/* * 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. * * @(#)tm.c 7.14 (Berkeley) 12/16/90 */ #include "te.h" #include "ts.h" #if NTE > 0 /* * TM11/TE10 tape driver * * TODO: * test driver with more than one controller * test reset code * what happens if you offline tape during rewind? * test using file system on tape */ #include "sys/param.h" #include "sys/systm.h" #include "sys/buf.h" #include "sys/conf.h" #include "sys/user.h" #include "sys/file.h" #include "sys/map.h" #include "sys/vm.h" #include "sys/ioctl.h" #include "sys/mtio.h" #include "sys/cmap.h" #include "sys/uio.h" #include "sys/kernel.h" #include "sys/syslog.h" #include "sys/tprintf.h" #include "../include/pte.h" #include "../include/cpu.h" #include "ubareg.h" #include "ubavar.h" #include "tmreg.h" /* * There is a ctmbuf per tape controller. * It is used as the token to pass to the internal routines * to execute tape ioctls, and also acts as a lock on the slaves * on the controller, since there is only one per controller. * In particular, when the tape is rewinding on close we release * the user process but any further attempts to use the tape drive * before the rewind completes will hang waiting for ctmbuf. */ struct buf ctmbuf[NTM]; /* * Driver unibus interface routines and variables. */ int tmprobe(), tmslave(), tmattach(), tmdgo(), tmintr(); struct uba_ctlr *tmminfo[NTM]; struct uba_device *tedinfo[NTE]; struct buf teutab[NTE]; short tetotm[NTE]; u_short tmstd[] = { 0772520, 0 }; struct uba_driver tmdriver = { tmprobe, tmslave, tmattach, tmdgo, tmstd, "te", tedinfo, "tm", tmminfo, 0 }; /* bits in minor device */ #define TEUNIT(dev) (minor(dev)&03) #define TMUNIT(dev) (tetotm[TEUNIT(dev)]) #define T_NOREWIND 04 #define T_1600BPI 0x8 #define INF (daddr_t)1000000L /* * Software state per tape transport. * * 1. A tape drive is a unique-open device; we refuse opens when it is already. * 2. We keep track of the current position on a block tape and seek * before operations by forward/back spacing if necessary. * 3. We remember if the last operation was a write on a tape, so if a tape * is open read write and the last thing done is a write we can * write a standard end of tape mark (two eofs). * 4. We remember the status registers after the last command, using * then internally and returning them to the SENSE ioctl. * 5. We remember the last density the tape was used at. If it is * not a BOT when we start using it and we are writing, we don't * let the density be changed. */ struct te_softc { char sc_openf; /* lock against multiple opens */ char sc_lastiow; /* last op was a write */ daddr_t sc_blkno; /* block number, for block device tape */ daddr_t sc_nxrec; /* position of end of tape, if known */ u_short sc_erreg; /* copy of last erreg */ u_short sc_ioerreg; /* copy of last erreg for I/O command */ u_short sc_dsreg; /* copy of last dsreg */ short sc_resid; /* copy of last bc */ #ifdef unneeded short sc_lastcmd; /* last command to handle direction changes */ #endif u_short sc_dens; /* prototype command with density info */ short sc_tact; /* timeout is active */ daddr_t sc_timo; /* time until timeout expires */ int sc_blks; /* number of