/* $NetBSD: iwm_fd.c,v 1.56.22.1 2019/11/14 15:38:02 martin Exp $ */ /* * Copyright (c) 1997, 1998 Hauke Fath. 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. * * 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. */ /* * iwm_fd.c -- Sony (floppy disk) driver for m68k Macintoshes * * The present implementation supports the GCR format (800K) on * non-{DMA,IOP} machines. */ #include __KERNEL_RCSID(0, "$NetBSD: iwm_fd.c,v 1.56.22.1 2019/11/14 15:38:02 martin Exp $"); #include "locators.h" #include #include #include #include #include #include #include #include #include #define FSTYPENAMES #define DKTYPENAMES #include #include #include #include #include #include #include #include #include #include #include #include #include /** ** Private functions **/ static int map_iwm_base(vm_offset_t); /* Autoconfig */ int iwm_match(device_t, cfdata_t, void *); void iwm_attach(device_t, device_t, void *); int iwm_print(void *, const char *); int fd_match(device_t, cfdata_t, void *); void fd_attach(device_t, device_t, void *); int fd_print(void *, const char *); /* Disklabel stuff */ static void fdGetDiskLabel(fd_softc_t *, dev_t); static void fdPrintDiskLabel(struct disklabel *); static fdInfo_t *getFDType(short); static fdInfo_t *fdDeviceToType(fd_softc_t *, dev_t); static void fdstart(fd_softc_t *); static void remap_geometry(daddr_t, int, diskPosition_t *); static void motor_off(void *); static int seek(fd_softc_t *, int); static int checkTrack(diskPosition_t *, int); static int initCylinderCache(fd_softc_t *); static void invalidateCylinderCache(fd_softc_t *); static int fdstart_Init(fd_softc_t *); static int fdstart_Seek(fd_softc_t *); static int fdstart_Read(fd_softc_t *); static int fdstart_Write(fd_softc_t *); static int fdstart_Flush(fd_softc_t *); static int fdstart_IOFinish(fd_softc_t *); static int fdstart_IOErr(fd_softc_t *); static int fdstart_Fault(fd_softc_t *); static int fdstart_Exit(fd_softc_t *); /** ** Driver debugging **/ #ifdef DEBUG #define IWM_DEBUG #endif static void hexDump(u_char *, int); /* * Stuff taken from Egan/Teixeira ch 8: 'if(TRACE_FOO)' debug output * statements don't break indentation, and when DEBUG is not defined, * the compiler code optimizer drops them as dead code. */ #ifdef IWM_DEBUG #define M_TRACE_CONFIG 0x0001 #define M_TRACE_OPEN 0x0002 #define M_TRACE_CLOSE 0x0004 #define M_TRACE_READ 0x0008 #define M_TRACE_WRITE 0x0010 #define M_TRACE_STRAT (M_TRACE_READ | M_TRACE_WRITE) #define M_TRACE_IOCTL 0x0020 #define M_TRACE_STEP 0x0040 #define M_TRACE_ALL 0xFFFF #define TRACE_CONFIG (iwmDebugging & M_TRACE_CONFIG) #define TRACE_OPEN (iwmDebugging & M_TRACE_OPEN) #define TRACE_CLOSE (iwmDebugging & M_TRACE_CLOSE) #define TRACE_READ (iwmDebugging & M_TRACE_READ) #define TRACE_WRITE (iwmDebugging & M_TRACE_WRITE) #define TRACE_STRAT (iwmDebugging & M_TRACE_STRAT) #define TRACE_IOCTL (iwmDebugging & M_TRACE_IOCTL) #define TRACE_STEP (iwmDebugging & M_TRACE_STEP) #define TRACE_ALL (iwmDebugging & M_TRACE_ALL) /* -1 = all active */ int iwmDebugging = 0 /* | M_TRACE_OPEN | M_TRACE_STRAT | M_TRACE_IOCTL */ ; #else #define TRACE_CONFIG 0 #define TRACE_OPEN 0 #define TRACE_CLOSE 0 #define TRACE_READ 0 #define TRACE_WRITE 0 #define TRACE_STRAT 0 #define TRACE_IOCTL 0 #define TRACE_STEP 0 #define TRACE_ALL 0 #endif #define DISABLED 0 /** ** Module-global Variables **/ /* The IWM base address */ u_long IWMBase; /* * Table of supported disk types. * The table order seems to be pretty standardized across NetBSD ports, but * then, they are all MFM... So we roll our own for now. */ static fdInfo_t fdTypes[] = { {1, 80, 512, 10, 10, 800, 12, 2, IWM_GCR, "400K Sony"}, {2, 80, 512, 10, 20, 1600, 12, 2, IWM_GCR, "800K Sony"} }; /* Table of GCR disk zones for one side (see IM II-211, The Disk Driver) */ static diskZone_t diskZones[] = { {16, 12, 0, 191}, {16, 11, 192, 367}, {16, 10, 368, 527}, {16, 9, 528, 671}, {16, 8, 672, 799} }; /* Drive format codes/indexes */ enum { IWM_400K_GCR = 0, IWM_800K_GCR = 1, IWM_720K_MFM = 2, IWM_1440K_MFM = 3 }; /** ** Autoconfiguration code **/ /* * Autoconfig data structures * * These data structures (see ) are referenced in * compile/$KERNEL/ioconf.c, which is generated by config(8). * Their names are formed like {device}_{ca,cd}. * * {device}_ca * is used for dynamically allocating driver data, probing and * attaching a device; * * {device}_cd * references all found devices of a type. */ extern struct cfdriver iwm_cd; extern struct cfdriver fd_cd; /* IWM floppy disk controller */ CFATTACH_DECL_NEW(iwm, sizeof(iwm_softc_t), iwm_match, iwm_attach, NULL, NULL); /* Attached floppy disk drives */ CFATTACH_DECL_NEW(fd, sizeof(fd_softc_t), fd_match, fd_attach, NULL, NULL); dev_type_open(fdopen); dev_type_close(fdclose); dev_type_read(fdread); dev_type_write(fdwrite); dev_type_ioctl(fdioctl); dev_type_strategy(fdstrategy); const struct bdevsw fd_bdevsw = { .d_open = fdopen, .d_close = fdclose, .d_strategy = fdstrategy, .d_ioctl = fdioctl, .d_dump = nodump, .d_psize = nosize, .d_discard = nodiscard, .d_flag = D_DISK }; const struct cdevsw fd_cdevsw = { .d_open = fdopen, .d_close = fdclose, .d_read = fdread, .d_write = fdwrite, .d_ioctl = fdioctl, .d_stop = nostop, .d_tty = notty, .d_poll = nopoll, .d_mmap = nommap, .d_kqfilter = nokqfilter, .d_discard = nodiscard, .d_flag = D_DISK }; /* disk(9) framework device switch */ struct dkdriver fd_dkDriver = { .d_strategy = fdstrategy }; /*** Configure the IWM controller ***/ /* * iwm_match * * Is the IWM chip present? Here, *aux is a ptr to struct confargs * (see ), which does not hold any information * to match against. After all, that's what the obio concept is * about: Onboard components that are present depending (only) * on machine type. */ int iwm_match(device_t parent, cfdata_t match, void *aux) { int matched; extern u_long IOBase; /* from mac68k/machdep.c */ extern u_long IWMBase; if (0 == map_iwm_base(IOBase)) { /* * Unknown machine HW: * The SWIM II/III chips that are present in post-Q700 * '040 Macs have dropped the IWM register structure. * We know next to nothing about the SWIM. */ matched = 0; if (TRACE_CONFIG) printf("IWM or SWIM not found: Unknown location (SWIM II?).\n"); } else { matched = 1; if (TRACE_CONFIG) { printf("iwm: IWMBase mapped to 0x%lx in VM.\n", IWMBase); } } return matched; } /* * iwm_attach * * The IWM is present, initialize it. Then look up the connected drives * and attach them. */ void iwm_attach(device_t parent, device_t self, void *aux) { int iwmErr; iwm_softc_t *iwm; iwmAttachArgs_t ia; printf(": Apple GCR floppy disk controller\n"); iwm = device_private(self); iwmErr = iwmInit(); if (TRACE_CONFIG) printf("initIWM() says %d.\n", iwmErr); if (0 == iwmErr) { /* Set up the IWM softc */ iwm->maxRetries = 10; /* Look for attached drives */ for (ia.unit = 0; ia.unit < IWM_MAX_DRIVE; ia.unit++) { iwm->fd[ia.unit] = NULL; ia.driveType = getFDType(ia.unit); if (NULL != ia.driveType) config_found(self, (void *)&ia, fd_print); } if (TRACE_CONFIG) printf("iwm: Initialization completed.\n"); } else { printf("iwm: Chip revision not supported (%d)\n", iwmErr); } } /* * iwm_print -- print device configuration. * * If the device is not configured 'controller' it is NULL and * we print a message in the *Attach routine; the return value * of *Print() is ignored. */ int iwm_print(void *aux, const char *controller) { return UNCONF; } /* * map_iwm_base * * Map physical IO address of IWM to VM address */ static int map_iwm_base(vm_offset_t base) { int known; extern u_long IWMBase; switch (current_mac_model->class) { case MACH_CLASSQ: case MACH_CLASSQ2: case MACH_CLASSP580: IWMBase = base + 0x1E000; known = 1; break; case MACH_CLASSII: case MACH_CLASSPB: case MACH_CLASSDUO: case MACH_CLASSIIci: case MACH_CLASSIIsi: case MACH_CLASSIIvx: case MACH_CLASSLC: IWMBase = base + 0x16000; known = 1; break; case MACH_CLASSIIfx: case MACH_CLASSAV: default: /* * Neither IIfx/Q9[05]0 style IOP controllers nor * Q[68]40AV DMA based controllers are supported. */ if (TRACE_CONFIG) printf("Unknown floppy controller chip.\n"); IWMBase = 0L; known = 0; break; } return known; } /*** Configure Sony disk drive(s) ***/ /* * fd_match */ int fd_match(device_t parent, cfdata_t match, void *aux) { int matched, cfUnit; struct cfdata *cfp; iwmAttachArgs_t *fdParams; cfp = match; fdParams = aux; cfUnit = cfp->cf_loc[IWMCF_DRIVE]; matched = (cfUnit == fdParams->unit || cfUnit == -1) ? 1 : 0; if (TRACE_CONFIG) { printf("fdMatch() drive %d ? cfUnit = %d\n", fdParams->unit, cfUnit); } return matched; } /* * fd_attach * * We have checked that the IWM is fine and the drive is present, * so we can attach it. */ void fd_attach(device_t parent, device_t self, void *aux) { iwm_softc_t *iwm; fd_softc_t *fd; iwmAttachArgs_t *ia; int driveInfo; iwm = device_private(parent); fd = device_private(self); fd->sc_dev = self; ia = aux; driveInfo = iwmCheckDrive(ia->unit); fd->currentType = ia->driveType; fd->unit = ia->unit; fd->defaultType = &fdTypes[IWM_800K_GCR]; fd->stepDirection = 0; iwm->fd[ia->unit] = fd; /* iwm has ptr to this drive */ iwm->drives++; bufq_alloc(&fd->bufQueue, "disksort", BUFQ_SORT_CYLINDER); callout_init(&fd->motor_ch, 0); printf(" drive %d: ", fd->unit); if (IWM_NO_DISK & driveInfo) { printf("(drive empty)\n"); } else if (!