/* $OpenBSD: fd.c,v 1.12 1997/08/08 21:46:35 niklas Exp $ */ /* $NetBSD: fd.c,v 1.36 1996/12/23 09:09:59 veego Exp $ */ /* * Copyright (c) 1994 Christian E. Hopps * Copyright (c) 1996 Ezra Story * 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 Christian E. Hopps. * This product includes software developed by Ezra Story. * 4. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include enum fdc_bits { FDB_CHANGED = 2, FDB_PROTECT, FDB_CYLZERO, FDB_READY }; /* * partitions in fd represent different format floppies * partition a is 0 etc.. */ enum fd_parttypes { FDAMIGAPART = 0, FDMSDOSPART, FDMAXPARTS }; #define FDBBSIZE (8192) #define FDSBSIZE (8192) #define b_cylin b_resid #define FDUNIT(dev) DISKUNIT(dev) #define FDPART(dev) DISKPART(dev) #define FDMAKEDEV(m, u, p) MAKEDISKDEV((m), (u), (p)) /* that's nice, but we don't want to always use this as an amiga drive bunghole :-) */ #define FDNHEADS (2) /* amiga drives always have 2 heads */ #define FDSECSIZE (512) /* amiga drives always have 512 byte sectors */ #define FDSECLWORDS (128) #define FDSETTLEDELAY (18000) /* usec delay after seeking after switch dir */ #define FDSTEPDELAY (3500) /* usec delay after steping */ #define FDPRESIDEDELAY (1000) /* usec delay before writing can occur */ #define FDWRITEDELAY (1300) /* usec delay after write */ #define FDSTEPOUT (1) /* decrease track step */ #define FDSTEPIN (0) /* increase track step */ #define FDCUNITMASK (0x78) /* mask for all units (bits 6-3) */ #define FDRETRIES (2) /* default number of retries */ #define FDMAXUNITS (4) /* maximum number of supported units */ #define DISKLEN_READ (0) /* fake mask for reading */ #define DISKLEN_WRITE (1 << 14) /* bit for writing */ #define DISKLEN_DMAEN (1 << 15) /* dma go */ #define DMABUFSZ ((DISKLEN_WRITE - 1) * 2) /* largest dma possible */ #define FDMFMSYNC (0x4489) #define FDMFMID (0x5554) #define FDMFMDATA (0x5545) #define FDMFMGAP1 (0x9254) #define FDMFMGAP2 (0xAAAA) #define FDMFMGAP3 (0x9254) #define CRC16POLY (0x1021) /* (x^16) + x^12 + x^5 + x^0 */ /* * Msdos-type MFM encode/decode */ static u_char msdecode[128]; static u_char msencode[16] = { 0x2a, 0x29, 0x24, 0x25, 0x12, 0x11, 0x14, 0x15, 0x4a, 0x49, 0x44, 0x45, 0x52, 0x51, 0x54, 0x55 }; static u_short mscrctab[256]; /* 5554 aaaa aaaa aaa5 2aa4 4452 aa51 00 00 03 02 ac 0d */ /* * floppy device type */ struct fdtype { u_int driveid; /* drive identification (from drive) */ u_int ncylinders; /* number of cylinders on drive */ u_int amiga_nsectors; /* number of sectors per amiga track */ u_int msdos_nsectors; /* number of sectors per msdos track */ u_int nreadw; /* number of words (short) read per track */ u_int nwritew; /* number of words (short) written per track */ u_int gap; /* track gap size in long words */ u_int precomp[2]; /* 1st and 2nd precomp values */ char *desc; /* description of drive type (useq) */ }; /* * floppy disk device data */ struct fd_softc { struct device sc_dv; /* generic device info; must come first */ struct disk dkdev; /* generic disk info */ struct buf bufq; /* queue of buf's */ struct fdtype *type; void *cachep; /* cached track data (write through) */ int cachetrk; /* cahced track -1 for none */ int hwunit; /* unit for amiga controlling hw */ int unitmask; /* mask for cia select deslect */ int pstepdir; /* previous step direction */ int curcyl; /* current curcyl head positioned on */ int flags; /* misc flags */ int wlabel; int stepdelay; /* useq to delay after seek user setable */ int nsectors; /* number of sectors per track */ int openpart; /* which partition [ab] == [12] is open */ short retries; /* number of times to retry failed io */ short retried; /* number of times current io retried */ int bytespersec; /* number of bytes per sector */ }; /* fd_softc->flags */ #define FDF_MOTORON (0x01) /* motor is running */ #define FDF_MOTOROFF (0x02) /* motor is waiting to be turned off */ #define FDF_WMOTOROFF (0x04) /* unit wants a wakeup after off */ #define FDF_DIRTY (0x08) /* track cache needs write */ #define FDF_WRITEWAIT (0x10) /* need to head select delay on next setpos */ #define FDF_HAVELABEL (0x20) /* label is valid */ #define FDF_JUSTFLUSH (0x40) /* don't bother caching track. */ #define FDF_NOTRACK0 (0x80) /* was not able to recalibrate drive */ int fdc_wantwakeup; int fdc_side; void *fdc_dmap; struct fd_softc *fdc_indma; int fdc_dmalen; int fdc_dmawrite; struct fdcargs { struct fdtype *type; int unit; }; int fdcmatch __P((struct device *, void *, void *)); void fdcattach __P((struct device *, struct device *, void *)); int fdcprint __P((void *, const char *)); int fdmatch __P((struct device *, void *, void *)); void fdattach __P((struct device *, struct device *, void *)); void fdintr __P((int)); void fdidxintr __P((void)); int fdpulseintr __P((void *)); void fdstrategy __P((struct buf *)); int fdloaddisk __P((struct fd_softc *)); int fdgetdisklabel __P((struct fd_softc *, dev_t)); int fdsetdisklabel __P((struct fd_softc *, struct disklabel *)); int fdputdisklabel __P((struct fd_softc *, dev_t)); struct fdtype * fdcgetfdtype __P((int)); void fdmotoroff __P((void *)); void fdsetpos __P((struct fd_softc *, int, int)); void fdselunit __P((struct fd_softc *)); void fdstart __P((struct fd_softc *)); void fdcont __P((struct fd_softc *)); void fddmastart __P((struct fd_softc *, int)); void fdcalibrate __P((void *)); void fddmadone __P((struct fd_softc *, int)); void fddone __P((struct