/* * Low-level libblkid probing API * * Copyright (C) 2008-2009 Karel Zak * * This file may be redistributed under the terms of the * GNU Lesser General Public License. */ /** * SECTION: lowprobe * @title: Low-level probing * @short_description: low-level prober initialization * * The low-level probing routines always and directly read information from * the selected (see blkid_probe_set_device()) device. * * The probing routines are grouped together into separate chains. Currently, * the library provides superblocks, partitions and topology chains. * * The probing routines is possible to filter (enable/disable) by type (e.g. * fstype "vfat" or partype "gpt") or by usage flags (e.g. BLKID_USAGE_RAID). * These filters are per-chain. Note that always when you touch the chain * filter the current probing position is reset and probing starts from * scratch. It means that the chain filter should not be modified during * probing, for example in loop where you call blkid_do_probe(). * * For more details see the chain specific documentation. * * The low-level API provides two ways how access to probing results. * * 1. The NAME=value (tag) interface. This interface is older and returns all data * as strings. This interface is generic for all chains. * * 2. The binary interfaces. These interfaces return data in the native formats. * The interface is always specific to the probing chain. * * Note that the previous probing result (binary or NAME=value) is always * zeroized when a chain probing function is called. For example: * * * * blkid_probe_enable_partitions(pr, TRUE); * blkid_probe_enable_superblocks(pr, FALSE); * * blkid_do_safeprobe(pr); * * * * overwrites the previous probing result for the partitions chain, the superblocks * result is not modified. */ /** * SECTION: lowprobe-tags * @title: Low-level tags * @short_description: generic NAME=value interface. * * The probing routines inside the chain are mutually exclusive by default -- * only few probing routines are marked as "tolerant". The "tolerant" probing * routines are used for filesystem which can share the same device with any * other filesystem. The blkid_do_safeprobe() checks for the "tolerant" flag. * * The SUPERBLOCKS chain is enabled by default. The all others chains is * necessary to enable by blkid_probe_enable_'CHAINNAME'(). See chains specific * documentation. * * The blkid_do_probe() function returns a result from only one probing * routine, and the next call from the next probing routine. It means you need * to call the function in loop, for example: * * * * while((blkid_do_probe(pr) == 0) * ... use result ... * * * * The blkid_do_safeprobe() is the same as blkid_do_probe(), but returns only * first probing result for every enabled chain. This function checks for * ambivalent results (e.g. more "intolerant" filesystems superblocks on the * device). * * The probing result is set of NAME=value pairs (the NAME is always unique). */ #include #include #include #include #include #include #include #ifdef HAVE_LINUX_CDROM_H #include #endif #ifdef HAVE_SYS_STAT_H #include #endif #ifdef HAVE_ERRNO_H #include #endif #include #include #include #include #include "blkidP.h" #include "all-io.h" #include "sysfs.h" #include "strutils.h" #include "list.h" /* * All supported chains */ static const struct blkid_chaindrv *chains_drvs[] = { [BLKID_CHAIN_SUBLKS] = &superblocks_drv, [BLKID_CHAIN_TOPLGY] = &topology_drv, [BLKID_CHAIN_PARTS] = &partitions_drv }; static void blkid_probe_reset_values(blkid_probe