/* * Copyright (c) 1982, 1986 Regents of the University of California. * All rights reserved. The Berkeley software License Agreement * specifies the terms and conditions for redistribution. * * @(#)dh.c 7.1 (Berkeley) 6/5/86 */ #include "dh.h" #if NDH > 0 /* * DH-11/DM-11 driver */ #include "../machine/pte.h" #include "bk.h" #include "uba.h" #include "param.h" #include "conf.h" #include "dir.h" #include "user.h" #include "proc.h" #include "ioctl.h" #include "tty.h" #include "map.h" #include "buf.h" #include "vm.h" #include "kernel.h" #include "syslog.h" #include "ubareg.h" #include "ubavar.h" #include "dhreg.h" #include "dmreg.h" #include "bkmac.h" #include "clist.h" #include "file.h" #include "uio.h" /* * Definition of the driver for the auto-configuration program. * There is one definition for the dh and one for the dm. */ int dhprobe(), dhattach(), dhrint(), dhxint(), dhtimer(); struct uba_device *dhinfo[NDH]; u_short dhstd[] = { 0 }; struct uba_driver dhdriver = { dhprobe, 0, dhattach, 0, dhstd, "dh", dhinfo }; int dmprobe(), dmattach(), dmintr(); struct uba_device *dminfo[NDH]; u_short dmstd[] = { 0 }; struct uba_driver dmdriver = { dmprobe, 0, dmattach, 0, dmstd, "dm", dminfo }; #ifndef PORTSELECTOR #define ISPEED B9600 #define IFLAGS (EVENP|ODDP|ECHO) #else #define ISPEED B4800 #define IFLAGS (EVENP|ODDP) #endif #define FASTTIMER (hz/30) /* scan rate with silos on */ /* * Local variables for the driver */ short dhsar[NDH]; /* software copy of last bar */ short dhsoftCAR[NDH]; struct tty dh11[NDH*16]; int ndh11 = NDH*16; int dhact; /* mask of active dh's */ int dhsilos; /* mask of dh's with silo in use */ int dhchars[NDH]; /* recent input count */ int dhrate[NDH]; /* smoothed input count */ int dhhighrate = 100; /* silo on if dhchars > dhhighrate */ int dhlowrate = 75; /* silo off if dhrate < dhlowrate */ static short timerstarted; int dhstart(), ttrstrt(); /* * The clist space is mapped by the driver onto each UNIBUS. * The UBACVT macro converts a clist space address for unibus uban * into an i/o space address for the DMA routine. */ int dh_ubinfo[NUBA]; /* info about allocated unibus map */ int cbase[NUBA]; /* base address in unibus map */ #define UBACVT(x, uban) (cbase[uban] + ((x)-(char *)cfree)) /* * Routine for configuration to force a dh to interrupt. * Set to transmit at 9600 baud, and cause a transmitter interrupt. */ /*ARGSUSED*/ dhprobe(reg) caddr_t reg; { register int br, cvec; /* these are ``value-result'' */ register struct dhdevice *dhaddr = (struct dhdevice *)reg; #ifdef lint br = 0; cvec = br; br = cvec; if (ndh11 == 0) ndh11 = 1; dhrint(0); dhxint(0); #endif #ifndef notdef dhaddr->un.dhcsr = DH_RIE|DH_MM|DH_RI; DELAY(1000); dhaddr->un.dhcsr &= ~DH_RI; dhaddr->un.dhcsr = 0; #else dhaddr->un.dhcsr = DH_TIE; DELAY(5); dhaddr->dhlpr = (B9600 << 10) | (B9600 << 6) | BITS7|PENABLE; dhaddr->dhbcr = -1; dhaddr->dhcar = 0; dhaddr->dhbar = 1; DELAY(100000); /* wait 1/10'th of a sec for interrupt */ dhaddr->un.dhcsr = 0; if (cvec && cvec != 0x200) cvec -= 4; /* transmit -> receive */ #endif return (sizeof (struct dhdevice)); } /* * Routine called to attach a