/* $OpenBSD: cl.c,v 1.2 1998/12/15 05:52:29 smurph Exp $ */ /* * Copyright (c) 1995 Dale Rahn. All rights reserved. * * * 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 Dale Rahn. * 4. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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. */ /* DMA mode still does not work!!! */ #include #include #include #include #include #include #include #include #include #include /* #include */ #include #include #include #if defined(MVME187) #include #else #include #endif #include #include "cl.h" #include "pcctwo.h" #if NPCCTWO > 0 #if defined(MVME187) #include #else #include #endif #endif #if defined(MVME187) #include #define splcl() splx(IPL_TTY) #else #define splcl() spl3() #endif /* min timeout 0xa, what is a good value */ #define CL_TIMEOUT 0x10 #define CL_FIFO_MAX 0x10 #define CL_FIFO_CNT 0xc #define CL_RX_TIMEOUT 0x10 #define CL_RXDMAINT 0x82 #define CL_TXDMAINT 0x42 #define CL_TXMASK 0x47 #define CL_RXMASK 0x87 #define CL_TXINTR 0x02 #define CL_RXINTR 0x02 #ifdef DEBUG #undef DEBUG #endif #define DEBUG_KERN 1 struct cl_cons { void *cl_paddr; volatile struct clreg *cl_vaddr; volatile struct pcctworeg *pcctwoaddr; u_char channel; } cl_cons; struct cl_info { struct tty *tty; u_char cl_swflags; u_char cl_softchar; u_char cl_consio; u_char cl_speed; u_char cl_parstop; /* parity, stop bits. */ u_char cl_rxmode; u_char cl_txmode; u_char cl_clen; u_char cl_parity; u_char transmitting; u_long txcnt; u_long rxcnt; void *rx[2]; void *rxp[2]; void *tx[2]; void *txp[2]; }; #define CLCD_PORTS_PER_CHIP 4 #define CL_BUFSIZE 256 #ifndef DO_MALLOC /* four (4) buffers per port */ char cl_dmabuf [CLCD_PORTS_PER_CHIP * CL_BUFSIZE * 4]; #endif struct clsoftc { struct device sc_dev; struct evcnt sc_txintrcnt; struct evcnt sc_rxintrcnt; struct evcnt sc_mxintrcnt; time_t sc_rotime; /* time of last ring overrun */ time_t sc_fotime; /* time of last fifo overrun */ u_char *pbase; struct clreg *cl_reg; struct cl_info sc_cl[CLCD_PORTS_PER_CHIP]; struct intrhand sc_ih_e; struct intrhand sc_ih_m; struct intrhand sc_ih_t; struct intrhand sc_ih_r; struct pcctworeg *sc_pcctwo; int sc_flags; }; struct { u_int speed; u_char divisor; u_char clock; u_char rx_timeout; } cl_clocks[] = { { 64000, 0x26, 0, 0x01}, { 56000, 0x2c, 0, 0x01}, { 38400, 0x40, 0, 0x01}, { 19200, 0x81, 0, 0x02}, { 9600, 0x40, 1, 0x04}, { 7200, 0x56, 1, 0x04}, { 4800, 0x81, 1, 0x08}, { 3600, 0xad, 1, 0x08}, { 2400, 0x40, 2, 0x10}, { 1200, 0x81, 2, 0x20}, { 600, 0x40, 3, 0x40}, { 300, 0x81, 3, 0x80}, { 150, 0x40, 3, 0x80}, { 110, 0x58, 4, 0xff}, { 50, 0xC2, 4, 0xff}, { 0, 0x00, 0, 0}, }; /* prototypes */ int clcnprobe __P((struct consdev *cp)); int clcninit __P((struct consdev *cp)); int clcngetc __P((dev_t dev)); int clcnputc __P((dev_t dev, u_char c)); u_char cl_clkdiv __P((int speed)); u_char cl_clknum __P((int speed)); u_char cl_clkrxtimeout __P((int speed)); void clstart __P((struct tty *tp)); void cl_unblock __P((struct tty *tp)); int clccparam __P((struct clsoftc *sc, struct termios *par, int channel)); int clparam __P((struct tty *tp, struct termios *t)); int cl_mintr __P((struct clsoftc *sc)); int cl_txintr __P((struct clsoftc *sc)); int cl_rxintr __P((struct clsoftc *sc)); void cl_overflow __P((struct clsoftc *sc, int channel, long *ptime, u_char *msg)); void cl_parity __P((struct clsoftc *sc, int channel)); void cl_frame __P((struct clsoftc *sc, int channel)); void cl_break __P(( struct clsoftc *sc, int channel)); int clmctl __P((dev_t dev, int bits, int how)); void cl_dumpport __P((int channel)); int clprobe __P((struct device *parent, void *self, void *aux)); void clattach __P((struct device *parent, struct device *self, void *aux)); int clopen __P((dev_t dev, int flag, int mode, struct proc *p)); int clclose __P((dev_t dev, int flag, int mode, struct proc *p)); int clread __P((dev_t dev, struct uio *uio, int flag)); int clwrite __P((dev_t dev, struct uio *uio, int flag)); int clioctl __P((dev_t dev, int cmd, caddr_t data, int flag, struct proc *p)); int clstop __P((struct tty *tp, int flag)); static void cl_initchannel __P((struct clsoftc *sc, int channel)); static void clputc __P((struct clsoftc *sc, int unit, u_char c)); static u_char clgetc __P((struct clsoftc *sc, int *channel)); static void cloutput __P( (struct tty *tp)); struct cfattach cl_ca = { sizeof(struct clsoftc), clprobe, clattach }; struct cfdriver cl_cd = { NULL, "cl", DV_TTY, 0 }; #define CLCDBUF 80 int dopoll = 1; #define CL_UNIT(x) (minor(x) >> 2) #define CL_CHANNEL(x) (minor(x) & 3) #define CL_TTY(x) (minor(x)) extern int cputyp; struct tty * cltty(dev) dev_t dev; { int unit, channel; struct clsoftc *sc; unit = CL_UNIT(dev); if (unit >= cl_cd.cd_ndevs || (sc = (struct clsoftc *) cl_cd.cd_devs[unit]) == NULL) { return (NULL); } channel = CL_CHANNEL(dev); return sc->sc_cl[channel].tty; } int clprobe(parent, self, aux) struct device *parent; void *self; void *aux; { /* probing onboard 166/167/187 CL-cd2400 * should be previously configured, * we can check the value before resetting the chip */ struct clreg *cl_reg; struct confargs *ca = aux; int ret; if (cputyp != CPU_187) return 0; ca->ca_ipl = IPL_TTY; ca->ca_paddr = (void *)CD2400_BASE_ADDR; cl_reg = (struct clreg *)ca->ca_vaddr; #if 0 ret = !badvaddr(&cl_reg->cl_gfrcr,1); #else ret = 1; #endif return ret; } void clattach(parent, self, aux) struct device *parent; struct device *self; void *aux; { struct clsoftc *sc = (struct clsoftc *)self; struct confargs *ca = aux; int i; sc->cl_reg = (struct clreg *)ca->ca_vaddr; sc->sc_pcctwo = ca->ca_master; if ((u_char *)ca->ca_paddr == (u_char *)cl_cons.cl_paddr) { /* if this device is configured as console, * line cl_cons.channel is the console */ sc->sc_cl[cl_cons.channel].cl_consio = 1; printf(" console"); } else { /* reset chip only if we are not console device */ /* wait for GFRCR */ } /* allow chip to settle before continuing */ delay(100); /* set up global registers */ sc->cl_reg->cl_tpr = CL_TIMEOUT; sc->cl_reg->cl_rpilr = 0x03; sc->cl_reg->cl_tpilr = 0x02; sc->cl_reg->cl_mpilr = 0x01; #ifdef DO_MALLOC sc->sc_cl[0].rx[0] = (void *)(dvma_malloc(16 * CL_BUFSIZE)); #else sc->sc_cl[0].rx[0] = (void *) (&cl_dmabuf); #endif sc->sc_cl[0].rx[1] = (void *)(((int)sc->sc_cl[0].rx[0]) + CL_BUFSIZE); sc->sc_cl[1].rx[0] = (void *)(((int)sc->sc_cl[0].rx[1]) + CL_BUFSIZE); sc->sc_cl[1].rx[1] = (void *)(((int)sc->sc_cl[1].rx[0]) + CL_BUFSIZE); sc->sc_cl[2].rx[0] = (void *)(((int)sc->sc_cl[1].rx[1]) + CL_BUFSIZE); sc->sc_cl[2].rx[1] = (void *)(((int)sc->sc_cl[2].rx[0]) + CL_BUFSIZE); sc->sc_cl[3].rx[0] = (void *)(((int)sc->sc_cl[2].rx[1]) + CL_BUFSIZE); sc->sc_cl[3].rx[1] = (void *)(((int)sc->sc_cl[3].rx[0]) + CL_BUFSIZE); sc->sc_cl[0].tx[0] = (void *)(((int)sc->sc_cl[3].rx[1]) + CL_BUFSIZE); sc->sc_cl[0].tx[1] = (void *)(((int)sc->sc_cl[0].tx[0]) + CL_BUFSIZE); sc->sc_cl[1].tx[0] = (void *)(((int)sc->sc_cl[0].tx[1]) + CL_BUFSIZE); sc->sc_cl[1].tx[1] = (void *)(((int)sc->sc_cl[1].tx[0]) + CL_BUFSIZE); sc->sc_cl[2].tx[0] = (void *)(((int)sc->sc_cl[1].tx[1]) + CL_BUFSIZE); sc->sc_cl[2].tx[1] = (void *)(((int)sc->sc_cl[2].tx[0]) + CL_BUFSIZE); sc->sc_cl[3].tx[0] = (void *)(((int)sc->sc_cl[2].tx[1]) + CL_BUFSIZE); sc->sc_cl[3].tx[1] = (void *)(((int)sc->sc_cl[3].tx[0]) + CL_BUFSIZE); for (i = 0; i < CLCD_PORTS_PER_CHIP; i++) { int j; #if 0 for (j = 0; j < 2 ; j++) { sc->sc_cl[i].rxp[j] = (void *)kvtop(sc->sc_cl[i].rx[j]); printf("cl[%d].rxbuf[%d] %x p %x\n", i, j, sc->sc_cl[i].rx[j], sc->sc_cl[i].rxp[j]); sc->sc_cl[i].txp[j] = (void *)kvtop(sc->sc_cl[i].tx[j]); printf("cl[%d].txbuf[%d] %x p %x\n", i, j, sc->sc_cl[i].tx[j], sc->sc_cl[i].txp[j]); } #endif #if 0 sc->sc_cl[i].cl_rxmode = !(!((flags >> (i * CL_FLAG_BIT_PCH)) & 0x01)); sc->sc_cl[i].cl_txmode = !(!((flags >> (i * CL_FLAG_BIT_PCH)) & 0x02)); sc->sc_cl[i].cl_softchar = !(!((flags >> (i * CL_FLAG_BIT_PCH)) & 0x04)); #endif cl_initchannel(sc, i); } /* enable interrupts */ sc->sc_ih_e.ih_fn = cl_rxintr; sc->sc_ih_e.ih_arg = sc; sc->sc_ih_e.ih_ipl = ca->ca_ipl; sc->sc_ih_e.ih_wantframe = 0; sc->sc_ih_m.ih_fn = cl_mintr; sc->sc_ih_m.ih_arg = sc; sc->sc_ih_m.ih_ipl = ca->ca_ipl; sc->sc_ih_m.ih_wantframe = 0; sc->sc_ih_t.ih_fn = cl_txintr; sc->sc_ih_t.ih_arg = sc; sc->sc_ih_t.ih_ipl = ca->ca_ipl; sc->sc_ih_t.ih_wantframe = 0; sc->sc_ih_r.ih_fn = cl_rxintr; sc->sc_ih_r.ih_arg = sc; sc->sc_ih_r.ih_ipl = ca->ca_ipl; sc->sc_ih_r.ih_wantframe = 0; switch (ca->ca_bustype) { case BUS_PCCTWO: dopoll = 0; intr_establish(PCC2_VECT + SRXEIRQ, &sc->sc_ih_e); intr_establish(PCC2_VECT + SMOIRQ, &sc->sc_ih_m); intr_establish(PCC2_VECT + STxIRQ, &sc->sc_ih_t); intr_establish(PCC2_VECT + SRxIRQ, &sc->sc_ih_r); sc->sc_pcctwo = ca->ca_master; sc->sc_pcctwo->pcc2_sccerr = 0x01; /* clear errors */ /* enable all interrupts at ca_ipl */ sc->sc_pcctwo->pcc2_sccirq = 0x10 | (ca->ca_ipl & 0x7); sc->sc_pcctwo->pcc2_scctx = 0x10 | (ca->ca_ipl & 0x7); sc->sc_pcctwo->pcc2_sccrx = 0x10 | (ca->ca_ipl & 0x7); break; default: /* oops */ panic ("cl driver on unknown bus\n"); } evcnt_attach(&sc->sc_dev, "intr", &sc->sc_txintrcnt); evcnt_attach(&sc->sc_dev, "intr", &sc->sc_rxintrcnt); evcnt_attach(&sc->sc_dev, "intr", &sc->sc_mxintrcnt); printf("\n"); } static void cl_initchannel(sc, channel) struct clsoftc *sc; int channel; { int s; struct clreg *cl_reg = sc->cl_reg; /* set up option registers */ sc->sc_cl[channel].tty = NULL; s = splhigh(); cl_reg->cl_car = (u_char) channel; cl_reg->cl_livr = PCC2_VECT + 0xc;/* set vector base at 5C */ cl_reg->cl_ier = 0x00; /* if the port is not the console, should be init for all ports??