pr); /** * blkid_new_probe: * * Returns: a pointer to the newly allocated probe struct or NULL in case of error. */ blkid_probe blkid_new_probe(void) { int i; blkid_probe pr; blkid_init_debug(0); pr = calloc(1, sizeof(struct blkid_struct_probe)); if (!pr) return NULL; DBG(LOWPROBE, ul_debug("allocate a new probe")); /* initialize chains */ for (i = 0; i < BLKID_NCHAINS; i++) { pr->chains[i].driver = chains_drvs[i]; pr->chains[i].flags = chains_drvs[i]->dflt_flags; pr->chains[i].enabled = chains_drvs[i]->dflt_enabled; } INIT_LIST_HEAD(&pr->buffers); INIT_LIST_HEAD(&pr->values); return pr; } /* * Clone @parent, the new clone shares all, but except: * * - probing result * - buffers if another device (or offset) is set to the prober */ blkid_probe blkid_clone_probe(blkid_probe parent) { blkid_probe pr; if (!parent) return NULL; DBG(LOWPROBE, ul_debug("allocate a probe clone")); pr = blkid_new_probe(); if (!pr) return NULL; pr->fd = parent->fd; pr->off = parent->off; pr->size = parent->size; pr->devno = parent->devno; pr->disk_devno = parent->disk_devno; pr->blkssz = parent->blkssz; pr->flags = parent->flags; pr->parent = parent; pr->flags &= ~BLKID_FL_PRIVATE_FD; return pr; } /** * blkid_new_probe_from_filename: * @filename: device or regular file * * This function is same as call open(filename), blkid_new_probe() and * blkid_probe_set_device(pr, fd, 0, 0). * * The @filename is closed by blkid_free_probe() or by the * blkid_probe_set_device() call. * * Returns: a pointer to the newly allocated probe struct or NULL in case of * error. */ blkid_probe blkid_new_probe_from_filename(const char *filename) { int fd; blkid_probe pr = NULL; fd = open(filename, O_RDONLY|O_CLOEXEC); if (fd < 0) return NULL; pr = blkid_new_probe(); if (!pr) goto err; if (blkid_probe_set_device(pr, fd, 0, 0)) goto err; pr->flags |= BLKID_FL_PRIVATE_FD; return pr; err: if (fd >= 0) close(fd); blkid_free_probe(pr); return NULL; } /** * blkid_free_probe: * @pr: probe * * Deallocates the probe struct, buffers and all allocated * data that are associated with this probing control struct. */ void blkid_free_probe(blkid_probe pr) { int i; if (!pr) return; for (i = 0; i < BLKID_NCHAINS; i++) { struct blkid_chain *ch = &pr->chains[i]; if (ch->driver->free_data) ch->driver->free_data(pr, ch->data); free(ch->fltr); } if ((pr->flags & BLKID_FL_PRIVATE_FD) && pr->fd >= 0) close(pr->fd); blkid_probe_reset_buffers(pr); blkid_probe_reset_values(pr); blkid_free_probe(pr->disk_probe); DBG(LOWPROBE, ul_debug("free probe")); free(pr); } void blkid_probe_free_value(struct blkid_prval *v) { if (!v) return; list_del(&v->prvals); free(v->data); DBG(LOWPROBE, ul_debug(" free value %s", v->name)); free(v); } /* * Removes chain values from probing result. */ void blkid_probe_chain_reset_values(blkid_probe pr, struct blkid_chain *chn) { struct list_head *p, *pnext; if (list_empty(&pr->values)) return; DBG(LOWPROBE, ul_debug("Resetting %s values", chn->driver->name)); list_for_each_safe(p, pnext, &pr->values) { struct blkid_prval *v = list_entry(p, struct blkid_prval, prvals); if (v->chain == chn) blkid_probe_free_value(v); } } static void blkid_probe_chain_reset_position(struct blkid_chain *chn) { chn->idx = -1; } /* * Move chain values from probing result to @vals */ int blkid_probe_chain_save_values(blkid_probe pr, struct blkid_chain *chn, struct list_head *vals) { struct list_head *p, *pnext; struct blkid_prval *v; DBG(LOWPROBE, ul_debug("saving %s values", chn->driver->name)); list_for_each_safe(p, pnext, &pr->values) { v = list_entry(p, struct blkid_prval, prvals); if (v->chain != chn) continue; list_del(&v->prvals); INIT_LIST_HEAD(&v->prvals); list_add_tail(&v->prvals, vals); } return 0; } /* * Appends values from @vals to the probing result */ void blkid_probe_append_values_list(blkid_probe pr, struct list_head *vals) { DBG(LOWPROBE, ul_debug("appending values")); list_splice(vals, &pr->values); INIT_LIST_HEAD(vals); } void blkid_probe_free_values_list(struct list_head *vals) { if (!vals) return; DBG(LOWPROBE, ul_debug("freeing values list")); while (!list_empty(vals)) { struct blkid_prval *v = list_entry(vals->next, struct blkid_prval, prvals); blkid_probe_free_value(v); } } struct blkid_chain *blkid_probe_get_chain(blkid_probe pr) { return pr->cur_chain; } static const char *blkid_probe_get_probername(blkid_probe pr) { struct blkid_chain *chn = blkid_probe_get_chain(pr); if (chn && chn->idx >= 0 && (unsigned)chn->idx < chn->driver->nidinfos) return chn->driver->idinfos[chn->idx]->name; return NULL; } void *blkid_probe_get_binary_data(blkid_probe pr, struct blkid_chain *chn) { int rc, org_prob_flags; struct blkid_chain *org_chn; /* save the current setting -- the binary API has to be completely * independent on the current probing status */ org_chn = pr->cur_chain; org_prob_flags = pr->prob_flags; pr->cur_chain = chn; pr->prob_flags = 0; chn->binary = TRUE; blkid_probe_chain_reset_position(chn); rc = chn->driver->probe(pr, chn); chn->binary = FALSE; blkid_probe_chain_reset_position(chn); /* restore the original setting */ pr->cur_chain = org_chn; pr->prob_flags = org_prob_flags; if (rc != 0) return NULL; DBG(LOWPROBE, ul_debug("returning %s binary data", chn->driver->name)); return chn->data; } /** * blkid_reset_probe: * @pr: probe * * Zeroize probing results and resets the current probing (this has impact to * blkid_do_probe() only). This function does not touch probing filters and * keeps assigned device. */ void blkid_reset_probe(blkid_probe pr) { int i; blkid_probe_reset_values(pr); blkid_probe_set_wiper(pr, 0, 0); pr->cur_chain = NULL; for (i = 0; i < BLKID_NCHAINS; i++) blkid_probe_chain_reset_position(&pr->chains[i]); } /*** static int blkid_probe_dump_filter(blkid_probe pr, int chain) { struct blkid_chain *chn; int i; if (!pr || chain < 0 || chain >= BLKID_NCHAINS) return -1; chn = &pr->chains[chain]; if (!chn->fltr) return -1; for (i = 0; i < chn->driver->nidinfos; i++) { const struct blkid_idinfo *id = chn->driver->idinfos[i]; DBG(LOWPROBE, ul_debug("%d: %s: %s", i, id->name, blkid_bmp_get_item(chn->fltr, i) ? "disabled" : "enabled <--")); } return 0; } ***/ /* * Returns properly initialized chain filter */ unsigned long *blkid_probe_get_filter(blkid_probe pr, int chain, int create) { struct blkid_chain *chn; if (chain < 0 || chain >= BLKID_NCHAINS) return NULL; chn = &pr->chains[chain]; /* always when you touch the chain filter all indexes are reset and * probing starts from scratch */ blkid_probe_chain_reset_position(chn); pr->cur_chain = NULL; if (!chn->driver->has_fltr || (!chn->fltr && !create)) return NULL; if (!chn->fltr) chn->fltr = calloc(1, blkid_bmp_nbytes(chn->driver->nidinfos)); else memset(chn->fltr, 0, blkid_bmp_nbytes(chn->driver->nidinfos)); /* blkid_probe_dump_filter(pr, chain); */ return chn->fltr; } /* * Generic private functions for filter setting */ int __blkid_probe_invert_filter(blkid_probe pr, int chain) { size_t i; struct blkid_chain *chn; chn = &pr->chains[chain]; if (!chn->driver->has_fltr || !chn->fltr) return -1; for (i = 0; i < blkid_bmp_nwords(chn->driver->nidinfos); i++) chn->fltr[i] = ~chn->fltr[i]; DBG(LOWPROBE, ul_debug("probing filter inverted")); /* blkid_probe_dump_filter(pr, chain); */ return 0; } int __blkid_probe_reset_filter(blkid_probe pr, int chain) { return blkid_probe_get_filter(pr, chain, FALSE) ? 