/* * 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. * * @(#)hp.c 7.1 (Berkeley) 6/5/86 */ #ifdef HPDEBUG int hpdebug; #endif #ifdef HPBDEBUG int hpbdebug; #endif #include "hp.h" #if NHP > 0 /* * HP disk driver for RP0x+RMxx+ML11 * * TODO: * see if DCLR and/or RELEASE set attention status */ #include "../machine/pte.h" #include "param.h" #include "systm.h" #include "dk.h" #include "buf.h" #include "conf.h" #include "dir.h" #include "user.h" #include "map.h" #include "../vax/mtpr.h" #include "vm.h" #include "cmap.h" #include "dkbad.h" #include "ioctl.h" #include "uio.h" #include "syslog.h" #include "../vax/dkio.h" #include "mbareg.h" #include "mbavar.h" #include "hpreg.h" /* THIS SHOULD BE READ OFF THE PACK, PER DRIVE */ struct size { daddr_t nblocks; int cyloff; } rp06_sizes[8] = { 15884, 0, /* A=cyl 0 thru 37 */ 33440, 38, /* B=cyl 38 thru 117 */ 340670, 0, /* C=cyl 0 thru 814 */ 15884, 118, /* D=cyl 118 thru 155 */ 55936, 156, /* E=cyl 156 thru 289 */ 219384, 290, /* F=cyl 290 thru 814 */ 291280, 118, /* G=cyl 118 thru 814 */ 0, 0, }, rp05_sizes[8] = { 15884, 0, /* A=cyl 0 thru 37 */ 33440, 38, /* B=cyl 38 thru 117 */ 171798, 0, /* C=cyl 0 thru 410 */ 15884, 118, /* D=cyl 118 thru 155 */ 55936, 156, /* E=cyl 156 thru 289 */ 50512, 290, /* F=cyl 290 thru 410 */ 122408, 118, /* G=cyl 118 thru 410 */ 0, 0, }, rm03_sizes[8] = { 15884, 0, /* A=cyl 0 thru 99 */ 33440, 100, /* B=cyl 100 thru 308 */ 131680, 0, /* C=cyl 0 thru 822 */ 15884, 309, /* D=cyl 309 thru 408 */ 55936, 409, /* E=cyl 409 thru 758 */ 10144, 759, /* F=cyl 759 thru 822 */ 82144, 309, /* G=cyl 309 thru 822 */ 0, 0, }, rm05_sizes[8] = { 15884, 0, /* A=cyl 0 thru 26 */ 33440, 27, /* B=cyl 27 thru 81 */ 500384, 0, /* C=cyl 0 thru 822 */ 15884, 562, /* D=cyl 562 thru 588 */ 55936, 589, /* E=cyl 589 thru 680 */ 86240, 681, /* F=cyl 681 thru 822 */ 158592, 562, /* G=cyl 562 thru 822 */ 291346, 82, /* H=cyl 82 thru 561 */ }, rm80_sizes[8] = { 15884, 0, /* A=cyl 0 thru 36 */ 33440, 37, /* B=cyl 37 thru 114 */ 242606, 0, /* C=cyl 0 thru 558 */ 15884, 115, /* D=cyl 115 thru 151 */ 55936, 152, /* E=cyl 152 thru 280 */ 120559, 281, /* F=cyl 281 thru 558 */ 192603, 115, /* G=cyl 115 thru 558 */ 0, 0, }, rp07_sizes[8] = { 15884, 0, /* A=cyl 0 thru 9 */ 66880, 10, /* B=cyl 10 thru 51 */ 1008000, 0, /* C=cyl 0 thru 629 */ 15884, 235, /* D=cyl 235 thru 244 */ 307200, 245, /* E=cyl 245 thru 436 */ 308650, 437, /* F=cyl 437 thru 629 */ 631850, 235, /* G=cyl 235 thru 629 */ 291346, 52, /* H=cyl 52 thru 234 */ }, cdc9775_sizes[8] = { 15884, 0, /* A=cyl 0 thru 12 */ 66880, 13, /* B=cyl 13 thru 65 */ 1077760, 0, /* C=cyl 0 thru 841 */ 15884, 294, /* D=cyl 294 thru 306 */ 307200, 307, /* E=cyl 307 thru 546 */ 377440, 547, /* F=cyl 547 thru 841 */ 701280, 294, /* G=cyl 294 thru 841 */ 291346, 66, /* H=cyl 66 thru 293 */ }, cdc9730_sizes[8] = { 15884, 0, /* A=cyl 0 thru 49 */ 33440, 50, /* B=cyl 50 thru 154 */ 263360, 0, /* C=cyl 0 thru 822 */ 15884, 155, /* D=cyl 155 thru 204 */ 55936, 205, /* E=cyl 