/* hp.c 4.21 81/03/03 */ #include "hp.h" #if NHP > 0 /* * HP disk driver for RP0x+RM0x * * TODO: * Check out handling of spun-down drives and write lock * Check RM80 skip sector handling, esp when ECC's occur later * Add reading of bad sector information and disk layout from sector 1 * Add bad sector forwarding code * Check interaction with tape driver on same mba * Check multiple drive handling */ #include "../h/param.h" #include "../h/systm.h" #include "../h/dk.h" #include "../h/buf.h" #include "../h/conf.h" #include "../h/dir.h" #include "../h/user.h" #include "../h/map.h" #include "../h/pte.h" #include "../h/mba.h" #include "../h/mtpr.h" #include "../h/vm.h" #include "../h/cmap.h" #include "../h/hpreg.h" /* THIS SHOULD BE READ OFF THE PACK, PER DRIVE */ struct size { daddr_t nblocks; int cyloff; } hp_sizes[8] = { 15884, 0, /* A=cyl 0 thru 37 */ 33440, 38, /* B=cyl 38 thru 117 */ 340670, 0, /* C=cyl 0 thru 814 */ 0, 0, 0, 0, 0, 0, 291346, 118, /* G=cyl 118 thru 814 */ 0, 0, }, rm_sizes[8] = { 15884, 0, /* A=cyl 0 thru 99 */ 33440, 100, /* B=cyl 100 thru 309 */ 131680, 0, /* C=cyl 0 thru 822 */ 2720, 291, 0, 0, 0, 0, 82080, 310, /* G=cyl 310 thru 822 */ 0, 0, }, rm5_sizes[8] = { 15884, 0, /* A=cyl 0 thru 26 */ 33440, 27, /* B=cyl 27 thru 81 */ 500992, 0, /* C=cyl 0 thru 823 */ 15884, 562, /* D=cyl 562 thru 588 */ 55936, 589, /* E=cyl 589 thru 680 */ 86944, 681, /* F=cyl 681 thru 823 */ 159296, 562, /* G=cyl 562 thru 823 */ 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 */ 0, 0, 0, 0, 0, 0, 82080, 115, /* G=cyl 115 thru 304 */ 110236, 305, /* H=cyl 305 thru 558 */ }; /* END OF STUFF WHICH SHOULD BE READ IN PER DISK */ #define _hpSDIST 2 #define _hpRDIST 3 int hpSDIST = _hpSDIST; int hpRDIST = _hpRDIST; short hptypes[] = { MBDT_RM03, MBDT_RM05, MBDT_RP06, MBDT_RM80, 0 }; struct mba_info *hpinfo[NHP]; int hpdkinit(),hpustart(),hpstart(),hpdtint(); struct mba_driver hpdriver = { hpdkinit, hpustart, hpstart, hpdtint, 0, hptypes, hpinfo }; struct hpst { short nsect; short ntrak; short nspc; short ncyl; struct size *sizes; } hpst[] = { 32, 5, 32*5, 823, rm_sizes, /* RM03 */ 32, 19, 32*19, 823, rm5_sizes, /* RM05 */ 22, 19, 22*19, 815, hp_sizes, /* RP06 */ 31, 14, 31*14, 559, rm80_sizes /* RM80 */ }; u_char hp_offset[16] = { HP_P400, HP_M400, HP_P400, HP_M400, HP_P800, HP_M800, HP_P800, HP_M800, HP_P1200, HP_M1200, HP_P1200, HP_M1200, 0, 0, 0, 0, }; struct buf rhpbuf[NHP]; char hprecal[NHP]; #define b_cylin b_resid #ifdef INTRLVE daddr_t dkblock(); #endif int hpseek; hpdkinit(mi) struct mba_info *mi; { register struct hpst *st = &hpst[mi->mi_type]; if (mi->mi_dk >= 0) dk_mspw[mi->mi_dk] = 1.0 / 60 / (st->nsect * 256); } hpstrategy(bp) register struct buf *bp; { register struct mba_info *mi; register struct hpst *st; register int unit; long sz, bn; int xunit = minor(bp->b_dev) & 07; sz = bp->b_bcount; sz = (sz+511) >> 9; unit = dkunit(bp); if (unit >= NHP) goto