I/O operations since open */ int sc_softerrs; /* number of soft I/O errors since open */ tpr_t sc_tpr; /* tprintf handle */ } te_softc[NTE]; #ifdef unneeded int tmgapsdcnt; /* DEBUG */ #endif /* * States for um->um_tab.b_active, the per controller state flag. * This is used to sequence control in the driver. */ #define SSEEK 1 /* seeking */ #define SIO 2 /* doing seq i/o */ #define SCOM 3 /* sending control command */ #define SREW 4 /* sending a drive rewind */ /* * Determine if there is a controller for * a tm at address reg. Our goal is to make the * device interrupt. */ tmprobe(reg) caddr_t reg; { register int br, cvec; /* must be r11,r10; value-result */ #ifdef lint br = 0; cvec = br; br = cvec; tmintr(0); #endif ((struct tmdevice *)reg)->tmcs = TM_IE; /* * If this is a tm11, it ought to have interrupted * by now, if it isn't (ie: it is a ts04) then we just * hope that it didn't interrupt, so autoconf will ignore it. * Just in case, we will reference one * of the more distant registers, and hope for a machine * check, or similar disaster if this is a ts. * * Note: on an 11/780, badaddr will just generate * a uba error for a ts; but our caller will notice that * so we won't check for it. */ if (badaddr((caddr_t)&((struct tmdevice *)reg)->tmrd, 2)) return (0); return (sizeof (struct tmdevice)); } /* * Due to a design flaw, we cannot ascertain if the tape * exists or not unless it is on line - ie: unless a tape is * mounted. This is too servere a restriction to bear, * so all units are assumed to exist. */ /*ARGSUSED*/ tmslave(ui, reg) struct uba_device *ui; caddr_t reg; { return (1); } /* * Record attachment of the unit to the controller. */ /*ARGSUSED*/ tmattach(ui) struct uba_device *ui; { /* * Tetotm is used in TMUNIT to index the ctmbuf * array given a te unit number. */ tetotm[ui->ui_unit] = ui->ui_mi->um_ctlr; } int tmtimer(); /* * Open the device. Tapes are unique open * devices, so we refuse if it is already open. * We also check that a tape is available, and * don't block waiting here; if you want to wait * for a tape you should timeout in user code. */ #ifdef AVIV int tmdens[4] = { 0x6000, 0x0000, 0x2000, 0 }; #endif AVIV int tmdiag; tmopen(dev, flag) dev_t dev; int flag; { register int teunit; register struct uba_device *ui; register struct te_softc *sc; int olddens, dens, error; int s; teunit = TEUNIT(dev); if (teunit>=NTE || (ui = tedinfo[teunit]) == 0 || ui->ui_alive == 0) return (ENXIO); if ((sc = &te_softc[teunit])->sc_openf) return (EBUSY); sc->sc_openf = 1; olddens = sc->sc_dens; dens = TM_IE | TM_GO | (ui->ui_slave << 8); #ifndef AVIV if ((minor(dev) & T_1600BPI) == 0) dens |= TM_D800; #else AVIV dens |= tmdens[(minor(dev)>>3)&03]; #endif AVIV sc->sc_dens = dens; get: tmcommand(dev, TM_SENSE, 1); if (sc->sc_erreg&TMER_SDWN) { if (error = tsleep((caddr_t)&lbolt, (PZERO+1) | PCATCH, devopn, 0)) return (error); goto get; } sc->sc_dens = olddens; if ((sc->sc_erreg&(TMER_SELR|TMER_TUR)) != (TMER_SELR|TMER_TUR)) { uprintf("te%d: not online\n", teunit); sc->sc_openf = 0; return (EIO); } if ((flag&FWRITE) && (sc->sc_erreg&TMER_WRL)) { uprintf("te%d: no write ring\n", teunit); sc->sc_openf = 