeof(sc->sc_chans));
for (chan = 0; chan < CLMPCC_NUM_CHANS; chan++) {
ch = &sc->sc_chans[chan];
ch->ch_sc = sc;
ch->ch_car = chan;
tp = ttymalloc();
tp->t_oproc = clmpcc_start;
tp->t_param = clmpcc_param;
ch->ch_tty = tp;
ch->ch_ibuf = malloc(clmpcc_ibuf_size * 2, M_DEVBUF, M_NOWAIT);
if ( ch->ch_ibuf == NULL ) {
printf("%s(%d): unable to allocate ring buffer\n",
sc->sc_dev.dv_xname, chan);
return;
}
ch->ch_ibuf_end = &(ch->ch_ibuf[clmpcc_ibuf_size * 2]);
ch->ch_ibuf_rd = ch->ch_ibuf_wr = ch->ch_ibuf;
tty_attach(tp);
}
printf("%s: %d channels available", sc->sc_dev.dv_xname,
CLMPCC_NUM_CHANS);
if ( cons_sc == sc ) {
printf(", console on channel %d.\n", cons_chan);
SET(sc->sc_chans[cons_chan].ch_flags, CLMPCC_FLG_IS_CONSOLE);
SET(sc->sc_chans[cons_chan].ch_openflags, TIOCFLAG_SOFTCAR);
} else
printf(".\n");
}
static int
clmpcc_init(sc)
struct clmpcc_softc *sc;
{
u_int tcor, tbpr;
u_int rcor, rbpr;
u_int msvr_rts, msvr_dtr;
u_int ccr;
int is_console;
int i;
/*
* All we're really concerned about here is putting the chip
* into a quiescent state so that it won't do anything until
* clmpccopen() is called. (Except the console channel.)
*/
/*
* If the chip is acting as console, set all channels to the supplied
* console baud rate. Otherwise, plump for 9600.
*/
if ( cons_sc &&
sc->sc_ioh == cons_sc->sc_ioh && sc->sc_iot == cons_sc->sc_iot ) {
clmpcc_speed(sc, cons_rate, &tcor, &tbpr);
clmpcc_speed(sc, cons_rate, &rcor, &rbpr);
is_console = 1;
} else {
clmpcc_speed(sc, 9600, &tcor, &tbpr);
clmpcc_speed(sc, 9600, &rcor, &rbpr);
is_console = 0;
}
/* Allow any pending output to be sent */
delay(10000);
/* Send the Reset All command to channel 0 (resets all channels!) */
clmpcc_channel_cmd(sc, 0, CLMPCC_CCR_T0_RESET_ALL);
delay(1000);
/*
* The chip will set it's firmware revision register to a non-zero
* value to indicate completion of reset.
*/
for (i = 10000; clmpcc_rdreg(sc, CLMPCC_REG_GFRCR) == 0 && i; i--)
delay(1);
if ( i == 0 ) {
/*
* Watch out... If this chip is console, the message
* probably won't be sent since we just reset it!
*/
printf("%s: Failed to reset chip\n", sc->sc_dev.dv_xname);
return -1;
}
for (i = 0; i < CLMPCC_NUM_CHANS; i++) {
clmpcc_select_channel(sc, i);
/* All interrupts are disabled to begin with */
clmpcc_wrreg(sc, CLMPCC_REG_IER, 0);
/* Make sure the channel interrupts on the correct vectors */
clmpcc_wrreg(sc, CLMPCC_REG_LIVR, sc->sc_vector_base);
clmpcc_wr_pilr(sc, CLMPCC_REG_RPILR, sc->sc_rpilr);
clmpcc_wr_pilr(sc, CLMPCC_REG_TPILR, sc->sc_tpilr);
clmpcc_wr_pilr(sc, CLMPCC_REG_MPILR, sc->sc_mpilr);
/* Receive timer prescaler set to 1ms */
clmpcc_wrreg(sc, CLMPCC_REG_TPR,
CLMPCC_MSEC_TO_TPR(sc->sc_clk, 1));
/* We support Async mode only */
clmpcc_wrreg(sc, CLMPCC_REG_CMR, CLMPCC_CMR_ASYNC);
/* Set the required baud rate */
clmpcc_wrreg(sc, CLMPCC_REG_TCOR, CLMPCC_TCOR_CLK(tcor));
clmpcc_wrreg(sc, CLMPCC_REG_TBPR, tbpr);
clmpcc_wrreg(sc, CLMPCC_REG_RCOR, CLMPCC_RCOR_CLK(rcor));
clmpcc_wrreg(sc, CLMPCC_REG_RBPR, rbpr);
/* Always default to 8N1 (XXX what about console?) */
clmpcc_wrreg(sc, CLMPCC_REG_COR1, CLMPCC_COR1_CHAR_8BITS |
CLMPCC_COR1_NO_PARITY |
CLMPCC_COR1_IGNORE_PAR);
clmpcc_wrreg(sc, CLMPCC_REG_COR2, 0);
clmpcc_wrreg(sc, CLMPCC_REG_COR3, CLMPCC_COR3_STOP_1);
clmpcc_wrreg(sc, CLMPCC_REG_COR4, CLMPCC_COR4_DSRzd |
CLMPCC_COR4_CDzd |
CLMPCC_COR4_CTSzd);
clmpcc_wrreg(sc, CLMPCC_REG_COR5, CLMPCC_COR5_DSRod |
CLMPCC_COR5_CDod |
CLMPCC_COR5_CTSod |