(IWM_DD_DISK & driveInfo)) { printf("(HD disk -- not supported)\n"); iwmDiskEject(fd->unit); /* XXX */ } else { printf("%s %d cyl, %d head(s)\n", fd->currentType->description, fd->currentType->tracks, fd->currentType->heads); } if (TRACE_CONFIG) { int reg, flags, spl; /* List contents of drive status registers */ spl = spl6(); for (reg = 0; reg < 0x10; reg++) { flags = iwmQueryDrvFlag(fd->unit, reg); printf("iwm: Drive register 0x%x = 0x%x\n", reg, flags); } splx(spl); } disk_init(&fd->diskInfo, device_xname(fd->sc_dev), &fd_dkDriver); disk_attach(&fd->diskInfo); } /* * fdPrint -- print device configuration. * * If the device is not configured 'controller' refers to a name string * we print here. * Else it is NULL and we print a message in the *Attach routine; the * return value of *Print() is ignored. */ int fd_print(void *aux, const char *controller) { iwmAttachArgs_t *ia; ia = aux; if (NULL != controller) aprint_normal("fd%d at %s", ia->unit, controller); return UNCONF; } /** ** Implementation section of driver interface ** ** The prototypes for these functions are set up automagically ** by macros in mac68k/conf.c. Their names are generated from {fd} ** and {open,close,strategy,dump,size,read,write}. The driver entry ** points are then plugged into bdevsw[] and cdevsw[]. **/ /* * fdopen * * Open a floppy disk device. */ int fdopen(dev_t dev, int flags, int devType, struct lwp *l) { fd_softc_t *fd; fdInfo_t *info; int partitionMask; int fdType, fdUnit; int ierr, err; iwm_softc_t *iwm = device_lookup_private(&iwm_cd, 0); /* XXX */ info = NULL; /* XXX shut up egcs */ fd = NULL; /* XXX shut up gcc3 */ /* * See for struct cfdriver, for * DISKUNIT() and for getsoftc(). */ fdType = minor(dev) % MAXPARTITIONS; fdUnit = minor(dev) / MAXPARTITIONS; if (TRACE_OPEN) printf("iwm: Open drive %d", fdUnit); /* Check if device # is valid */ err = (iwm->drives < fdUnit) ? ENXIO : 0; if (!err) { (void)iwmSelectDrive(fdUnit); if (TRACE_OPEN) printf(".\n Get softc"); /* Get fd state */ fd = iwm->fd[fdUnit]; err = (NULL == fd) ? ENXIO : 0; } if (!err) { if (fd->state & IWM_FD_IS_OPEN) { /* * Allow multiple open calls only if for identical * floppy format. */ if (TRACE_OPEN) printf(".\n Drive already opened!\n"); err = (fd->partition == fdType) ? 0 : ENXIO; } else { if (TRACE_OPEN) printf(".\n Get format info"); /* Get format type */ info = fdDeviceToType(fd, dev); if (NULL == info) { err = ENXIO; if (TRACE_OPEN) printf(".\n No such drive.\n"); } } } if (!err && !(fd->state & IWM_FD_IS_OPEN)) { if (TRACE_OPEN) printf(".\n Set diskInfo flags.\n"); fd->writeLabel = 0; /* XXX currently unused */ fd->partition = fdType; fd->currentType = info; fd->drvFlags = iwmCheckDrive(fd->unit); if (fd->drvFlags & IWM_NO_DISK) { err = EIO; #ifdef DIAGNOSTIC printf(" Drive %d is empty.\n", fd->unit); #endif } else { if (!(fd->drvFlags & IWM_WRITABLE) && (flags & FWRITE)) { err = EPERM; #ifdef DIAGNOSTIC printf(" Disk is write protected.\n"); #endif } else { if (!(fd->drvFlags & IWM_DD_DISK)) { err = ENXIO; #ifdef DIAGNOSTIC printf(" HD format not supported.\n"); #endif (void)iwmDiskEject(fd->unit); } else { /* We're open now! */ fd->state |= IWM_FD_IS_OPEN; err = initCylinderCache(fd); } } } } if (!err) { /* * Later, we might not want to recalibrate the drive when it * is already open. For now, it doesn't hurt. */ if (TRACE_OPEN) printf(" Seek track 00 says"); memset(&fd->pos, 0, sizeof(diskPosition_t)); ierr = seek(fd, IWM_SEEK_RECAL); if (TRACE_OPEN) printf(" %d.\n", ierr); err = (0 == ierr) ? 0 : EIO; } if (!err) { /* * Update disklabel if we are not yet open. * (We shouldn't be: We are synchronous.) */ if (fd->diskInfo.dk_openmask == 0) fdGetDiskLabel(fd, dev); partitionMask = (1 << fdType); switch (devType) { case S_IFCHR: fd->diskInfo.dk_copenmask |= partitionMask; break; case S_IFBLK: fd->diskInfo.dk_bopenmask |= partitionMask; break; } fd->diskInfo.dk_openmask = fd->diskInfo.dk_copenmask | fd->diskInfo.dk_bopenmask; } if (TRACE_OPEN) printf("iwm: fdopen() says %d.\n", err); return err; } /* * fdclose */ int fdclose(dev_t dev, int flags, int devType, struct lwp *l) { fd_softc_t *fd; int partitionMask, fdUnit, fdType; iwm_softc_t *iwm = device_lookup_private(&iwm_cd, 0); if (TRACE_CLOSE) printf("iwm: Closing driver."); fdUnit = minor(dev) / MAXPARTITIONS; fdType = minor(dev) % MAXPARTITIONS; fd = iwm->fd[fdUnit]; /* release cylinder cache memory */ if (fd->cbuf != NULL) free(fd->cbuf, M_DEVBUF); partitionMask = (1 << fdType); /* Set state flag. */ fd->state &= ~IWM_FD_IS_OPEN; switch (devType) { case S_IFCHR: fd->diskInfo.dk_copenmask &= ~partitionMask; break; case S_IFBLK: fd->diskInfo.dk_bopenmask &= ~partitionMask; break; } fd->diskInfo.dk_openmask = fd->diskInfo.dk_copenmask | fd->diskInfo.dk_bopenmask; return 0; } /* * fdioctl * * We deal with all the disk-specific ioctls in here even if * we do not support them. */ int fdioctl(dev_t dev, u_long cmd, void *data, int flag, struct lwp *l) { int result, fdUnit, fdType; fd_softc_t *fd; iwm_softc_t *iwm = device_lookup_private(&iwm_cd, 0); int error; if (TRACE_IOCTL) printf("iwm: Execute ioctl... "); /* Check if device # is valid and get its softc */ fdUnit = minor(dev) / MAXPARTITIONS; fdType = minor(dev) % MAXPARTITIONS; if (fdUnit >= iwm->drives) { if (TRACE_IOCTL) { printf("iwm: Wanted device no (%d) is >= %d.\n", fdUnit, iwm->drives); } return ENXIO; } fd = iwm->fd[fdUnit]; result = 0; error = disk_ioctl(&fd->diskInfo, fdType, cmd, data, flag, l); if (error != EPASSTHROUGH) return error; switch (cmd) { case DIOCSDINFO: if (TRACE_IOCTL) printf(" DIOCSDINFO: Set in-core disklabel.