0 : -1; } int __blkid_probe_filter_types(blkid_probe pr, int chain, int flag, char *names[]) { unsigned long *fltr; struct blkid_chain *chn; size_t i; fltr = blkid_probe_get_filter(pr, chain, TRUE); if (!fltr) return -1; chn = &pr->chains[chain]; for (i = 0; i < chn->driver->nidinfos; i++) { int has = 0; const struct blkid_idinfo *id = chn->driver->idinfos[i]; char **n; for (n = names; *n; n++) { if (!strcmp(id->name, *n)) { has = 1; break; } } if (has) { if (flag & BLKID_FLTR_NOTIN) blkid_bmp_set_item(fltr, i); } else if (flag & BLKID_FLTR_ONLYIN) blkid_bmp_set_item(fltr, i); } DBG(LOWPROBE, ul_debug("%s: a new probing type-filter initialized", chn->driver->name)); /* blkid_probe_dump_filter(pr, chain); */ return 0; } static struct blkid_bufinfo *read_buffer(blkid_probe pr, uint64_t real_off, uint64_t len) { ssize_t ret; struct blkid_bufinfo *bf = NULL; if (blkid_llseek(pr->fd, real_off, SEEK_SET) < 0) { errno = 0; return NULL; } /* someone trying to overflow some buffers? */ if (len > ULONG_MAX - sizeof(struct blkid_bufinfo)) { errno = ENOMEM; return NULL; } /* allocate info and space for data by one malloc call */ bf = calloc(1, sizeof(struct blkid_bufinfo) + len); if (!bf) { errno = ENOMEM; return NULL; } bf->data = ((unsigned char *) bf) + sizeof(struct blkid_bufinfo); bf->len = len; bf->off = real_off; INIT_LIST_HEAD(&bf->bufs); DBG(LOWPROBE, ul_debug("\tread: off=%"PRIu64" len=%"PRIu64"", real_off, len)); ret = read(pr->fd, bf->data, len); if (ret != (ssize_t) len) { DBG(LOWPROBE, ul_debug("\tread failed: %m")); free(bf); /* I/O errors on CDROMs are non-fatal to work with hybrid * audio+data disks */ if (ret >= 0 || blkid_probe_is_cdrom(pr)) errno = 0; return NULL; } return bf; } /* * Search in buffers we already in memory */ static struct blkid_bufinfo *get_cached_buffer(blkid_probe pr, uint64_t off, uint64_t len) { uint64_t real_off = pr->off + off; struct list_head *p; list_for_each(p, &pr->buffers) { struct blkid_bufinfo *x = list_entry(p, struct blkid_bufinfo, bufs); if (real_off >= x->off && real_off + len <= x->off + x->len) { DBG(BUFFER, ul_debug("\treuse: off=%"PRIu64" len=%"PRIu64" (for off=%"PRIu64" len=%"PRIu64")", x->off, x->len, real_off, len)); return x; } } return NULL; } /* * Zeroize in-memory data in already read buffer. The next blkid_probe_get_buffer() * will return modified buffer. This is usable when you want to call the same probing * function more than once and hide previously detected magic strings. * * See blkid_probe_hide_range(). */ static int hide_buffer(blkid_probe pr, uint64_t off, uint64_t len) { uint64_t real_off = pr->off + off; struct list_head *p; int ct = 0; list_for_each(p, &pr->buffers) { struct blkid_bufinfo *x = list_entry(p, struct blkid_bufinfo, bufs); unsigned char *data; if (real_off >= x->off && real_off + len <= x->off + x->len) { assert(x->off <= real_off); assert(x->off + x->len >= real_off + len); data = real_off ? x->data + (real_off - x->off) : x->data; DBG(BUFFER, ul_debug("\thidding: off=%"PRIu64" len=%"PRIu64, off, len)); memset(data, 0, len); ct++; } } return ct == 0 ? -EINVAL : 0; } /* * Note that @off is offset within probing area, the probing area is defined by * pr->off and pr->size. */ unsigned char *blkid_probe_get_buffer(blkid_probe pr, uint64_t off, uint64_t len) { struct blkid_bufinfo *bf = NULL; uint64_t real_off = pr->off + off; /* DBG(BUFFER, ul_debug("\t>>>> off=%ju, real-off=%ju (probe <%ju..