0; return (EIO); } if ((sc->sc_erreg&TMER_BOT) == 0 && (flag&FWRITE) && dens != sc->sc_dens) { uprintf("te%d: can't change density in mid-tape\n", teunit); sc->sc_openf = 0; return (EIO); } sc->sc_blkno = (daddr_t)0; sc->sc_nxrec = INF; sc->sc_lastiow = 0; sc->sc_dens = dens; sc->sc_blks = 0; sc->sc_softerrs = 0; sc->sc_tpr = tprintf_open(); s = splclock(); if (sc->sc_tact == 0) { sc->sc_timo = INF; sc->sc_tact = 1; timeout(tmtimer, (caddr_t)dev, 5*hz); } splx(s); return (0); } /* * Close tape device. * * If tape was open for writing or last operation was * a write, then write two EOF's and backspace over the last one. * Unless this is a non-rewinding special file, rewind the tape. * Make the tape available to others. */ tmclose(dev, flag) register dev_t dev; register flag; { register struct te_softc *sc = &te_softc[TEUNIT(dev)]; if (flag == FWRITE || (flag&FWRITE) && sc->sc_lastiow) { tmcommand(dev, TM_WEOF, 1); tmcommand(dev, TM_WEOF, 1); tmcommand(dev, TM_SREV, 1); } if ((minor(dev)&T_NOREWIND) == 0) /* * 0 count means don't hang waiting for rewind complete * rather ctmbuf stays busy until the operation completes * preventing further opens from completing by * preventing a TM_SENSE from completing. */ tmcommand(dev, TM_REW, 0); if (sc->sc_blks > 100 && sc->sc_softerrs > sc->sc_blks / 100) log(LOG_INFO, "te%d: %d soft errors in %d blocks\n", TEUNIT(dev), sc->sc_softerrs, sc->sc_blks); tprintf_close(sc->sc_tpr); sc->sc_openf = 0; return (0); } /* * Execute a command on the tape drive * a specified number of times. */ tmcommand(dev, com, count) dev_t dev; int com, count; { register struct buf *bp; register int s; bp = &ctmbuf[TMUNIT(dev)]; s = spl5(); while (bp->b_flags&B_BUSY) { /* * This special check is because B_BUSY never * gets cleared in the non-waiting rewind case. */ if (bp->b_repcnt == 0 && (bp->b_flags&B_DONE)) break; bp->b_flags |= B_WANTED; sleep((caddr_t)bp, PRIBIO); } bp->b_flags = B_BUSY|B_READ; splx(s); bp->b_dev = dev; bp->b_repcnt = -count; bp->b_command = com; bp->b_blkno = 0; tmstrategy(bp); /* * In case of rewind from close, don't wait. * This is the only case where count can be 0. */ if (count == 0) return; iowait(bp); if (bp->b_flags&B_WANTED) wakeup((caddr_t)bp); bp->b_flags &= B_ERROR; } /* * Queue a tape operation. */ tmstrategy(bp) register struct buf *bp; { int teunit = TEUNIT(bp->b_dev); register struct uba_ctlr *um; register struct buf *dp; int s; /* * Put transfer at end of unit queue */ dp = &teutab[teunit]; bp->av_forw = NULL; s = spl5(); um = tedinfo[teunit]->ui_mi; if (dp->b_actf == NULL) { dp->b_actf = bp; /* * Transport not already active... * put at end of controller queue. */ dp->b_forw = NULL; if (um->um_tab.b_actf == NULL) um->um_tab.b_actf = dp; else um->um_tab.b_actl->b_forw = dp; um->um_tab.b_actl = dp; } else dp->b_actl->av_forw = bp; dp->b_actl = bp; /* * If the controller is not busy, get * it going. */ if (um->um_tab.b_active == 0) tmstart(um); splx(s); } /* * Start activity on a tm controller. */ tmstart(um) register struct uba_ctlr *um; { register struct buf *bp, *dp; register struct tmdevice *addr = (struct tmdevice *)um->um_addr; register struct te_softc *sc; register struct uba_device *ui; int teunit, cmd; daddr_t blkno; /* * Look for an idle transport on the controller. */ loop: if ((dp = um->um_tab.b_actf) == NULL) return; if ((bp = dp->b_actf) == NULL) { um->um_tab.b_actf = dp->b_forw; goto loop; } teunit = TEUNIT(bp->b_dev); ui = tedinfo[teunit]; /* * Record pre-transfer status (e.g. for TM_SENSE) */ sc = &te_softc[teunit]; addr = (struct tmdevice *)um->um_addr; addr->tmcs = (ui->ui_slave << 8); sc->sc_dsreg = addr->tmcs; sc->sc_erreg = addr->tmer; sc->sc_resid = addr->tmbc; /* * Default is that last command was NOT a write command; * if we do a write command we will notice this in tmintr(). */ sc->sc_lastiow = 0; if (sc->sc_openf < 0 || (addr->tmcs&TM_CUR) == 0) { /* * Have had a hard error on a non-raw tape * or the tape unit is now unavailable * (e.g. taken off line). */ bp->b_flags |= B_ERROR; goto next; } if (bp == &ctmbuf[TMUNIT(bp->b_dev)]) { /* * Execute control operation with the specified count. */ if (bp->b_command == TM_SENSE) goto next; /* * Set next state; give 5 minutes to complete * rewind, or 10 seconds per iteration (minimum 60 * seconds and max 5 minutes) to complete other ops. */ if (bp->b_command == TM_REW) { um->um_tab.b_active = SREW; sc->sc_timo = 5 * 60; } else { um->um_tab.b_active = SCOM; sc->sc_timo = imin(imax(10*(int)-bp->b_repcnt,60),5*60); } if (bp->b_command == TM_SFORW || bp->b_command == TM_SREV) addr->tmbc = bp->b_repcnt; goto dobpcmd; } /* * For raw I/O, fudge the current block number * so we don't seek except on a retry. * For raw I/O, fudge the current block number * so we don't seek except on a retry. */ if (bp->b_flags & B_RAW) { if (um->um_tab.b_errcnt == 0) { sc->sc_blkno = bdbtofsb(bp->b_blkno); sc->sc_nxrec = sc->sc_blkno + 1; } } else { /* * Handle boundary cases for operation * on non-raw tapes. */ if (bdbtofsb(bp->b_blkno) > sc->sc_nxrec) { /* * Can't read past known end-of-file. */ bp->b_flags |= B_ERROR; bp->b_error = ENXIO; goto next; } if (bdbtofsb(bp->b_blkno) == sc->sc_nxrec && bp->b_flags&B_READ) { /* * Reading at end of file returns 0 bytes. */ bp->b_resid = bp->b_bcount; clrbuf(bp); goto next; } if ((bp->b_flags&B_READ) == 0) /* * Writing sets EOF */ sc->sc_nxrec = bdbtofsb(bp->b_blkno) + 1; } /* * If the data transfer command is in the correct place, * set up all the registers except the csr, and give * control over to the UNIBUS adapter routines, to * wait for resources to start the i/o. */ if ((blkno = sc->sc_blkno) == bdbtofsb(bp->b_blkno)) { addr->tmbc = -bp->b_bcount; if ((bp->b_flags&B_READ) == 0) { if (um->um_tab.b_errcnt && (sc->sc_ioerreg&(TMER_HARD|TMER_SOFT)) != TMER_BGL) cmd = TM_WIRG; else cmd = TM_WCOM; } else cmd = TM_RCOM; um->um_tab.b_active = SIO; um->um_cmd = sc->sc_dens|cmd; #ifdef notdef if (tmreverseop(sc->sc_lastcmd)) while (addr->tmer & TMER_SDWN) DELAY(10),tmgapsdcnt++; sc->sc_lastcmd = TM_RCOM; /* will serve */ #endif sc->sc_timo = 60; /* premature, but should serve */ (void) ubago(ui); return; } /* * Tape positioned incorrectly; * set to seek forwards or backwards to the correct spot. * This happens for raw tapes only on error retries. */ um->um_tab.b_active = SSEEK; if (blkno < bdbtofsb(bp->b_blkno)) { bp->b_command = TM_SFORW; addr->tmbc = blkno - bdbtofsb(bp->b_blkno); } else { bp->b_command = TM_SREV; addr->tmbc = bdbtofsb(bp->b_blkno) - blkno; } sc->sc_timo = imin(imax(10 * -addr->tmbc, 60), 5 * 60); dobpcmd: #ifdef notdef /* * It is strictly necessary to wait for the tape * to stop before changing directions, but the TC11 * handles this for us. */ if (tmreverseop(sc->sc_lastcmd) != tmreverseop(bp->b_command)) while (addr->tmer & TM_SDWN) DELAY(10),tmgapsdcnt++; sc->sc_lastcmd = bp->b_command; #endif /* * Do the command in bp. */ addr->tmcs = (sc->sc_dens | bp->b_command); return; next: /* * Done with this operation due to error or * the fact that it doesn't do anything. * Release UBA resources (if any), dequeue * the transfer and continue processing this slave. */ if (um->um_ubinfo) ubadone(um); um->um_tab.b_errcnt = 0; dp->b_actf = bp->av_forw; iodone(bp); goto loop; } /* * The UNIBUS resources we needed have been * allocated to us; start the device. */ tmdgo(um) register struct uba_ctlr *um; { register struct tmdevice *addr = (struct tmdevice *)um->um_addr; addr->tmba = um->um_ubinfo; addr->tmcs = um->um_cmd | ((um->um_ubinfo >> 12) & 0x30); } /* * Tm interrupt routine. */ /*ARGSUSED*/ tmintr(tm11) int tm11; { struct buf *dp; register struct buf *bp; register struct uba_ctlr *um = tmminfo[tm11]; register struct tmdevice *addr; register struct te_softc *sc; int teunit; register state; if ((dp = um->um_tab.b_actf) == NULL) return; bp = dp->b_actf; teunit = TEUNIT(bp->b_dev); addr = (struct tmdevice *)tedinfo[teunit]->ui_addr; sc = &te_softc[teunit]; /* * If last command was a rewind, and tape is still * rewinding, wait for the rewind complete interrupt. */ if (um->um_tab.b_active == SREW) { um->um_tab.b_active = SCOM; if (addr->tmer&TMER_RWS) { sc->sc_timo = 5*60; /* 5 minutes */ return; } } /* * An operation completed... record status */ sc->sc_timo = INF; if (um->um_tab.b_active == SIO) if (um->um_tab.b_active == SIO) sc->sc_ioerreg = addr->tmer; sc->sc_dsreg = addr->tmcs; sc->sc_erreg = addr->tmer; sc->sc_resid = addr->tmbc; if ((bp->b_flags & B_READ) == 0) sc->sc_lastiow = 1; state = um->um_tab.b_active; um->um_tab.b_active = 0; /* * Check for errors. */ if (addr->tmcs&TM_ERR) { while (addr->tmer & TMER_SDWN) DELAY(10); /* await settle down */ /* * If we hit the end of the tape file, update our position. */ if (addr->tmer&TMER_EOF) { tmseteof(bp); /* set blkno and nxrec */ state = SCOM; /* force completion */ /* * Stuff bc so it will be unstuffed correctly * later to get resid. */ addr->tmbc = -bp->b_bcount; goto opdone; } /* * If we were reading raw tape and the only error was that the * record was too long, then we don't consider this an error. */ if ((bp->b_flags & (B_READ|B_RAW)) == (B_READ|B_RAW) && (addr->tmer&(TMER_HARD|TMER_SOFT)) == TMER_RLE) goto ignoreerr; /* * If error is not hard, and this was an i/o operation * retry up to 8 times. */ if ((addr->tmer&TMER_HARD)==0 && state==SIO) { if (um->um_tab.b_errcnt++ < 8) { if (tmdiag) log(LOG_DEBUG, "te%d: soft error bn%d er=%b\n", minor(bp->b_dev)&03, bp->b_blkno, sc->sc_erreg, TMER_BITS); sc->sc_blkno++; /* force