*/ if (sc->sc_cl[channel].cl_consio != 1) { cl_reg->cl_cmr = 0x02; cl_reg->cl_cor1 = 0x17; cl_reg->cl_cor2 = 0x00; cl_reg->cl_cor3 = 0x02; cl_reg->cl_cor4 = 0xec; cl_reg->cl_cor5 = 0xec; cl_reg->cl_cor6 = 0x00; cl_reg->cl_cor7 = 0x00; cl_reg->cl_schr1 = 0x00; cl_reg->cl_schr2 = 0x00; cl_reg->cl_schr3 = 0x00; cl_reg->cl_schr4 = 0x00; cl_reg->cl_scrl = 0x00; cl_reg->cl_scrh = 0x00; cl_reg->cl_lnxt = 0x00; cl_reg->cl_rbpr = 0x40; /* 9600 */ cl_reg->cl_rcor = 0x01; cl_reg->cl_tbpr = 0x40; /* 9600 */ cl_reg->cl_tcor = 0x01 << 5; /* console port should be 0x88 already */ cl_reg->cl_msvr_rts = 0x00; cl_reg->cl_msvr_dtr = 0x00; cl_reg->cl_rtprl = CL_RX_TIMEOUT; cl_reg->cl_rtprh = 0x00; } sc->cl_reg->cl_ccr = 0x20; while (sc->cl_reg->cl_ccr != 0) { } splx(s); } int cldefaultrate = TTYDEF_SPEED; int clmctl (dev, bits, how) dev_t dev; int bits; int how; { int s; struct clsoftc *sc; /* should only be called with valid device */ sc = (struct clsoftc *) cl_cd.cd_devs[CL_UNIT(dev)]; /* printf("mctl: dev %x, bits %x, how %x,\n",dev, bits, how); */ /* settings are currently ignored */ s = splcl(); switch (how) { case DMSET: if( bits & TIOCM_RTS) { sc->cl_reg->cl_msvr_rts = 0x01; } else { sc->cl_reg->cl_msvr_rts = 0x00; } if( bits & TIOCM_DTR) { sc->cl_reg->cl_msvr_dtr = 0x02; } else { sc->cl_reg->cl_msvr_dtr = 0x00; } break; case DMBIC: if( bits & TIOCM_RTS) { sc->cl_reg->cl_msvr_rts = 0x00; } if( bits & TIOCM_DTR) { sc->cl_reg->cl_msvr_dtr = 0x00; } break; case DMBIS: if( bits & TIOCM_RTS) { sc->cl_reg->cl_msvr_rts = 0x01; } if( bits & TIOCM_DTR) { sc->cl_reg->cl_msvr_dtr = 0x02; } break; case DMGET: bits = 0; { u_char msvr; msvr = sc->cl_reg->cl_msvr_rts; if( msvr & 0x80) { bits |= TIOCM_DSR; } if( msvr & 0x40) { bits |= TIOCM_CD; } if( msvr & 0x20) { bits |= TIOCM_CTS; } if( msvr & 0x10) { bits |= TIOCM_DTR; } if( msvr & 0x02) { bits |= TIOCM_DTR; } if( msvr & 0x01) { bits |= TIOCM_RTS; } } break; } (void)splx(s); #if 0 bits = 0; /* proper defaults? */ bits |= TIOCM_DTR; bits |= TIOCM_RTS; bits |= TIOCM_CTS; bits |= TIOCM_CD; /* bits |= TIOCM_RI; */ bits |= TIOCM_DSR; #endif /* printf("retbits %x\n", bits); */ return(bits); } int clopen (dev, flag, mode, p) dev_t dev; int flag; int mode; struct proc *p; { int s, unit, channel; struct cl_info *cl; struct clsoftc *sc; struct tty *tp; unit = CL_UNIT(dev); if (unit >= cl_cd.cd_ndevs || (sc = (struct clsoftc *) cl_cd.cd_devs[unit]) == NULL) { return (ENODEV); } channel = CL_CHANNEL(dev); cl = &sc->sc_cl[channel]; s = splcl(); if (cl->tty) { tp = cl->tty; } else { tp = cl->tty = ttymalloc(); /* tty_attach(tp);*/ } tp->t_oproc = clstart; tp->t_param = clparam; tp->t_dev = dev; if ((tp->t_state & TS_ISOPEN) == 0) { tp->t_state |= TS_WOPEN; ttychars(tp); if (tp->t_ispeed == 0) { /* * only when cleared do we reset to defaults. */ tp->t_iflag = TTYDEF_IFLAG; tp->t_oflag = TTYDEF_OFLAG; tp->t_lflag = TTYDEF_LFLAG; tp->t_ispeed = tp->t_ospeed = cldefaultrate; if(sc->sc_cl[channel].cl_consio == 1) { /* console is 8N1 */ tp->t_cflag = (CREAD | CS8 | HUPCL); } else { tp->t_cflag = TTYDEF_CFLAG; } } /* * do these all the time */ if (cl->cl_swflags & TIOCFLAG_CLOCAL) tp->t_cflag |= CLOCAL; if (cl->cl_swflags & TIOCFLAG_CRTSCTS) tp->t_cflag |= CRTSCTS; if (cl->cl_swflags & TIOCFLAG_MDMBUF) tp->t_cflag |= MDMBUF; clparam(tp, &tp->t_termios); ttsetwater(tp); (void)clmctl(dev, TIOCM_DTR | TIOCM_RTS, DMSET); #ifdef XXX if ((cl->cl_swflags & TIOCFLAG_SOFTCAR) || (clmctl(dev, 0, DMGET) & TIOCM_CD)) { tp->t_state |= TS_CARR_ON; } else { tp->t_state &= ~TS_CARR_ON; } #endif tp->t_state |= TS_CARR_ON; { u_char save = sc->cl_reg->cl_car; sc->cl_reg->cl_car = channel; sc->cl_reg->cl_ier = 0x88; #ifdef CL_DMA_WORKS { sc->cl_reg->cl_cmr = /* CL_TXDMAINT | */ CL_RXDMAINT; sc->cl_reg->cl_ier = 0xa8; sc->cl_reg->cl_licr = 0x00; } sc->cl_reg->cl_arbadrl = ((u_long)sc->sc_cl[channel].rxp[0]) & 0xffff; sc->cl_reg->cl_arbadru = ((u_long)sc->sc_cl[channel].rxp[0]) >> 16; sc->cl_reg->cl_brbadrl = ((u_long)sc->sc_cl[channel].rxp[1]) & 0xffff; sc->cl_reg->cl_brbadru = ((u_long)sc->sc_cl[channel].rxp[1]) >> 16; sc->cl_reg->cl_atbadrl = ((u_long)sc->sc_cl[channel].txp[0]) & 0xffff; sc->cl_reg->cl_atbadru = ((u_long)sc->sc_cl[channel].txp[0]) >> 16; sc->cl_reg->cl_btbadrl = ((u_long)sc->sc_cl[channel].txp[1]) & 0xffff; sc->cl_reg->cl_btbadru = ((u_long)sc->sc_cl[channel].txp[1]) >> 16; sc->cl_reg->cl_arbcnt = CL_BUFSIZE; sc->cl_reg->cl_brbcnt = CL_BUFSIZE; sc->cl_reg->cl_arbsts = 0x01; sc->cl_reg->cl_brbsts = 0x01; if (channel == 2) { /* test one channel now */ /* shift for tx DMA */ /* no shift for rx DMA */ #if 0 /* tx only */ sc->cl_reg->cl_licr = (CL_DMAMODE << 4); sc->cl_reg->cl_cmr = 0x42; #endif /* rx only */ sc->cl_reg->cl_licr = 0x00; sc->cl_reg->cl_cmr = 0x82; } sc->cl_reg->cl_ccr = 0x20; while (sc->cl_reg->cl_ccr != 0) { } #endif /* CL_DMA_WORKS */ sc->cl_reg->cl_car = save; } } else if (tp->t_state & TS_XCLUDE && p->p_ucred->cr_uid != 0) { splx(s); return(EBUSY); } #ifdef XXX /* * if NONBLOCK requested, ignore carrier */ if (flag & O_NONBLOCK) goto done; #endif splx(s); /* * Reset the tty pointer, as there could have been a dialout * use of the tty with a dialin open waiting. */ tp->t_dev = dev; #ifdef DEBUG cl_dumpport(channel); #endif return((*linesw[tp->t_line].l_open)(dev, tp)); } int clparam(tp, t) struct tty *tp; struct termios *t; { int unit, channel; struct clsoftc *sc; int s; dev_t dev; dev = tp->t_dev; unit = CL_UNIT(dev); if (unit >= cl_cd.cd_ndevs || (sc = (struct clsoftc *) cl_cd.cd_devs[unit]) == NULL) { return (ENODEV); } channel = CL_CHANNEL(dev); tp->t_ispeed = t->c_ispeed; tp->t_ospeed = t->c_ospeed; tp->t_cflag = t->c_cflag; clccparam(sc, t, channel); s = splcl(); cl_unblock(tp); splx(s); return 0; } void cloutput(tp) struct tty *tp; { int