\n"); result = ((flag & FWRITE) == 0) ? EBADF : 0; if (result == 0) result = setdisklabel(fd->diskInfo.dk_label, (struct disklabel *)data, 0, fd->diskInfo.dk_cpulabel); break; case DIOCWDINFO: if (TRACE_IOCTL) printf(" DIOCWDINFO: Set in-core disklabel " "& update disk.\n"); result = ((flag & FWRITE) == 0) ? EBADF : 0; if (result == 0) result = setdisklabel(fd->diskInfo.dk_label, (struct disklabel *)data, 0, fd->diskInfo.dk_cpulabel); if (result == 0) result = writedisklabel(dev, fdstrategy, fd->diskInfo.dk_label, fd->diskInfo.dk_cpulabel); break; case DIOCRFORMAT: case DIOCWFORMAT: if (TRACE_IOCTL) printf(" DIOC{R,W}FORMAT: No formatter support (yet?).\n"); result = EINVAL; break; case DIOCSSTEP: if (TRACE_IOCTL) printf(" DIOCSSTEP: IWM does step handshake.\n"); result = EINVAL; break; case DIOCSRETRIES: if (TRACE_IOCTL) printf(" DIOCSRETRIES: Set max. # of retries.\n"); if (*(int *)data < 0) result = EINVAL; else { iwm->maxRetries = *(int *)data; result = 0; } break; case DIOCWLABEL: if (TRACE_IOCTL) printf(" DIOCWLABEL: Set write access to disklabel.\n"); result = ((flag & FWRITE) == 0) ? EBADF : 0; if (result == 0) fd->writeLabel = *(int *)data; break; case DIOCSBAD: if (TRACE_IOCTL) printf(" DIOCSBAD: No bad144-style handling.\n"); result = EINVAL; break; case ODIOCEJECT: case DIOCEJECT: /* XXX Eject disk only when unlocked */ if (TRACE_IOCTL) printf(" DIOCEJECT: Eject disk from unit %d.\n", fd->unit); result = iwmDiskEject(fd->unit); break; case DIOCLOCK: /* XXX Use lock to prevent ejectimg a mounted disk */ if (TRACE_IOCTL) printf(" DIOCLOCK: No need to (un)lock Sony drive.\n"); result = 0; break; default: if (TRACE_IOCTL) printf(" Not a disk related ioctl!\n"); result = ENOTTY; break; } return result; } /* * fdread */ int fdread(dev_t dev, struct uio *uio, int flags) { return physio(fdstrategy, NULL, dev, B_READ, minphys, uio); } /* * fdwrite */ int fdwrite(dev_t dev, struct uio *uio, int flags) { return physio(fdstrategy, NULL, dev, B_WRITE, minphys, uio); } /* * fdstrategy * * Entry point for read and write requests. The strategy routine usually * queues io requests and kicks off the next transfer if the device is idle; * but we get no interrupts from the IWM and have to do synchronous * transfers - no queue. */ void fdstrategy(struct buf *bp) { int fdUnit, err, done, spl; int sectSize, transferSize; diskPosition_t physDiskLoc; fd_softc_t *fd; iwm_softc_t *iwm = device_lookup_private(&iwm_cd, 0); err = 0; done = 0; sectSize = 0; /* XXX shut up gcc3 */ fd = NULL; /* XXX shut up gcc3 */ fdUnit = minor(bp->b_dev) / MAXPARTITIONS; if (TRACE_STRAT) { printf("iwm: fdstrategy()...\n"); printf(" struct buf is at %p\n", bp); printf(" Allocated buffer size (b_bufsize): 0x0%x\n", bp->b_bufsize); printf(" Base address of buffer (b_data): %p\n", bp->b_data); printf(" Bytes to be transferred (b_bcount): 0x0%x\n", bp->b_bcount); printf(" Remaining I/O (b_resid): 0x0%x\n", bp->b_resid); } /* Check for valid fd unit, controller and io request */ if (fdUnit >= iwm->drives) { if (TRACE_STRAT) printf(" No such unit (%d)\n", fdUnit); err = EINVAL; } if (!err) { fd = iwm->fd[fdUnit]; err = (NULL == fd) ? EINVAL : 0; } if (!err) { sectSize = fd->currentType->sectorSize; if (bp->b_blkno < 0 || (bp->b_bcount % sectSize) != 0) { if (TRACE_STRAT) printf(" Illegal transfer size: " "block %lld, %d bytes\n", (long long) bp->b_blkno, bp->b_bcount); err = EINVAL; } } if (!err) { /* Null transfer: Return, nothing to do. */ if (0 == bp->b_bcount) { if (TRACE_STRAT) printf(" Zero transfer length.\n"); done = 1; } } if (!err && !done) { /* What to do if we touch the boundaries of the disk? */ transferSize = (bp->b_bcount + (sectSize - 1)) / sectSize; if (bp->b_blkno + transferSize > fd->currentType->secPerDisk) { if (TRACE_STRAT) { printf("iwm: Transfer beyond end of disk!\n" \ " (Starting block %lld, # of blocks %d," \ " last disk block %d).\n", (long long) bp->b_blkno, transferSize, fd->currentType->secPerDisk); } /* Return EOF if we are exactly at the end of the * disk, EINVAL if we try to reach past the end; else * truncate the request. */ transferSize = fd->currentType->secPerDisk - bp->b_blkno; if (0 == transferSize) { bp->b_resid = bp->b_bcount; done = 1; } else if (0 > transferSize) err = EINVAL; else bp->b_bcount = transferSize << DEV_BSHIFT; } } if (!err && !done) { /* * Calculate cylinder # for disksort(). * * XXX Shouldn't we use the (fake) logical cyl no here? */ remap_geometry(bp->b_blkno, fd->currentType->heads, &physDiskLoc); bp->b_rawblkno = bp->b_blkno; bp->b_cylinder = physDiskLoc.track; if (TRACE_STRAT) { printf(" This job starts at b_blkno %lld; ", (long long) bp->b_blkno); printf("it gets sorted for cylinder # %d.\n", bp->b_cylinder); } spl = splbio(); callout_stop(&fd->motor_ch); bufq_put(fd->bufQueue, bp); if (fd->sc_active == 0) fdstart(fd); splx(spl); } /* Clean up, if necessary */ else { if (TRACE_STRAT) printf(" fdstrategy() finished early, err = %d.\n", err); if (err) bp->b_error = err; bp->b_resid = bp->b_bcount; biodone(bp); } /* Comment on results */ if (TRACE_STRAT) { printf("iwm: fdstrategy() done.