bad; mi = hpinfo[unit]; if (mi == 0 || mi->mi_alive == 0) goto bad; st = &hpst[mi->mi_type]; if (bp->b_blkno < 0 || (bn = dkblock(bp))+sz > st->sizes[xunit].nblocks) goto bad; bp->b_cylin = bn/st->nspc + st->sizes[xunit].cyloff; (void) spl5(); disksort(&mi->mi_tab, bp); if (mi->mi_tab.b_active == 0) mbustart(mi); (void) spl0(); return; bad: bp->b_flags |= B_ERROR; iodone(bp); return; } hpustart(mi) register struct mba_info *mi; { register struct hpdevice *hpaddr = (struct hpdevice *)mi->mi_drv; register struct buf *bp = mi->mi_tab.b_actf; register struct hpst *st; daddr_t bn; int sn, dist, flags; if ((hpaddr->hpcs1&HP_DVA) == 0) return (MBU_BUSY); if ((hpaddr->hpds & HP_VV) == 0) { hpaddr->hpcs1 = HP_DCLR|HP_GO; hpaddr->hpcs1 = HP_PRESET|HP_GO; hpaddr->hpof = HP_FMT22; } if (mi->mi_tab.b_active || mi->mi_hd->mh_ndrive == 1) return (MBU_DODATA); if ((hpaddr->hpds & (HP_DPR|HP_MOL)) != (HP_DPR|HP_MOL)) return (MBU_DODATA); st = &hpst[mi->mi_type]; bn = dkblock(bp); sn = bn%st->nspc; sn = (sn+st->nsect-hpSDIST)%st->nsect; if (bp->b_cylin == (hpaddr->hpdc & 0xffff)) { if (hpseek) return (MBU_DODATA); dist = ((hpaddr->hpla & 0xffff)>>6) - st->nsect + 1; if (dist < 0) dist += st->nsect; if (dist > st->nsect - hpRDIST) return (MBU_DODATA); } else hpaddr->hpdc = bp->b_cylin; if (hpseek) hpaddr->hpcs1 = HP_SEEK|HP_GO; else { hpaddr->hpda = sn; hpaddr->hpcs1 = HP_SEARCH|HP_GO; } return (MBU_STARTED); } hpstart(mi) register struct mba_info *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]; daddr_t bn; int sn, tn; bn = dkblock(bp); sn = bn%st->nspc; tn = sn/st->nsect; sn %= st->nsect; if (mi->mi_tab.b_errcnt >= 16 && (bp->b_flags&B_READ) != 0) { hpaddr->hpof = hp_offset[mi->mi_tab.b_errcnt & 017] | HP_FMT22; hpaddr->hpcs1 = HP_OFFSET|HP_GO; while (hpaddr->hpds & HP_PIP) ; mbclrattn(mi); } hpaddr->hpdc = bp->b_cylin; hpaddr->hpda = (tn << 8) + sn; } hpdtint(mi, mbasr) register struct mba_info *mi; int mbasr; { register struct hpdevice *hpaddr = (struct hpdevice *)mi->mi_drv; register struct buf *bp = mi->mi_tab.b_actf; int retry = 0; if (hpaddr->hpds&HP_ERR || mbasr&MBAEBITS) { if (hpaddr->hper1&HP_WLE) { printf("hp%d is write locked\n", dkunit(bp)); bp->b_flags |= B_ERROR; } else if (++mi->mi_tab.b_errcnt > 27 || mbasr & MBASR_HARD || hpaddr->hper1 & HPER1_HARD || hpaddr->hper2 & HPER2_HARD) { harderr(bp); printf("hp%d%c mbasr=%b er1=%b er2=%b\n", dkunit(bp), 'a'+(minor(bp->b_dev)&07), mbasr, mbasr_bits, hpaddr->hper1, HPER1_BITS, hpaddr->hper2, HPER2_BITS); bp->b_flags |= B_ERROR; #ifdef notdef } else if (hpaddr->hper2&HP_SSE) { hpecc(mi, 1); return (MBD_RESTARTED); #endif } else if ((hpaddr->hper1&(HP_DCK|HP_ECH)) == HP_DCK) { if (hpecc(mi, 0)) return (MBD_RESTARTED); /* else done */ } else retry = 1; hpaddr->hpcs1 = HP_DCLR|HP_GO; if ((mi->mi_tab.b_errcnt&07) == 4) { hpaddr->hpcs1 = HP_RECAL|HP_GO; hprecal[mi->mi_unit] = 1; return (MBD_RESTARTED); } if (retry) return (MBD_RETRY); } if (hprecal[mi->mi_unit]) { hprecal[mi->mi_unit] = 0; return (MBD_RETRY); } bp->b_resid = -(mi->mi_mba->mba_bcr) & 0xffff; if (mi->mi_tab.b_errcnt > 16) { hpaddr->hpcs1 = HP_RTC|HP_GO; while (hpaddr->hpds & HP_PIP) ; mbclrattn(mi); } hpaddr->hpcs1 = HP_RELEASE|HP_GO; return (MBD_DONE); } hpread(dev) dev_t dev; { register int unit = minor(dev) >> 3; if (unit >= NHP) u.u_error = ENXIO; else physio(hpstrategy, &rhpbuf[unit], dev, B_READ, minphys); } hpwrite(dev) dev_t dev; { register int unit = minor(dev) >> 3; if (unit >= NHP) u.u_error = ENXIO; else physio(hpstrategy, &rhpbuf[unit], dev, B_WRITE, minphys); } hpecc(mi, rm80sse) register struct mba_info *mi; int rm80sse; { 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; register int i; caddr_t addr; int reg, bit, byte, npf, mask, o; int bn, cn, tn, sn; struct pte mpte; int bcr; bcr = mbp->mba_bcr & 0xffff; if (bcr) bcr |= 0xffff0000; /* sxt */ npf = btop(bcr + bp->b_bcount) - 1; reg = npf; #ifdef notdef if (rm80sse) { rp->hpof |= HP_SSEI; reg--; /* compensate in advance for reg-- below */ goto sse; } #endif o = (int)bp->b_un.b_addr & PGOFSET; printf("soft ecc hp%d%c bn%d\n", dkunit(bp), 'a'+(minor(bp->b_dev)&07), bp->b_blkno + npf); mask = rp->hpec2&0xffff; i = (rp->hpec1&0xffff) - 1; /* -1 makes 0 origin */ bit = i&07; i = (i&~07)>>3; byte = i + o; while (i < 512 && (int)ptob(npf)+i < bp->b_bcount && bit > -11) { mpte = mbp->mba_map[reg+btop(byte)]; addr = ptob(mpte.pg_pfnum) + (byte & PGOFSET); putmemc(addr, getmemc(addr)^(mask<hpda = rp->hpda + 1; rp->hper1 = 0; rp->hpcs1 = HP_RCOM|HP_GO; #else sse: rp->hpcs1 = HP_DCLR|HP_GO; bn = dkblock(bp); st = &hpst[mi->mi_type]; cn = bp->b_cylin; sn = bn%(st->nspc) + npf + 1; tn = sn/st->nsect; sn %= st->nsect; cn += tn/st->ntrak; tn %= st->ntrak; #ifdef notdef if (rp->hpof&SSEI) sn++; #endif rp->hpdc = cn; rp->hpda = (tn<<8) + sn; mbp->mba_sr = -1; mbp->mba_var = (int)ptob(reg+1) + o; rp->hpcs1 = HP_RCOM|HP_GO; #endif return (1); } #define DBSIZE 20 hpdump(dev) dev_t dev; { register struct mba_info *mi; register struct mba_regs *mba; struct hpdevice *hpaddr; char *start; int num, unit; register struct hpst *st; num = maxfree; start = 0; unit = minor(dev) >> 3; if (unit >= NHP) return (ENXIO); #define phys(a,b) ((b)((int)(a)&0x7fffffff)) mi = phys(hpinfo[unit],struct mba_info *); if (mi == 0 || mi->mi_alive == 0) return (ENXIO); mba = phys(mi->mi_hd, struct mba_hd *)->mh_physmba; mba->mba_cr = MBAINIT; hpaddr = (struct hpdevice *)&mba->mba_drv[mi->mi_drive]; if ((hpaddr->hpds & HP_VV) == 0) { hpaddr->hpcs1 = HP_DCLR|HP_GO; hpaddr->hpcs1 = HP_PRESET|HP_GO; hpaddr->hpof = HP_FMT22; } st = &hpst[mi->mi_type]; if (dumplo < 0 || dumplo + num >= st->sizes[minor(dev)&07].nblocks) return (EINVAL); 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 & HP_DRY) == 0) ; if (hpaddr->hpds&HP_ERR) return (EIO); start += blk*NBPG; num -= blk; } return (0); } #endif