205 thru 379 */ 141664, 380, /* F=cyl 380 thru 822 */ 213664, 155, /* G=cyl 155 thru 822 */ 0, 0, }, capricorn_sizes[8] = { 15884, 0, /* A=cyl 0 thru 31 */ 33440, 32, /* B=cyl 32 thru 97 */ 524288, 0, /* C=cyl 0 thru 1023 */ 15884, 668, /* D=cyl 668 thru 699 */ 55936, 700, /* E=cyl 700 thru 809 */ 109472, 810, /* F=cyl 810 thru 1023 */ 182176, 668, /* G=cyl 668 thru 1023 */ 291346, 98, /* H=cyl 98 thru 667 */ }, eagle_sizes[8] = { 15884, 0, /* A=cyl 0 thru 16 */ 66880, 17, /* B=cyl 17 thru 86 */ 808320, 0, /* C=cyl 0 thru 841 */ 15884, 391, /* D=cyl 391 thru 407 */ 307200, 408, /* E=cyl 408 thru 727 */ 109296, 728, /* F=cyl 728 thru 841 */ 432816, 391, /* G=cyl 391 thru 841 */ 291346, 87, /* H=cyl 87 thru 390 */ }, ampex_sizes[8] = { 15884, 0, /* A=cyl 0 thru 26 */ 33440, 27, /* B=cyl 27 thru 81 */ 495520, 0, /* C=cyl 0 thru 814 */ 15884, 562, /* D=cyl 562 thru 588 */ 55936, 589, /* E=cyl 589 thru 680 */ 81312, 681, /* F=cyl 681 thru 814 */ 153664, 562, /* G=cyl 562 thru 814 */ 291346, 82, /* H=cyl 82 thru 561 */ }, fj2361_sizes[8] = { 15884, 0, /* A=cyl 0 thru 12 */ 66880, 13, /* B=cyl 13 thru 65 */ 1077760, 0, /* C=cyl 0 thru 841 */ 15884, 294, /* D=cyl 294 thru 306 */ 307200, 307, /* E=cyl 307 thru 546 */ 377408, 547, /* F=cyl 547 thru 841 */ 701248, 294, /* G=cyl 294 thru 841 */ 291346, 66, /* H=cyl 66 thru 293 */ }; /* END OF STUFF WHICH SHOULD BE READ IN PER DISK */ /* * Table for converting Massbus drive types into * indices into the partition tables. Slots are * left for those drives divined from other means * (e.g. SI, AMPEX, etc.). */ short hptypes[] = { #define HPDT_RM03 0 MBDT_RM03, #define HPDT_RM05 1 MBDT_RM05, #define HPDT_RP06 2 MBDT_RP06, #define HPDT_RM80 3 MBDT_RM80, #define HPDT_RP04 4 MBDT_RP04, #define HPDT_RP05 5 MBDT_RP05, #define HPDT_RP07 6 MBDT_RP07, #define HPDT_ML11A 7 MBDT_ML11A, #define HPDT_ML11B 8 MBDT_ML11B, #define HPDT_9775 9 -1, #define HPDT_9730 10 -1, #define HPDT_CAPRICORN 11 -1, #define HPDT_EAGLE 12 -1, #define HPDT_9300 13 -1, #define HPDT_RM02 14 MBDT_RM02, /* beware, actually mapped */ #define HPDT_2361 15 -1, 0 }; struct mba_device *hpinfo[NHP]; int hpattach(),hpustart(),hpstart(),hpdtint(); struct mba_driver hpdriver = { hpattach, 0, hpustart, hpstart, hpdtint, 0, hptypes, "hp", 0, hpinfo }; /* * These variable are all measured in sectors. * Sdist is how much to "lead" in the search for a desired sector * (i.e. if want N, search for N-sdist.) * Maxdist and mindist define the region right before our desired sector within * which we don't bother searching. We don't search when we are already less * then maxdist and more than mindist sectors "before" our desired sector. * Maxdist should be >= sdist. * * Beware, sdist, mindist and maxdist are not well tuned * for many of the drives listed in this table. * Try patching things with something i/o intensive * running and watch iostat. */ struct hpst { short nsect; /* # sectors/track */ short ntrak; /* # tracks/cylinder */ short nspc; /* # sector/cylinders */ short ncyl; /* # cylinders */ struct size *sizes; /* partition tables */ short sdist; /* seek distance metric */ short maxdist; /* boundaries of non-searched area */ short mindist; /* preceding the target sector */ char *name; /* name of disk type */ } hpst[] = { { 32, 5, 32*5, 823, rm03_sizes, 7, 4, 1, "RM03" }, { 32, 19, 32*19, 823, rm05_sizes, 7, 4, 1, "RM05" }, { 22,19, 22*19, 815, rp06_sizes, 7, 4, 1, "RP06"}, { 31, 14, 31*14, 559, rm80_sizes, 7, 4, 1, "RM80"}, { 22, 19, 22*19, 411, rp05_sizes, 7, 4, 1, "RP04"}, { 22, 19, 22*19, 411, rp05_sizes, 7, 4, 1, "RP05"}, { 50, 32, 50*32, 630, rp07_sizes, 15, 8, 3, "RP07"}, { 1, 1, 1, 1, 0, 0, 0, 0, "ML11A"}, { 1, 1, 1, 1, 0, 0, 0, 0, "ML11B" }, { 32, 40, 32*40, 843, cdc9775_sizes, 7, 4, 1, "9775" }, { 32, 10, 32*10, 823, cdc9730_sizes, 7, 4, 1, "9730-160" }, { 32, 16, 32*16, 1024, capricorn_sizes,10,4, 3, "capricorn" }, { 48, 20, 48*20, 842, eagle_sizes, 15, 8, 3, "eagle" }, { 32, 19, 32*19, 815, ampex_sizes, 7, 4, 1, "9300" }, { 64, 20, 64*20, 842, fj2361_sizes, 15, 8, 3, "2361" }, }; u_char hp_offset[16] = { HPOF_P400, HPOF_M400, HPOF_P400, HPOF_M400, HPOF_P800, HPOF_M800, HPOF_P800, HPOF_M800, HPOF_P1200, HPOF_M1200, HPOF_P1200, HPOF_M1200, 0, 0, 0, 0, }; struct buf rhpbuf[NHP]; struct buf bhpbuf[NHP]; struct dkbad hpbad[NHP]; struct hpsoftc { u_char sc_hpinit; /* drive initialized */ u_char sc_recal; /* recalibrate state */ u_char sc_hdr; /* next i/o includes header */ u_char sc_doseeks; /* perform explicit seeks */ daddr_t sc_mlsize; /* ML11 size */ int sc_blkdone; /* amount sucessfully transfered */ daddr_t sc_badbn; /* replacement block number */ } hpsoftc[NHP]; #define b_cylin b_resid /* #define ML11 0 to remove ML11 support */ #define ML11 (hptypes[mi->mi_type] == MBDT_ML11A) #define RP06 (hptypes[mi->mi_type] <= MBDT_RP06) #define RM80 (hptypes[mi->mi_type] == MBDT_RM80) #define hpunit(dev) (minor(dev) >> 3) #define MASKREG(reg) ((reg)&0xffff) #ifdef lint #define HPWAIT(mi, addr) (hpwait(mi)) #else #define HPWAIT(mi, addr) (((addr)->hpds & HPDS_DRY) || hpwait(mi)) #endif /*ARGSUSED*/ hpattach(mi, slave) register struct mba_device *mi; { mi->mi_type = hpmaptype(mi); if (!ML11 && mi->mi_dk >= 0) { struct hpst *st = &hpst[mi->mi_type]; dk_mspw[mi->mi_dk] = 1.0 / 60 / (st->nsect * 256); } } /* * Map apparent MASSBUS drive type into manufacturer * specific configuration. For SI controllers this is done * based on codes in the serial number register. For * EMULEX controllers, the track and sector attributes are * used when the drive type is an RM02 (not supported by DEC). */ hpmaptype(mi) register struct mba_device *mi; { register struct hpdevice *hpaddr = (struct hpdevice *)mi->mi_drv; register int type = mi->mi_type; /* * Model-byte processing for SI controllers. * NB: Only deals with RM03 and RM05 emulations. */ if (type == HPDT_RM03 || type == HPDT_RM05) { int hpsn = hpaddr->hpsn; if ((hpsn & SIMB_LU) != mi->mi_drive) return (type); switch ((hpsn & SIMB_MB) & ~(SIMB_S6|SIRM03|SIRM05)) { case