\n"); printf(" We have b_resid = %d bytes left, " \ "b_error is %d;\n", bp->b_resid, bp->b_error); printf(" b_flags are 0x0%x.\n", bp->b_flags); } } /* ======================================================================== */ /* * fdstart * * we are called from the strategy() routine to perform a data transfer. * * The disk(9) framework demands we run at splbio(); our caller * takes care of that. * * Wish we had pascalish local functions here... */ /* fdstart FSM states */ enum { state_Init = 0, state_Seek, state_Read, state_Write, state_Flush, state_IOFinish, state_IOErr, state_Fault, state_Exit, state_Done }; static void fdstart(fd_softc_t *fd) { int st; static const char *stateDesc[] = { "Init", "Seek", "Read", "Write", "Flush", "IOFinish", "IOErr", "Fault", "Exit", "Done" }; int (*state[])(fd_softc_t *) = { fdstart_Init, fdstart_Seek, fdstart_Read, fdstart_Write, fdstart_Flush, fdstart_IOFinish, fdstart_IOErr, fdstart_Fault, fdstart_Exit }; st = state_Init; do { if (TRACE_STRAT) printf(" fdstart state %d [%s] ", st, stateDesc[st]); st = (*state[st])(fd); if (TRACE_STRAT) printf(".\n"); } while (st != state_Done); } /* * fdstart_Init * * Set up things */ static int fdstart_Init(fd_softc_t *fd) { struct buf *bp; /* * Get the first entry from the queue. This is the buf we gave to * fdstrategy(); disksort() put it into our softc. */ bp = bufq_peek(fd->bufQueue); if (NULL == bp) { if (TRACE_STRAT) printf("Queue empty: Nothing to do"); return state_Done; } fd->ioDirection = bp->b_flags & B_READ; disk_busy(&fd->diskInfo); if (!(fd->state & IWM_FD_MOTOR_ON)) { iwmMotor(fd->unit, 1); fd->state |= IWM_FD_MOTOR_ON; } fd->current_buffer = bp->b_data; /* XXX - assumes blocks of 512 bytes */ fd->startBlk = bp->b_blkno; fd->iwmErr = 0; fd->ioRetries = 0; /* XXX */ fd->seekRetries = 0; fd->bytesDone = 0; fd->bytesLeft = bp->b_bcount; return state_Seek; } /* * fdstart_Seek */ static int fdstart_Seek(fd_softc_t *fd) { int state; /* Calculate the side/track/sector our block is at. */ if (TRACE_STRAT) printf(" Remap block %lld ", (long long) fd->startBlk); remap_geometry(fd->startBlk, fd->currentType->heads, &fd->pos); if (TRACE_STRAT) printf("to c%d_h%d_s%d ", fd->pos.track, fd->pos.side, fd->pos.sector); if (fd->cachedSide != fd->pos.side) { if (TRACE_STRAT) printf(" (invalidate cache) "); invalidateCylinderCache(fd); fd->cachedSide = fd->pos.side; } /* * If necessary, seek to wanted track. Note that * seek() performs any necessary retries. */ if (fd->pos.track != fd->pos.oldTrack && 0 != (fd->iwmErr = seek(fd, IWM_SEEK_VANILLA))) { state = state_Fault; } else { state = (fd->ioDirection == IWM_WRITE) ? state_Write : state_Read; } return state; } /* * fdstart_Read * * Transfer a sector from disk. Get it from the track cache, if available; * otherwise, while we are at it, store in the cache all the sectors we find * on the way. * * Track buffering reads: * o Look if the sector is already cached. * o Else, read sectors into track cache until we meet the header of * the sector we want. * o Read that sector directly to fs buffer and return. */ static int fdstart_Read(fd_softc_t *fd) { int i; diskPosition_t *pos; sectorHdr_t *shdr; iwm_softc_t *iwm = device_lookup_private(&iwm_cd, 0); /* XXX */ /* Initialize retry counters */ fd->seekRetries = 0; fd->sectRetries = 0; pos = &fd->pos; shdr = &fd->sHdr; if (TRACE_STRAT) printf("<%s c%d_h%d_s%d> ", fd->ioDirection ? "Read" : "Write", pos->track, pos->side, pos->sector); /* Sector already cached? */ i = pos->sector; if (fd->r_slots[i].valid) { if (TRACE_STRAT) printf("(cached)"); memcpy(fd->current_buffer, fd->r_slots[i].secbuf, fd->currentType->sectorSize); return state_IOFinish; } /* Get sector from disk */ shdr->side = pos->side; shdr->sector = pos->sector; shdr->track = pos->track; (void)iwmSelectSide(pos->side); fd->iwmErr = iwmReadSector(&fd->sHdr, fd->r_slots, fd->current_buffer); /* Check possible error conditions */ if (TRACE_STRAT) printf("c%d_h%d_s%d_err(%d)_sr%d ", shdr->track, shdr->side >> 3, shdr->sector, fd->iwmErr, fd->sectRetries); /* IWM IO error? */ if (fd->iwmErr != 0) return state_IOErr; /* Bad seek? Retry */ if (shdr->track != pos->track) { if (TRACE_STRAT) { printf("Wanted track %d, got %d, %d seek retries.