CLMPCC_COR5_FLOW_NORM);
clmpcc_wrreg(sc, CLMPCC_REG_COR6, 0);
clmpcc_wrreg(sc, CLMPCC_REG_COR7, 0);
/* Set the receive FIFO timeout */
clmpcc_wrreg(sc, CLMPCC_REG_RTPRl, CLMPCC_RTPR_DEFAULT);
clmpcc_wrreg(sc, CLMPCC_REG_RTPRh, 0);
/* At this point, we set up the console differently */
if ( is_console && i == cons_chan ) {
msvr_rts = CLMPCC_MSVR_RTS;
msvr_dtr = CLMPCC_MSVR_DTR;
ccr = CLMPCC_CCR_T0_RX_EN | CLMPCC_CCR_T0_TX_EN;
} else {
msvr_rts = 0;
msvr_dtr = 0;
ccr = CLMPCC_CCR_T0_RX_DIS | CLMPCC_CCR_T0_TX_DIS;
}
clmpcc_wrreg(sc, CLMPCC_REG_MSVR_RTS, msvr_rts);
clmpcc_wrreg(sc, CLMPCC_REG_MSVR_DTR, msvr_dtr);
clmpcc_channel_cmd(sc, i, CLMPCC_CCR_T0_INIT | ccr);
delay(100);
}
return 0;
}
static void
clmpcc_shutdown(ch)
struct clmpcc_chan *ch;
{
int oldch;
oldch = clmpcc_select_channel(ch->ch_sc, ch->ch_car);
/* Turn off interrupts. */
clmpcc_wrreg(ch->ch_sc, CLMPCC_REG_IER, 0);
if ( ISCLR(ch->ch_flags, CLMPCC_FLG_IS_CONSOLE) ) {
/* Disable the transmitter and receiver */
clmpcc_channel_cmd(ch->ch_sc, ch->ch_car, CLMPCC_CCR_T0_RX_DIS |
CLMPCC_CCR_T0_TX_DIS);
/* Drop RTS and DTR */
clmpcc_modem_control(ch, TIOCM_RTS | TIOCM_DTR, DMBIS);
}
clmpcc_select_channel(ch->ch_sc, oldch);
}
int
clmpccopen(dev, flag, mode, p)
dev_t dev;
int flag, mode;
struct proc *p;
{
struct clmpcc_softc *sc;
struct clmpcc_chan *ch;
struct tty *tp;
int oldch;
int error;
int unit;
if ( (unit = CLMPCCUNIT(dev)) >= clmpcc_cd.cd_ndevs ||
(sc = clmpcc_cd.cd_devs[unit]) == NULL ) {
return ENXIO;
}
ch = &sc->sc_chans[CLMPCCCHAN(dev)];
tp = ch->ch_tty;
if ( ISSET(tp->t_state, TS_ISOPEN) &&
ISSET(tp->t_state, TS_XCLUDE) && p->p_ucred->cr_uid != 0 )
return EBUSY;
/*
* Do the following iff this is a first open.
*/
if ( ISCLR(tp->t_state, TS_ISOPEN) && tp->t_wopen == 0 ) {
ttychars(tp);
tp->t_dev = dev;
tp->t_iflag = TTYDEF_IFLAG;
tp->t_oflag = TTYDEF_OFLAG;
tp->t_lflag = TTYDEF_LFLAG;
tp->t_cflag = TTYDEF_CFLAG;
tp->t_ospeed = tp->t_ispeed = TTYDEF_SPEED;
if ( ISSET(ch->ch_openflags, TIOCFLAG_CLOCAL) )
SET(tp->t_cflag, CLOCAL);
if ( ISSET(ch->ch_openflags, TIOCFLAG_CRTSCTS) )
SET(tp->t_cflag, CRTSCTS);
if ( ISSET(ch->ch_openflags, TIOCFLAG_MDMBUF) )
SET(tp->t_cflag, MDMBUF);
/*
* Override some settings if the channel is being
* used as the console.
*/
if ( ISSET(ch->ch_flags, CLMPCC_FLG_IS_CONSOLE) ) {
tp->t_ospeed = tp->t_ispeed = cons_rate;
SET(tp->t_cflag, CLOCAL);
CLR(tp->t_cflag, CRTSCTS);
CLR(tp->t_cflag, HUPCL);
}
ch->ch_control = 0;
clmpcc_param(tp, &tp->t_termios);
ttsetwater(tp);
/* Clear the input ring */
ch->ch_ibuf_rd = ch->ch_ibuf_wr = ch->ch_ibuf;
/* Select the channel */
oldch = clmpcc_select_channel(sc, ch->ch_car);
/* Reset it */
clmpcc_channel_cmd(sc, ch->ch_car, CLMPCC_CCR_T0_CLEAR |
CLMPCC_CCR_T0_RX_EN |
CLMPCC_CCR_T0_TX_EN);
/* Enable receiver and modem change interrupts. */
clmpcc_wrreg(sc, CLMPCC_REG_IER, CLMPCC_IER_MODEM |
CLMPCC_IER_RET |
CLMPCC_IER_RX_FIFO);
/* Raise RTS and DTR */
clmpcc_modem_control(ch, TIOCM_RTS | TIOCM_DTR, DMBIS);
clmpcc_select_channel(sc, oldch);
} else
if ( ISSET(tp->t_state, TS_XCLUDE) && p->p_ucred->cr_uid != 0 )
return EBUSY;
error = ttyopen(tp, CLMPCCDIALOUT(dev), ISSET(flag, O_NONBLOCK));
if (error)
goto bad;
error = (*linesw[tp->t_line].l_open)(dev, tp);
if (error)
goto bad;
return 0;
bad:
if ( ISCLR(tp->t_state, TS_ISOPEN) && tp->t_wopen == 0 ) {
/*
* We failed to open the device, and nobody else had it opened.
* Clean up the state as appropriate.