backspace */ ubadone(um); goto opcont; } } else /* * Hard or non-i/o errors on non-raw tape * cause it to close. */ if ((bp->b_flags&B_RAW) == 0 && sc->sc_openf > 0) sc->sc_openf = -1; /* * Couldn't recover error */ tprintf(sc->sc_tpr, "te%d: hard error bn%d er=%b\n", minor(bp->b_dev)&03, bp->b_blkno, sc->sc_erreg, TMER_BITS); #ifdef AVIV if (tmdiag) { addr->tmmr = DAB; printf("reject code 0%o", addr->tmmr & DAB_MASK); addr->tmmr = DTS; if (addr->tmmr & DTS_MASK) printf(", dead track 0%o", addr->tmmr & DTS_MASK); addr->tmmr = RWERR; printf(", read/write errors %b\n", addr->tmmr & RWERR_MASK, RWERR_BITS); addr->tmmr = DRSENSE; printf("drive sense %b, ", addr->tmmr & DRSENSE_MASK, DRSENSE_BITS); printf("fsr %b\n", addr->tmfsr, FSR_BITS); } #endif AVIV bp->b_flags |= B_ERROR; goto opdone; } /* * Advance tape control FSM. */ ignoreerr: switch (state) { case SIO: /* * Read/write increments tape block number */ sc->sc_blkno++; sc->sc_blks++; if (um->um_tab.b_errcnt) sc->sc_softerrs++; goto opdone; case SCOM: /* * For forward/backward space record update current position. */ if (bp == &ctmbuf[TMUNIT(bp->b_dev)]) switch ((int)bp->b_command) { case TM_SFORW: sc->sc_blkno -= bp->b_repcnt; break; case TM_SREV: sc->sc_blkno += bp->b_repcnt; break; } goto opdone; case SSEEK: sc->sc_blkno = bdbtofsb(bp->b_blkno); goto opcont; default: panic("tmintr"); } opdone: /* * Reset error count and remove * from device queue. */ um->um_tab.b_errcnt = 0; dp->b_actf = bp->av_forw; /* * Check resid; watch out for resid >32767 (tmbc not negative). */ bp->b_resid = ((int) -addr->tmbc) & 0xffff; ubadone(um); iodone(bp); /* * Circulate slave to end of controller * queue to give other slaves a chance. */ um->um_tab.b_actf = dp->b_forw; if (dp->b_actf) { dp->b_forw = NULL; if (um->um_tab.b_actf == NULL) um->um_tab.b_actf = dp; else um->um_tab.b_actl->b_forw = dp; um->um_tab.b_actl = dp; } if (um->um_tab.b_actf == 0) return; opcont: tmstart(um); } tmtimer(dev) int dev; { register struct te_softc *sc = &te_softc[TEUNIT(dev)]; register short x; if (sc->sc_timo != INF && (sc->sc_timo -= 5) < 0) { printf("te%d: lost interrupt\n", TEUNIT(dev)); sc->sc_timo = INF; x = spl5(); tmintr(TMUNIT(dev)); (void) splx(x); } timeout(tmtimer, (caddr_t)dev, 5*hz); } tmseteof(bp) register struct buf *bp; { register int teunit = TEUNIT(bp->b_dev); register struct tmdevice *addr = (struct tmdevice *)tedinfo[teunit]->ui_addr; register struct te_softc *sc = &te_softc[teunit]; if (bp == &ctmbuf[TMUNIT(bp->b_dev)]) { if (sc->sc_blkno > bdbtofsb(bp->b_blkno)) { /* reversing */ sc->sc_nxrec = bdbtofsb(bp->b_blkno) - addr->tmbc; sc->sc_blkno = sc->sc_nxrec; } else { /* spacing forward */ sc->sc_blkno = bdbtofsb(bp->b_blkno) + addr->tmbc; sc->sc_nxrec = sc->sc_blkno - 1; } return; } /* eof on read */ sc->sc_nxrec = bdbtofsb(bp->b_blkno); } tmreset(uban) int uban; { register struct uba_ctlr *um; register tm11, teunit; register struct uba_device *ui; register struct buf *dp; for (tm11 = 0; tm11 < NTM; tm11++) { if ((um = tmminfo[tm11]) == 0 || um->um_alive == 0 || um->um_ubanum != uban) continue; printf(" tm%d", tm11); um->um_tab.b_active = 0; um->um_tab.b_actf = um->um_tab.b_actl = 0; if (um->um_ubinfo) { printf("<%d>", (um->um_ubinfo>>28)&0xf); um->um_ubinfo = 0; } ((struct tmdevice *)(um->um_addr))->tmcs = TM_DCLR; for (teunit = 0; teunit < NTE; teunit++) { if ((ui = tedinfo[teunit]) == 0 || ui->ui_mi != um || ui->ui_alive == 0) continue; dp = &teutab[teunit]; dp->b_active = 0; dp->b_forw = 0; if (um->um_tab.b_actf == NULL) um->um_tab.b_actf = dp; else um->um_tab.b_actl->b_forw = dp; um->um_tab.b_actl = dp; if (te_softc[teunit].sc_openf > 0) te_softc[teunit].sc_openf = -1; } tmstart(um); } } /*ARGSUSED*/ tmioctl(dev, cmd, data, flag) caddr_t data; dev_t dev; { int teunit = TEUNIT(dev); register struct te_softc *sc = &te_softc[teunit]; register struct buf *bp = &ctmbuf[TMUNIT(dev)]; register callcount; int fcount, error = 0; struct mtop *mtop; struct mtget *mtget; /* we depend of the values and order of the MT codes here */ static tmops[] = {TM_WEOF,TM_SFORW,TM_SREV,TM_SFORW,TM_SREV,TM_REW,TM_OFFL,TM_SENSE}; switch (cmd) { case MTIOCTOP: /* tape operation */ mtop = (struct mtop *)data; switch (mtop->mt_op) { case MTWEOF: callcount = mtop->mt_count; fcount = 1; break; case MTFSF: case MTBSF: callcount = mtop->mt_count; fcount = INF; break; case MTFSR: case MTBSR: callcount = 1; fcount = mtop->mt_count; break; case MTREW: case MTOFFL: case MTNOP: callcount = 1; fcount = 1; break; default: return (ENXIO); } if (callcount <= 0 || fcount <= 0) return (EINVAL); while (--callcount >= 0) { tmcommand(dev, tmops[mtop->mt_op], fcount); if ((mtop->mt_op == MTFSR || mtop->mt_op == MTBSR) && bp->b_resid) return (EIO); if ((bp->b_flags&B_ERROR) || sc->sc_erreg&TMER_BOT) break; } if (bp->b_flags&B_ERROR) if ((error = bp->b_error)==0) return (EIO); return (error); case MTIOCGET: mtget = (struct mtget *)data; mtget->mt_dsreg = sc->sc_dsreg; mtget->mt_erreg = sc->sc_erreg; mtget->mt_resid = sc->sc_resid; mtget->mt_type = MT_ISTM; break; default: return (ENXIO); } return (0); } #define DBSIZE 20 tmdump() { register struct uba_device *ui; register struct uba_regs *up; register struct tmdevice *addr; int blk, num; int start; start = 0; num = maxfree; #define phys(a,b) ((b)((int)(a)&0x7fffffff)) if (tedinfo[0] == 0) return (ENXIO); ui = phys(tedinfo[0], struct uba_device *); up = phys(ui->ui_hd, struct uba_hd *)->uh_physuba; ubainit(up); DELAY(1000000); addr = (struct tmdevice *)ui->ui_physaddr; tmwait(addr); addr->tmcs = TM_DCLR | TM_GO; while (num > 0) { blk = num > DBSIZE ? DBSIZE : num; tmdwrite(start, blk, addr, up); start += blk; num -= blk; } tmeof(addr); tmeof(addr); tmwait(addr); if (addr->tmcs&TM_ERR) return (EIO); addr->tmcs = TM_REW | TM_GO; tmwait(addr); return (0); } tmdwrite(dbuf, num, addr, up) register dbuf, num; register struct tmdevice *addr; struct uba_regs *up; { register struct pte *io; register int npf; tmwait(addr); io = up->uba_map; npf = num+1; while (--npf != 0) *(int *)io++ = (dbuf++ | (1<tmbc = -(num*NBPG); addr->tmba = 0; addr->tmcs = TM_WCOM | TM_GO; } tmwait(addr) register struct tmdevice *addr; { register s; do s = addr->tmcs; while ((s & TM_CUR) == 0); } tmeof(addr) struct tmdevice *addr; { tmwait(addr); addr->tmcs = TM_WEOF | TM_GO; } #endif