\n", pos->track, shdr->track, fd->seekRetries); } if (iwm->maxRetries > fd->seekRetries++) { fd->iwmErr = seek(fd, IWM_SEEK_RECAL); if (TRACE_STRAT) { printf("[%d]", fd->seekRetries); (void)checkTrack(&fd->pos, 1); } } else fd->iwmErr = seekErr; return (0 == fd->iwmErr) ? state_Read : state_Fault; } /* Sector not found? */ if (shdr->sector != pos->sector) { if (TRACE_STRAT) printf("c%d_h%d_s%d sect not found, %d retries ", shdr->track, shdr->side >> 3, shdr->sector, fd->sectRetries); fd->iwmErr = noAdrMkErr; return state_Fault; } /* Success */ return state_IOFinish; } /* * fdstart_Write * * Insert a sector into a write buffer slot and mark the slot dirty. */ static int fdstart_Write(fd_softc_t *fd) { int i; /* XXX let's see... */ fd->sHdr.side = fd->pos.side; fd->sHdr.sector = fd->pos.sector; fd->sHdr.track = fd->pos.track; i = fd->pos.sector; fd->w_slots[i].secbuf = fd->current_buffer; fd->w_slots[i].valid = 1; /* "valid" is a dirty buffer here */ if (TRACE_STRAT) printf("<%s c%d_h%d_s%d> (cached) ", fd->ioDirection ? "Read" : "Write", fd->pos.track, fd->pos.side, fd->pos.sector); return state_IOFinish; } /* * fdstart_Flush * * Flush dirty buffers in the track cache to disk. */ static int fdstart_Flush(fd_softc_t *fd) { int state; int i, dcnt; diskPosition_t *pos; sectorHdr_t *shdr; iwm_softc_t *iwm = device_lookup_private(&iwm_cd, 0); /* XXX */ dcnt = 0; pos = &fd->pos; shdr = &fd->sHdr; if (TRACE_STRAT) { for (i=0; i < IWM_MAX_GCR_SECTORS; i++) if (fd->w_slots[i].valid) { printf("|%d", i); dcnt++; } printf("|\n"); printf(" <%s c%d_h%d_#s%d>\n", fd->ioDirection ? "Read" : "Write", pos->track, pos->side, dcnt); } (void)iwmSelectSide(pos->side); fd->iwmErr = iwmWriteSector(&fd->sHdr, fd->w_slots); switch (fd->iwmErr) { case noErr: /* Success */ #ifdef DIAGNOSTIC /* XXX Panic if buffer not clean? */ for (i=0; iw_slots[i].valid) printf("Oops! not flushed.\n", fd->pos.track, fd->pos.side, fd->pos.sector); #endif if (TRACE_STRAT) printf("(Cache flushed, re-initialize) "); for (i=0; i < IWM_MAX_GCR_SECTORS; i++) { fd->w_slots[i].valid = 0; fd->w_slots[i].secbuf = NULL; } fd->seekRetries = 0; state = state_Exit; break; case seekErr: /* Bad seek? Retry */ if (TRACE_STRAT) { printf("Wanted track %d, got %d, %d seek retries.\n", pos->track, shdr->track, fd->seekRetries); } if (iwm->maxRetries > fd->seekRetries++) { fd->iwmErr = seek(fd, IWM_SEEK_RECAL); if (TRACE_STRAT) { printf("[%d]", fd->seekRetries); } } state = (0 == fd->iwmErr) ? state_Exit : state_Fault; break; default: /* General IWM IO error? */ state = state_IOErr; } return state; } /* * fdstart_IOFinish * * Prepare for next block, if any is available */ static int fdstart_IOFinish(fd_softc_t *fd) { int state; if (DISABLED && TRACE_STRAT) printf("%s c%d_h%d_s%d ok ", fd->ioDirection ? "Read" : "Write", fd->sHdr.track, fd->sHdr.side >> 3, fd->sHdr.sector); fd->bytesDone += fd->currentType->sectorSize; fd->bytesLeft -= fd->currentType->sectorSize; fd->current_buffer += fd->currentType->sectorSize; /* * Instead of recalculating the chs mapping for * each and every sector, check for * 'current sector# <= max sector#' and recalculate * after overflow. */ fd->startBlk++; if (fd->bytesLeft > 0) { if (++fd->pos.sector < fd->pos.maxSect) { if (TRACE_STRAT) printf("continue"); state = (fd->ioDirection == IWM_WRITE) ? state_Write : state_Read; } else { /* * Invalidate read cache when changing track; * flush write cache to disk. */ if (fd->ioDirection == IWM_WRITE) { if (TRACE_STRAT) printf("flush "); state = (state_Exit == fdstart_Flush(fd)) ? state_Seek : state_IOErr; } else { if (TRACE_STRAT) printf("step "); invalidateCylinderCache(fd); state = state_Seek; } } } else { state = (fd->ioDirection == IWM_WRITE) ? state_Flush : state_Exit; } return state; } /* * fdstart_IOErr * * Bad IO, repeat */ static int fdstart_IOErr(fd_softc_t *fd) { int state; iwm_softc_t *iwm = device_lookup_private(&iwm_cd, 0); /* XXX */ #ifdef DIAGNOSTIC printf("iwm%sSector() err = %d, %d retries, on c%d_h%d_s%d.\n", fd->ioDirection ? "Read" : "Write", fd->iwmErr, fd->ioRetries, fd->pos.track, fd->pos.side, fd->pos.sector); #endif /* XXX Do statistics */ if (fd->ioRetries++ < iwm->maxRetries) state = (fd->ioDirection == IWM_WRITE) ? state_Flush : state_Read; else state = state_Fault; return state; } /* * fdstart_Fault * * A non-recoverable error */ static int fdstart_Fault(fd_softc_t *fd) { #ifdef DIAGNOSTIC printf("Seek retries %d, IO retries %d, sect retries %d :\n" \ "\t\t only found c%d_h%d_s%d \n", fd->seekRetries, fd->ioRetries, fd->sectRetries, fd->sHdr.track, fd->sHdr.side >> 3, fd->sHdr.sector); printf("A non-recoverable error: %d ", fd->iwmErr); #else /* ARGSUSED */ #endif return state_Exit; } /* * fdstart_Exit * * We are done, for good or bad */ static int fdstart_Exit(fd_softc_t *fd) { struct buf *bp; #ifdef DIAGNOSTIC int i; #endif invalidateCylinderCache(fd); #ifdef DIAGNOSTIC /* XXX Panic if buffer not clean? */ for (i=0; iw_slots[i].valid) printf("Oops! not flushed.\n", fd->pos.track, fd->pos.side, fd->pos.sector); #endif bp = bufq_get(fd->bufQueue); bp->b_resid = fd->bytesLeft; bp->b_error = (0 == fd->iwmErr) ? 