%ju>, len=%ju", off, real_off, pr->off, pr->off + pr->size, len)); */ if (pr->size == 0) { errno = EINVAL; return NULL; } if (len == 0 || (!S_ISCHR(pr->mode) && pr->off + pr->size < real_off + len)) { DBG(BUFFER, ul_debug("\t ignore: request out of probing area")); errno = 0; return NULL; } if (pr->parent && pr->parent->devno == pr->devno && pr->parent->off <= pr->off && pr->parent->off + pr->parent->size >= pr->off + pr->size) { /* * This is a cloned prober and points to the same area as * parent. Let's use parent's buffers. * * Note that pr->off (and pr->parent->off) is always from the * begin of the device. */ return blkid_probe_get_buffer(pr->parent, pr->off + off - pr->parent->off, len); } /* try buffers we already have in memory or read from device */ bf = get_cached_buffer(pr, off, len); if (!bf) { bf = read_buffer(pr, real_off, len); if (!bf) return NULL; list_add_tail(&bf->bufs, &pr->buffers); } assert(bf->off <= real_off); assert(bf->off + bf->len >= real_off + len); errno = 0; return real_off ? bf->data + (real_off - bf->off) : bf->data; } /** * blkid_probe_reset_buffers: * @pr: prober * * libblkid reuse all already read buffers from the device. The bufferes may be * modified by blkid_probe_hide_range(). This function reset and free all * cached bufferes. The next blkid_do_probe() will read all data from the * device. * * Returns: <0 in case of failure, or 0 on success. */ int blkid_probe_reset_buffers(blkid_probe pr) { uint64_t ct = 0, len = 0; pr->flags &= ~BLKID_FL_MODIF_BUFF; if (list_empty(&pr->buffers)) return 0; DBG(BUFFER, ul_debug("Resetting probing buffers")); while (!list_empty(&pr->buffers)) { struct blkid_bufinfo *bf = list_entry(pr->buffers.next, struct blkid_bufinfo, bufs); ct++; len += bf->len; list_del(&bf->bufs); DBG(BUFFER, ul_debug(" remove buffer: [off=%"PRIu64", len=%"PRIu64"]", bf->off, bf->len)); free(bf); } DBG(LOWPROBE, ul_debug(" buffers summary: %"PRIu64" bytes by %"PRIu64" read() calls", len, ct)); INIT_LIST_HEAD(&pr->buffers); return 0; } /** * blkid_probe_hide_range: * @pr: prober * @off: start of the range * @len: size of the range * * This function modifies in-memory cached data from the device. The specified * range is zeroized. This is usable together with blkid_probe_step_back(). * The next blkid_do_probe() will not see specified area. * * Note that this is usable for already (by library) read data, and this * function is not a way how to hide any large areas on your device. * * The function blkid_probe_reset_buffers() reverts all. * * Returns: <0 in case of failure, or 0 on success. */ int blkid_probe_hide_range(blkid_probe pr, uint64_t off, uint64_t len) { int rc = hide_buffer(pr, off, len); if (rc == 0) pr->flags |= BLKID_FL_MODIF_BUFF; return rc; } static void blkid_probe_reset_values(blkid_probe pr) { if (list_empty(&pr->values)) return; DBG(LOWPROBE, ul_debug("resetting results")); while (!list_empty(&pr->values)) { struct blkid_prval *v = list_entry(pr->values.next, struct blkid_prval, prvals); blkid_probe_free_value(v); } INIT_LIST_HEAD(&pr->values); } /* * Small devices need a special care. */ int blkid_probe_is_tiny(blkid_probe pr) { return (pr->flags & BLKID_FL_TINY_DEV); } /* * CDROMs may fail when probed for RAID (last sector problem) */ int