fd_softc *)); void fdfindwork __P((int)); void fdminphys __P((struct buf *)); void fdcachetoraw __P((struct fd_softc *)); void amcachetoraw __P((struct fd_softc *)); int amrawtocache __P((struct fd_softc *)); u_long *fdfindsync __P((u_long *, u_long *)); int fdrawtocache __P((struct fd_softc *)); void mscachetoraw __P((struct fd_softc *)); int msrawtocache __P((struct fd_softc *)); u_long *mfmblkencode __P((u_long *, u_long *, u_long *, int)); u_long *mfmblkdecode __P((u_long *, u_long *, u_long *, int)); u_short *msblkdecode __P((u_short *, u_char *, int)); u_short *msblkencode __P((u_short *, u_char *, int, u_short *)); struct dkdriver fddkdriver = { fdstrategy }; /* * read size is (nsectors + 1) * mfm secsize + gap bytes + 2 shorts * write size is nsectors * mfm secsize + gap bytes + 3 shorts * the extra shorts are to deal with a dma hw bug in the controller * they are probably too much (I belive the bug is 1 short on write and * 3 bits on read) but there is no need to be cheap here. */ #define MAXTRKSZ (22 * FDSECSIZE) struct fdtype fdtype[] = { { 0x00000000, 80, 11, 9, 7358, 6815, 414, { 80, 161 }, "3.5dd" }, { 0x55555555, 40, 11, 9, 7358, 6815, 414, { 80, 161 }, "5.25dd" }, { 0xAAAAAAAA, 80, 22, 18, 14716, 13630, 828, { 80, 161 }, "3.5hd" } }; int nfdtype = sizeof(fdtype) / sizeof(*fdtype); struct cfattach fd_ca = { sizeof(struct fd_softc), fdmatch, fdattach }; struct cfdriver fd_cd = { NULL, "fd", DV_DISK, NULL, 0 }; struct cfattach fdc_ca = { sizeof(struct device), fdcmatch, fdcattach }; struct cfdriver fdc_cd = { NULL, "fdc", DV_DULL, NULL, 0 }; /* * all hw access through macros, this helps to hide the active low * properties */ #define FDUNITMASK(unit) (1 << (3 + (unit))) /* * select units using mask */ #define FDSELECT(um) do { ciab.prb &= ~(um); } while (0) /* * deselect units using mask */ #define FDDESELECT(um) do { ciab.prb |= (um); delay(1); } while (0) /* * test hw condition bits */ #define FDTESTC(bit) ((ciaa.pra & (1 << (bit))) == 0) /* * set motor for select units, true motor on else off */ #define FDSETMOTOR(on) do { \ if (on) ciab.prb &= ~CIAB_PRB_MTR; else ciab.prb |= CIAB_PRB_MTR; \ } while (0) /* * set head for select units */ #define FDSETHEAD(head) do { \ if (head) ciab.prb &= ~CIAB_PRB_SIDE; else ciab.prb |= CIAB_PRB_SIDE; \ delay(1); } while (0) /* * select direction, true towards spindle else outwards */ #define FDSETDIR(in) do { \ if (in) ciab.prb &= ~CIAB_PRB_DIR; else ciab.prb |= CIAB_PRB_DIR; \ delay(1); } while (0) /* * step the selected units */ #define FDSTEP do { \ ciab.prb &= ~CIAB_PRB_STEP; ciab.prb |= CIAB_PRB_STEP; \ } while (0) #define FDDMASTART(len, towrite) do { \ int dmasz = (len) | ((towrite) ? DISKLEN_WRITE : 0) | DISKLEN_DMAEN; \ custom.dsklen = dmasz; custom.dsklen = dmasz; } while (0) #define FDDMASTOP do { custom.dsklen = 0; } while (0) int fdcmatch(pdp, match, auxp) struct device *pdp; void *match, *auxp; { struct cfdata *cfp = match; if (matchname("fdc", auxp) == 0 || cfp->cf_unit != 0) return(0); if ((fdc_dmap = alloc_chipmem(DMABUFSZ)) == NULL) { printf("fdc: unable to allocate dma buffer\n"); return(0); } return(1); } void fdcattach(pdp, dp, auxp) struct device *pdp, *dp; void *auxp; { struct fdcargs args; #if defined(IPL_REMAP_1) || defined(IPL_REMAP_2) static struct isr isr; #endif printf(": dmabuf pa 0x%x", kvtop(fdc_dmap)); printf(": dmabuf ka %p\n", fdc_dmap); args.unit = 0; args.type = fdcgetfdtype(args.unit); fdc_side = -1; config_found(dp, &args, fdcprint); for (args.unit++; args.unit < FDMAXUNITS; args.unit++) { if ((args.type = fdcgetfdtype(args.unit)) == NULL) continue; config_found(dp, &args, fdcprint); } #if defined(IPL_REMAP_1) || defined(IPL_REMAP_2) isr.isr_intr = fdpulseintr; isr.isr_ipl = 6; isr.isr_mapped_ipl = IPL_BIO; add_isr(&isr); #endif } int fdcprint(auxp, pnp) void *auxp; const char *pnp; { struct fdcargs *fcp; fcp = auxp; if (pnp) printf("fd%d at %s unit %d:", fcp->unit, pnp, fcp->type->driveid); return(UNCONF); } /*ARGSUSED*/ int fdmatch(pdp, match, auxp) struct device *pdp; void *match, *auxp; { struct cfdata *cfp = match; #define cf_unit cf_loc[0] struct fdcargs *fdap; fdap = auxp; if (cfp->cf_unit == fdap->unit || cfp->cf_unit == -1) return(1); return(0); #undef cf_unit } void fdattach(pdp, dp, auxp) struct device *pdp, *dp; void *auxp; { struct fdcargs *ap; struct fd_softc *sc; int i; ap = auxp; sc = (struct fd_softc *)dp; sc->curcyl = sc->cachetrk = -1; sc->openpart = -1; sc->type = ap->type; sc->hwunit = ap->unit; sc->unitmask = 1 << (3 + ap->unit); sc->retries = FDRETRIES; sc->stepdelay = FDSTEPDELAY; sc->bytespersec = 512; printf(" unit %d: %s %d cyl, %d head, %d sec [%d sec], 512 bytes/sec\n", sc->hwunit, sc->type->desc, sc->type->ncylinders, FDNHEADS, sc->type->amiga_nsectors, sc->type->msdos_nsectors); /* * Initialize and attach the disk structure. */ sc->dkdev.dk_name = sc->sc_dv.dv_xname; sc->dkdev.dk_driver = &fddkdriver; disk_attach(&sc->dkdev); /* * calibrate the drive */ fdsetpos(sc, 0, 0); fdsetpos(sc, sc->type->ncylinders, 0); fdsetpos(sc, 0, 0); fdmotoroff(sc); /* * precalc msdos MFM and CRC */ for (i = 0; i < 128; i++) msdecode[i] = 0xff; for (i = 0; i < 16; i++) msdecode[msencode[i]] = i; for (i = 0; i < 256; i++) { mscrctab[i] = (0x1021 * (i & 0xf0)) ^ (0x1021 * (i & 0x0f)) ^ (0x1021 * (i >> 4)); } /* * enable disk related interrupts */ custom.dmacon = DMAF_SETCLR | DMAF_MASTER | DMAF_DISK; custom.intena = INTF_SETCLR | INTF_DSKBLK; ciab.icr = CIA_ICR_FLG; } #if defined(IPL_REMAP_1) || defined(IPL_REMAP_2) int fdpulseintr(arg) void *arg; { /* Is it our interrupt? */ if (ciab.icr & (1 << 4)) { fdidxintr(); return 1; } return 0; } #endif /*ARGSUSED*/ int fdopen(dev, flags, devtype, p) dev_t dev; int flags, devtype; struct proc *p; { struct fd_softc *sc; int wasopen, fwork, error, s; error = 0; if (FDPART(dev) >= FDMAXPARTS) return(ENXIO); if ((sc = getsoftc(fd_cd, FDUNIT(dev))) == NULL) return(ENXIO); if (sc->flags & FDF_NOTRACK0) return(ENXIO); if (sc->cachep == NULL) sc->cachep = malloc(MAXTRKSZ, M_DEVBUF, M_WAITOK); s = splbio(); /* * if we are sleeping in fdclose(); waiting for a chance to * shut the motor off, do a sleep here also. */ while (sc->flags & FDF_WMOTOROFF) tsleep(fdmotoroff, PRIBIO, "fdopen", 0); fwork = 0; /* * if not open let user open request type, otherwise * ensure they are trying to open same type. */ if (sc->openpart == FDPART(dev)) wasopen = 1; else if (sc->openpart == -1) { sc->openpart = FDPART(dev); wasopen = 0; } else { wasopen = 1; error = EPERM; goto done; } /* * wait for current io to complete if any */ if (fdc_indma) { fwork = 1; fdc_wantwakeup++; tsleep(fdopen, PRIBIO, "fdopen", 0); } if ((error = fdloaddisk(sc)) != 0) goto done; if ((error = fdgetdisklabel(sc, dev)) != 0) goto done; #ifdef FDDEBUG printf(" open successful\n"); #endif done: /* * if we requested that fddone()->fdfindwork() wake us, allow it to * complete its job now */ if (fwork) fdfindwork(FDUNIT(dev)); splx(s); /* * if we were not open and we marked us so reverse that. */ if (error && wasopen == 0) sc->openpart = -1; return(error); } /*ARGSUSED*/ int fdclose(dev, flags, devtype, p) dev_t dev; int flags, devtype; struct proc *p; { struct fd_softc *sc; int s; #ifdef FDDEBUG printf("fdclose()\n"); #endif sc = getsoftc(fd_cd, FDUNIT(dev)); s = splbio(); if (sc->flags & FDF_MOTORON) { sc->flags |= FDF_WMOTOROFF; tsleep(fdmotoroff, PRIBIO, "fdclose", 0); sc->flags &= ~FDF_WMOTOROFF; wakeup(fdmotoroff); } sc->openpart = -1; splx(s); return(0); } int fdioctl(dev, cmd, addr, flag, p) dev_t dev; u_long cmd; caddr_t addr; int flag; struct proc *p; { struct fd_softc *sc; int error, wlab; sc = getsoftc(fd_cd, FDUNIT(dev)); if ((sc->flags & FDF_HAVELABEL) == 0) return(EBADF); switch (cmd) { case DIOCSBAD: return(EINVAL); case DIOCSRETRIES: if (*(int *)addr < 0) return(EINVAL); sc->retries = *(int *)addr; return(0); case DIOCSSTEP: if (*(int *)addr < FDSTEPDELAY) return(EINVAL); sc->dkdev.dk_label->d_trkseek = sc->stepdelay = *(int *)addr; return(0); case DIOCGDINFO: *(struct disklabel *)addr = *(sc->dkdev.dk_label); return(0); case DIOCGPART: ((struct partinfo *)addr)->disklab = sc->dkdev.dk_label; ((struct partinfo *)addr)->part = &sc->dkdev.dk_label->d_partitions[FDPART(dev)]; return(0); case DIOCSDINFO: if ((flag & FWRITE) == 0) return(EBADF); return(fdsetdisklabel(sc, (struct disklabel *)addr)); case DIOCWDINFO: if ((flag & FWRITE) == 0) return(EBADF); if ((error = fdsetdisklabel(sc, (struct disklabel *)addr)) != 0) return(error); wlab = sc->wlabel; sc->wlabel = 1; error = fdputdisklabel(sc, dev); sc->wlabel = wlab; return(error); case DIOCWLABEL: if ((flag & FWRITE) == 0) return(EBADF); sc->wlabel = *(int *)addr; return(0); default: return(ENOTTY); } } /* * no dumps to floppy disks thank you. */ int fdsize(dev) dev_t dev; { return(-1); } int fdread(dev, uio, flags) dev_t dev; struct uio *uio; int flags; { return (physio(fdstrategy, NULL, dev, B_READ, fdminphys, uio)); } int fdwrite(dev, uio, flags) dev_t dev; struct uio *uio; int flags; { return (physio(fdstrategy, NULL, dev, B_WRITE, fdminphys, uio)); } void fdintr(flag) int flag; { int s; s = splbio(); if (fdc_indma) fddmadone(fdc_indma, 0); splx(s); } void fdidxintr() { if (fdc_indma && fdc_dmalen) { /* * turn off intr and start actual dma */ ciab.icr = CIA_ICR_FLG; FDDMASTART(fdc_dmalen, fdc_dmawrite); fdc_dmalen = 0; } } void fdstrategy(bp) struct buf *bp; { struct disklabel *lp; struct fd_softc *sc; struct buf *dp; int unit, part, s; unit = FDUNIT(bp->b_dev); part = FDPART(bp->b_dev); sc = getsoftc(fd_cd, unit); #ifdef FDDEBUG printf("fdstrategy: 0x%x\n", bp); #endif /* * check for valid partition and bounds */ lp = sc->dkdev.dk_label; if ((sc->flags & FDF_HAVELABEL) == 0) { bp->b_error = EIO; goto bad; } if (bounds_check_with_label(bp, lp, sc->dkdev.dk_cpulabel, sc->wlabel) <= 0) goto done; /* * trans count of zero or bounds check indicates io is done * we are done. */ if (bp->b_bcount == 0) goto done; /* * queue the buf and kick the low level code */ s = splbio(); dp = &sc->bufq; disksort(dp, bp); fdstart(sc); splx(s); return; bad: bp->b_flags |= B_ERROR; done: bp->b_resid = bp->b_bcount; biodone(bp); } /* * make sure disk is loaded and label is up-to-date. */ int fdloaddisk(sc) struct fd_softc *sc; { /* * if diskchange is low step drive to 0 then up one then to zero. */ fdselunit(sc); /* make sure the unit is selected */ if (FDTESTC(FDB_CHANGED)) { fdsetpos(sc, 0, 0); sc->cachetrk = -1; /* invalidate the cache */ sc->flags &= ~FDF_HAVELABEL; fdsetpos(sc, FDNHEADS, 0); fdsetpos(sc, 0, 0); if (FDTESTC(FDB_CHANGED)) { fdmotoroff(sc); FDDESELECT(sc->unitmask); return(ENXIO); } } FDDESELECT(sc->unitmask); fdmotoroff(sc); sc->type = fdcgetfdtype(sc->hwunit); if (sc->type == NULL) return(ENXIO); if (sc->openpart == FDMSDOSPART) sc->nsectors = sc->type->msdos_nsectors; else sc->nsectors = sc->type->amiga_nsectors; return(0); } /* * read disk label, if present otherwise create one * return a new label if raw part and none found, otherwise err. */ int fdgetdisklabel(sc, dev) struct fd_softc *sc; dev_t dev; { struct disklabel *lp, *dlp; struct cpu_disklabel *clp; struct buf *bp; int error, part; if (sc->flags & FDF_HAVELABEL && sc->dkdev.dk_label->d_npartitions == (FDPART(dev) + 1)) return(0); #ifdef FDDEBUG printf("fdgetdisklabel()\n"); #endif part = FDPART(dev); lp = sc->dkdev.dk_label; clp = sc->dkdev.dk_cpulabel; bzero(lp, sizeof(struct disklabel)); bzero(clp, sizeof(struct cpu_disklabel)); lp->d_secsize = FDSECSIZE; lp->d_ntracks = FDNHEADS; lp->d_ncylinders = sc->type->ncylinders; lp->d_nsectors = sc->nsectors; lp->d_secpercyl = lp->d_ntracks * lp->d_nsectors; lp->d_secperunit = lp->d_secpercyl * lp->d_ncylinders; lp->d_npartitions = part + 1; lp->d_partitions[part].p_size = lp->d_secperunit; lp->d_partitions[part].p_fstype = FS_UNUSED; lp->d_partitions[part].p_fsize = 1024; lp->d_partitions[part].p_frag = 8; lp->d_partitions[part].p_cpg = 2; /* for adosfs: reserved blks */ sc->flags |= FDF_HAVELABEL; bp = (void *)geteblk((int)lp->d_secsize); bp->b_dev = dev; bp->b_blkno = 0; bp->b_cylin = 0; bp->b_bcount = FDSECSIZE; bp->b_flags = B_BUSY | B_READ; fdstrategy(bp); if ((error = biowait(bp)) != 0) goto nolabel; dlp = (struct disklabel *)(bp->b_data + LABELOFFSET); if (dlp->d_magic != DISKMAGIC || dlp->d_magic2 != DISKMAGIC || dkcksum(dlp)) { error = EINVAL; goto nolabel; } bcopy(dlp, lp, sizeof(struct disklabel)); if (lp->d_trkseek > FDSTEPDELAY) sc->stepdelay = lp->d_trkseek; brelse(bp); return(0); nolabel: bzero(lp, sizeof(struct disklabel)); lp->d_secsize = FDSECSIZE; lp->d_ntracks = FDNHEADS; lp->d_ncylinders = sc->type->ncylinders; lp->d_nsectors = sc->nsectors; lp->d_secpercyl = lp->d_ntracks * lp->d_nsectors; lp->d_type = DTYPE_FLOPPY; lp->d_secperunit = lp->d_secpercyl * lp->d_ncylinders; lp->d_rpm = 300; /* good guess I suppose. */ lp->d_interleave = 1; /* should change when adding msdos */ sc->stepdelay = lp->d_trkseek = FDSTEPDELAY; lp->d_bbsize = 0; lp->d_sbsize = 0; lp->d_partitions[part].p_size = lp->d_secperunit; lp->d_partitions[part].p_fstype = FS_UNUSED; lp->d_partitions[part].p_fsize = 1024; lp->d_partitions[part].p_frag = 8; lp->d_partitions[part].p_cpg = 2; /* adosfs: reserved blocks */ lp->d_npartitions = part + 1; lp->d_magic = lp->d_magic2 = DISKMAGIC; lp->d_checksum = dkcksum(lp); brelse(bp); return(0); } /* * set the incore copy of this units disklabel */ int fdsetdisklabel(sc, lp) struct fd_softc *sc; struct disklabel *lp; { struct disklabel *clp; struct partition *pp; /* * must have at least opened raw unit to fetch the * raw_part stuff. */ if ((sc->flags & FDF_HAVELABEL) == 0) return(EINVAL); clp = sc->dkdev.dk_label; /* * make sure things check out and we only have one valid * partition */ #ifdef FDDEBUG printf("fdsetdisklabel\n"); #endif if (lp->d_secsize != FDSECSIZE || lp->d_nsectors != clp->d_nsectors || lp->d_ntracks != FDNHEADS || lp->d_ncylinders != clp->d_ncylinders || lp->d_secpercyl != clp->d_secpercyl || lp->d_secperunit != clp->d_secperunit || lp->d_magic != DISKMAGIC || lp->d_magic2 != DISKMAGIC || lp->d_npartitions == 0 || lp->d_npartitions > FDMAXPARTS || (lp->d_partitions[0].p_offset && lp->d_partitions[1].p_offset) || dkcksum(lp)) return(EINVAL); /* * if any partitions are present make sure they * represent the currently open type */ if ((pp = &lp->d_partitions[0])->p_size) { if ((pp = &lp->d_partitions[1])->p_size == 0) goto done; else if (sc->openpart != 1) return(EINVAL); } else if (sc->openpart != 0) return(EINVAL); /* * make sure selected partition is within bounds * XXX on the second check, its to handle a bug in * XXX the cluster routines as they require mutliples * XXX of CLBYTES currently */ if ((pp->p_offset + pp->p_size >= lp->d_secperunit) || (pp->p_frag * pp->p_fsize % CLBYTES)) return(EINVAL); done: bcopy(lp, clp, sizeof(struct disklabel)); return(0); } /* * write out the incore copy of this units disklabel */ int fdputdisklabel(sc, dev) struct fd_softc *sc; dev_t dev; { struct disklabel *lp, *dlp; struct buf *bp; int error; if ((sc->flags & FDF_HAVELABEL) == 0) return(EBADF); #ifdef FDDEBUG printf("fdputdisklabel\n"); #endif /* * get buf and read in sector 0 */ lp = sc->dkdev.dk_label; bp = (void *)geteblk((int)lp->d_secsize); bp->b_dev = FDMAKEDEV(major(dev), FDUNIT(dev), RAW_PART); bp->b_blkno = 0; bp->b_cylin = 0; bp->b_bcount = FDSECSIZE; bp->b_flags = B_BUSY | B_READ; fdstrategy(bp); if ((error = biowait(bp)) != 0) goto done; /* * copy disklabel to buf and write it out syncronous */ dlp = (struct disklabel *)(bp->b_data + LABELOFFSET); bcopy(lp, dlp, sizeof(struct disklabel)); bp->b_blkno = 0; bp->b_cylin = 0; bp->b_flags = B_WRITE; fdstrategy(bp); error = biowait(bp); done: brelse(bp); return(error); } /* * figure out drive type or NULL if none. */ struct fdtype * fdcgetfdtype(unit) int unit; { struct fdtype *ftp; u_long id, idb; int cnt, umask; id = 0; umask = 1 << (3 + unit); FDDESELECT(FDCUNITMASK); FDSETMOTOR(1); delay(1); FDSELECT(umask); delay(1); FDDESELECT(umask); FDSETMOTOR(0); delay(1); FDSELECT(umask); delay(1); FDDESELECT(umask); for (idb = 0x80000000; idb; idb >>= 1) { FDSELECT(umask); delay(1); if (FDTESTC(FDB_READY) == 0) id |= idb; FDDESELECT(umask); delay(1); } #ifdef FDDEBUG printf("fdcgettype unit %d id 