cc, s, unit, cnt; u_char *tptr; int channel; struct clsoftc *sc; dev_t dev; u_char cl_obuffer[CLCDBUF+1]; dev = tp->t_dev; unit = CL_UNIT(dev); if (unit >= cl_cd.cd_ndevs || (sc = (struct clsoftc *) cl_cd.cd_devs[unit]) == NULL) { return; } channel = CL_CHANNEL(dev); if ((tp->t_state & TS_ISOPEN) == 0) return; s = splcl(); cc = tp->t_outq.c_cc; while (cc > 0) { /*XXX*/ cnt = min (CLCDBUF,cc); cnt = q_to_b(&tp->t_outq, cl_obuffer, cnt); if (cnt == 0) { break; } for (tptr = cl_obuffer; tptr < &cl_obuffer[cnt]; tptr++) { clputc(sc, channel, *tptr); } cc -= cnt; } splx(s); } int clclose (dev, flag, mode, p) dev_t dev; int flag; int mode; struct proc *p; { int unit, channel; struct tty *tp; struct cl_info *cl; struct clsoftc *sc; int s; unit = CL_UNIT(dev); if (unit >= cl_cd.cd_ndevs || (sc = (struct clsoftc *) cl_cd.cd_devs[unit]) == NULL) { return (ENODEV); } channel = CL_CHANNEL(dev); cl = &sc->sc_cl[channel]; tp = cl->tty; (*linesw[tp->t_line].l_close)(tp, flag); s = splcl(); sc->cl_reg->cl_car = channel; if(cl->cl_consio == 0 && (tp->t_cflag & HUPCL) != 0) { sc->cl_reg->cl_msvr_rts = 0x00; sc->cl_reg->cl_msvr_dtr = 0x00; sc->cl_reg->cl_ccr = 0x05; } splx(s); ttyclose(tp); #if 0 cl->tty = NULL; #endif #ifdef DEBUG cl_dumpport(channel); #endif return 0; } int clread (dev, uio, flag) dev_t dev; struct uio *uio; int flag; { int unit, channel; struct tty *tp; struct cl_info *cl; struct clsoftc *sc; unit = CL_UNIT(dev); if (unit >= cl_cd.cd_ndevs || (sc = (struct clsoftc *) cl_cd.cd_devs[unit]) == NULL) { return (ENODEV); } channel = CL_CHANNEL(dev); cl = &sc->sc_cl[channel]; tp = cl->tty; if (!tp) return ENXIO; return((*linesw[tp->t_line].l_read)(tp, uio, flag)); } int clwrite (dev, uio, flag) dev_t dev; struct uio *uio; int flag; { int unit, channel; struct tty *tp; struct cl_info *cl; struct clsoftc *sc; unit = CL_UNIT(dev); if (unit >= cl_cd.cd_ndevs || (sc = (struct clsoftc *) cl_cd.cd_devs[unit]) == NULL) { return (ENODEV); } channel = CL_CHANNEL(dev); cl = &sc->sc_cl[channel]; tp = cl->tty; if (!tp) return ENXIO; return((*linesw[tp->t_line].l_write)(tp, uio, flag)); } int clioctl (dev, cmd, data, flag, p) dev_t dev; int cmd; caddr_t data; int flag; struct proc *p; { int error; int unit, channel; struct tty *tp; struct cl_info *cl; struct clsoftc *sc; unit = CL_UNIT(dev); if (unit >= cl_cd.cd_ndevs || (sc = (struct clsoftc *) cl_cd.cd_devs[unit]) == NULL) { return (ENODEV); } channel = CL_CHANNEL(dev); cl = &sc->sc_cl[channel]; tp = cl->tty; if (!tp) return ENXIO; 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); switch (cmd) { case TIOCSBRK: /* */ break; case TIOCCBRK: /* */ break; case TIOCSDTR: (void) clmctl(dev, TIOCM_DTR | TIOCM_RTS, DMBIS); break; case TIOCCDTR: (void) clmctl(dev, TIOCM_DTR | TIOCM_RTS, DMBIC); break; case TIOCMSET: (void) clmctl(dev, *(int *) data, DMSET); break; case TIOCMBIS: (void) clmctl(dev, *(int *) data, DMBIS); break; case TIOCMBIC: (void) clmctl(dev, *(int *) data, DMBIC); break; case TIOCMGET: *(int *)data = clmctl(dev, 0, DMGET); break; case TIOCGFLAGS: *(int *)data = cl->cl_swflags; break; case TIOCSFLAGS: error = suser(p->p_ucred, &p->p_acflag); if (error != 0) return(EPERM); cl->cl_swflags = *(int *)data; cl->cl_swflags &= /* only allow valid flags */ (TIOCFLAG_SOFTCAR | TIOCFLAG_CLOCAL | TIOCFLAG_CRTSCTS); break; default: return(ENOTTY); } return 0; } int clstop(tp, flag) struct tty *tp; int flag; { int s; s = splcl(); if (tp->t_state & TS_BUSY) { if ((tp->t_state & TS_TTSTOP) == 0) tp->t_state |= TS_FLUSH; } splx(s); return 0; } /* * clcn* stuff happens before configure() runs kicking off * autoconfig. Use a virtual mapping set up in locore till * the device is actually configured. Need mappings for * pcc2 space and Cirrus chip area. */ int clcnprobe(cp) struct consdev *cp; { /* always there ? */ /* serial major */ int maj; /* locate the major number */ for (maj = 0; maj < nchrdev; maj++) if (cdevsw[maj].d_open == clopen) break; cp->cn_dev = makedev (maj, 0); cp->cn_pri = CN_NORMAL; return 1; } int clcninit(cp) struct consdev *cp; { volatile struct clreg *cl_reg; cl_cons.cl_paddr = (void *)0xfff45000; cl_cons.cl_vaddr = (struct clreg *)IIOV(cl_cons.cl_paddr); cl_cons.pcctwoaddr = (void *)IIOV(0xfff42000); cl_reg = cl_cons.cl_vaddr; /* reset the chip? */ #ifdef CLCD_DO_RESET #endif /* set up globals */ #ifdef NOT_ALREADY_SETUP cl_reg->cl_tftc = 0x10; cl_reg->cl_tpr = CL_TIMEOUT; /* is this correct?? */ cl_reg->cl_rpilr = 0x03; cl_reg->cl_tpilr = 0x02; cl_reg->cl_mpilr = 0x01; /* set up the tty00 to be 9600 8N1 */ cl_reg->cl_car = 0x00; cl_reg->cl_cor1 = 0x17; /* No parity, ignore parity, 8 bit char */ cl_reg->cl_cor2 = 0x00; cl_reg->cl_cor3 = 0x02; /* 1 stop bit */ cl_reg->cl_cor4 = 0x00; cl_reg->cl_cor5 = 0x00; cl_reg->cl_cor6 = 0x00; cl_reg->cl_cor7 = 0x00; cl_reg->cl_schr1 = 0x00; cl_reg->cl_schr2 = 0x00; cl_reg->cl_schr3 = 0x00; cl_reg->cl_schr4 = 0x00; cl_reg->cl_scrl = 0x00; cl_reg->cl_scrh = 0x00; cl_reg->cl_lnxt = 0x00; cl_reg->cl_cpsr = 0x00; #endif return 0; } int cl_instat(sc) struct clsoftc *sc; { volatile struct clreg *cl_reg; if ( NULL == sc) { cl_reg = cl_cons.cl_vaddr; } else { cl_reg = sc->cl_reg; } return (cl_reg->cl_rir & 0x40); } int clcngetc(dev) dev_t dev; { u_char val, reoir, licr, isrl, data, status, fifo_cnt; int got_char = 0; u_char ier_old = 0xff; volatile struct clreg *cl_reg = cl_cons.cl_vaddr; volatile struct pcctworeg *pcc2_base = cl_cons.pcctwoaddr; cl_reg->cl_car = 0; if (!