SI9775D: printf("hp%d: 9775 (direct)\n", mi->mi_unit); type = HPDT_9775; break; case SI9730D: printf("hp%d: 9730 (direct)\n", mi->mi_unit); type = HPDT_9730; break; case SI9766: printf("hp%d: 9766\n", mi->mi_unit); type = HPDT_RM05; break; case SI9762: printf("hp%d: 9762\n", mi->mi_unit); type = HPDT_RM03; break; case SICAPD: printf("hp%d: capricorn\n", mi->mi_unit); type = HPDT_CAPRICORN; break; case SI9751D: printf("hp%d: eagle\n", mi->mi_unit); type = HPDT_EAGLE; break; } return (type); } /* * EMULEX SC750 or SC780. Poke the holding register. */ if (type == HPDT_RM02) { int nsectors, ntracks, ncyl; hpaddr->hpof = HPOF_FMT22; mbclrattn(mi); hpaddr->hpcs1 = HP_NOP; hpaddr->hphr = HPHR_MAXTRAK; ntracks = MASKREG(hpaddr->hphr) + 1; DELAY(100); hpaddr->hpcs1 = HP_NOP; hpaddr->hphr = HPHR_MAXSECT; nsectors = MASKREG(hpaddr->hphr) + 1; DELAY(100); hpaddr->hpcs1 = HP_NOP; hpaddr->hphr = HPHR_MAXCYL; ncyl = MASKREG(hpaddr->hphr) + 1; for (type = 0; hptypes[type] != 0; type++) if (hpst[type].nsect == nsectors && hpst[type].ntrak == ntracks && hpst[type].ncyl == ncyl) break; if (hptypes[type] == 0) { printf("hp%d: %d sectors, %d tracks, %d cylinders: unknown device\n", mi->mi_unit, nsectors, ntracks, ncyl); type = HPDT_RM02; } printf("hp%d: %s\n", mi->mi_unit, hpst[type].name); hpaddr->hpcs1 = HP_DCLR|HP_GO; mbclrattn(mi); /* conservative */ return (type); } /* * Map all ML11's to the same type. Also calculate * transfer rates based on device characteristics. */ if (type == HPDT_ML11A || type == HPDT_ML11B) { register struct hpsoftc *sc = &hpsoftc[mi->mi_unit]; register int trt; sc->sc_mlsize = hpaddr->hpmr & HPMR_SZ; if ((hpaddr->hpmr & HPMR_ARRTYP) == 0) sc->sc_mlsize >>= 2; if (mi->mi_dk >= 0) { trt = (hpaddr->hpmr & HPMR_TRT) >> 8; dk_mspw[mi->mi_dk] = 1.0 / (1<<(20-trt)); } type = HPDT_ML11A; } return (type); } hpopen(dev) dev_t dev; { register int unit = hpunit(dev); register struct mba_device *mi; if (unit >= NHP || (mi = hpinfo[unit]) == 0 || mi->mi_alive == 0) return (ENXIO); return (0); } hpstrategy(bp) register struct buf *bp; { register struct mba_device *mi; register struct hpst *st; register int unit; long sz; int xunit = minor(bp->b_dev) & 07; int s; sz = bp->b_bcount; sz = (sz+511) >> 9; unit = hpunit(bp->b_dev); if (unit >= NHP) { bp->b_error = ENXIO; goto bad; } mi = hpinfo[unit]; if (mi == 0 || mi->mi_alive == 0) { bp->b_error = ENXIO; goto bad; } st = &hpst[mi->mi_type]; if (ML11) { struct hpsoftc *sc = &hpsoftc[unit]; if (bp->b_blkno < 0 || bp->b_blkno+sz > sc->sc_mlsize) { if (bp->b_blkno == sc->sc_mlsize) { bp->b_resid = bp->b_bcount; goto done; } bp->b_error = EINVAL; goto bad; } bp->b_cylin = 0; } else { if (bp->b_blkno < 0 || bp->b_blkno+sz > st->sizes[xunit].nblocks) { if (bp->b_blkno == st->sizes[xunit].nblocks) { bp->b_resid = bp->b_bcount; goto done; } bp->b_error = EINVAL; goto bad; } bp->b_cylin = bp->b_blkno/st->nspc + st->sizes[xunit].cyloff; } s = spl5(); disksort(&mi->mi_tab, bp); if (mi->mi_tab.b_active == 