0x%lx\n", unit, id); #endif for (cnt = 0, ftp = fdtype; cnt < nfdtype; ftp++, cnt++) if (ftp->driveid == id) return(ftp); /* * 3.5dd's at unit 0 do not always return id. */ if (unit == 0) return(fdtype); return(NULL); } /* * turn motor off if possible otherwise mark as needed and will be done * later. */ void fdmotoroff(arg) void *arg; { struct fd_softc *sc; int s; sc = arg; s = splbio(); #ifdef FDDEBUG printf("fdmotoroff: unit %d\n", sc->hwunit); #endif if ((sc->flags & FDF_MOTORON) == 0) goto done; /* * if we have a timeout on a dma operation let fddmadone() * deal with it. */ if (fdc_indma == sc) { fddmadone(sc, 1); goto done; } #ifdef FDDEBUG printf(" motor was on, turning off\n"); #endif /* * flush cache if needed */ if (sc->flags & FDF_DIRTY) { sc->flags |= FDF_JUSTFLUSH | FDF_MOTOROFF; #ifdef FDDEBUG printf(" flushing dirty buffer first\n"); #endif /* * if dma'ing done for now, fddone() will call us again */ if (fdc_indma) goto done; fddmastart(sc, sc->cachetrk); goto done; } /* * if controller is busy just schedule us to be called back */ if (fdc_indma) { /* * someone else has the controller now * just set flag and let fddone() call us again. */ sc->flags |= FDF_MOTOROFF; goto done; } #ifdef FDDEBUG printf(" hw turning unit off\n"); #endif sc->flags &= ~(FDF_MOTORON | FDF_MOTOROFF); FDDESELECT(FDCUNITMASK); FDSETMOTOR(0); delay(1); FDSELECT(sc->unitmask); delay(4); FDDESELECT(sc->unitmask); delay(1); if (sc->flags & FDF_WMOTOROFF) wakeup(fdmotoroff); done: splx(s); } /* * select drive seek to track exit with motor on. * fdsetpos(x, 0, 0) does calibrates the drive. */ void fdsetpos(sc, trk, towrite) struct fd_softc *sc; int trk, towrite; { int nstep, sdir, ondly, ncyl, nside; FDDESELECT(FDCUNITMASK); FDSETMOTOR(1); delay(1); FDSELECT(sc->unitmask); delay(1); if ((sc->flags & FDF_MOTORON) == 0) { ondly = 0; while (FDTESTC(FDB_READY) == 0) { delay(1000); if (++ondly >= 1000) break; } } sc->flags |= FDF_MOTORON; ncyl = trk / FDNHEADS; nside = trk % FDNHEADS; if (sc->curcyl == ncyl && fdc_side == nside) return; if (towrite) sc->flags |= FDF_WRITEWAIT; #ifdef FDDEBUG printf("fdsetpos: cyl %d head %d towrite %d\n", trk / FDNHEADS, trk % FDNHEADS, towrite); #endif nstep = ncyl - sc->curcyl; if (nstep) { /* * figure direction */ if (nstep > 0 && ncyl != 0) { sdir = FDSTEPIN; FDSETDIR(1); } else { nstep = -nstep; sdir = FDSTEPOUT; FDSETDIR(0); } if (ncyl == 0) { /* * either just want cylinder 0 or doing * a calibrate. */ nstep = 256; while (FDTESTC(FDB_CYLZERO) == 0 && nstep--) { FDSTEP; delay(sc->stepdelay); } if (nstep < 0) sc->flags |= FDF_NOTRACK0; } else { /* * step the needed amount amount. */ while (nstep--) { FDSTEP; delay(sc->stepdelay); } } /* * if switched directions * allow drive to settle. */ if (sc->pstepdir != sdir) delay(FDSETTLEDELAY); sc->pstepdir = sdir; sc->curcyl = ncyl; } if (nside == fdc_side) return; /* * select side */ fdc_side = nside; FDSETHEAD(nside); delay(FDPRESIDEDELAY); } void fdselunit(sc) struct fd_softc *sc; { FDDESELECT(FDCUNITMASK); /* deselect all */ FDSETMOTOR(sc->flags & FDF_MOTORON); /* set motor to unit's state */ delay(1); FDSELECT(sc->unitmask); /* select unit */ delay(1); } /* * process next buf on device queue. * normall sequence of events: * fdstart() -> fddmastart(); * fdidxintr(); * fdintr() -> fddmadone() -> fddone(); * if the track is in the cache then fdstart() will short-circuit * to fddone() else if the track cache is dirty it will flush. If * the buf is not an entire track it will cache the requested track. */ void fdstart(sc) struct fd_softc *sc; { int trk, error, write; struct buf *bp, *dp; int changed; #ifdef FDDEBUG printf("fdstart: unit %d\n", sc->hwunit); #endif /* * if dma'ing just return. we must have been called from fdstartegy. */ if (fdc_indma) return; /* * get next buf if there. */ dp = &sc->bufq; if ((bp = dp->b_actf) == NULL) { #ifdef FDDEBUG printf(" nothing to do\n"); #endif return; } /* * Mark us as busy now, in case fddone() gets called in one * of the cases below. */ disk_busy(&sc->dkdev); /* * make sure same disk is loaded */ fdselunit(sc); changed = FDTESTC(FDB_CHANGED); FDDESELECT(sc->unitmask); if (changed) { /* * disk missing, invalidate all future io on * this unit until re-open()'ed also invalidate * all current io */ printf("fdstart: disk changed\n"); #ifdef FDDEBUG printf(" disk was removed invalidating all io\n"); #endif sc->flags &= ~FDF_HAVELABEL; for (;;) { bp->b_flags |= B_ERROR; bp->b_error = EIO; if (bp->b_actf == NULL) break; biodone(bp); bp = bp->b_actf; } /* * do fddone() on last buf to allow other units to start. */ dp->b_actf = bp; fddone(sc); return; } /* * we have a valid buf, setup our local version * we use this count to allow reading over multiple tracks. * into a single buffer */ dp->b_bcount = bp->b_bcount; dp->b_blkno = bp->b_blkno; dp->b_data = bp->b_data; dp->b_flags = bp->b_flags; dp->b_resid = 0; if (bp->b_flags & B_READ) write = 0; else if (FDTESTC(FDB_PROTECT) == 0) write = 1; else { error = EPERM; goto bad; } /* * figure trk given blkno */ trk = bp->b_blkno / sc->nsectors; /* * check to see if same as currently cached track * if so we need to do no dma read. */ if (trk == sc->cachetrk) { fddone(sc); return; } /* * if we will be overwriting the entire cache, don't bother to * fetch it. */ if (bp->b_bcount == (sc->nsectors * FDSECSIZE) && write && bp->b_blkno % sc->nsectors == 0) { if (sc->flags & FDF_DIRTY) sc->flags |= FDF_JUSTFLUSH; else { sc->cachetrk = trk; fddone(sc); return; } } /* * start dma read of `trk' */ fddmastart(sc, trk); return; bad: bp->b_flags |= B_ERROR; bp->b_error = error; fddone(sc); } /* * continue a started operation on next track. always begin at * sector 0 on the next track. */ void fdcont(sc) struct fd_softc *sc; { struct buf *dp, *bp; int trk, write; dp = &sc->bufq; bp = dp->b_actf; dp->b_data += (dp->b_bcount - bp->b_resid); dp->b_blkno += (dp->b_bcount - bp->b_resid) / FDSECSIZE; dp->b_bcount = bp->b_resid; /* * figure trk given blkno */ trk = dp->b_blkno / sc->nsectors; #ifdef DEBUG if (trk != sc->cachetrk + 1 || dp->b_blkno % sc->nsectors != 0) panic("fdcont: confused"); #endif if (dp->b_flags & B_READ) write = 0; else write = 1; /* * if we will be overwriting the entire cache, don't bother to * fetch it. */ if (dp->b_bcount == (sc->nsectors * FDSECSIZE) && write) { if (sc->flags & FDF_DIRTY) sc->flags |= FDF_JUSTFLUSH; else { sc->cachetrk = trk; fddone(sc); return; } } /* * start dma read of `trk' */ fddmastart(sc, trk); return; } void fddmastart(sc, trk) struct fd_softc *sc; int trk; { int adkmask, ndmaw, write, dmatrk; #ifdef FDDEBUG printf("fddmastart: unit %d cyl %d head %d", sc->hwunit, trk / FDNHEADS, trk % FDNHEADS); #endif /* * flush the cached track if dirty else read requested track. */ if (sc->flags & FDF_DIRTY) { fdcachetoraw(sc); ndmaw = sc->type->nwritew; dmatrk = sc->cachetrk; write = 1; } else { ndmaw = sc->type->nreadw; dmatrk = trk; write = 0; } #ifdef FDDEBUG printf(" %s", write ? " flushing cache\n" : " loading cache\n"); #endif sc->cachetrk = trk; fdc_indma = sc; fdsetpos(sc, dmatrk, write); /* * setup dma stuff */ if (write == 0) { custom.adkcon = ADKF_MSBSYNC; custom.adkcon = ADKF_SETCLR | ADKF_WORDSYNC | ADKF_FAST; custom.dsksync = FDMFMSYNC; } else { custom.adkcon = ADKF_PRECOMP1 | ADKF_PRECOMP0 | ADKF_WORDSYNC | ADKF_MSBSYNC; adkmask = ADKF_SETCLR | ADKF_FAST | ADKF_MFMPREC; if (dmatrk >= sc->type->precomp[0]) adkmask |= ADKF_PRECOMP0; if (dmatrk >= sc->type->precomp[1]) adkmask |= ADKF_PRECOMP1; custom.adkcon = adkmask; } custom.dskpt = (u_char *)kvtop(fdc_dmap); /* * If writing an MSDOS track, activate disk index pulse * interrupt, dma will be started in the intr routine fdidxintr() * Otherwise, start the DMA here. */ if (write && sc->openpart == FDMSDOSPART) { fdc_dmalen = ndmaw; fdc_dmawrite = write; ciab.icr = CIA_ICR_IR_SC | CIA_ICR_FLG; } else { FDDMASTART(ndmaw, write); fdc_dmalen = 0; } #ifdef FDDEBUG printf(" dma started\n"); #endif } /* * recalibrate the drive */ void fdcalibrate(arg) void *arg; { struct fd_softc *sc; static int loopcnt; sc = arg; if (loopcnt == 0) { /* * seek cyl 0 */ fdc_indma = sc; sc->stepdelay += 900; if (sc->cachetrk > 1) fdsetpos(sc, sc->cachetrk % FDNHEADS, 0); sc->stepdelay -= 900; } if (loopcnt++ & 1) fdsetpos(sc, sc->cachetrk, 0); else fdsetpos(sc, sc->cachetrk + FDNHEADS, 0); /* * trk++, trk, trk++, trk, trk++, trk, trk++, trk and dma */ if (loopcnt < 8) timeout(fdcalibrate, sc, hz / 8); else { loopcnt = 0; fdc_indma = NULL; timeout(fdmotoroff, sc, 3 * hz / 2); fddmastart(sc, sc->cachetrk); } } void fddmadone(sc, timeo) struct fd_softc *sc; int timeo; { #ifdef FDDEBUG printf("fddmadone: unit %d, timeo %d\n", sc->hwunit, timeo); #endif fdc_indma = NULL; untimeout(fdmotoroff, sc); FDDMASTOP; /* * guarantee the drive has been at current head and cyl * for at least FDWRITEDELAY after a write. */ if (sc->flags & FDF_WRITEWAIT) { delay(FDWRITEDELAY); sc->flags &= ~FDF_WRITEWAIT; } if ((sc->flags & FDF_MOTOROFF) == 0) { /* * motor runs for 1.5 seconds after last dma */ timeout(fdmotoroff, sc, 3 * hz / 2); } if (sc->flags & FDF_DIRTY) { /* * if buffer dirty, the last dma cleaned it */ sc->flags &= ~FDF_DIRTY; if (timeo) printf("%s: write of track cache timed out.\n", sc->sc_dv.dv_xname); if (sc->flags & FDF_JUSTFLUSH) { sc->flags &= ~FDF_JUSTFLUSH; /* * we are done dma'ing */ fddone(sc); return; } /* * load the cache */ fddmastart(sc, sc->cachetrk); return; } #ifdef FDDEBUG else if (sc->flags & FDF_MOTOROFF) panic("fddmadone: FDF_MOTOROFF with no FDF_DIRTY"); #endif /* * cache loaded decode it into cache buffer */ if (timeo == 0 && fdrawtocache(sc) == 0) sc->retried = 0; else { #ifdef FDDEBUG if (timeo) printf("%s: fddmadone: cache load timed out.\n", sc->sc_dv.dv_xname); #endif if (sc->retried >= sc->retries) { sc->retried = 0; sc->cachetrk = -1; } else { sc->retried++; /* * this will be restarted at end of calibrate loop. */ untimeout(fdmotoroff, sc); fdcalibrate(sc); return; } } fddone(sc); } void fddone(sc) struct fd_softc *sc; { struct buf *dp, *bp; char *data; int sz; #ifdef FDDEBUG printf("fddone: unit %d\n", sc->hwunit); #endif /* * check to see if unit is just flushing the cache, * that is we have no io queued. */ if (sc->flags & FDF_MOTOROFF) goto nobuf; dp = &sc->bufq; if ((bp = dp->b_actf) == NULL) panic ("fddone"); /* * check for an error that may have occured * while getting the track. */ if (sc->cachetrk == -1) { sc->retried = 0; bp->b_flags |= B_ERROR; bp->b_error = EIO; } else if ((bp->b_flags & B_ERROR) == 0) { data = sc->cachep; /* * get offset of data in track cache and limit * the copy size to not exceed the cache's end. */ data += (dp->b_blkno % sc->nsectors) * FDSECSIZE; sz = sc->nsectors - dp->b_blkno % sc->nsectors; sz *= FDSECSIZE; sz = min(dp->b_bcount, sz); if (bp->b_flags & B_READ) bcopy(data, dp->b_data, sz); else { bcopy(dp->b_data, data, sz); sc->flags |= FDF_DIRTY; } bp->b_resid = dp->b_bcount - sz; if (bp->b_resid == 0) { bp->b_error = 0; } else { /* * not done yet need to read next track */ fdcont(sc); return; } } /* * remove from queue. */ dp->b_actf = bp->b_actf; disk_unbusy(&sc->dkdev, (bp->b_bcount - bp->b_resid)); biodone(bp); nobuf: fdfindwork(sc->sc_dv.dv_unit); } void fdfindwork(unit) int unit; { struct fd_softc *ssc, *sc; int i, last; /* * first see if we have any fdopen()'s waiting */ if (fdc_wantwakeup) { wakeup(fdopen); fdc_wantwakeup--; return; } /* * start next available unit, linear search from the next unit * wrapping and finally this unit. */ last = 0; ssc = NULL; for (i = unit + 1; last == 0; i++) { if (i == unit) last = 1; if (i >= fd_cd.cd_ndevs) { i = -1; continue; } if ((sc = fd_cd.cd_devs[i]) == NULL) continue; /* * if unit has requested to be turned off * and it has no buf's queued do it now */ if (sc->flags & FDF_MOTOROFF) { if (sc->bufq.b_actf == NULL) fdmotoroff(sc); else { /* * we gained a buf request while * we waited, forget the motoroff */ sc->flags &= ~FDF_MOTOROFF; } /* * if we now have dma unit must have needed * flushing, quit */ if (fdc_indma) return; } /* * if we have no start unit and the current unit has * io waiting choose this unit to start. */ if (ssc == NULL && sc->bufq.b_actf) ssc = sc; } if (ssc) fdstart(ssc); } /* * min byte count to whats left of the track in question */ void fdminphys(bp) struct buf *bp; { struct fd_softc *sc; int trk, sec, toff, tsz; if ((sc = getsoftc(fd_cd, FDUNIT(bp->b_dev))) == NULL) panic("fdminphys: couldn't get softc"); trk = bp->b_blkno / sc->nsectors; sec = bp->b_blkno % sc->nsectors; toff = sec * FDSECSIZE; tsz = sc->nsectors * FDSECSIZE; #ifdef FDDEBUG printf("fdminphys: before %d", bp->b_bcount); #endif bp->b_bcount = min(bp->b_bcount, tsz - toff); #ifdef FDDEBUG printf(" after %d\n", bp->b_bcount); #endif minphys(bp); } /* * encode the track cache into raw MFM ready for dma * when we go to multiple disk formats, this will call type dependent * functions */ void fdcachetoraw(sc) struct fd_softc *sc; { if (sc->openpart == FDMSDOSPART) mscachetoraw(sc); else amcachetoraw(sc); } /* * decode raw MFM from dma into units track cache. * when we go to multiple disk formats, this will call type dependent * functions */ int fdrawtocache(sc) struct fd_softc *sc; { if (sc->openpart == FDMSDOSPART) return(msrawtocache(sc)); else return(amrawtocache(sc)); } void amcachetoraw(sc) struct fd_softc *sc; { static u_long mfmnull[4]; u_long *rp, *crp, *dp, hcksum, dcksum, info, zero; int sec, i; rp = fdc_dmap; /* * not yet one sector (- 1 long) gap. * for now use previous drivers values */ for (i = 0; i < sc->type->gap; i++) *rp++ = 0xaaaaaaaa; /* * process sectors */ dp = sc->cachep; zero = 0; info = 0xff000000 | (sc->cachetrk << 16) | sc->nsectors; for (sec = 0; sec < sc->nsectors; sec++, info += (1 << 8) - 1) { hcksum = dcksum = 0; /* * sector format * offset description *----------------------------------- * 0 null * 1 sync * oddbits evenbits *---------------------- * 2 3 [0xff]b [trk]b [sec]b [togap]b * 4-7 8-11 null * 12 13 header cksum [2-11] * 14 15 data cksum [16-271] * 16-143 144-271 data */ *rp = 0xaaaaaaaa; if (*(rp - 1) & 0x1) *rp &= 0x7fffffff; /* clock bit correction */ rp++; *rp++ = (FDMFMSYNC << 16) | FDMFMSYNC; rp = mfmblkencode(&info, rp, &hcksum, 1); rp = mfmblkencode(mfmnull, rp, &hcksum, 4); rp = mfmblkencode(&hcksum, rp, NULL, 1); crp = rp; rp = mfmblkencode(dp, rp + 2, &dcksum, FDSECLWORDS); dp += FDSECLWORDS; crp = mfmblkencode(&dcksum, crp, NULL, 1); if (*(crp - 1) & 0x1) *crp &= 0x7fffffff; /* clock bit correction */ else if ((*crp & 0x40000000) == 0) *crp |= 0x80000000; } *rp = 0xaaa80000; if (*(rp - 1) & 0x1) *rp &= 0x7fffffff; } u_long * fdfindsync(rp, ep) u_long *rp, *ep; { u_short *sp; sp = (u_short *)rp; while ((u_long *)sp < ep && *sp != FDMFMSYNC) sp++; while ((u_long *)sp < ep && *sp == FDMFMSYNC) sp++; if ((u_long *)sp < ep) return((u_long *)sp); return(NULL); } int amrawtocache(sc) struct fd_softc *sc; { u_long mfmnull[4]; u_long *dp, *rp, *erp, *crp, *srp, hcksum, dcksum, info, cktmp; int cnt, doagain; doagain = 1; srp = rp = fdc_dmap; erp = (u_long *)((u_short *)rp + sc->type->nreadw); cnt = 0; again: if (doagain == 0 || (rp = srp = fdfindsync(srp, erp)) == NULL) { #ifdef DIAGNOSTIC printf("%s: corrupted track (%d) data.\n", sc->sc_dv.dv_xname, sc->cachetrk); #endif return(-1); } /* * process sectors */ for (; cnt < sc->nsectors; cnt++) { hcksum = dcksum = 0; rp = mfmblkdecode(rp, &info, &hcksum, 1); rp = mfmblkdecode(rp, mfmnull, &hcksum, 4); rp = mfmblkdecode(rp, &cktmp, NULL, 1); if (cktmp != hcksum) { #ifdef FDDEBUG printf(" info 0x%x hchksum 0x%x trkhcksum 0x%x\n", info, hcksum, cktmp); #endif goto again; } if (((info >> 16) & 0xff) != sc->cachetrk) { #ifdef DEBUG printf("%s: incorrect track found: 0x%lx %d\n", sc->sc_dv.dv_xname, info, sc->cachetrk); #endif goto again; } #ifdef FDDEBUG printf(" info 0x%x\n", info); #endif rp = mfmblkdecode(rp, &cktmp, NULL, 1); dp = sc->cachep; dp += FDSECLWORDS * ((info >> 8) & 0xff); crp = mfmblkdecode(rp, dp, &dcksum, FDSECLWORDS); if (cktmp != dcksum) { #ifdef FDDEBUG printf(" info 0x%x dchksum 0x%x trkdcksum 0x%x\n", info, dcksum, cktmp); #endif goto again; } /* * if we are at gap then we can no longer be sure * of correct sync marks */ if ((info && 0xff) == 1) doagain = 1; else doagain = 0; srp = rp = fdfindsync(crp, erp); } return(0); } void mscachetoraw(sc) struct fd_softc *sc; { u_short *rp, *erp, crc; u_char *cp, tb[5]; int sec, i; rp = (u_short *)fdc_dmap; erp = rp + sc->type->nwritew; cp = sc->cachep; /* * initial track filler (828 * GAP1) */ for (i = 0; i < sc->type->gap; i++) { *rp++ = FDMFMGAP1; *rp++ = FDMFMGAP1; } for (sec = 0; sec < sc->nsectors; sec++) { /* * leading sector gap * (12 * GAP2) + (3 * SYNC) */ for (i = 0; i < 12; i++) *rp++ = FDMFMGAP2; *rp++ = FDMFMSYNC; *rp++ = FDMFMSYNC; *rp++ = FDMFMSYNC; /* * sector information * (ID) + track + side + sector + sector size + CRC16 */ *rp++ = FDMFMID; tb[0] = sc->cachetrk / FDNHEADS; tb[1] = sc->cachetrk % FDNHEADS; tb[2] = sec + 1; i = sc->bytespersec; tb[3] = i < 256 ? 