*/
clmpcc_shutdown(ch);
}
return error;
}
int
clmpccclose(dev, flag, mode, p)
dev_t dev;
int flag, mode;
struct proc *p;
{
struct clmpcc_softc *sc = clmpcc_cd.cd_devs[CLMPCCUNIT(dev)];
struct clmpcc_chan *ch = &sc->sc_chans[CLMPCCCHAN(dev)];
struct tty *tp = ch->ch_tty;
int s;
if ( ISCLR(tp->t_state, TS_ISOPEN) )
return 0;
(*linesw[tp->t_line].l_close)(tp, flag);
s = spltty();
if ( ISCLR(tp->t_state, TS_ISOPEN) && tp->t_wopen == 0 ) {
/*
* Although we got a last close, the device may still be in
* use; e.g. if this was the dialout node, and there are still
* processes waiting for carrier on the non-dialout node.
*/
clmpcc_shutdown(ch);
}
ttyclose(tp);
splx(s);
return 0;
}
int
clmpccread(dev, uio, flag)
dev_t dev;
struct uio *uio;
int flag;
{
struct clmpcc_softc *sc = clmpcc_cd.cd_devs[CLMPCCUNIT(dev)];
struct tty *tp = sc->sc_chans[CLMPCCCHAN(dev)].ch_tty;
return ((*linesw[tp->t_line].l_read)(tp, uio, flag));
}
int
clmpccwrite(dev, uio, flag)
dev_t dev;
struct uio *uio;
int flag;
{
struct clmpcc_softc *sc = clmpcc_cd.cd_devs[CLMPCCUNIT(dev)];
struct tty *tp = sc->sc_chans[CLMPCCCHAN(dev)].ch_tty;
return ((*linesw[tp->t_line].l_write)(tp, uio, flag));
}
struct tty *
clmpcctty(dev)
dev_t dev;
{
struct clmpcc_softc *sc = clmpcc_cd.cd_devs[CLMPCCUNIT(dev)];
return (sc->sc_chans[CLMPCCCHAN(dev)].ch_tty);
}
int
clmpccioctl(dev, cmd, data, flag, p)
dev_t dev;
u_long cmd;
caddr_t data;
int flag;
struct proc *p;
{
struct clmpcc_softc *sc = clmpcc_cd.cd_devs[CLMPCCUNIT(dev)];
struct clmpcc_chan *ch = &sc->sc_chans[CLMPCCCHAN(dev)];
struct tty *tp = ch->ch_tty;
int error;
error = (*linesw[tp->t_line].l_ioctl)(tp, cmd, data, flag, p);
if (error >= 0)
return error;
error = ttioctl(tp, cmd, data, flag, p);
if (error >= 0)
return error;
error = 0;
switch (cmd) {
case TIOCSBRK:
SET(ch->ch_flags, CLMPCC_FLG_START_BREAK);
clmpcc_enable_transmitter(ch);
break;
case TIOCCBRK:
SET(ch->ch_flags, CLMPCC_FLG_END_BREAK);
clmpcc_enable_transmitter(ch);
break;
case TIOCSDTR:
clmpcc_modem_control(ch, TIOCM_DTR, DMBIS);
break;
case TIOCCDTR:
clmpcc_modem_control(ch, TIOCM_DTR, DMBIC);
break;
case TIOCMSET:
clmpcc_modem_control(ch, *((int *)data), DMSET);
break;
case TIOCMBIS:
clmpcc_modem_control(ch, *((int *)data), DMBIS);
break;
case TIOCMBIC:
clmpcc_modem_control(ch, *((int *)data), DMBIC);
break;
case TIOCMGET:
*((int *)data) = clmpcc_modem_control(ch, 0, DMGET);
break;
case TIOCGFLAGS:
*((int *)data) = ch->ch_openflags;
break;
case TIOCSFLAGS:
error = suser(p->p_ucred, &p->p_acflag);
if ( error )
break;
ch->ch_openflags = *((int *)data) &
(TIOCFLAG_SOFTCAR | TIOCFLAG_CLOCAL |
TIOCFLAG_CRTSCTS | TIOCFLAG_MDMBUF);
if ( ISSET(ch->ch_flags, CLMPCC_FLG_IS_CONSOLE) )
SET(ch->ch_openflags, TIOCFLAG_SOFTCAR);
break;
default:
error = ENOTTY;
break;
}
return error;
}
int
clmpcc_modem_control(ch, bits, howto)
struct clmpcc_chan *ch;
int bits;
int howto;
{
struct clmpcc_softc *sc = ch->ch_sc;
struct tty *tp = ch->ch_tty;
int oldch;
int msvr;
int rbits = 0;
oldch = clmpcc_select_channel(sc, ch->ch_car);
switch ( howto ) {
case DMGET:
msvr = clmpcc_rd_msvr(sc);
if ( sc->sc_swaprtsdtr ) {
rbits |= (msvr & CLMPCC_MSVR_RTS) ? TIOCM_DTR : 0;
rbits |= (msvr & CLMPCC_MSVR_DTR) ? TIOCM_RTS : 0;
} else {
rbits |= (msvr & CLMPCC_MSVR_RTS) ? TIOCM_RTS : 0;
rbits |= (msvr & CLMPCC_MSVR_DTR) ? TIOCM_DTR : 0;
}
rbits |= (msvr & CLMPCC_MSVR_CTS) ? TIOCM_CTS : 0;
rbits |= (msvr & CLMPCC_MSVR_CD) ? TIOCM_CD : 0;
rbits |= (msvr & CLMPCC_MSVR_DSR) ? TIOCM_DSR : 0;
break;
case DMSET:
if ( sc->sc_swaprtsdtr ) {