0) mbustart(mi); splx(s); return; bad: bp->b_flags |= B_ERROR; done: iodone(bp); return; } hpustart(mi) register struct mba_device *mi; { register struct hpdevice *hpaddr = (struct hpdevice *)mi->mi_drv; register struct buf *bp = mi->mi_tab.b_actf; register struct hpst *st; struct hpsoftc *sc = &hpsoftc[mi->mi_unit]; daddr_t bn; int sn, tn, dist; st = &hpst[mi->mi_type]; hpaddr->hpcs1 = 0; if ((hpaddr->hpcs1&HP_DVA) == 0) return (MBU_BUSY); switch (sc->sc_recal) { case 1: (void)HPWAIT(mi, hpaddr); hpaddr->hpdc = bp->b_cylin; hpaddr->hpcs1 = HP_SEEK|HP_GO; sc->sc_recal++; return (MBU_STARTED); case 2: break; } sc->sc_recal = 0; if ((hpaddr->hpds & HPDS_VV) == 0 || !sc->sc_hpinit) { struct buf *bbp = &bhpbuf[mi->mi_unit]; sc->sc_hpinit = 1; hpaddr->hpcs1 = HP_DCLR|HP_GO; if (mi->mi_mba->mba_drv[0].mbd_as & (1<mi_drive)) printf("DCLR attn\n"); hpaddr->hpcs1 = HP_PRESET|HP_GO; if (!ML11) hpaddr->hpof = HPOF_FMT22; mbclrattn(mi); if (!ML11) { bbp->b_flags = B_READ|B_BUSY; bbp->b_dev = bp->b_dev; bbp->b_bcount = 512; bbp->b_un.b_addr = (caddr_t)&hpbad[mi->mi_unit]; bbp->b_blkno = st->ncyl*st->nspc - st->nsect; bbp->b_cylin = st->ncyl - 1; mi->mi_tab.b_actf = bbp; bbp->av_forw = bp; bp = bbp; } } if (mi->mi_tab.b_active || mi->mi_hd->mh_ndrive == 1) { if (mi->mi_tab.b_errcnt >= 16 && (bp->b_flags & B_READ)) { hpaddr->hpof = hp_offset[mi->mi_tab.b_errcnt & 017]|HPOF_FMT22; hpaddr->hpcs1 = HP_OFFSET|HP_GO; (void)HPWAIT(mi, hpaddr); mbclrattn(mi); } return (MBU_DODATA); } if (ML11) return (MBU_DODATA); if ((hpaddr->hpds & HPDS_DREADY) != HPDS_DREADY) return (MBU_DODATA); bn = bp->b_blkno; sn = bn % st->nspc; tn = sn / st->nsect; sn = sn % st->nsect; if (bp->b_cylin == MASKREG(hpaddr->hpdc)) { if (sc->sc_doseeks) return (MBU_DODATA); dist = sn - (MASKREG(hpaddr->hpla) >> 6) - 1; if (dist < 0) dist += st->nsect; if (dist > st->maxdist || dist < st->mindist) return (MBU_DODATA); } else hpaddr->hpdc = bp->b_cylin; if (sc->sc_doseeks) hpaddr->hpcs1 = HP_SEEK|HP_GO; else { sn = (sn + st->nsect - st->sdist) % st->nsect; hpaddr->hpda = (tn << 8) + sn; hpaddr->hpcs1 = HP_SEARCH|HP_GO; } return (MBU_STARTED); } hpstart(mi) register struct mba_device *mi; { register struct hpdevice *hpaddr = (struct hpdevice *)mi->mi_drv; register struct buf *bp = mi->mi_tab.b_actf; register struct hpst *st = &hpst[mi->mi_type]; struct hpsoftc *sc = &hpsoftc[mi->mi_unit]; daddr_t bn; int sn, tn, cn; if (ML11) hpaddr->hpda = bp->b_blkno + sc->sc_blkdone; else { if (bp->b_flags & B_BAD) { bn = sc->sc_badbn; cn = bn / st->nspc; } else { bn = bp->b_blkno; cn = bp->b_cylin; } sn = bn % st->nspc; if ((bp->b_flags & B_BAD) == 0) sn += sc->sc_blkdone; tn = sn / st->nsect; sn %= st->nsect; cn += tn / st->ntrak; tn %= st->ntrak; hpaddr->hpda = (tn << 8) + sn; hpaddr->hpdc = cn; } mi->mi_tab.b_bdone = dbtob(sc->sc_blkdone); if (sc->sc_hdr) { if (bp->b_flags & B_READ) return (HP_RHDR|HP_GO); else return (HP_WHDR|HP_GO); } return (0); } hpdtint(mi, mbsr) register struct mba_device *mi; int mbsr; { register