0 : EIO; if (TRACE_STRAT) { printf(" fdstart() finished job; fd->iwmErr = %d, b_error = %d", fd->iwmErr, bp->b_error); if (DISABLED) hexDump(bp->b_data, bp->b_bcount); } if (DISABLED && TRACE_STRAT) printf(" Next buf (bufQueue first) at %p\n", bufq_peek(fd->bufQueue)); disk_unbusy(&fd->diskInfo, bp->b_bcount - bp->b_resid, (bp->b_flags & B_READ)); biodone(bp); /* * Stop motor after 10s * * XXX Unloading the module while the timeout is still * running WILL crash the machine. */ callout_reset(&fd->motor_ch, 10 * hz, motor_off, fd); return state_Done; } /* * remap_geometry * * Remap the rigid UN*X view of a disk's cylinder/sector geometry * to our zone recorded real Sony drive by splitting the disk * into zones. * * Loop { * Look if logical block number is in current zone * NO: Add # of tracks for current zone to track counter * Process next zone * * YES: Subtract (number of first sector of current zone times heads) * from logical block number, then break up the difference * in tracks/side/sectors (spt is constant within a zone). * Done * } */ static void remap_geometry(daddr_t block, int heads, diskPosition_t *loc) { int zone, spt; extern diskZone_t diskZones[]; spt = 0; /* XXX Shut up egcs warning */ loc->oldTrack = loc->track; loc->track = 0; for (zone = 0; zone < IWM_GCR_DISK_ZONES; zone++) { if (block >= heads * (diskZones[zone].lastBlock + 1)) { /* Process full zones */ loc->track += diskZones[zone].tracks; } else { /* Process partial zone */ spt = diskZones[zone].sectPerTrack; block -= heads * diskZones[zone].firstBlock; loc->track += block / (spt * heads); loc->sector = (block % spt); loc->side = (block % (spt * heads)) / spt; break; } } loc->maxSect = spt; } /* * motor_off * * Callback for timeout() */ static void motor_off(void *param) { int spl; fd_softc_t *fd; fd = param; if (TRACE_STRAT) printf("iwm: Switching motor OFF (timeout).\n"); spl = spl6(); (void)iwmMotor(fd->unit, 0); fd->state &= ~IWM_FD_MOTOR_ON; splx(spl); } /* * fdGetDiskLabel * * Set up disk label with parameters from current disk type. * Then call the generic disklabel read routine which tries to * read a label from disk and insert it. If it doesn't exist use * our defaults. */ static void fdGetDiskLabel(fd_softc_t *fd, dev_t dev) { const char *msg; int fdType; struct disklabel *lp; struct cpu_disklabel *clp; if (TRACE_IOCTL) printf("iwm: fdGetDiskLabel() for disk %" PRIu64 ".\n", (dev_t) (minor(dev) / MAXPARTITIONS)); fdType = minor(dev) % MAXPARTITIONS; lp = fd->diskInfo.dk_label; clp = fd->diskInfo.dk_cpulabel; memset(lp, 0, sizeof(struct disklabel)); memset(clp, 0, sizeof(struct cpu_disklabel)); /* * How to describe a drive with a variable # of sectors per * track (8..12) and variable rpm (300..550)? Apple came up * with ZBR in 1983! Un*x drive management sucks. */ lp->d_type = DKTYPE_FLOPPY; lp->d_rpm = 300; lp->d_secsize = fd->currentType->sectorSize; lp->d_ntracks = fd->currentType->heads; lp->d_ncylinders = fd->currentType->tracks; lp->d_nsectors = fd->currentType->secPerTrack; lp->d_secpercyl = fd->currentType->secPerCyl; lp->d_secperunit = fd->currentType->secPerDisk; lp->d_interleave = fd->currentType->interleave; lp->d_trkseek = fd->currentType->stepRate; strcpy(lp->d_typename, dktypenames[DKTYPE_FLOPPY]); strncpy(lp->d_packname, "fictitious", sizeof(lp->d_packname)); lp->d_npartitions = fdType + 1; lp->d_partitions[fdType].p_offset = 0; lp->d_partitions[fdType].p_size = lp->d_secperunit; lp->d_partitions[fdType].p_fstype = FS_BSDFFS; lp->d_partitions[fdType].p_fsize = 512; lp->d_partitions[fdType].p_frag = 8; lp->d_magic = DISKMAGIC; lp->d_magic2 = DISKMAGIC; lp->d_checksum = dkcksum(lp); /* * Call the generic disklabel extraction routine. If we don't * find a label on disk, keep our faked one. */ if (TRACE_OPEN) printf(" now calling readdisklabel()...\n"); msg = readdisklabel(dev, fdstrategy, lp, clp); if (msg == NULL) { strncpy(lp->d_packname, "default label", sizeof(lp->d_packname)); /* XXX - ?? */ } #ifdef IWM_DEBUG else printf("iwm: %s.\n", msg); #endif if (TRACE_OPEN) fdPrintDiskLabel(lp); } /* * initCylinderCache * * Allocate cylinder cache and set up pointers to sectors. */ static int initCylinderCache(fd_softc_t *fd) { int i; int err; int secsize; err = 0; secsize = fd->currentType->sectorSize; fd->cachedSide = 0; fd->cbuf = (unsigned char *) malloc(IWM_MAX_GCR_SECTORS * secsize, M_DEVBUF, M_WAITOK); if (NULL == fd->cbuf) err = ENOMEM; else for (i=0; i < IWM_MAX_GCR_SECTORS; i++) { fd->w_slots[i].valid = 0; fd->w_slots[i].secbuf = NULL; fd->r_slots[i].valid = 0; fd->r_slots[i].secbuf = fd->cbuf + i * secsize; } return err; } /* * invalidateCylinderCache * * Switching cylinders (tracks?) invalidates the read cache. */ static void invalidateCylinderCache(fd_softc_t *fd) { int i; fd->cachedSide = 0; for (i=0; i < IWM_MAX_GCR_SECTORS; i++) { fd->r_slots[i].valid = 0; } } /* * getFDType * * return pointer to disk format description */ static fdInfo_t * getFDType(short unit) { int driveFlags; fdInfo_t *thisType; extern fdInfo_t fdTypes[]; driveFlags = iwmCheckDrive(unit); /* * Drive flags are: Bit 0 - 1 = Drive is double sided * 1 - 1 = No disk inserted * 2 - 1 = Motor is off * 3 - 1 = Disk is writable * 4 - 1 = Disk is DD (800/720K) * 31 - 1 = No drive / invalid drive # */ if (TRACE_CONFIG) { printf("iwm: Drive %d says 0x0%x (%d)\n", unit, driveFlags, driveFlags); } if (driveFlags < 0) thisType = NULL;/* no such drive */ else if (driveFlags & 0x01) thisType = &fdTypes[1]; /* double sided */ else thisType = &fdTypes[0]; /* single