/* $NetBSD: fhpib.c,v 1.6 1995/01/07 10:30:10 mycroft Exp $ */ /* * Copyright (c) 1982, 1990, 1993 * The Regents of the University of California. 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 the University of * California, Berkeley and its contributors. * 4. Neither the name of the University 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 REGENTS 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 REGENTS 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. * * @(#)fhpib.c 8.2 (Berkeley) 1/12/94 */ /* * 98625A/B HPIB driver */ #include "hpib.h" #if NHPIB > 0 #include #include #include #include #include #include #include #include /* * Inline version of fhpibwait to be used in places where * we don't worry about getting hung. */ #define FHPIBWAIT(hd, m) while (((hd)->hpib_intr & (m)) == 0) DELAY(1) #ifdef DEBUG int fhpibdebugunit = -1; int fhpibdebug = 0; #define FDB_FAIL 0x01 #define FDB_DMA 0x02 #define FDB_WAIT 0x04 #define FDB_PPOLL 0x08 int dopriodma = 0; /* use high priority DMA */ int doworddma = 1; /* non-zero if we should attempt word dma */ int doppollint = 1; /* use ppoll interrupts instead of watchdog */ int fhpibppolldelay = 50; long fhpibbadint[2] = { 0 }; long fhpibtransfer[NHPIB] = { 0 }; long fhpibnondma[NHPIB] = { 0 }; long fhpibworddma[NHPIB] = { 0 }; long fhpibppollfail[NHPIB] = { 0 }; #endif int fhpibcmd[NHPIB]; fhpibtype(hc) register struct hp_ctlr *hc; { register struct hpib_softc *hs = &hpib_softc[hc->hp_unit]; register struct fhpibdevice *hd = (struct fhpibdevice *)hc->hp_addr; if (hd->hpib_cid != HPIBC) return(0); hs->sc_type = HPIBC; hs->sc_ba = HPIBC_BA; hc->hp_ipl = HPIB_IPL(hd->hpib_ids); return(1); } fhpibreset(unit) int unit; { register struct hpib_softc *hs = &hpib_softc[unit]; register struct fhpibdevice *hd; hd = (struct fhpibdevice *)hs->sc_hc->hp_addr; hd->hpib_cid = 0xFF; DELAY(100); hd->hpib_cmd = CT_8BIT; hd->hpib_ar = AR_ARONC; fhpibifc(hd); hd->hpib_ie = IDS_IE; hd->hpib_data = C_DCL; DELAY(100000); /* * See if we can do word dma. * If so, we should be able to write and read back the appropos bit. */ hd->hpib_ie |= IDS_WDMA; if (hd->hpib_ie & IDS_WDMA) { hd->hpib_ie &= ~IDS_WDMA; hs->sc_flags |= HPIBF_DMA16; #ifdef DEBUG if (fhpibdebug & FDB_DMA) printf("fhpibtype: unit %d has word dma\n", unit); #endif } } fhpibifc(hd) register struct fhpibdevice *hd; { hd->hpib_cmd |= CT_IFC; hd->hpib_cmd |= CT_INITFIFO; DELAY(100); hd->hpib_cmd &= ~CT_IFC; hd->hpib_cmd |= CT_REN; hd->hpib_stat = ST_ATN; } fhpibsend(unit, slave, sec, addr, origcnt) int unit, slave, sec, origcnt; register char *addr; { register struct hpib_softc *hs = &hpib_softc[unit]; register struct fhpibdevice *hd; register int cnt = origcnt; register int timo; hd = (struct fhpibdevice *)hs->sc_hc->hp_addr; hd->hpib_stat = 0; hd->hpib_imask = IM_IDLE | IM_ROOM; if (fhpibwait(hd, IM_IDLE) < 0) goto senderr; hd->hpib_stat = ST_ATN; hd->hpib_data = C_UNL; hd->hpib_data = C_TAG + hs->sc_ba; hd->hpib_data = C_LAG + slave; if (sec < 0) { if (sec == -2) /* selected device clear KLUDGE */ hd->hpib_data = C_SDC; } else hd->hpib_data = C_SCG + sec; if (fhpibwait(hd, IM_IDLE) < 