struct hpdevice *hpaddr = (struct hpdevice *)mi->mi_drv; register struct buf *bp = mi->mi_tab.b_actf; register int er1, er2; struct hpsoftc *sc = &hpsoftc[mi->mi_unit]; int retry = 0; int npf; daddr_t bn; int bcr; bcr = MASKREG(-mi->mi_mba->mba_bcr); if (hpaddr->hpds&HPDS_ERR || mbsr&MBSR_EBITS) { er1 = hpaddr->hper1; er2 = hpaddr->hper2; if (bp->b_flags & B_BAD) { npf = bp->b_error; bn = sc->sc_badbn; } else { npf = btop(bp->b_bcount - bcr); if (er1 & (HPER1_DCK | HPER1_ECH)) npf--; bn = bp->b_blkno + npf; } if (HPWAIT(mi, hpaddr) == 0) goto hard; #ifdef HPDEBUG if (hpdebug) { int dc = hpaddr->hpdc, da = hpaddr->hpda; log(LOG_DEBUG, "hperr: bp %x cyl %d blk %d blkdone %d as %o dc %x da %x\n", bp, bp->b_cylin, bn, sc->sc_blkdone, hpaddr->hpas&0xff, MASKREG(dc), MASKREG(da)); log(LOG_DEBUG, "errcnt %d mbsr=%b er1=%b er2=%b bcr -%d\n", mi->mi_tab.b_errcnt, mbsr, mbsr_bits, MASKREG(er1), HPER1_BITS, MASKREG(er2), HPER2_BITS, bcr); } #endif if (er1 & HPER1_HCRC) { er1 &= ~(HPER1_HCE|HPER1_FER); er2 &= ~HPER2_BSE; } if (er1 & HPER1_WLE) { log(LOG_WARNING, "hp%d: write locked\n", hpunit(bp->b_dev)); bp->b_flags |= B_ERROR; } else if (sc->sc_hdr) { goto hard; } else if (RM80 && er2&HPER2_SSE) { (void) hpecc(mi, SSE); return (MBD_RESTARTED); } else if ((er2 & HPER2_BSE) && !ML11) { if (hpecc(mi, BSE)) return (MBD_RESTARTED); goto hard; } else if (MASKREG(er1) == HPER1_FER && RP06) { if (hpecc(mi, BSE)) return (MBD_RESTARTED); goto hard; } else if ((er1 & (HPER1_DCK | HPER1_ECH)) == HPER1_DCK && mi->mi_tab.b_errcnt >= 3) { if (hpecc(mi, ECC)) return (MBD_RESTARTED); /* * ECC corrected. Only log retries below * if we got errors other than soft ECC * (as indicated by additional retries). */ if (mi->mi_tab.b_errcnt == 3) mi->mi_tab.b_errcnt = 0; } else if ((er1 & HPER1_HCRC) && !ML11 && hpecc(mi, BSE)) { /* * HCRC means the header is screwed up and the sector * might well exist in the bad sector table, * better check.... */ return (MBD_RESTARTED); } else if (++mi->mi_tab.b_errcnt > 27 || (ML11 && mi->mi_tab.b_errcnt > 15) || mbsr & MBSR_HARD || er1 & HPER1_HARD || (!ML11 && (er2 & HPER2_HARD))) { hard: bp->b_blkno = bn; /* XXX */ harderr(bp, "hp"); if (mbsr & (MBSR_EBITS &~ (MBSR_DTABT|MBSR_MBEXC))) printf("mbsr=%b ", mbsr, mbsr_bits); printf("er1=%b er2=%b", MASKREG(hpaddr->hper1), HPER1_BITS, MASKREG(hpaddr->hper2), HPER2_BITS); if (sc->sc_hdr) printf(" (hdr i/o)"); printf("\n"); bp->b_flags |= B_ERROR; bp->b_flags &= ~B_BAD; } else retry = 1; hpaddr->hpcs1 = HP_DCLR|HP_GO; if (retry && (mi->mi_tab.b_errcnt & 07) == 4) { hpaddr->hpcs1 = HP_RECAL|HP_GO; sc->sc_recal = 1; return (MBD_REPOSITION); } } #ifdef HPDEBUG else if (hpdebug && sc->sc_recal) { log(LOG_DEBUG, "recal %d errcnt %d mbsr=%b er1=%b er2=%b\n", sc->sc_recal, mi->mi_tab.b_errcnt, mbsr, mbsr_bits, hpaddr->hper1, HPER1_BITS, hpaddr->hper2, HPER2_BITS); } #endif (void)HPWAIT(mi, hpaddr); if (retry) return (MBD_RETRY); if (mi->mi_tab.b_errcnt >= 16) { /* * This is fast and occurs rarely; we don't * bother with interrupts. */ hpaddr->hpcs1 = HP_RTC|HP_GO; (void)HPWAIT(mi, hpaddr); mbclrattn(mi); } if (mi->mi_tab.b_errcnt && (bp->b_flags & B_ERROR) == 0) log(LOG_INFO, "hp%d%c: %d retries %sing sn%d\n", hpunit(bp->b_dev), 'a'+(minor(bp->b_dev)&07), mi->mi_tab.b_errcnt, (bp->b_flags & B_READ) ? "read" : "writ", (bp->b_flags & B_BAD) ? sc->sc_badbn : bp->b_blkno + sc->sc_blkdone); if ((bp->b_flags & B_BAD) && hpecc(mi, CONT)) return (MBD_RESTARTED); sc->sc_hdr = 0; sc->sc_blkdone = 0; bp->b_resid = bcr; if (!ML11) { hpaddr->hpof = HPOF_FMT22; hpaddr->hpcs1 = HP_RELEASE|HP_GO; } return (MBD_DONE); } /* * Wait (for a bit) for a drive to come ready; * returns nonzero on success. */ hpwait(mi) register struct mba_device *mi; { register struct hpdevice *hpaddr = (struct hpdevice *)mi->mi_drv; register i = 100000; while ((hpaddr->hpds & HPDS_DRY) == 0 && --i) DELAY(10); if (i == 0) printf("hp%d: intr, not ready\n", mi->mi_unit); return (i); } hpread(dev, uio) dev_t dev; struct uio *uio; { register int unit = hpunit(dev); if (unit >= NHP) return (ENXIO); return (physio(hpstrategy, &rhpbuf[unit], dev, B_READ, minphys, uio)); } hpwrite(dev, uio) dev_t dev; struct uio *uio; { register int unit = hpunit(dev); if (unit >= NHP) return (ENXIO); return (physio(hpstrategy, &rhpbuf[unit], dev, B_WRITE, minphys, uio)); } /*ARGSUSED*/ hpioctl(dev, cmd, data, flag) dev_t dev; int cmd; caddr_t data; int flag; { switch (cmd) { case DKIOCHDR: /* do header read/write */ hpsoftc[hpunit(dev)].sc_hdr = 1; return (0); default: return (ENXIO); } } hpecc(mi, flag) register struct mba_device *mi; int flag; { register struct mba_regs *mbp = mi->mi_mba; register struct hpdevice *rp = (struct hpdevice *)mi->mi_drv; register struct buf *bp = mi->mi_tab.b_actf; register struct hpst *st = &hpst[mi->mi_type]; struct hpsoftc *sc = &hpsoftc[mi->mi_unit]; int npf, o; int bn, cn, tn, sn; int bcr; bcr = MASKREG(-mbp->mba_bcr); if (bp->b_flags & B_BAD) npf = bp->b_error; else { npf = bp->b_bcount - bcr; /* * Watch out for fractional sector at end of transfer; * want to round up if finished, otherwise round down. */ if (bcr == 0) npf += 511; npf = btodb(npf); } o = (int)bp->b_un.b_addr & PGOFSET; bn = bp->b_blkno; cn = bp->b_cylin; sn = bn%(st->nspc) + npf; tn = sn/st->nsect; sn %= st->nsect; cn += tn/st->ntrak; tn %= st->ntrak; bn += npf; switch (flag) { case ECC: { register int i; caddr_t addr; struct pte mpte; int bit, byte, mask; npf--; /* because block in error is previous block */ bn--; if (bp->b_flags & B_BAD) bn = sc->sc_badbn; log(LOG_WARNING, "hp%d%c: soft ecc sn%d\n", hpunit(bp->b_dev), 'a'+(minor(bp->b_dev)&07), bn); mask = MASKREG(rp->hpec2); i = MASKREG(rp->hpec1) - 1; /* -1 makes 0 origin */ bit = i&07; i = (i&~07)>>3; byte = i + o; while (i < 512 && (int)dbtob(npf)+i < bp->b_bcount && bit > -11) { mpte = mbp->mba_map[npf+btop(byte)]; addr = ptob(mpte.pg_pfnum) + (byte & PGOFSET); putmemc(addr, getmemc(addr)^(mask<hpof |= HPOF_SSEI; if (bp->b_flags & B_BAD) { bn = sc->sc_badbn; goto