if ( ISCLR(tp->t_cflag, CRTSCTS) )
clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_DTR,
bits & TIOCM_RTS ? CLMPCC_MSVR_DTR : 0);
clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_RTS,
bits & TIOCM_DTR ? CLMPCC_MSVR_RTS : 0);
} else {
if ( ISCLR(tp->t_cflag, CRTSCTS) )
clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_RTS,
bits & TIOCM_RTS ? CLMPCC_MSVR_RTS : 0);
clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_DTR,
bits & TIOCM_DTR ? CLMPCC_MSVR_DTR : 0);
}
break;
case DMBIS:
if ( sc->sc_swaprtsdtr ) {
if ( ISCLR(tp->t_cflag, CRTSCTS) && ISSET(bits, TIOCM_RTS) )
clmpcc_wr_msvr(sc,CLMPCC_REG_MSVR_DTR, CLMPCC_MSVR_DTR);
if ( ISSET(bits, TIOCM_DTR) )
clmpcc_wr_msvr(sc,CLMPCC_REG_MSVR_RTS, CLMPCC_MSVR_RTS);
} else {
if ( ISCLR(tp->t_cflag, CRTSCTS) && ISSET(bits, TIOCM_RTS) )
clmpcc_wr_msvr(sc,CLMPCC_REG_MSVR_RTS, CLMPCC_MSVR_RTS);
if ( ISSET(bits, TIOCM_DTR) )
clmpcc_wr_msvr(sc,CLMPCC_REG_MSVR_DTR, CLMPCC_MSVR_DTR);
}
break;
case DMBIC:
if ( sc->sc_swaprtsdtr ) {
if ( ISCLR(tp->t_cflag, CRTSCTS) && ISCLR(bits, TIOCM_RTS) )
clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_DTR, 0);
if ( ISCLR(bits, TIOCM_DTR) )
clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_RTS, 0);
} else {
if ( ISCLR(tp->t_cflag, CRTSCTS) && ISCLR(bits, TIOCM_RTS) )
clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_RTS, 0);
if ( ISCLR(bits, TIOCM_DTR) )
clmpcc_wr_msvr(sc, CLMPCC_REG_MSVR_DTR, 0);
}
break;
}
clmpcc_select_channel(sc, oldch);
return rbits;
}
static int
clmpcc_param(tp, t)
struct tty *tp;
struct termios *t;
{
struct clmpcc_softc *sc = clmpcc_cd.cd_devs[CLMPCCUNIT(tp->t_dev)];
struct clmpcc_chan *ch = &sc->sc_chans[CLMPCCCHAN(tp->t_dev)];
u_char cor;
u_char oldch;
int oclk, obpr;
int iclk, ibpr;
int s;
/* Check requested parameters. */
if ( t->c_ospeed && clmpcc_speed(sc, t->c_ospeed, &oclk, &obpr) < 0 )
return EINVAL;
if ( t->c_ispeed && clmpcc_speed(sc, t->c_ispeed, &iclk, &ibpr) < 0 )
return EINVAL;
/*
* For the console, always force CLOCAL and !HUPCL, so that the port
* is always active.
*/
if ( ISSET(ch->ch_openflags, TIOCFLAG_SOFTCAR) ||
ISSET(ch->ch_flags, CLMPCC_FLG_IS_CONSOLE) ) {
SET(t->c_cflag, CLOCAL);
CLR(t->c_cflag, HUPCL);
}
CLR(ch->ch_flags, CLMPCC_FLG_UPDATE_PARMS);
/* If ospeed it zero, hangup the line */
clmpcc_modem_control(ch, TIOCM_DTR, t->c_ospeed == 0 ? DMBIC : DMBIS);
if ( t->c_ospeed ) {
ch->ch_tcor = CLMPCC_TCOR_CLK(oclk);
ch->ch_tbpr = obpr;
} else {
ch->ch_tcor = 0;
ch->ch_tbpr = 0;
}
if ( t->c_ispeed ) {
ch->ch_rcor = CLMPCC_RCOR_CLK(iclk);
ch->ch_rbpr = ibpr;
} else {
ch->ch_rcor = 0;
ch->ch_rbpr = 0;
}
/* Work out value to use for COR1 */
cor = 0;
if ( ISSET(t->c_cflag, PARENB) ) {
cor |= CLMPCC_COR1_NORM_PARITY;
if ( ISSET(t->c_cflag, PARODD) )
cor |= CLMPCC_COR1_ODD_PARITY;
}
if ( ISCLR(t->c_cflag, INPCK) )
cor |= CLMPCC_COR1_IGNORE_PAR;
switch ( t->c_cflag & CSIZE ) {
case CS5:
cor |= CLMPCC_COR1_CHAR_5BITS;
break;
case CS6:
cor |= CLMPCC_COR1_CHAR_6BITS;
break;
case CS7:
cor |= CLMPCC_COR1_CHAR_7BITS;
break;
case CS8:
cor |= CLMPCC_COR1_CHAR_8BITS;
break;
}
ch->ch_cor1 = cor;
/*
* The only interesting bit in COR2 is 'CTS Automatic Enable'
* when hardware flow control is in effect.
*/
ch->ch_cor2 = ISSET(t->c_cflag, CRTSCTS) ? CLMPCC_COR2_CtsAE : 0;
/* COR3 needs to be set to the number of stop bits... */
ch->ch_cor3 = ISSET(t->c_cflag, CSTOPB) ? CLMPCC_COR3_STOP_2 :
CLMPCC_COR3_STOP_1;
/*
* COR4 contains the FIFO threshold setting.
* We adjust the threshold depending on the input speed...