(cl_reg->cl_ier & 0x08)) { ier_old = cl_reg->cl_ier; cl_reg->cl_ier = 0x08; } while (got_char == 0) { val = cl_reg->cl_rir; /* if no receive interrupt pending wait */ if (!(val & 0x80)) { continue; } /* XXX do we need to suck the entire FIFO contents? */ reoir = pcc2_base->pcc2_sccrxiack; /* receive PIACK */ licr = cl_reg->cl_licr; if (((licr >> 2) & 0x3) == 0) { /* is the interrupt for us (port 0) */ /* the character is for us yea. */ isrl = cl_reg->cl_risrl; #if 0 if (isrl & 0x01) { status = BREAK; } if (isrl & 0x02) { status = FRAME; } if (isrl & 0x04) { status = PARITY; } if (isrl & 0x08) { status = OVERFLOW; } /* we do not have special characters ;-) */ #endif fifo_cnt = cl_reg->cl_rfoc; data = cl_reg->cl_rdr; if (ier_old != 0xff) { cl_reg->cl_ier = ier_old; } got_char = 1; cl_reg->cl_teoir = 0x00; } else { data = cl_reg->cl_rdr; cl_reg->cl_teoir = 0x00; } } return data; } int clcnputc(dev, c) dev_t dev; u_char c; { /* is this the correct location for the cr -> cr/lf tranlation? */ if (c == '\n') clputc(0, 0, '\r'); clputc(0, 0, c); return 0; } clcnpollc(dev, on) dev_t dev; int on; { if (1 == on) { /* enable polling */ } else { /* disable polling */ } return; } static void clputc(sc, unit, c) struct clsoftc *sc; int unit; u_char c; { int s; u_char schar; u_char oldchannel; volatile struct clreg *cl_reg; if (0 == sc) { /* output on console */ cl_reg = cl_cons.cl_vaddr; } else { cl_reg = sc->cl_reg; } #ifdef NEW_CLCD_STRUCT /* should we disable, flush and all that goo? */ cl->car = unit; schar = cl->schr3; cl->schr3 = c; cl->stcr = 0x08 | 0x03; /* send special char, char 3 */ while (0 != cl->stcr) { /* wait until cl notices the command * otherwise it may not notice the character * if we send characters too fast. */ } cl->schr3 = schar; #else if (unit == 0) { s = splhigh(); oldchannel = cl_reg->cl_car; cl_reg->cl_car = unit; schar = cl_reg->cl_schr3; cl_reg->cl_schr3 = c; cl_reg->cl_stcr = 0x08 | 0x03; /* send special char, char 3 */ while (0 != cl_reg->cl_stcr) { /* wait until cl notices the command * otherwise it may not notice the character * if we send characters too fast. */ } DELAY(5); cl_reg->cl_schr3 = schar; cl_reg->cl_car = oldchannel; splx(s); } else { s = splhigh(); oldchannel = cl_reg->cl_car; cl_reg->cl_car = unit; if (cl_reg->cl_tftc > 0) { cl_reg->cl_tdr = c; } cl_reg->cl_car = oldchannel; splx(s); } #endif return; } /* #ifdef CLCD_DO_POLLED_INPUT */ #if 1 void cl_chkinput() { struct tty *tp; int unit; struct clsoftc *sc; int channel; if (dopoll == 0) return; for (unit = 0; unit < cl_cd.cd_ndevs; unit++) { if (unit >= cl_cd.cd_ndevs || (sc = (struct clsoftc *) cl_cd.cd_devs[unit]) == NULL) { continue; } if (cl_instat(sc)) { while (cl_instat(sc)){ int ch; u_char c; /* *(pinchar++) = clcngetc(); */ ch = clgetc(sc,&channel) & 0xff; c = ch; tp = sc->sc_cl[channel].tty; if (NULL != tp) { (*linesw[tp->t_line].l_rint)(c,tp); } } /* wakeup(tp); */ } } } #endif static u_char clgetc(sc, channel) struct clsoftc *sc; int *channel; { volatile struct clreg *cl_reg; volatile struct pcctworeg *pcc2_base; u_char val, reoir, licr, isrl, fifo_cnt, data; if (0 == sc) { cl_reg = cl_cons.cl_vaddr; pcc2_base = cl_cons.pcctwoaddr; } else { cl_reg = sc->cl_reg; pcc2_base = sc->sc_pcctwo; } val = cl_reg->cl_rir; /* if no receive interrupt pending wait */ if (!(val & 0x80)) { return 0; } /* XXX do we need to suck the entire FIFO contents? */ reoir = pcc2_base->pcc2_sccrxiack; /* receive PIACK */ licr = cl_reg->cl_licr; *channel = (licr >> 2) & 0x3; /* is the interrupt for us (port 0) */ /* the character is for us yea. */ isrl = cl_reg->cl_risrl; #if 0 if (isrl & 0x01) { status = BREAK; } if (isrl & 0x02) { status = FRAME; } if (isrl & 0x04) { status = PARITY; } if (isrl & 0x08) { status = OVERFLOW; } /* we do not have special characters ;-) */ #endif fifo_cnt = cl_reg->cl_rfoc; if (fifo_cnt > 0) { data = cl_reg->cl_rdr; cl_reg->cl_teoir = 0x00; } else { data = 0; cl_reg->cl_teoir = 0x08; } return data; } int clccparam(sc, par, channel) struct clsoftc *sc; struct termios *par; int channel; { u_int divisor, clk, clen; int s, imask, ints; s = splcl(); sc->cl_reg->cl_car = channel; if (par->c_ospeed == 0) { /* dont kill the console */ if(sc->sc_cl[channel].cl_consio == 0) { /* disconnect, drop RTS DTR stop reciever */ sc->cl_reg->cl_msvr_rts = 0x00; sc->cl_reg->cl_msvr_dtr = 0x00; sc->cl_reg->cl_ccr = 0x05; } splx(s); return (0xff); } sc->cl_reg->cl_msvr_rts = 0x03; sc->cl_reg->cl_msvr_dtr = 0x03; divisor = cl_clkdiv(par->c_ospeed); clk = cl_clknum(par->c_ospeed); sc->cl_reg->cl_tbpr = divisor; sc->cl_reg->cl_tcor = clk << 5; divisor = cl_clkdiv(par->c_ispeed); clk = cl_clknum(par->c_ispeed); sc->cl_reg->cl_rbpr = divisor; sc->cl_reg->cl_rcor = clk; sc->cl_reg->cl_rtprl = cl_clkrxtimeout(par->c_ispeed); sc->cl_reg->cl_rtprh = 0x00; switch (par->c_cflag & CSIZE) { case CS5: clen = 4; /* this is the mask for the chip. */ imask = 0x1F; break; case CS6: clen = 5; imask = 0x3F; break; case CS7: clen = 6; imask = 0x7F; break; default: clen = 7; imask = 0xFF; } sc->cl_reg->cl_cor3 = par->c_cflag & PARENB ? 