0 : (i < 512 ? 1 : (i < 1024 ? 2 : 3)); rp = msblkencode(rp, tb, 4, &crc); tb[0] = crc >> 8; tb[1] = crc & 0xff; tb[2] = 0x4e; /* GAP1 decoded */ rp = msblkencode(rp, tb, 3, 0); /* * sector info/data gap * (22 * GAP1) + (12 * GAP2) + (3 * SYNC) */ for (i = 0; i < 21; i++) *rp++ = FDMFMGAP1; for (i = 0; i < 12; i++) *rp++ = FDMFMGAP2; *rp++ = FDMFMSYNC; *rp++ = FDMFMSYNC; *rp++ = FDMFMSYNC; /* * sector data * (DATA) + ...data... + CRC16 */ *rp++ = FDMFMDATA; rp = msblkencode(rp, cp, sc->bytespersec, &crc); cp += sc->bytespersec; tb[0] = crc >> 8; tb[1] = crc & 0xff; tb[2] = 0x4e; /* GAP3 decoded */ rp = msblkencode(rp, tb, 3, 0); /* * trailing sector gap * (80 * GAP3) */ for (i = 0; i < 79; i++) *rp++ = FDMFMGAP3; } /* * fill rest of track with GAP3 */ while (rp != erp) *rp++ = FDMFMGAP3; } int msrawtocache(sc) struct fd_softc *sc; { u_short *rp, *srp, *erp; u_char tb[5], *cp; int ct, sec, retry; srp = rp = (u_short *)fdc_dmap; erp = rp + sc->type->nreadw; cp = sc->cachep; for (ct = 0; ct < sc->nsectors; ct++) { retry = 1; do { /* * skip leading gap to sync */ if ((rp = (u_short *)fdfindsync((u_long *)rp, (u_long *)erp)) == NULL) { #ifdef DIAGNOSTIC printf("%s: corrupted track (%d) data.\n", sc->sc_dv.dv_xname, sc->cachetrk); #endif return(-1); } /* * Grab sector info */ if (*rp++ != FDMFMID) continue; rp = msblkdecode(rp, tb, 4); #ifdef FDDEBUG printf("sector id: sector %d, track %d, side %d," "bps %d\n", tb[2], tb[0], tb[1], 128 << tb[3]); #endif if ((tb[0] * FDNHEADS + tb[1]) != sc->cachetrk || tb[2] > sc->nsectors) continue; sec = tb[2]; sc->bytespersec = 128 << tb[3]; rp += 2; /* skip CRC-16 */ /* * skip gap and read in data */ if ((rp = (u_short *)fdfindsync((u_long *)rp, (u_long *)erp)) == NULL) return(-1); if (*rp++ != FDMFMDATA) continue; rp = msblkdecode(rp, cp + ((sec-1) * sc->bytespersec), sc->bytespersec); rp += 2; /* skip CRC-16 */ retry = 0; } while (retry); } return(0); } /* * encode len longwords of `dp' data in amiga mfm block format (`rp') * this format specified that the odd bits are at current pos and even * bits at len + current pos */ u_long * mfmblkencode(dp, rp, cp, len) u_long *dp, *rp, *cp; int len; { u_long *sdp, *edp, d, dtmp, correct; sdp = dp; edp = dp + len; if (*(rp - 1) & 0x1) correct = 1; else correct = 0; /* * do odd bits */ while (dp < edp) { d = (*dp >> 1) & 0x55555555; /* remove clock bits */ dtmp = d ^ 0x55555555; d |= ((dtmp >> 1) | 0x80000000) & (dtmp << 1); /* * correct upper clock bit if needed */ if (correct) d &= 0x7fffffff; if (d & 0x1) correct = 1; else correct = 0; /* * do checksums and store in raw buffer */ if (cp) *cp ^= d; *rp++ = d; dp++; } /* * do even bits */ dp = sdp; while (dp < edp) { d = *dp & 0x55555555; /* remove clock bits */ dtmp = d ^ 0x55555555; d |= ((dtmp >> 1) | 0x80000000) & (dtmp << 1); /* * correct upper clock bit if needed */ if (correct) d &= 0x7fffffff; if (d & 0x1) correct = 1; else correct = 0; /* * do checksums and store in raw buffer */ if (cp) *cp ^= d; *rp++ = d; dp++; } if (cp) *cp &= 0x55555555; return(rp); } /* * decode len longwords of `dp' data in amiga mfm block format (`rp') * this format specified that the odd bits are at current pos and even * bits at len + current pos */ u_long * mfmblkdecode(rp, dp, cp, len) u_long *rp, *dp, *cp; int len; { u_long o, e; int cnt; cnt = len; while (cnt--) { o = *rp; e = *(rp + len); if (cp) { *cp ^= o; *cp ^= e; } o &= 0x55555555; e &= 0x55555555; *dp++ = (o << 1) | e; rp++; } if (cp) *cp &= 0x55555555; return(rp + len); } /* * decode len words in standard MFM format to len bytes * of data. */ u_short * msblkdecode(rp, cp, len) u_short *rp; u_char *cp; int len; { while (len--) { *cp++ = msdecode[*rp & 0x7f] | (msdecode[(*rp >> 8) & 0x7f] << 4); rp++; } return(rp); } /* * encode len bytes of data into len words in standard MFM format. * If a pointer is supplied for crc, calculate the CRC-16 of the data * as well. */ u_short * msblkencode(rp, cp, len, crc) u_short *rp; u_char *cp; int len; u_short *crc; { u_short td; u_short mycrc; /* preload crc for header (4 bytes) * or data (anything else) */ mycrc = (len == 4) ? 0xb230 : 0xe295; while (len--) { td = (msencode[*cp >> 4] << 8) | msencode[*cp & 0x0f]; /* Check for zeros in top bit of encode and bottom * bit of previous encode. if so, slap a one in betweem * them. */ if ((td & 0x140) == 0) td |= 0x80; if ((td & 0x4000) == 0 && (rp[-1] & 1) == 0) td |= 0x8000; *rp++ = td; /* * calc crc if requested */ if (crc) mycrc = (mycrc << 8) ^ mscrctab[*cp ^ (mycrc >> 8)]; cp++; } if (crc) *crc = mycrc; return(rp); } int fddump(dev, blkno, va, size) dev_t dev; daddr_t blkno; caddr_t va; size_t size; { return (EINVAL); }