fixregs; } mbp->mba_bcr = -(bp->b_bcount - (int)ptob(npf)); break; case BSE: if (rp->hpof & HPOF_SSEI) sn++; #ifdef HPBDEBUG if (hpbdebug) log(LOG_DEBUG, "hpecc, BSE: bn %d cn %d tn %d sn %d\n", bn, cn, tn, sn); #endif if (bp->b_flags & B_BAD) return (0); if ((bn = isbad(&hpbad[mi->mi_unit], cn, tn, sn)) < 0) return (0); bp->b_flags |= B_BAD; bp->b_error = npf + 1; rp->hpof &= ~HPOF_SSEI; bn = st->ncyl*st->nspc - st->nsect - 1 - bn; sc->sc_badbn = bn; fixregs: cn = bn/st->nspc; sn = bn%st->nspc; tn = sn/st->nsect; sn %= st->nsect; bcr = bp->b_bcount - (int)ptob(npf); bcr = MIN(bcr, 512); mbp->mba_bcr = -bcr; #ifdef HPBDEBUG if (hpbdebug) log(LOG_DEBUG, "revector to cn %d tn %d sn %d\n", cn, tn, sn); #endif break; case CONT: #ifdef HPBDEBUG if (hpbdebug) log(LOG_DEBUG, "hpecc, CONT: bn %d cn %d tn %d sn %d\n", bn,cn,tn,sn); #endif bp->b_flags &= ~B_BAD; if ((int)ptob(npf) >= bp->b_bcount) return (0); mbp->mba_bcr = -(bp->b_bcount - (int)ptob(npf)); break; } rp->hpcs1 = HP_DCLR|HP_GO; if (rp->hpof & HPOF_SSEI) sn++; rp->hpdc = cn; rp->hpda = (tn<<8) + sn; mbp->mba_sr = -1; mbp->mba_var = (int)ptob(npf) + o; rp->hpcs1 = bp->b_flags&B_READ ? HP_RCOM|HP_GO : HP_WCOM|HP_GO; mi->mi_tab.b_errcnt = 0; /* error has been corrected */ sc->sc_blkdone = npf; return (1); } #define DBSIZE 20 hpdump(dev) dev_t dev; { register struct mba_device *mi; register struct mba_regs *mba; struct hpdevice *hpaddr; char *start; int num, unit; register struct hpst *st; num = maxfree; start = 0; unit = hpunit(dev); if (unit >= NHP) return (ENXIO); #define phys(a,b) ((b)((int)(a)&0x7fffffff)) mi = phys(hpinfo[unit],struct mba_device *); if (mi == 0 || mi->mi_alive == 0) return (ENXIO); mba = phys(mi->mi_hd, struct mba_hd *)->mh_physmba; mba->mba_cr = MBCR_INIT; hpaddr = (struct hpdevice *)&mba->mba_drv[mi->mi_drive]; if ((hpaddr->hpds & HPDS_VV) == 0) { hpaddr->hpcs1 = HP_DCLR|HP_GO; hpaddr->hpcs1 = HP_PRESET|HP_GO; hpaddr->hpof = HPOF_FMT22; } st = &hpst[mi->mi_type]; if (dumplo < 0) return (EINVAL); if (dumplo + num >= st->sizes[minor(dev)&07].nblocks) num = st->sizes[minor(dev)&07].nblocks - dumplo; while (num > 0) { register struct pte *hpte = mba->mba_map; register int i; int blk, cn, sn, tn; daddr_t bn; blk = num > DBSIZE ? DBSIZE : num; bn = dumplo + btop(start); cn = bn/st->nspc + st->sizes[minor(dev)&07].cyloff; sn = bn%st->nspc; tn = sn/st->nsect; sn = sn%st->nsect; hpaddr->hpdc = cn; hpaddr->hpda = (tn << 8) + sn; for (i = 0; i < blk; i++) *(int *)hpte++ = (btop(start)+i) | PG_V; mba->mba_sr = -1; mba->mba_bcr = -(blk*NBPG); mba->mba_var = 0; hpaddr->hpcs1 = HP_WCOM | HP_GO; while ((hpaddr->hpds & HPDS_DRY) == 0) DELAY(10); if (hpaddr->hpds&HPDS_ERR) return (EIO); start += blk*NBPG; num -= blk; } return (0); } hpsize(dev) dev_t dev; { int unit = hpunit(dev); struct mba_device *mi; struct hpst *st; if (unit >= NHP || (mi = hpinfo[unit]) == 0 || mi->mi_alive == 0) return (-1); st = &hpst[mi->mi_type]; return ((int)st->sizes[minor(dev) & 07].nblocks); } #endif