0) goto senderr; if (cnt) { hd->hpib_stat = ST_WRITE; while (--cnt) { hd->hpib_data = *addr++; timo = hpibtimeout; while ((hd->hpib_intr & IM_ROOM) == 0) { if (--timo <= 0) goto senderr; DELAY(1); } } hd->hpib_stat = ST_EOI; hd->hpib_data = *addr; FHPIBWAIT(hd, IM_ROOM); hd->hpib_stat = ST_ATN; /* XXX: HP-UX claims bug with CS80 transparent messages */ if (sec == 0x12) DELAY(150); hd->hpib_data = C_UNL; (void) fhpibwait(hd, IM_IDLE); } hd->hpib_imask = 0; return (origcnt); senderr: hd->hpib_imask = 0; fhpibifc(hd); #ifdef DEBUG if (fhpibdebug & FDB_FAIL) { printf("hpib%d: fhpibsend failed: slave %d, sec %x, ", unit, slave, sec); printf("sent %d of %d bytes\n", origcnt-cnt-1, origcnt); } #endif return (origcnt - cnt - 1); } fhpibrecv(unit, slave, sec, addr, origcnt) int unit, slave, sec, origcnt; register char *addr; { register struct hpib_softc *hs = &hpib_softc[unit]; register struct fhpibdevice *hd; register int cnt = origcnt; register int timo; hd = (struct fhpibdevice *)hs->sc_hc->hp_addr; /* * Slave < 0 implies continuation of a previous receive * that probably timed out. */ if (slave >= 0) { hd->hpib_stat = 0; hd->hpib_imask = IM_IDLE | IM_ROOM | IM_BYTE; if (fhpibwait(hd, IM_IDLE) < 0) goto recverror; hd->hpib_stat = ST_ATN; hd->hpib_data = C_UNL; hd->hpib_data = C_LAG + hs->sc_ba; hd->hpib_data = C_TAG + slave; if (sec != -1) hd->hpib_data = C_SCG + sec; if (fhpibwait(hd, IM_IDLE) < 0) goto recverror; hd->hpib_stat = ST_READ0; hd->hpib_data = 0; } if (cnt) { while (--cnt >= 0) { timo = hpibtimeout; while ((hd->hpib_intr & IM_BYTE) == 0) { if (--timo == 0) goto recvbyteserror; DELAY(1); } *addr++ = hd->hpib_data; } FHPIBWAIT(hd, IM_ROOM); hd->hpib_stat = ST_ATN; hd->hpib_data = (slave == 31) ? C_UNA : C_UNT; (void) fhpibwait(hd, IM_IDLE); } hd->hpib_imask = 0; return (origcnt); recverror: fhpibifc(hd); recvbyteserror: hd->hpib_imask = 0; #ifdef DEBUG if (fhpibdebug & FDB_FAIL) { printf("hpib%d: fhpibrecv failed: slave %d, sec %x, ", unit, slave, sec); printf("got %d of %d bytes\n", origcnt-cnt-1, origcnt); } #endif return (origcnt - cnt - 1); } fhpibgo(unit, slave, sec, addr, count, rw, timo) register int unit; int slave, sec, count, rw; char *addr; { register struct hpib_softc *hs = &hpib_softc[unit]; register struct fhpibdevice *hd; register int i; int flags = 0; hd = (struct fhpibdevice *)hs->sc_hc->hp_addr; hs->sc_flags |= HPIBF_IO; if (timo) hs->sc_flags |= HPIBF_TIMO; if (rw == B_READ) hs->sc_flags |= HPIBF_READ; #ifdef DEBUG else if (hs->sc_flags & HPIBF_READ) { printf("fhpibgo: HPIBF_READ still set\n"); hs->sc_flags &= ~HPIBF_READ; } #endif hs->sc_count = count; hs->sc_addr = addr; #ifdef DEBUG fhpibtransfer[unit]++; #endif if ((hs->sc_flags & HPIBF_DMA16) && ((int)addr & 1) == 0 && count && (count & 1) == 0 #ifdef DEBUG && doworddma #endif ) { #ifdef DEBUG fhpibworddma[unit]++; #endif flags |= DMAGO_WORD; hd->hpib_latch = 0; } #ifdef DEBUG if (dopriodma) flags |= DMAGO_PRI; #endif if (hs->sc_flags & HPIBF_READ) { fhpibcmd[unit] = CT_REN | CT_8BIT; hs->sc_curcnt = count; dmago(hs->sc_dq.dq_ctlr, addr, count, flags|DMAGO_READ); if (fhpibrecv(unit, slave, sec, 0, 0) < 0) { #ifdef DEBUG printf("fhpibgo: recv failed, retrying...