dh. */ dhattach(ui) struct uba_device *ui; { dhsoftCAR[ui->ui_unit] = ui->ui_flags; cbase[ui->ui_ubanum] = -1; } /* * Configuration routine to cause a dm to interrupt. */ dmprobe(reg) caddr_t reg; { register int br, vec; /* value-result */ register struct dmdevice *dmaddr = (struct dmdevice *)reg; #ifdef lint br = 0; vec = br; br = vec; dmintr(0); #endif dmaddr->dmcsr = DM_DONE|DM_IE; DELAY(20); dmaddr->dmcsr = 0; return (1); } /*ARGSUSED*/ dmattach(ui) struct uba_device *ui; { /* no local state to set up */ } /* * Open a DH11 line, mapping the clist onto the uba if this * is the first dh on this uba. Turn on this dh if this is * the first use of it. Also do a dmopen to wait for carrier. */ /*ARGSUSED*/ dhopen(dev, flag) dev_t dev; { register struct tty *tp; register int unit, dh; register struct dhdevice *addr; register struct uba_device *ui; int s; unit = minor(dev); dh = unit >> 4; if (unit >= NDH*16 || (ui = dhinfo[dh])== 0 || ui->ui_alive == 0) return (ENXIO); tp = &dh11[unit]; if (tp->t_state&TS_XCLUDE && u.u_uid!=0) return (EBUSY); addr = (struct dhdevice *)ui->ui_addr; tp->t_addr = (caddr_t)addr; tp->t_oproc = dhstart; tp->t_state |= TS_WOPEN; /* * While setting up state for this uba and this dh, * block uba resets which can clear the state. */ s = spl5(); if (cbase[ui->ui_ubanum] == -1) { dh_ubinfo[ui->ui_ubanum] = uballoc(ui->ui_ubanum, (caddr_t)cfree, nclist*sizeof(struct cblock), 0); cbase[ui->ui_ubanum] = UBAI_ADDR(dh_ubinfo[ui->ui_ubanum]); } if (timerstarted == 0) { timerstarted++; timeout(dhtimer, (caddr_t) 0, hz); } if ((dhact&(1<un.dhcsr |= DH_IE; dhact |= (1<dhsilo = 0; } splx(s); /* * If this is first open, initialize tty state to default. */ if ((tp->t_state&TS_ISOPEN) == 0) { ttychars(tp); #ifndef PORTSELECTOR if (tp->t_ispeed == 0) { #else tp->t_state |= TS_HUPCLS; #endif PORTSELECTOR tp->t_ispeed = ISPEED; tp->t_ospeed = ISPEED; tp->t_flags = IFLAGS; #ifndef PORTSELECTOR } #endif PORTSELECTOR dhparam(unit); } /* * Wait for carrier, then process line discipline specific open. */ dmopen(dev); return ((*linesw[tp->t_line].l_open)(dev, tp)); } /* * Close a DH11 line, turning off the DM11. */ /*ARGSUSED*/ dhclose(dev, flag) dev_t dev; int flag; { register struct tty *tp; register unit; unit = minor(dev); tp = &dh11[unit]; (*linesw[tp->t_line].l_close)(tp); ((struct dhdevice *)(tp->t_addr))->dhbreak &= ~(1<<(unit&017)); if (tp->t_state&TS_HUPCLS || (tp->t_state&TS_ISOPEN)==0) dmctl(unit, DML_OFF, DMSET); ttyclose(tp); } dhread(dev, uio) dev_t dev; struct uio *uio; { register struct tty *tp = &dh11[minor(dev)]; return ((*linesw[tp->t_line].l_read)(tp, uio)); } dhwrite(dev, uio) dev_t dev; struct uio *uio; { register struct tty *tp = &dh11[minor(dev)]; return ((*linesw[tp->t_line].l_write)(tp, uio)); } /* * DH11 receiver interrupt. */ dhrint(dh) int dh; { register struct tty *tp; register c; register struct dhdevice *addr; register struct tty *tp0; register struct uba_device *ui; int overrun = 0; ui = dhinfo[dh]; if (ui == 0 || ui->ui_alive == 0) return; addr = (struct dhdevice *)ui->ui_addr; tp0 = &dh11[dh<<4]; /* * Loop fetching characters from the silo for this * dh until there are no more in the silo. */ while ((c = addr->dhrcr) < 0) { tp = tp0 + ((c>>8)&0xf); dhchars[dh]++; if ((tp->t_state&TS_ISOPEN)==0) { wakeup((caddr_t)&tp->t_rawq); #ifdef PORTSELECTOR if ((tp->t_state&TS_WOPEN) == 0) #endif continue; } if (c & DH_PE) if ((tp->t_flags&(EVENP|ODDP))==EVENP || (tp->t_flags&(EVENP|ODDP))==ODDP ) continue; if ((c & DH_DO) && overrun == 0) { log(LOG_WARNING, "dh%d: silo overflow\n", dh); overrun = 1; } if (c & DH_FE) /* * At framing error (break) generate * a null (in raw mode, for getty), or a * interrupt (in cooked/cbreak mode). */ if (tp->t_flags&RAW) c = 0; else c = tp->t_intrc; #if NBK > 0 if (tp->t_line == NETLDISC) { c &= 0177; BKINPUT(c, tp); } else #endif (*linesw[tp->t_line].l_rint)(c, tp); } } /* * Ioctl for DH11. */ /*ARGSUSED*/ dhioctl(dev, cmd, data, flag) caddr_t data; { register struct tty *tp; register int unit = minor(dev); int error; tp = &dh11[unit]; error = (*linesw[tp->t_line].l_ioctl)(tp, cmd, data, flag); if (error >= 0) return (error); error = ttioctl(tp, cmd, data, flag); if (error >= 0) { if (cmd == TIOCSETP || cmd == TIOCSETN || cmd == TIOCLBIS || cmd == TIOCLBIC || cmd == TIOCLSET) dhparam(unit); return (error); } switch (cmd) { case TIOCSBRK: ((struct dhdevice *)(tp->t_addr))->dhbreak |= 1<<(unit&017); break; case TIOCCBRK: ((struct dhdevice *)(tp->t_addr))->dhbreak &= ~(1<<(unit&017)); break; case TIOCSDTR: dmctl(unit, DML_DTR|DML_RTS, DMBIS); break; case TIOCCDTR: dmctl(unit, DML_DTR|DML_RTS, DMBIC); break; default: return (ENOTTY); } return (0); } /* * Set parameters from open or stty into the DH hardware * registers. */ dhparam(unit) register int unit; { register struct tty *tp; register struct dhdevice *addr; register int lpar; int s; tp = &dh11[unit]; addr = (struct dhdevice *)tp->t_addr; /* * Block interrupts so parameters will be set * before the line interrupts. */ s = spl5(); addr->un.dhcsrl = (unit&0xf) | DH_IE; if ((tp->t_ispeed)==0) { tp->t_state |= TS_HUPCLS; dmctl(unit, DML_OFF, DMSET); splx(s); return; } lpar = ((tp->t_ospeed)<<10) | ((tp->t_ispeed)<<6); if ((tp->t_ispeed) == B134) lpar |= BITS6|PENABLE|HDUPLX; else if (tp->t_flags & (RAW|LITOUT|PASS8)) lpar |= BITS8; else lpar |= BITS7|PENABLE; if ((tp->t_flags&EVENP) == 0) lpar |= OPAR; if ((tp->t_ospeed) == B110) lpar |= TWOSB; addr->dhlpr = lpar; splx(s); } /* * DH11 transmitter interrupt. * Restart each line which used to be active but has * terminated transmission since the last interrupt. */ dhxint(dh) int dh; { register struct tty *tp; register struct dhdevice *addr; short ttybit, bar, *sbar; register struct uba_device *ui; register int unit; u_short cntr; ui = dhinfo[dh]; addr = (struct dhdevice *)ui->ui_addr; if (addr->un.dhcsr & DH_NXM) { addr->un.dhcsr |= DH_CNI; printf("dh%d: NXM\n", dh); } sbar = &dhsar[dh]; bar = *sbar & ~addr->dhbar; unit = dh * 16; ttybit = 1; addr->un.dhcsr &= (short)~DH_TI; for (; bar; unit++, ttybit <<= 1) { if (bar & ttybit) { *sbar &= ~ttybit; bar &= ~ttybit; tp = &dh11[unit]; tp->t_state &= ~TS_BUSY; if (tp->t_state&TS_FLUSH) tp->t_state &= ~TS_FLUSH; else { addr->un.dhcsrl = (unit&017)|DH_IE; /* * Do