sided */ return thisType; } /* * fdDeviceToType * * maps the minor device number (elsewhere: partition type) to * a corresponding disk format. * This is currently: * fdXa default (800K GCR) * fdXb 400K GCR * fdXc 800K GCR */ static fdInfo_t * fdDeviceToType(fd_softc_t *fd, dev_t dev) { int type; fdInfo_t *thisInfo; /* XXX This broke with egcs 1.0.2 */ /* extern fdInfo_t fdTypes[]; */ type = minor(dev) % MAXPARTITIONS; /* 1,2,... */ if (type > sizeof(fdTypes) / sizeof(fdTypes[0])) thisInfo = NULL; else thisInfo = (type == 0) ? fd->defaultType : &fdTypes[type - 1]; return thisInfo; } /* * seek * * Step to given track; optionally restore to track zero before * and/or verify correct track. * Note that any necessary retries are done here. * We keep the current position on disk in a 'struct diskPosition'. */ static int seek(fd_softc_t *fd, int style) { int state, done; int err, ierr; int steps; diskPosition_t *loc; sectorHdr_t hdr; char action[32]; iwm_softc_t *iwm = device_lookup_private(&iwm_cd, 0); /* XXX */ const char *stateDesc[] = { "Init", "Seek", "Recalibrate", "Verify", "Exit" }; enum { seek_state_Init = 0, seek_state_Seek, seek_state_Recalibrate, seek_state_Verify, seek_state_Exit }; /* XXX egcs */ done = err = ierr = 0; fd->seekRetries = 0; fd->verifyRetries = 0; loc = &fd->pos; state = seek_state_Init; do { if (TRACE_STEP) printf(" seek state %d [%s].\n", state, stateDesc[state]); switch (state) { case seek_state_Init: if (TRACE_STEP) printf("Current track is %d, new track %d.\n", loc->oldTrack, loc->track); memset(&hdr, 0, sizeof(hdr)); err = ierr = 0; fd->seekRetries = 0; fd->verifyRetries = 0; state = (style == IWM_SEEK_RECAL) ? seek_state_Recalibrate : seek_state_Seek; done = 0; break; case seek_state_Recalibrate: ierr = iwmTrack00(); if (ierr == 0) { loc->oldTrack = 0; state = seek_state_Seek; } else { strncpy(action, "Recalibrate (track 0)", sizeof(action)); state = seek_state_Exit; } break; case seek_state_Seek: ierr = 0; steps = loc->track - loc->oldTrack; if (steps != 0) ierr = iwmSeek(steps); if (ierr == 0) { /* No error or nothing to do */ state = (style == IWM_SEEK_VERIFY) ? seek_state_Verify : seek_state_Exit; } else { if (fd->seekRetries++ < iwm->maxRetries) state = seek_state_Recalibrate; else { strncpy(action, "Seek retries", sizeof(action)); state = seek_state_Exit; } } break; case seek_state_Verify: ierr = checkTrack(loc, TRACE_STEP); if (ierr == 0 && loc->track == hdr.track) state = seek_state_Exit; else { if (fd->verifyRetries++ < iwm->maxRetries) state = seek_state_Recalibrate; else { strncpy(action, "Verify retries", sizeof(action)); state = seek_state_Exit; } } break; case seek_state_Exit: if (ierr == 0) { loc->oldTrack = loc->track; err = 0; /* Give the head some time to settle down */ delay(3000); } else { #ifdef DIAGNOSTIC printf(" seek() action \"%s\", err = %d.\n", action, ierr); #endif err = EIO; } done = 1; break; } } while (!done); return err; } /* * checkTrack * * After positioning, get a sector header for validation */ static int checkTrack(diskPosition_t *loc, int debugFlag) { int spl; int iwmErr; sectorHdr_t hdr; spl = spl6(); iwmSelectSide(loc->side); iwmErr = iwmReadSectHdr(&hdr); splx(spl); if (debugFlag) { printf("Seeked for %d, got at %d, Hdr read err %d.\n", loc->track, hdr.track, iwmErr); } return iwmErr; } /* Debugging stuff */ static void hexDump(u_char *buf, int len) { int i, j; u_char ch; printf("\nDump %d from %p:\n", len, buf); i = j = 0; if (NULL != buf) do { printf("%04x: ", i); for (j = 0; j < 8; j++) printf("%02x ", buf[i + j]); printf(" "); for (j = 8; j < 16; j++) printf("%02x ", buf[i + j]); printf(" "); for (j = 0; j < 16; j++) { ch = buf[i + j]; if (ch > 31 && ch < 127) printf("%c", ch); else printf("."); } printf("\n"); i += 16; } while (len > i); } static void fdPrintDiskLabel(struct disklabel *lp) { int i; printf("iwm: Disklabel entries of current floppy.\n"); printf("\t d_type:\t%d (%s)\n", lp->d_type, dktypenames[lp->d_type]); printf("\t d_typename:\t%s\n", lp->d_typename); printf("\t d_packname:\t%s\n", lp->d_packname); printf("\t d_secsize:\t%d\n", lp->d_secsize); printf("\t d_nsectors:\t%d\n", lp->d_nsectors); printf("\t d_ntracks:\t%d\n", lp->d_ntracks); printf("\t d_ncylinders:\t%d\n", lp->d_ncylinders); printf("\t d_secpercyl:\t%d\n", lp->d_secpercyl); printf("\t d_secperunit:\t%d\n", lp->d_secperunit); printf("\t d_rpm: \t%d\n", lp->d_rpm); printf("\t d_interleave:\t%d\n", lp->d_interleave); printf("\t d_trkseek:\t%d [ms]\n", lp->d_trkseek); printf(" d_npartitions:\t%d\n", lp->d_npartitions); for (i = 0; i < lp->d_npartitions; i++) { printf("\t d_partitions[%d].p_offset:\t%d\n", i, lp->d_partitions[i].p_offset); printf("\t d_partitions[%d].p_size:\t%d\n", i, lp->d_partitions[i].p_size); printf("\t d_partitions[%d].p_fstype:\t%d (%s)\n", i, lp->d_partitions[i].p_fstype, fstypenames[lp->d_partitions[i].p_fstype]); printf("\t d_partitions[%d].p_frag:\t%d\n", i, lp->d_partitions[i].p_frag); printf("\n"); } }