*/
if ( t->c_ispeed <= 1200 )
ch->ch_cor4 = CLMPCC_COR4_FIFO_LOW;
else if ( t->c_ispeed <= 19200 )
ch->ch_cor4 = CLMPCC_COR4_FIFO_MED;
else
ch->ch_cor4 = CLMPCC_COR4_FIFO_HIGH;
/*
* If chip is used with CTS and DTR swapped, we can enable
* automatic hardware flow control.
*/
if ( sc->sc_swaprtsdtr && ISSET(t->c_cflag, CRTSCTS) )
ch->ch_cor5 = CLMPCC_COR5_FLOW_NORM;
else
ch->ch_cor5 = 0;
s = splserial();
oldch = clmpcc_select_channel(sc, ch->ch_car);
/*
* COR2 needs to be set immediately otherwise we might never get
* a Tx EMPTY interrupt to change the other parameters.
*/
if ( clmpcc_rdreg(sc, CLMPCC_REG_COR2) != ch->ch_cor2 )
clmpcc_wrreg(sc, CLMPCC_REG_COR2, ch->ch_cor2);
if ( ISCLR(ch->ch_tty->t_state, TS_BUSY) )
clmpcc_set_params(ch);
else
SET(ch->ch_flags, CLMPCC_FLG_UPDATE_PARMS);
clmpcc_select_channel(sc, oldch);
splx(s);
return 0;
}
static void
clmpcc_set_params(ch)
struct clmpcc_chan *ch;
{
struct clmpcc_softc *sc = ch->ch_sc;
u_char r1;
u_char r2;
if ( ch->ch_tcor && ch->ch_tbpr ) {
r1 = clmpcc_rdreg(sc, CLMPCC_REG_TCOR);
r2 = clmpcc_rdreg(sc, CLMPCC_REG_TBPR);
/* Only write Tx rate if it really has changed */
if ( ch->ch_tcor != r1 || ch->ch_tbpr != r2 ) {
clmpcc_wrreg(sc, CLMPCC_REG_TCOR, ch->ch_tcor);
clmpcc_wrreg(sc, CLMPCC_REG_TBPR, ch->ch_tbpr);
}
}
if ( ch->ch_rcor && ch->ch_rbpr ) {
r1 = clmpcc_rdreg(sc, CLMPCC_REG_RCOR);
r2 = clmpcc_rdreg(sc, CLMPCC_REG_RBPR);
/* Only write Rx rate if it really has changed */
if ( ch->ch_rcor != r1 || ch->ch_rbpr != r2 ) {
clmpcc_wrreg(sc, CLMPCC_REG_RCOR, ch->ch_rcor);
clmpcc_wrreg(sc, CLMPCC_REG_RBPR, ch->ch_rbpr);
}
}
if ( clmpcc_rdreg(sc, CLMPCC_REG_COR1) != ch->ch_cor1 ) {
clmpcc_wrreg(sc, CLMPCC_REG_COR1, ch->ch_cor1);
/* Any change to COR1 requires an INIT command */
SET(ch->ch_flags, CLMPCC_FLG_NEED_INIT);
}
if ( clmpcc_rdreg(sc, CLMPCC_REG_COR3) != ch->ch_cor3 )
clmpcc_wrreg(sc, CLMPCC_REG_COR3, ch->ch_cor3);
r1 = clmpcc_rdreg(sc, CLMPCC_REG_COR4);
if ( ch->ch_cor4 != (r1 & CLMPCC_COR4_FIFO_MASK) ) {
/*
* Note: If the Rx FIFO has changed, we always set it to
* zero here and disable the Receive Timeout interrupt.
* It's up to the Rx Interrupt handler to pick the
* appropriate moment to write the Rx FIFO length.
*/
clmpcc_wrreg(sc, CLMPCC_REG_COR4, r1 & ~CLMPCC_COR4_FIFO_MASK);
r1 = clmpcc_rdreg(sc, CLMPCC_REG_IER);
clmpcc_wrreg(sc, CLMPCC_REG_IER, r1 & ~CLMPCC_IER_RET);
SET(ch->ch_flags, CLMPCC_FLG_FIFO_CLEAR);
}
r1 = clmpcc_rdreg(sc, CLMPCC_REG_COR5);
if ( ch->ch_cor5 != (r1 & CLMPCC_COR5_FLOW_MASK) ) {
r1 &= ~CLMPCC_COR5_FLOW_MASK;
clmpcc_wrreg(sc, CLMPCC_REG_COR5, r1 | ch->ch_cor5);
}
}
static void
clmpcc_start(tp)
struct tty *tp;
{
struct clmpcc_softc *sc = clmpcc_cd.cd_devs[CLMPCCUNIT(tp->t_dev)];
struct clmpcc_chan *ch = &sc->sc_chans[CLMPCCCHAN(tp->t_dev)];
u_int oldch;
int s;
s = spltty();
if ( ISCLR(tp->t_state, TS_TTSTOP | TS_TIMEOUT | TS_BUSY) ) {
if ( tp->t_outq.c_cc <= tp->t_lowat ) {
if ( ISSET(tp->t_state, TS_ASLEEP) ) {
CLR(tp->t_state, TS_ASLEEP);
wakeup(&tp->t_outq);
}
selwakeup(&tp->t_wsel);
}
if ( tp->t_outq.c_cc > 0 ) {
ch->ch_obuf_addr = tp->t_outq.c_cf;
ch->ch_obuf_size = ndqb(&tp->t_outq, 0);
/* Enable TX empty interrupts */
oldch = clmpcc_select_channel(ch->ch_sc, ch->ch_car);
clmpcc_wrreg(ch->ch_sc, CLMPCC_REG_IER,
clmpcc_rdreg(ch->ch_sc, CLMPCC_REG_IER) |
CLMPCC_IER_TX_EMPTY);
clmpcc_select_channel(ch->ch_sc, oldch);
SET(tp->t_state, TS_BUSY);
}
}
splx(s);
}
/*
* Stop output on a line.