arithmetic in a short to make up * for lost 16&17 bits. */ cntr = addr->dhcar - UBACVT(tp->t_outq.c_cf, ui->ui_ubanum); ndflush(&tp->t_outq, (int)cntr); } if (tp->t_line) (*linesw[tp->t_line].l_start)(tp); else dhstart(tp); } } } /* * Start (restart) transmission on the given DH11 line. */ dhstart(tp) register struct tty *tp; { register struct dhdevice *addr; register int car, dh, unit, nch; int s; unit = minor(tp->t_dev); dh = unit >> 4; unit &= 0xf; addr = (struct dhdevice *)tp->t_addr; /* * Must hold interrupts in following code to prevent * state of the tp from changing. */ s = spl5(); /* * If it's currently active, or delaying, no need to do anything. */ if (tp->t_state&(TS_TIMEOUT|TS_BUSY|TS_TTSTOP)) goto out; /* * If there are sleepers, and output has drained below low * water mark, wake up the sleepers. */ if (tp->t_outq.c_cc<=TTLOWAT(tp)) { if (tp->t_state&TS_ASLEEP) { tp->t_state &= ~TS_ASLEEP; wakeup((caddr_t)&tp->t_outq); } if (tp->t_wsel) { selwakeup(tp->t_wsel, tp->t_state & TS_WCOLL); tp->t_wsel = 0; tp->t_state &= ~TS_WCOLL; } } /* * Now restart transmission unless the output queue is * empty. */ if (tp->t_outq.c_cc == 0) goto out; if (tp->t_flags & (RAW|LITOUT)) nch = ndqb(&tp->t_outq, 0); else { nch = ndqb(&tp->t_outq, 0200); /* * If first thing on queue is a delay process it. */ if (nch == 0) { nch = getc(&tp->t_outq); timeout(ttrstrt, (caddr_t)tp, (nch&0x7f)+6); tp->t_state |= TS_TIMEOUT; goto out; } } /* * If characters to transmit, restart transmission. */ if (nch) { car = UBACVT(tp->t_outq.c_cf, dhinfo[dh]->ui_ubanum); addr->un.dhcsrl = unit|((car>>12)&0x30)|DH_IE; /* * The following nonsense with short word * is to make sure the dhbar |= word below * is done with an interlocking bisw2 instruction. */ { short word = 1 << unit; dhsar[dh] |= word; addr->dhcar = car; addr->dhbcr = -nch; addr->dhbar |= word; } tp->t_state |= TS_BUSY; } out: splx(s); } /* * Stop output on a line, e.g. for ^S/^Q or output flush. */ /*ARGSUSED*/ dhstop(tp, flag) register struct tty *tp; { register struct dhdevice *addr; register int unit, s; addr = (struct dhdevice *)tp->t_addr; /* * Block input/output interrupts while messing with state. */ s = spl5(); if (tp->t_state & TS_BUSY) { /* * Device is transmitting; stop output * by selecting the line and setting the byte * count to -1. We will clean up later * by examining the address where the dh stopped. */ unit = minor(tp->t_dev); addr->un.dhcsrl = (unit&017) | DH_IE; if ((tp->t_state&TS_TTSTOP)==0) tp->t_state |= TS_FLUSH; addr->dhbcr = -1; } splx(s); } /* * Reset state of driver if UBA reset was necessary. * Reset the csrl and lpr registers on open lines, and * restart transmitters. */ dhreset(uban) int uban; { register int dh, unit; register struct tty *tp; register struct uba_device *ui; int i; dh = 0; for (dh = 0; dh < NDH; dh++) { ui = dhinfo[dh]; if (ui == 0 || ui->ui_alive == 0 || ui->ui_ubanum != uban) continue; printf(" dh%d", dh); if (dh_ubinfo[uban]) { dh_ubinfo[uban] = uballoc(uban, (caddr_t)cfree, nclist*sizeof (struct cblock), 0); cbase[uban] = UBAI_ADDR(dh_ubinfo[uban]); } ((struct dhdevice *)ui->ui_addr)->un.dhcsr |= DH_IE; ((struct dhdevice *)ui->ui_addr)->dhsilo = 0; unit = dh * 16; for (i = 0; i < 16; i++) { tp = &dh11[unit]; if (tp->t_state & (TS_ISOPEN|TS_WOPEN)) { dhparam(unit); dmctl(unit, DML_ON, DMSET); tp->t_state &= ~TS_BUSY; dhstart(tp); } unit++; } } dhsilos = 0; } int dhtransitions, dhslowtimers, dhfasttimers; /*DEBUG*/ /* * At software clock interrupt time, check status. * Empty all the dh silos that are in use, and decide whether * to turn any silos off or on. */ dhtimer() { register int dh, s; static int timercalls; if (dhsilos) { dhfasttimers++; /*DEBUG*/ timercalls++; s = spl5(); for (dh = 0; dh < NDH; dh++) if (dhsilos & (1 << dh)) dhrint(dh); splx(s); } if ((dhsilos == 0) || ((timercalls += FASTTIMER) >= hz)) { dhslowtimers++; /*DEBUG*/ timercalls = 0; for (dh = 0; dh < NDH; dh++) { ave(dhrate[dh], dhchars[dh], 8); if ((dhchars[dh] > dhhighrate) && ((dhsilos & (1 << dh)) == 0)) { ((struct dhdevice *)(dhinfo[dh]->ui_addr))->dhsilo = (dhchars[dh] > 500? 32 : 16); dhsilos |= (1 << dh); dhtransitions++; /*DEBUG*/ } else if ((dhsilos & (1 << dh)) && (dhrate[dh] < dhlowrate)) { ((struct dhdevice *)(dhinfo[dh]->ui_addr))->dhsilo = 0; dhsilos &= ~(1 << dh); } dhchars[dh] = 0; } } timeout(dhtimer, (caddr_t) 0, dhsilos? FASTTIMER: hz); } /* * Turn on the line associated with dh dev. */ dmopen(dev) dev_t dev; { register struct tty *tp; register struct dmdevice *addr; register struct uba_device *ui; register int unit; register int dm; int s; unit = minor(dev); dm = unit >> 4; tp = &dh11[unit]; unit &= 0xf; if (dm >= NDH || (ui = dminfo[dm]) == 0 || ui->ui_alive == 0) { tp->t_state |= TS_CARR_ON; return; } addr = (struct dmdevice *)ui->ui_addr; s = spl5(); addr->dmcsr &= ~DM_SE; while (addr->dmcsr & DM_BUSY) ; addr->dmcsr = unit; addr->dmlstat = DML_ON; if ((addr->dmlstat&DML_CAR) || (dhsoftCAR[dm]&(1<t_state |= TS_CARR_ON; addr->dmcsr = DM_IE|DM_SE; while ((tp->t_state&TS_CARR_ON)==0) sleep((caddr_t)&tp->t_rawq, TTIPRI); splx(s); } /* * Dump control bits into the DM registers. */ dmctl(dev, bits, how) dev_t dev; int bits, how; { register struct uba_device *ui; register struct dmdevice *addr; register int unit, s; int dm; unit = minor(dev); dm = unit >> 4; if ((ui = dminfo[dm]) == 0 || ui->ui_alive == 0) return; addr = (struct dmdevice *)ui->ui_addr; s = spl5(); addr->dmcsr &= ~DM_SE; while (addr->dmcsr & DM_BUSY) ; addr->dmcsr = unit & 0xf; switch(how) { case DMSET: addr->dmlstat = bits; break; case DMBIS: addr->dmlstat |= bits; break; case DMBIC: addr->dmlstat &= ~bits; break; } addr->dmcsr = DM_IE|DM_SE; splx(s); } /* * DM11 interrupt; deal with carrier transitions. */ dmintr(dm) register int dm; { register struct uba_device *ui; register struct tty *tp; register struct dmdevice *addr; int unit; ui = dminfo[dm]; if (ui == 0) return; addr = (struct dmdevice *)ui->ui_addr; if (addr->dmcsr&DM_DONE) { if (addr->dmcsr&DM_CF) { unit = addr->dmcsr & 0xf; tp = &dh11[(dm << 4) + unit]; if (addr->dmlstat & DML_CAR) (void)(*linesw[tp->t_line].l_modem)(tp, 1); else if ((dhsoftCAR[dm] & (1<t_line].l_modem)(tp, 0) == 0) addr->dmlstat = 0; } addr->dmcsr = DM_IE|DM_SE; } } #endif