4 : 2; { u_char cor1; if (par->c_cflag & PARENB) { if (par->c_cflag & PARODD) { cor1 = 0xE0 | clen ; /* odd */ } else { cor1 = 0x40 | clen ; /* even */ } } else { cor1 = 0x10 | clen; /* ignore parity */ } if (sc->cl_reg->cl_cor1 != cor1) { sc->cl_reg->cl_cor1 = cor1; sc->cl_reg->cl_ccr = 0x20; while (sc->cl_reg->cl_ccr != 0) { } } } if (sc->sc_cl[channel].cl_consio == 0 && (par->c_cflag & CREAD) == 0 ) { sc->cl_reg->cl_ccr = 0x08; } else { sc->cl_reg->cl_ccr = 0x0a; } while (sc->cl_reg->cl_ccr != 0) { } ints = 0; #define SCC_DSR 0x80 #define SCC_DCD 0x40 #define SCC_CTS 0x20 if ((par->c_cflag & CLOCAL) == 0) { ints |= SCC_DCD; } if ((par->c_cflag & CCTS_OFLOW) != 0) { ints |= SCC_CTS; } if ((par->c_cflag & CRTSCTS) != 0) { ints |= SCC_CTS; } #ifdef DONT_LET_HARDWARE if ((par->c_cflag & CCTS_IFLOW) != 0) { ints |= SCC_DSR; } #endif sc->cl_reg->cl_cor4 = ints | CL_FIFO_CNT; sc->cl_reg->cl_cor5 = ints | CL_FIFO_CNT; return imask; } static int clknum = 0; u_char cl_clkdiv(speed) int speed; { int i = 0; if (cl_clocks[clknum].speed == speed) { return cl_clocks[clknum].divisor; } for (i = 0; cl_clocks[i].speed != 0; i++) { if (cl_clocks[i].speed == speed) { clknum = i; return cl_clocks[clknum].divisor; } } /* return some sane value if unknown speed */ return cl_clocks[4].divisor; } u_char cl_clknum(speed) int speed; { int found = 0; int i = 0; if (cl_clocks[clknum].speed == speed) { return cl_clocks[clknum].clock; } for (i = 0; found != 0 && cl_clocks[i].speed != 0; i++) { if (cl_clocks[clknum].speed == speed) { clknum = i; return cl_clocks[clknum].clock; } } /* return some sane value if unknown speed */ return cl_clocks[4].clock; } u_char cl_clkrxtimeout(speed) int speed; { int i = 0; if (cl_clocks[clknum].speed == speed) { return cl_clocks[clknum].rx_timeout; } for (i = 0; cl_clocks[i].speed != 0; i++) { if (cl_clocks[i].speed == speed) { clknum = i; return cl_clocks[clknum].rx_timeout; } } /* return some sane value if unknown speed */ return cl_clocks[4].rx_timeout; } void cl_unblock(tp) struct tty *tp; { tp->t_state &= ~TS_FLUSH; if (tp->t_outq.c_cc != 0) clstart(tp); } void clstart(tp) struct tty *tp; { dev_t dev; u_char cbuf; struct clsoftc *sc; int channel, unit, s, cnt; dev = tp->t_dev; channel = CL_CHANNEL(dev); /* hack to test output on non console only */ #if 0 if (channel == 0) { cloutput(tp); return; } #endif unit = CL_UNIT(dev); if (unit >= cl_cd.cd_ndevs || (sc = (struct clsoftc *) cl_cd.cd_devs[unit]) == NULL) { return; } if ((tp->t_state & TS_ISOPEN) == 0) return; s = splcl(); #if 0 if (sc->sc_cl[channel].transmitting == 1) { /* i'm busy, go away, I will get to it later. */ splx(s); return; } cnt = q_to_b(&tp->t_outq, &cbuf, 1); if ( cnt != 0 ) { sc->sc_cl[channel].transmitting = 1; sc->cl_reg->cl_car = channel; sc->cl_reg->cl_tdr = cbuf; } else { sc->sc_cl[channel].transmitting = 0; } #else if ((tp->t_state & (TS_TIMEOUT | TS_BUSY | TS_TTSTOP | TS_FLUSH)) == 0) { tp->t_state |= TS_BUSY; sc->cl_reg->cl_car = channel; sc->cl_reg->cl_ier = sc->cl_reg->cl_ier | 0x3; } #endif splx(s); return; } int cl_mintr(sc) struct clsoftc *sc; { u_char mir, misr, msvr; int channel; struct tty *tp; if(((mir = sc->cl_reg->cl_mir) & 0x40) == 0x0) { /* only if intr is not shared? */ log(LOG_WARNING, "cl_mintr extra intr\n"); return 0; } sc->sc_mxintrcnt.ev_count++; channel = mir & 0x03; misr = sc->cl_reg->cl_misr; msvr = sc->cl_reg->cl_msvr_rts; if (misr & 0x01) { /* timers are not currently used?? */ log(LOG_WARNING, "cl_mintr: channel %x timer 1 unexpected\n",channel); } if (misr & 0x02) { /* timers are not currently used?? */ log(LOG_WARNING, "cl_mintr: channel %x timer 2 unexpected\n",channel); } if (misr & 0x20) { log(LOG_WARNING, "cl_mintr: channel %x cts %x\n",channel, ((msvr & 0x20) != 0x0) ); } if (misr & 0x40) { struct tty *tp = sc->sc_cl[channel].tty; log(LOG_WARNING, "cl_mintr: channel %x cd %x\n",channel, ((msvr & 0x40) != 0x0) ); ttymodem(tp, ((msvr & 0x40) != 0x0) ); } if (misr & 0x80) { log(LOG_WARNING, "cl_mintr: channel %x dsr %x\n",channel, ((msvr & 0x80) != 0x0) ); } sc->cl_reg->cl_meoir = 0x00; return 1; } int cl_txintr(sc) struct clsoftc *sc; { static empty = 0; u_char tir, cmr, teoir; u_char max; int channel; struct tty *tp; int cnt; u_char buffer[CL_FIFO_MAX +1]; u_char *tptr; if(((tir = sc->cl_reg->cl_tir) & 0x40) == 0x0) { /* only if intr is not shared ??? */ log(LOG_WARNING, "cl_txintr extra intr\n"); return 0; } sc->sc_txintrcnt.ev_count++; channel = tir & 0x03; cmr = sc->cl_reg->cl_cmr; sc->sc_cl[channel].txcnt ++; tp = sc->sc_cl[channel].tty; if (tp == NULL || (tp->t_state & TS_ISOPEN) == 0) { sc->cl_reg->cl_ier = sc->cl_reg->cl_ier & ~0x3; sc->cl_reg->cl_teoir = 0x08; return 1; } switch (cmr & CL_TXMASK) { case CL_TXDMAINT: { u_char dmabsts; int nbuf, busy, resid; void *pbuffer; dmabsts = sc->cl_reg->cl_dmabsts; log(LOG_WARNING, "cl_txintr: DMAMODE channel %x dmabsts %x\n", channel, dmabsts); nbuf = ((dmabsts & 0x8) >> 3) & 0x1; busy = ((dmabsts & 0x4) >> 2) & 0x1; do { pbuffer = sc->sc_cl[channel].tx[nbuf]; resid = tp->t_outq.c_cc; cnt = min (CL_BUFSIZE,resid); log(LOG_WARNING, "cl_txintr: resid %x cnt %x pbuf %x\n", resid, cnt, pbuffer); if (cnt != 0) { cnt = q_to_b(&tp->t_outq, pbuffer, cnt); resid -= cnt; if (nbuf == 0) { sc->cl_reg->cl_atbadru = ((u_long) sc->sc_cl[channel].txp[nbuf]) >> 16; sc->cl_reg->cl_atbadrl = ((u_long) sc->sc_cl[channel].txp[nbuf]) & 0xffff; sc->cl_reg->cl_atbcnt = cnt; sc->cl_reg->cl_atbsts = 0x43; } else { sc->cl_reg->cl_btbadru = ((u_long) sc->sc_cl[channel].txp[nbuf]) >> 16; sc->cl_reg->cl_btbadrl = ((u_long) sc->sc_cl[channel].txp[nbuf]) & 0xffff; sc->cl_reg->cl_btbcnt = cnt; sc->cl_reg->cl_btbsts = 0x43; } teoir = 0x08; } else { teoir = 0x08; if (tp->t_state & TS_BUSY) { tp->t_state &= ~(TS_BUSY | TS_FLUSH); if (tp->t_state & TS_ASLEEP) { tp->t_state &= ~TS_ASLEEP; wakeup((caddr_t) &tp->t_outq); } selwakeup(&tp->t_wsel); } sc->cl_reg->cl_ier = sc->cl_reg->cl_ier & ~0x3; } nbuf = ~nbuf & 0x1; busy--; } while (resid != 0 && busy != -1);/* if not busy do other buffer */ log(LOG_WARNING, "cl_txintr: done\n"); } break; case CL_TXINTR: max = sc->cl_reg->cl_tftc; cnt = min ((int)max,tp->t_outq.c_cc); if (cnt != 0) { cnt = q_to_b(&tp->t_outq, buffer, cnt); empty = 0; for (tptr = buffer; tptr < &buffer[cnt]; tptr++) { sc->cl_reg->cl_tdr = *tptr; } teoir = 0x00; } else { if (empty > 5 && ((empty % 20000 )== 0)) { log(LOG_WARNING, "cl_txintr to many empty intr %d channel %d\n", empty, channel); } empty++; teoir = 0x08; if (tp->t_state & TS_BUSY) { tp->t_state &= ~(TS_BUSY | TS_FLUSH); if (tp->t_state & TS_ASLEEP) { tp->t_state &= ~TS_ASLEEP; wakeup((caddr_t) &tp->t_outq); } selwakeup(&tp->t_wsel); } sc->cl_reg->cl_ier = sc->cl_reg->cl_ier & ~0x3; } break; default: log(LOG_WARNING, "cl_txintr unknown mode %x\n", cmr); /* we probably will go to hell quickly now */ teoir = 0x08; } sc->cl_reg->cl_teoir = teoir; return 1; } int cl_rxintr(sc) struct clsoftc *sc; { u_char rir, channel, cmr, risrl; u_char c; u_char fifocnt; struct tty *tp; int i; u_char reoir; u_char buffer[CL_FIFO_MAX +1]; #ifdef CONSOLEBREAKDDB int wantddb = 0; #endif rir = sc->cl_reg->cl_rir; if((rir & 0x40) == 0x0) { /* only if intr is not shared ??? */ log(LOG_WARNING, "cl_rxintr extra intr\n"); return 0; } sc->sc_rxintrcnt.ev_count++; channel = rir & 0x3; cmr = sc->cl_reg->cl_cmr; reoir = 0x08; sc->sc_cl[channel].rxcnt ++; risrl = sc->cl_reg->cl_risrl; if (risrl & 0x80) { /* timeout, no characters */ reoir = 0x08; } else /* We don't need no sinkin special characters */ if (risrl & 0x08) { cl_overflow (sc, channel, (long*)&sc->sc_fotime, "fifo"); reoir = 0x08; } else if (risrl & 0x04) { cl_parity(sc, channel); reoir = 0x08; } else if (risrl & 0x02) { cl_frame(sc, channel); reoir = 0x08; } else if (risrl & 0x01) { #ifdef CONSOLEBREAKDDB if (sc->sc_cl[channel].cl_consio) wantddb = 1; #endif cl_break(sc, channel); reoir = 0x08; } switch (cmr & CL_RXMASK) { case CL_RXDMAINT: { int nbuf; u_short cnt; int bufcomplete; u_char status, dmabsts; u_char risrh = sc->cl_reg->cl_risrh; dmabsts = sc->cl_reg->cl_dmabsts; #ifdef DMA_DEBUG log(LOG_WARNING, "cl_txintr: DMAMODE channel %x dmabsts %x risrl %x risrh %x\n", channel, dmabsts, risrl, risrh); #endif nbuf = (risrh & 0x08) ? 1 : 0; bufcomplete = (risrh & 0x20) ? 1 : 0; if (nbuf == 0) { cnt = sc->cl_reg->cl_arbcnt; status = sc->cl_reg->cl_arbsts; } else { cnt = sc->cl_reg->cl_brbcnt; status = sc->cl_reg->cl_brbsts; } #ifdef DMA_DEBUG log(LOG_WARNING, "cl_rxintr: 1channel %x buf %x cnt %x status %x\n", channel, nbuf, cnt, status); #endif #if USE_BUFFER cl_appendbufn(sc, channel, sc->rx[nbuf], cnt); #else { int i; u_char *pbuf; tp = sc->sc_cl[channel].tty; pbuf = sc->sc_cl[channel].rx[nbuf]; /* this should be done at off level */ { u_short rcbadru, rcbadrl; u_char arbsts, brbsts; u_char *pbufs, *pbufe; rcbadru = sc->cl_reg->cl_rcbadru; rcbadrl = sc->cl_reg->cl_rcbadrl; arbsts = sc->cl_reg->cl_arbsts; brbsts = sc->cl_reg->cl_brbsts; pbufs = sc->sc_cl[channel].rxp[nbuf]; pbufe = (u_char *)(((u_long)rcbadru << 16) | (u_long)rcbadrl); cnt = pbufe - pbufs; #ifdef DMA_DEBUG log(LOG_WARNING, "cl_rxintr: rcbadru %x rcbadrl %x arbsts %x brbsts %x cnt %x\n", rcbadru, rcbadrl, arbsts, brbsts, cnt); #endif #ifdef DMA_DEBUG1 log(LOG_WARNING, "cl_rxintr: buf %x cnt %x\n", nbuf, cnt); #endif } reoir = 0x0 | (bufcomplete) ? 