\n"); #endif (void) fhpibrecv(unit, slave, sec, 0, 0); } i = hd->hpib_cmd; hd->hpib_cmd = fhpibcmd[unit]; hd->hpib_ie = IDS_DMA(hs->sc_dq.dq_ctlr) | ((flags & DMAGO_WORD) ? IDS_WDMA : 0); return; } fhpibcmd[unit] = CT_REN | CT_8BIT | CT_FIFOSEL; if (count < hpibdmathresh) { #ifdef DEBUG fhpibnondma[unit]++; if (flags & DMAGO_WORD) fhpibworddma[unit]--; #endif hs->sc_curcnt = count; (void) fhpibsend(unit, slave, sec, addr, count); fhpibdone(unit); return; } count -= (flags & DMAGO_WORD) ? 2 : 1; hs->sc_curcnt = count; dmago(hs->sc_dq.dq_ctlr, addr, count, flags); if (fhpibsend(unit, slave, sec, 0, 0) < 0) { #ifdef DEBUG printf("fhpibgo: send failed, retrying...\n"); #endif (void) fhpibsend(unit, slave, sec, 0, 0); } i = hd->hpib_cmd; hd->hpib_cmd = fhpibcmd[unit]; hd->hpib_ie = IDS_DMA(hs->sc_dq.dq_ctlr) | IDS_WRITE | ((flags & DMAGO_WORD) ? IDS_WDMA : 0); } /* * A DMA read can finish but the device can still be waiting (MAG-tape * with more data than we're waiting for). This timeout routine * takes care of that. Somehow, the thing gets hosed. For now, since * this should be a very rare occurence, we RESET it. */ void fhpibdmadone(arg) void *arg; { register int unit; register struct hpib_softc *hs; int s = splbio(); unit = (int)arg; hs = &hpib_softc[unit]; if (hs->sc_flags & HPIBF_IO) { register struct fhpibdevice *hd; register struct devqueue *dq; hd = (struct fhpibdevice *)hs->sc_hc->hp_addr; hd->hpib_imask = 0; hd->hpib_cid = 0xFF; DELAY(100); hd->hpib_cmd = CT_8BIT; hd->hpib_ar = AR_ARONC; fhpibifc(hd); hd->hpib_ie = IDS_IE; hs->sc_flags &= ~(HPIBF_DONE|HPIBF_IO|HPIBF_READ|HPIBF_TIMO); dmafree(&hs->sc_dq); dq = hs->sc_sq.dq_forw; (dq->dq_driver->d_intr)(dq->dq_unit); } (void) splx(s); } fhpibdone(unit) int unit; { register struct hpib_softc *hs = &hpib_softc[unit]; register struct fhpibdevice *hd; register char *addr; register int cnt; hd = (struct fhpibdevice *)hs->sc_hc->hp_addr; cnt = hs->sc_curcnt; hs->sc_addr += cnt; hs->sc_count -= cnt; #ifdef DEBUG if ((fhpibdebug & FDB_DMA) && fhpibdebugunit == unit) printf("fhpibdone: addr %x cnt %d\n", hs->sc_addr, hs->sc_count); #endif if (hs->sc_flags & HPIBF_READ) { hd->hpib_imask = IM_IDLE | IM_BYTE; if (hs->sc_flags & HPIBF_TIMO) timeout(fhpibdmadone, (void *)unit, hz >> 2); } else { cnt = hs->sc_count; if (cnt) { addr = hs->sc_addr; hd->hpib_imask = IM_IDLE | IM_ROOM; FHPIBWAIT(hd, IM_IDLE); hd->hpib_stat = ST_WRITE; while (--cnt) { hd->hpib_data = *addr++; FHPIBWAIT(hd, IM_ROOM); } hd->hpib_stat = ST_EOI; hd->hpib_data = *addr; } hd->hpib_imask = IM_IDLE; } hs->sc_flags |= HPIBF_DONE; hd->hpib_stat = ST_IENAB; hd->hpib_ie = IDS_IE; } fhpibintr(unit) register int unit; { register struct hpib_softc *hs = &hpib_softc[unit]; register struct fhpibdevice *hd; register struct devqueue *dq; register int stat0; hd = (struct fhpibdevice *)hs->sc_hc->hp_addr; stat0 = hd->hpib_ids; if ((stat0 & (IDS_IE|IDS_IR)) != (IDS_IE|IDS_IR)) { #ifdef DEBUG if ((fhpibdebug & FDB_FAIL) && (stat0 & IDS_IR) && (hs->sc_flags & (HPIBF_IO|HPIBF_DONE)) != HPIBF_IO) printf("hpib%d: fhpibintr: bad status %x\n", unit, stat0); fhpibbadint[0]++; #endif return(0); } if ((hs->sc_flags & (HPIBF_IO|HPIBF_DONE)) == HPIBF_IO) { #ifdef DEBUG fhpibbadint[1]++; #endif return(0); } #ifdef DEBUG if ((fhpibdebug & FDB_DMA) && fhpibdebugunit == unit) printf("fhpibintr: flags %x\n", hs->sc_flags); #endif dq = hs->sc_sq.dq_forw; if (hs->sc_flags & HPIBF_IO) { if (hs->sc_flags & HPIBF_TIMO) untimeout(fhpibdmadone, (void *)unit); stat0 = hd->hpib_cmd; hd->hpib_cmd = fhpibcmd[unit] & ~CT_8BIT; hd->hpib_stat = 0; hd->hpib_cmd = CT_REN | CT_8BIT; stat0 = hd->hpib_intr; hd->hpib_imask = 0; hs->sc_flags &= ~(HPIBF_DONE|HPIBF_IO|HPIBF_READ|HPIBF_TIMO); dmafree(&hs->sc_dq); (dq->dq_driver->d_intr)(dq->dq_unit); } else if (hs->sc_flags & HPIBF_PPOLL) { stat0 = hd->hpib_intr; #ifdef DEBUG if ((fhpibdebug & FDB_FAIL) && doppollint && (stat0 & IM_PPRESP) == 0) printf("hpib%d: fhpibintr: bad intr reg %x\n", unit, stat0); #endif hd->hpib_stat = 0; hd->hpib_imask = 0; #ifdef DEBUG stat0 = fhpibppoll(unit); if ((fhpibdebug & FDB_PPOLL) && unit == fhpibdebugunit) printf("fhpibintr: got PPOLL status %x\n", stat0); if ((stat0 & (0x80 >> dq->dq_slave)) == 0) { /* * XXX give it another shot (68040) */ fhpibppollfail[unit]++; DELAY(fhpibppolldelay); stat0 = fhpibppoll(unit); if ((stat0 & (0x80 >> dq->dq_slave)) == 0 && (fhpibdebug & FDB_PPOLL) && unit == fhpibdebugunit) printf("fhpibintr: PPOLL: unit %d slave %d stat %x\n", unit, dq->dq_slave, stat0); } #endif hs->sc_flags &= ~HPIBF_PPOLL; (dq->dq_driver->d_intr)(dq->dq_unit); } return(1); } fhpibppoll(unit) int unit; { register struct fhpibdevice *hd; register int ppoll; hd = (struct fhpibdevice *)hpib_softc[unit].sc_hc->hp_addr; hd->hpib_stat = 0; hd->hpib_psense = 0; hd->hpib_pmask = 0xFF; hd->hpib_imask = IM_PPRESP | IM_PABORT; DELAY(25); hd->hpib_intr = IM_PABORT; ppoll = hd->hpib_data; if (hd->hpib_intr & IM_PABORT) ppoll = 0; hd->hpib_imask = 0; hd->hpib_pmask = 0; hd->hpib_stat = ST_IENAB; return(ppoll); } fhpibwait(hd, x) register struct fhpibdevice *hd; int x; { register int timo = hpibtimeout; while ((hd->hpib_intr & x) == 0 && --timo) DELAY(1); if (timo == 0) { #ifdef DEBUG if (fhpibdebug & FDB_FAIL) printf("fhpibwait(%x, %x) timeout\n", hd, x); #endif return(-1); } return(0); } /* * XXX: this will have to change if we ever allow more than one * pending operation per HP-IB. */ void fhpibppwatch(arg) void *arg; { register int unit; register struct hpib_softc *hs; register struct fhpibdevice *hd; register int slave; unit = (int)arg; hs = &hpib_softc[unit]; if ((hs->sc_flags & HPIBF_PPOLL) == 0) return; hd = (struct fhpibdevice *)hs->sc_hc->hp_addr; slave = (0x80 >> hs->sc_sq.dq_forw->dq_slave); #ifdef DEBUG if (!doppollint) { if (fhpibppoll(unit) & slave) { hd->hpib_stat = ST_IENAB; hd->hpib_imask = IM_IDLE | IM_ROOM; } else timeout(fhpibppwatch, (void *)unit, 1); return; } if ((fhpibdebug & FDB_PPOLL) && unit == fhpibdebugunit) printf("fhpibppwatch: sense request on %d\n", unit); #endif hd->hpib_psense = ~slave; hd->hpib_pmask = slave; hd->hpib_stat = ST_IENAB; hd->hpib_imask = IM_PPRESP | IM_PABORT; hd->hpib_ie = IDS_IE; } #endif