*/
void
clmpccstop(tp, flag)
struct tty *tp;
int flag;
{
struct clmpcc_softc *sc = clmpcc_cd.cd_devs[CLMPCCUNIT(tp->t_dev)];
struct clmpcc_chan *ch = &sc->sc_chans[CLMPCCCHAN(tp->t_dev)];
int s;
s = splserial();
if ( ISSET(tp->t_state, TS_BUSY) ) {
if ( ISCLR(tp->t_state, TS_TTSTOP) )
SET(tp->t_state, TS_FLUSH);
ch->ch_obuf_size = 0;
}
splx(s);
}
/*
* RX interrupt routine
*/
int
clmpcc_rxintr(arg)
void *arg;
{
struct clmpcc_softc *sc = (struct clmpcc_softc *)arg;
struct clmpcc_chan *ch;
u_int8_t *put, *end, rxd;
u_char errstat;
u_char fc, tc;
u_char risr;
u_char rir;
#ifdef DDB
int saw_break = 0;
#endif
/* Receive interrupt active? */
rir = clmpcc_rdreg(sc, CLMPCC_REG_RIR);
/*
* If we're using auto-vectored interrupts, we have to
* verify if the chip is generating the interrupt.
*/
if ( sc->sc_vector_base == 0 && (rir & CLMPCC_RIR_RACT) == 0 )
return 0;
/* Get pointer to interrupting channel's data structure */
ch = &sc->sc_chans[rir & CLMPCC_RIR_RCN_MASK];
/* Get the interrupt status register */
risr = clmpcc_rdreg(sc, CLMPCC_REG_RISRl);
if ( risr & CLMPCC_RISR_TIMEOUT ) {
u_char reg;
/*
* Set the FIFO threshold to zero, and disable
* further receive timeout interrupts.
*/
reg = clmpcc_rdreg(sc, CLMPCC_REG_COR4);
clmpcc_wrreg(sc, CLMPCC_REG_COR4, reg & CLMPCC_COR4_FIFO_MASK);
reg = clmpcc_rdreg(sc, CLMPCC_REG_IER);
clmpcc_wrreg(sc, CLMPCC_REG_IER, reg & ~CLMPCC_IER_RET);
clmpcc_wrreg(sc, CLMPCC_REG_REOIR, CLMPCC_REOIR_NO_TRANS);
SET(ch->ch_flags, CLMPCC_FLG_FIFO_CLEAR);
return 1;
}
/* How many bytes are waiting in the FIFO? */
fc = tc = clmpcc_rdreg(sc, CLMPCC_REG_RFOC) & CLMPCC_RFOC_MASK;
#ifdef DDB
/*
* Allow BREAK on the console to drop to the debugger.
*/
if ( ISSET(ch->ch_flags, CLMPCC_FLG_IS_CONSOLE) &&
risr & CLMPCC_RISR_BREAK ) {
saw_break = 1;
}
#endif
if ( ISCLR(ch->ch_tty->t_state, TS_ISOPEN) && fc ) {
/* Just get rid of the data */
while ( fc-- )
(void) clmpcc_rd_rxdata(sc);
goto rx_done;
}
put = ch->ch_ibuf_wr;
end = ch->ch_ibuf_end;
/*
* Note: The chip is completely hosed WRT these error
* conditions; there seems to be no way to associate
* the error with the correct character in the FIFO.
* We compromise by tagging the first character we read
* with the error. Not perfect, but there's no other way.
*/
errstat = 0;
if ( risr & CLMPCC_RISR_PARITY )
errstat |= TTY_PE;
if ( risr & (CLMPCC_RISR_FRAMING | CLMPCC_RISR_BREAK) )
errstat |= TTY_FE;
/*
* As long as there are characters in the FIFO, and we
* have space for them...
*/
while ( fc > 0 ) {
*put++ = rxd = clmpcc_rd_rxdata(sc);
*put++ = errstat;
if ( put >= end )
put = ch->ch_ibuf;
if ( put == ch->ch_ibuf_rd ) {
put -= 2;
if ( put < ch->ch_ibuf )
put = end - 2;
}
errstat = 0;
fc--;
}
ch->ch_ibuf_wr = put;
#if 0
if ( sc->sc_swaprtsdtr == 0 &&
ISSET(cy->cy_tty->t_cflag, CRTSCTS) && cc < ch->ch_r_hiwat) {
/*
* If RTS/DTR are not physically swapped, we have to
* do hardware flow control manually
*/
clmpcc_wr_msvr(sc, CLMPCC_MSVR_RTS, 0);
}
#endif
rx_done:
if ( fc != tc ) {
if ( ISSET(ch->ch_flags, CLMPCC_FLG_FIFO_CLEAR) ) {
u_char reg;
/*
* Set the FIFO threshold to the preset value,
* and enable receive timeout interrupts.
*/
reg = clmpcc_rdreg(sc, CLMPCC_REG_COR4);
reg = (reg & ~CLMPCC_COR4_FIFO_MASK) | ch->ch_cor4;
clmpcc_wrreg(sc, CLMPCC_REG_COR4, reg);
reg = clmpcc_rdreg(sc, CLMPCC_REG_IER);
clmpcc_wrreg(sc, CLMPCC_REG_IER, reg | CLMPCC_IER_RET);
CLR(ch->ch_flags, CLMPCC_FLG_FIFO_CLEAR);
}
clmpcc_wrreg(sc, CLMPCC_REG_REOIR, 0);
if ( sc->sc_soft_running == 0 ) {
sc->sc_soft_running = 1;
(sc->sc_softhook)(sc);
}
} else
clmpcc_wrreg(sc, CLMPCC_REG_REOIR, CLMPCC_REOIR_NO_TRANS);
#ifdef DDB
/*
* Only =after= we write REOIR is it safe to drop to the debugger.