0 : 0xd0; sc->cl_reg->cl_reoir = reoir; #ifdef DMA_DEBUG log(LOG_WARNING, "cl_rxintr: reoir %x\n", reoir); #endif delay(10); /* give the chip a moment */ #ifdef DMA_DEBUG log(LOG_WARNING, "cl_rxintr: 2channel %x buf %x cnt %x status %x\n", channel, nbuf, cnt, status); #endif for (i = 0; i < cnt; i++) { u_char c; c = pbuf[i]; (*linesw[tp->t_line].l_rint)(c,tp); } /* this should be done at off level */ if (nbuf == 0) { sc->cl_reg->cl_arbcnt = CL_BUFSIZE; sc->cl_reg->cl_arbsts = 0x01; } else { sc->cl_reg->cl_brbcnt = CL_BUFSIZE; sc->cl_reg->cl_brbsts = 0x01; } } #endif } sc->cl_reg->cl_reoir = reoir; break; case CL_RXINTR: fifocnt = sc->cl_reg->cl_rfoc; tp = sc->sc_cl[channel].tty; for (i = 0; i < fifocnt; i++) { buffer[i] = sc->cl_reg->cl_rdr; } if (NULL == tp) { /* if the channel is not configured, * dont send characters upstream. * also fix problem with NULL dereference */ reoir = 0x00; break; } sc->cl_reg->cl_reoir = reoir; for (i = 0; i < fifocnt; i++) { u_char c; c = buffer[i]; #if USE_BUFFER cl_appendbuf(sc, channel, c); #else /* does any restricitions exist on spl * for this call */ (*linesw[tp->t_line].l_rint)(c,tp); reoir = 0x00; #endif } break; default: log(LOG_WARNING, "cl_rxintr unknown mode %x\n", cmr); /* we probably will go to hell quickly now */ reoir = 0x08; sc->cl_reg->cl_reoir = reoir; } #ifdef CONSOLEBREAKDDB if (wantddb) Debugger(); #endif return 1; } void cl_overflow (sc, channel, ptime, msg) struct clsoftc *sc; int channel; long *ptime; u_char *msg; { /* if (*ptime != time.tv_sec) { */ { /* *ptime = time.tv_sec; */ log(LOG_WARNING, "%s%d[%d]: %s overrun\n", cl_cd.cd_name, 0 /* fix */, channel, msg); } return; } void cl_parity (sc, channel) struct clsoftc *sc; int channel; { log(LOG_WARNING, "%s%d[%d]: parity error\n", cl_cd.cd_name, 0, channel); return; } void cl_frame (sc, channel) struct clsoftc *sc; int channel; { log(LOG_WARNING, "%s%d[%d]: frame error\n", cl_cd.cd_name, 0, channel); return; } void cl_break (sc, channel) struct clsoftc *sc; int channel; { #ifdef DEBUG_KERN Debugger(); #else log(LOG_WARNING, "%s%d[%d]: break detected\n", cl_cd.cd_name, 0, channel); #endif return; } void cl_dumpport0() { cl_dumpport(0); return; } void cl_dumpport1() { cl_dumpport(1); return; } void cl_dumpport2() { cl_dumpport(2); return; } void cl_dumpport3() { cl_dumpport(3); return; } void cl_dumpport(channel) int channel; { u_char livr, cmr, cor1, cor2, cor3, cor4, cor5, cor6, cor7, schr1, schr2, schr3, schr4, scrl, scrh, lnxt, rbpr, rcor, tbpr, tcor, rpilr, rir, tpr, ier, ccr, dmabsts, arbsts, brbsts, atbsts, btbsts, csr, rts, dtr, rtprl, rtprh; volatile void * parbadru, *parbadrl, *parbsts, *parbcnt; u_short rcbadru, rcbadrl, arbadru, arbadrl, arbcnt, brbadru, brbadrl, brbcnt; u_short tcbadru, tcbadrl, atbadru, atbadrl, atbcnt, btbadru, btbadrl, btbcnt; struct clsoftc *sc; volatile struct clreg *cl_reg; int s; cl_reg = cl_cons.cl_vaddr; sc = (struct clsoftc *) cl_cd.cd_devs[0]; s = splcl(); cl_reg->cl_car = (u_char) channel; livr = cl_reg->cl_livr; cmr = cl_reg->cl_cmr; cor1 = cl_reg->cl_cor1; cor2 = cl_reg->cl_cor2; cor3 = cl_reg->cl_cor3; cor4 = cl_reg->cl_cor4; cor5 = cl_reg->cl_cor5; cor6 = cl_reg->cl_cor6; cor7 = cl_reg->cl_cor7; schr1 = cl_reg->cl_schr1; schr2 = cl_reg->cl_schr2; schr3 = cl_reg->cl_schr3; schr4 = cl_reg->cl_schr4; scrl = cl_reg->cl_scrl; scrh = cl_reg->cl_scrh; lnxt = cl_reg->cl_lnxt; rbpr = cl_reg->cl_rbpr; rcor = cl_reg->cl_rcor; tbpr = cl_reg->cl_tbpr; rpilr = cl_reg->cl_rpilr; ier = cl_reg->cl_ier; ccr = cl_reg->cl_ccr; tcor = cl_reg->cl_tcor; csr = cl_reg->cl_csr; tpr = cl_reg->cl_tpr; rts = cl_reg->cl_msvr_rts; dtr = cl_reg->cl_msvr_dtr; rtprl = cl_reg->cl_rtprl; rtprh = cl_reg->cl_rtprh; dmabsts = cl_reg->cl_dmabsts; tcbadru = cl_reg->cl_tcbadru; tcbadrl = cl_reg->cl_tcbadrl; rcbadru = cl_reg->cl_rcbadru; rcbadrl = cl_reg->cl_rcbadrl; parbadru = &(cl_reg->cl_arbadru); parbadrl = &(cl_reg->cl_arbadrl); parbcnt = &(cl_reg->cl_arbcnt); parbsts = &(cl_reg->cl_arbsts); arbadru = cl_reg->cl_arbadru; arbadrl = cl_reg->cl_arbadrl; arbcnt = cl_reg->cl_arbcnt; arbsts = cl_reg->cl_arbsts; brbadru = cl_reg->cl_brbadru; brbadrl = cl_reg->cl_brbadrl; brbcnt = cl_reg->cl_brbcnt; brbsts = cl_reg->cl_brbsts; atbadru = cl_reg->cl_atbadru; atbadrl = cl_reg->cl_atbadrl; atbcnt = cl_reg->cl_atbcnt; atbsts = cl_reg->cl_atbsts; btbadru = cl_reg->cl_btbadru; btbadrl = cl_reg->cl_btbadrl; btbcnt = cl_reg->cl_btbcnt; btbsts = cl_reg->cl_btbsts; splx(s); printf("{ port %x livr %x cmr %x\n", channel,livr, cmr); printf("cor1 %x cor2 %x cor3 %x cor4 %x cor5 %x cor6 %x cor7 %x\n", cor1, cor2, cor3, cor4, cor5, cor6, cor7); printf("schr1 %x schr2 %x schr3 %x schr4 %x\n", schr1, schr2, schr3, schr4); printf("scrl %x scrh %x lnxt %x\n", scrl, scrh, lnxt); printf("rbpr %x rcor %x tbpr %x tcor %x\n", rbpr, rcor, tbpr, tcor); printf("rpilr %x rir %x ier %x ccr %x\n", rpilr, rir, ier, ccr); printf("tpr %x csr %x rts %x dtr %x\n", tpr, csr, rts, dtr); printf("rtprl %x rtprh %x\n", rtprl, rtprh); printf("rxcnt %x txcnt %x\n", sc->sc_cl[channel].rxcnt, sc->sc_cl[channel].txcnt); printf("dmabsts %x, tcbadru %x, tcbadrl %x, rcbadru %x, rcbadrl %x,\n", dmabsts, tcbadru, tcbadrl, rcbadru, rcbadrl ); printf("parbadru %x, parbadrl %x, parbcnt %x, parbsts %x\n", parbadru, parbadrl, parbcnt, parbsts); printf("arbadru %x, arbadrl %x, arbcnt %x, arbsts %x\n", arbadru, arbadrl, arbcnt, arbsts); printf("brbadru %x, brbadrl %x, brbcnt %x, brbsts %x\n", brbadru, brbadrl, brbcnt, brbsts); printf("atbadru %x, atbadrl %x, atbcnt %x, atbsts %x\n", atbadru, atbadrl, atbcnt, atbsts); printf("btbadru %x, btbadrl %x, btbcnt %x, btbsts %x\n", btbadru, btbadrl, btbcnt, btbsts); printf("}\n"); return; }