*/
if ( saw_break )
Debugger();
#endif
return 1;
}
/*
* Tx interrupt routine
*/
int
clmpcc_txintr(arg)
void *arg;
{
struct clmpcc_softc *sc = (struct clmpcc_softc *)arg;
struct clmpcc_chan *ch;
struct tty *tp;
u_char ftc, oftc;
u_char tir;
/* Tx interrupt active? */
tir = clmpcc_rdreg(sc, CLMPCC_REG_TIR);
/*
* If we're using auto-vectored interrupts, we have to
* verify if the chip is generating the interrupt.
*/
if ( sc->sc_vector_base == 0 && (tir & CLMPCC_TIR_TACT) == 0 )
return 0;
/* Get pointer to interrupting channel's data structure */
ch = &sc->sc_chans[tir & CLMPCC_TIR_TCN_MASK];
tp = ch->ch_tty;
/* Dummy read of the interrupt status register */
(void) clmpcc_rdreg(sc, CLMPCC_REG_TISR);
ftc = oftc = clmpcc_rdreg(sc, CLMPCC_REG_TFTC);
/* Handle a delayed parameter change */
if ( ISSET(ch->ch_flags, CLMPCC_FLG_UPDATE_PARMS) ) {
CLR(ch->ch_flags, CLMPCC_FLG_UPDATE_PARMS);
clmpcc_set_params(ch);
}
if ( ch->ch_obuf_size > 0 ) {
u_int n = min(ch->ch_obuf_size, ftc);
clmpcc_wrtx_multi(sc, ch->ch_obuf_addr, n);
ftc -= n;
ch->ch_obuf_size -= n;
ch->ch_obuf_addr += n;
} else {
/*
* No data to send -- check if we should
* start/stop a break
*/
if ( ISSET(ch->ch_flags, CLMPCC_FLG_START_BREAK) ) {
CLR(ch->ch_flags, CLMPCC_FLG_START_BREAK);
/* TBD */
}
if ( ISSET(ch->ch_flags, CLMPCC_FLG_END_BREAK) ) {
CLR(ch->ch_flags, CLMPCC_FLG_END_BREAK);
/* TBD */
}
/*
* Disable transmit interrupt
*/
clmpcc_wrreg(sc, CLMPCC_REG_IER,
clmpcc_rdreg(sc, CLMPCC_REG_IER) &
~CLMPCC_IER_TX_EMPTY);
/*
* Request Tx processing in the soft interrupt handler
*/
ch->ch_tx_done = 1;
if ( ! sc->sc_soft_running ) {
sc->sc_soft_running = 1;
(sc->sc_softhook)(sc);
}
}
if ( ftc != oftc )
clmpcc_wrreg(sc, CLMPCC_REG_TEOIR, 0);
else
clmpcc_wrreg(sc, CLMPCC_REG_TEOIR, CLMPCC_TEOIR_NO_TRANS);
return 1;
}
/*
* Modem change interrupt routine
*/
int
clmpcc_mdintr(arg)
void *arg;
{
struct clmpcc_softc *sc = (struct clmpcc_softc *)arg;
u_char mir;
/* Modem status interrupt active? */
mir = clmpcc_rdreg(sc, CLMPCC_REG_MIR);
/*
* If we're using auto-vectored interrupts, we have to
* verify if the chip is generating the interrupt.
*/
if ( sc->sc_vector_base == 0 && (mir & CLMPCC_MIR_MACT) == 0 )
return 0;
/* Dummy read of the interrupt status register */
(void) clmpcc_rdreg(sc, CLMPCC_REG_MISR);
/* Retrieve current status of modem lines. */
sc->sc_chans[mir & CLMPCC_MIR_MCN_MASK].ch_control |=
clmpcc_rd_msvr(sc) & CLMPCC_MSVR_CD;
clmpcc_wrreg(sc, CLMPCC_REG_MEOIR, 0);
if ( sc->sc_soft_running == 0 ) {
sc->sc_soft_running = 1;
(sc->sc_softhook)(sc);
}
return 1;
}
int
clmpcc_softintr(arg)
void *arg;
{
struct clmpcc_softc *sc = (struct clmpcc_softc *)arg;
struct clmpcc_chan *ch;
struct tty *tp;
int (*rint) __P((int, struct tty *));
u_char *get;
u_char reg;
u_int c;
int chan;
sc->sc_soft_running = 0;
/* Handle Modem state changes too... */
for (chan = 0; chan < CLMPCC_NUM_CHANS; chan++) {
ch = &sc->sc_chans[chan];
tp = ch->ch_tty;
get = ch->ch_ibuf_rd;
rint = linesw[tp->t_line].l_rint;
/* Squirt buffered incoming data into the tty layer */
while ( get != ch->ch_ibuf_wr ) {
c = get[0];
c |= ((u_int)get[1]) << 8;
if ( (rint)(c, tp) == -1 ) {
ch->ch_ibuf_rd = ch->ch_ibuf_wr;
break;
}
get += 2;
if ( get == ch->ch_ibuf_end )
get = ch->ch_ibuf;
ch->ch_ibuf_rd = get;
}
/*
* Is the transmitter idle and in need of attention?
*/
if ( ch->ch_tx_done ) {
ch->ch_tx_done = 0;
if ( ISSET(ch->ch_flags, CLMPCC_FLG_NEED_INIT) ) {
clmpcc_channel_cmd(sc, ch->ch_car,
CLMPCC_CCR_T0_INIT |
CLMPCC_CCR_T0_RX_EN |
CLMPCC_CCR_T0_TX_EN);
CLR(ch->ch_flags, CLMPCC_FLG_NEED_INIT);
/*
* Allow time for the channel to initialise.
* (Empirically derived duration; there must
* be another way to determine the command
* has completed without busy-waiting...)
*/
delay(800);
/*
* Update the tty layer's idea of the carrier
* bit, in case we changed CLOCAL or MDMBUF.
* We don't hang up here; we only do that by
* explicit request.
*/
reg = clmpcc_rd_msvr(sc) & CLMPCC_MSVR_CD;
(*linesw[tp->t_line].l_modem)(tp, reg != 0);
}
CLR(tp->t_state, TS_BUSY);
if ( ISSET(tp->t_state, TS_FLUSH) )
CLR(tp->t_state, TS_FLUSH);
else
ndflush(&tp->t_outq,
(int)(ch->ch_obuf_addr - tp->t_outq.c_cf));
(*linesw[tp->t_line].l_start)(tp);
}
}
return 0;
}
/*XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX*/
/*XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX*/
/*XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX*/
/*
* Following are all routines needed for a cd240x channel to act as console
*/
int
clmpcc_cnattach(sc, chan, rate)
struct clmpcc_softc *sc;
int chan;
int rate;
{
cons_sc = sc;
cons_chan = chan;
cons_rate = rate;
return 0;
}
/*
* The following functions are polled getc and putc routines, for console use.
*/
static int
clmpcc_common_getc(sc, chan)
struct clmpcc_softc *sc;
int chan;
{
u_char old_chan;
u_char old_ier;
u_char ch, rir, risr;
int s;
s = splhigh();
/* Save the currently active channel */
old_chan = clmpcc_select_channel(sc, chan);
/*
* We have to put the channel into RX interrupt mode before
* trying to read the Rx data register. So save the previous
* interrupt mode.
*/
old_ier = clmpcc_rdreg(sc, CLMPCC_REG_IER);
clmpcc_wrreg(sc, CLMPCC_REG_IER, CLMPCC_IER_RX_FIFO);
/* Loop until we get a character */
for (;;) {
/*
* The REN bit will be set in the Receive Interrupt Register
* when the CD240x has a character to process. Remember,
* the RACT bit won't be set until we generate an interrupt
* acknowledge cycle via the MD front-end.
*/
rir = clmpcc_rdreg(sc, CLMPCC_REG_RIR);
if ( (rir & CLMPCC_RIR_REN) == 0 )
continue;
/* Acknowledge the request */
if ( sc->sc_iackhook )
(sc->sc_iackhook)(sc, CLMPCC_IACK_RX);
/*
* Determine if the interrupt is for the required channel
* and if valid data is available.
*/
rir = clmpcc_rdreg(sc, CLMPCC_REG_RIR);
risr = clmpcc_rdreg(sc, CLMPCC_REG_RISR);
if ( (rir & CLMPCC_RIR_RCN_MASK) != chan ||
risr != 0 ) {
/* Rx error, or BREAK */
clmpcc_wrreg(sc, CLMPCC_REG_REOIR,
CLMPCC_REOIR_NO_TRANS);
} else {
/* Dummy read of the FIFO count register */
(void) clmpcc_rdreg(sc, CLMPCC_REG_RFOC);
/* Fetch the received character */
ch = clmpcc_rd_rxdata(sc);
clmpcc_wrreg(sc, CLMPCC_REG_REOIR, 0);
break;
}
}
/* Restore the original IER and CAR register contents */
clmpcc_wrreg(sc, CLMPCC_REG_IER, old_ier);
clmpcc_select_channel(sc, old_chan);
splx(s);
return ch;
}
static void
clmpcc_common_putc(sc, chan, c)
struct clmpcc_softc *sc;
int chan;
int c;
{
u_char old_chan;
int s = splhigh();
/* Save the currently active channel */
old_chan = clmpcc_select_channel(sc, chan);
/*
* We wait here until the Tx FIFO is empty, and
* the chip signifies that the Tx output is idle.
*/
while ((clmpcc_rdreg(sc,CLMPCC_REG_TISR) & CLMPCC_TISR_TX_EMPTY) ==0 &&
(clmpcc_rdreg(sc,CLMPCC_REG_TFTC) & CLMPCC_TFTC_MASK) != 0 )
; /* Do nothing */
/*
* Since we can only access the Tx Data register from within
* the interrupt handler, the easiest way to get console data
* onto the wire is using one of the Special Transmit Character
* registers.
*/
clmpcc_wrreg(sc, CLMPCC_REG_SCHR4, c);
clmpcc_wrreg(sc, CLMPCC_REG_STCR, CLMPCC_STCR_SSPC(4) |
CLMPCC_STCR_SND_SPC);
/* Wait until the "Send Special Character" command is accepted */
while ( clmpcc_rdreg(sc, CLMPCC_REG_STCR) != 0 )
;
/* Restore the previous channel selected */
clmpcc_select_channel(sc, old_chan);
splx(s);
}
int
clmpcccngetc(dev)
dev_t dev;
{
return clmpcc_common_getc(cons_sc, cons_chan);
}
/*
* Console kernel output character routine.
*/
void
clmpcccnputc(dev, c)
dev_t dev;
int c;
{
if ( c == '\n' )
clmpcc_common_putc(cons_sc, cons_chan, '\r');
clmpcc_common_putc(cons_sc, cons_chan, c);
}