blkid_probe_is_cdrom(blkid_probe pr) { return (pr->flags & BLKID_FL_CDROM_DEV); } #ifdef CDROM_GET_CAPABILITY static int is_sector_readable(int fd, uint64_t sector) { char buf[512]; ssize_t sz; if (blkid_llseek(fd, sector * 512, SEEK_SET) < 0) goto failed; sz = read(fd, buf, sizeof(buf)); if (sz != (ssize_t) sizeof(buf)) goto failed; return 1; failed: DBG(LOWPROBE, ul_debug("CDROM: read sector %"PRIu64" failed %m", sector)); errno = 0; return 0; } /* * Linux kernel reports (BLKGETSIZE) cdrom device size greater than area * readable by read(2). We have to reduce the probing area to avoid unwanted * I/O errors in probing functions. It seems that unreadable are always last 2 * or 3 CD blocks (CD block size is 2048 bytes, it means 12 in 512-byte * sectors). */ static void cdrom_size_correction(blkid_probe pr) { uint64_t n, nsectors = pr->size >> 9; for (n = nsectors - 12; n < nsectors; n++) { if (!is_sector_readable(pr->fd, n)) goto failed; } DBG(LOWPROBE, ul_debug("CDROM: full size available")); return; failed: /* 'n' is the failed sector, reduce device size to n-1; */ DBG(LOWPROBE, ul_debug("CDROM: reduce size from %ju to %ju.", (uintmax_t) pr->size, (uintmax_t) n << 9)); pr->size = n << 9; } #endif /** * blkid_probe_set_device: * @pr: probe * @fd: device file descriptor * @off: begin of probing area * @size: size of probing area (zero means whole device/file) * * Assigns the device to probe control struct, resets internal buffers and * resets the current probing. * * Returns: -1 in case of failure, or 0 on success. */ int blkid_probe_set_device(blkid_probe pr, int fd, blkid_loff_t off, blkid_loff_t size) { struct stat sb; uint64_t devsiz = 0; char *dm_uuid = NULL; blkid_reset_probe(pr); blkid_probe_reset_buffers(pr); if ((pr->flags & BLKID_FL_PRIVATE_FD) && pr->fd >= 0) close(pr->fd); pr->flags &= ~BLKID_FL_PRIVATE_FD; pr->flags &= ~BLKID_FL_TINY_DEV; pr->flags &= ~BLKID_FL_CDROM_DEV; pr->prob_flags = 0; pr->fd = fd; pr->off = (uint64_t) off; pr->size = 0; pr->devno = 0; pr->disk_devno = 0; pr->mode = 0; pr->blkssz = 0; pr->wipe_off = 0; pr->wipe_size = 0; pr->wipe_chain = NULL; #if defined(POSIX_FADV_RANDOM) && defined(HAVE_POSIX_FADVISE) /* Disable read-ahead */ posix_fadvise(fd, 0, 0, POSIX_FADV_RANDOM); #endif if (fstat(fd, &sb)) goto err; if (!S_ISBLK(sb.st_mode) && !S_ISCHR(sb.st_mode) && !S_ISREG(sb.st_mode)) { errno = EINVAL; goto err; } pr->mode = sb.st_mode; if (S_ISBLK(sb.st_mode) || S_ISCHR(sb.st_mode)) pr->devno = sb.st_rdev; if (S_ISBLK(sb.st_mode)) { if (blkdev_get_size(fd, (unsigned long long *) &devsiz)) { DBG(LOWPROBE, ul_debug("failed to get device size")); goto err; } } else if (S_ISCHR(sb.st_mode)) devsiz = 1; /* UBI devices are char... */ else if (S_ISREG(sb.st_mode)) devsiz = sb.st_size; /* regular file */ pr->size = size ? (uint64_t)size : devsiz; if (off && size == 0) /* only offset without size specified */ pr->size -= (uint64_t) off; if (pr->off + pr->size > devsiz) { DBG(LOWPROBE, ul_debug("area specified by offset and size is bigger than device")); errno = EINVAL; goto err; } if (pr->size <= 1440 * 1024 && !S_ISCHR(sb.st_mode)) pr->flags |= BLKID_FL_TINY_DEV; if (S_ISBLK(sb.st_mode) && sysfs_devno_is_dm_private(sb.st_rdev, &dm_uuid)) { DBG(LOWPROBE, ul_debug("ignore private device mapper device")); pr->flags |= BLKID_FL_NOSCAN_DEV; } #ifdef CDROM_GET_CAPABILITY else if (S_ISBLK(sb.st_mode) && !blkid_probe_is_tiny(pr) && !dm_uuid && blkid_probe_is_wholedisk(pr) && ioctl(fd, CDROM_GET_CAPABILITY, NULL) >= 0) { pr->flags |= BLKID_FL_CDROM_DEV; cdrom_size_correction(pr); } #endif free(dm_uuid); DBG(LOWPROBE, ul_debug("ready for low-probing, offset=%"PRIu64", size=%"PRIu64"", pr->off, pr->size)); DBG(LOWPROBE, ul_debug("whole-disk: %s, regfile: %s", blkid_probe_is_wholedisk(pr) ?"YES" : "NO", S_ISREG(pr->mode) ? "YES" : "NO")); return 0; err: DBG(LOWPROBE, ul_debug("failed to prepare a device for low-probing")); return -1; } int blkid_probe_get_dimension(blkid_probe pr, uint64_t *off, uint64_t *size) { *off = pr->off; *size = pr->size; return 0; } int blkid_probe_set_dimension(blkid_probe pr, uint64_t off, uint64_t size) { DBG(LOWPROBE, ul_debug( "changing probing area: size=%"PRIu64", off=%"PRIu64" " "-to-> size=%"PRIu64", off=%"PRIu64"", pr->size, pr->off, size, off)); pr->off = off; pr->size = size; pr->flags &= ~BLKID_FL_TINY_DEV; if (pr->size <= 1440ULL * 1024ULL && !S_ISCHR(pr->mode)) pr->flags |= BLKID_FL_TINY_DEV; blkid_probe_reset_buffers(pr); return 0; } /* * Check for matching magic value. * Returns BLKID_PROBE_OK if found, BLKID_PROBE_NONE if not found * or no magic present, or negative value on error. */ int blkid_probe_get_idmag(blkid_probe pr, const struct blkid_idinfo *id, uint64_t *offset, const struct blkid_idmag **res) { const struct blkid_idmag *mag = NULL; uint64_t off = 0; if (id) mag = &id->magics[0]; if (res) *res = NULL; /* try to detect by magic string */ while(mag && mag->magic) { unsigned char *buf; off = (mag->kboff + (mag->sboff >> 10)) << 10; buf = blkid_probe_get_buffer(pr, off, 1024); if (!buf && errno) return -errno; if (buf && !memcmp(mag->magic, buf + (mag->sboff & 0x3ff), mag->len)) { DBG(LOWPROBE, ul_debug("\tmagic sboff=%u, kboff=%ld", mag->sboff, mag->kboff)); if (offset) *offset = off + (mag->sboff & 0x3ff); if (res) *res = mag; return BLKID_PROBE_OK; } mag++; } if (id && id->magics[0].magic) /* magic string(s) defined, but not found */ return BLKID_PROBE_NONE; return BLKID_PROBE_OK; } static inline void blkid_probe_start(blkid_probe pr) { DBG(LOWPROBE, ul_debug("start probe")); pr->cur_chain = NULL; pr->prob_flags = 0; blkid_probe_set_wiper(pr, 0, 0); } static inline void blkid_probe_end(blkid_probe pr) { DBG(LOWPROBE, ul_debug("end probe")); pr->cur_chain = NULL; pr->prob_flags = 0; blkid_probe_set_wiper(pr, 0, 0); } /** * blkid_do_probe: * @pr: prober * * Calls probing functions in all enabled chains. The superblocks chain is * enabled by default. The blkid_do_probe() stores result from only one * probing function. It's necessary to call this routine in a loop to get * results from all probing functions in all chains. The probing is reset * by blkid_reset_probe() or by filter functions. * * This is string-based NAME=value interface only. * * * basic case - use the first result only * * if (blkid_do_probe(pr) == 0) { * int nvals = blkid_probe_numof_values(pr); * for (n = 0; n < nvals; n++) { * if (blkid_probe_get_value(pr, n, &name, &data, &len) == 0) * printf("%s = %s\n", name, data); * } * } * * * * * advanced case - probe for all signatures * * while (blkid_do_probe(pr) == 0) { * int nvals = blkid_probe_numof_values(pr); * ... * } * * * * See also blkid_reset_probe(). * * Returns: 0 on success, 1 when probing is done and -1 in case of error. */ int blkid_do_probe(blkid_probe pr) { int rc = 1; if (pr->flags & BLKID_FL_NOSCAN_DEV) return 1; do { struct blkid_chain *chn = pr->cur_chain; if (!chn) { blkid_probe_start(pr); chn = pr->cur_chain = &pr->chains[0]; } /* we go to the next chain only when the previous probing * result was nothing (rc == 1) and when the current chain is * disabled or we are at end of the current chain (chain->idx + * 1 == sizeof chain) or the current chain bailed out right at * the start (chain->idx == -1) */ else if (rc == 1 && (chn->enabled == FALSE || chn->idx + 1 == (int) chn->driver->nidinfos || chn->idx == -1)) { size_t idx = chn->driver->id + 1; if (idx < BLKID_NCHAINS) chn = pr->cur_chain = &pr->chains[idx]; else { blkid_probe_end(pr); return 1; /* all chains already probed */ } } chn->binary = FALSE; /* for sure... */ DBG(LOWPROBE, ul_debug("chain probe %s %s (idx=%d)", chn->driver->name, chn->enabled? "ENABLED" : "DISABLED", chn->idx)); if (!chn->enabled) continue; /* rc: -1 = error, 0 = success, 1 = no result */ rc = chn->driver->probe(pr, chn); } while (rc == 1); return rc; } /** * blkid_do_wipe: * @pr: prober * @dryrun: if TRUE then don't touch the device. * * This function erases the current signature detected by @pr. The @pr has to * be open in O_RDWR mode, BLKID_SUBLKS_MAGIC or/and BLKID_PARTS_MAGIC flags * has to be enabled (if you want to erase also superblock with broken check * sums then use BLKID_SUBLKS_BADCSUM too). * * After successful signature removing the @pr prober will be moved one step * back and the next blkid_do_probe() call will again call previously called * probing function. All in-memory cached data from the device are always * reset. * * * wipe all filesystems or raids from the device * * fd = open(devname, O_RDWR|O_CLOEXEC); * blkid_probe_set_device(pr, fd, 0, 0); * * blkid_probe_enable_superblocks(pr, 1); * blkid_probe_set_superblocks_flags(pr, BLKID_SUBLKS_MAGIC); * * while (blkid_do_probe(pr) == 0) * blkid_do_wipe(pr, FALSE); * * * * See also blkid_probe_step_back() if you cannot use this build-in wipe * function, but you want to use libblkid probing as a source for wiping. * * Returns: 0 on success, and -1 in case of error. */ int blkid_do_wipe(blkid_probe pr, int dryrun) { const char *off = NULL; size_t len = 0; uint64_t offset, magoff, l; char buf[BUFSIZ]; int fd, rc = 0; struct blkid_chain *chn; chn = pr->cur_chain; if (!chn) return -1; switch (chn->driver->id) { case BLKID_CHAIN_SUBLKS: rc = blkid_probe_lookup_value(pr, "SBMAGIC_OFFSET", &off, NULL); if (!rc) rc = blkid_probe_lookup_value(pr, "SBMAGIC", NULL, &len); break; case BLKID_CHAIN_PARTS: rc = blkid_probe_lookup_value(pr, "PTMAGIC_OFFSET", &off, NULL); if (!rc) rc = blkid_probe_lookup_value(pr, "PTMAGIC", NULL, &len); break; default: return 0; } if (rc || len == 0 || off == NULL) return 0; magoff = strtoumax(off, NULL, 10); offset = magoff + pr->off; fd = blkid_probe_get_fd(pr); if (fd < 0) return -1; if (len > sizeof(buf)) len = sizeof(buf); DBG(LOWPROBE, ul_debug( "do_wipe [offset=0x%"PRIx64" (%"PRIu64"), len=%zu, chain=%s, idx=%d, dryrun=%s]\n", offset, offset, len, chn->driver->name, chn->idx, dryrun ? "yes" : "not")); l = blkid_llseek(fd, offset, SEEK_SET); if ((blkid_loff_t)l == (off_t) -1) return -1; memset(buf, 0, len); if (!dryrun && len) { /* wipen on device */ if (write_all(fd, buf, len)) return -1; fsync(fd); pr->flags &= ~BLKID_FL_MODIF_BUFF; /* be paranoid */ return blkid_probe_step_back(pr); } else if (dryrun) { /* wipe in memory only */ blkid_probe_hide_range(pr, magoff, len); return blkid_probe_step_back(pr); } return 0; } /** * blkid_probe_step_back: * @pr: prober * * This function move pointer to the probing chain one step back -- it means * that the previously used probing function will be called again in the next * blkid_do_probe() call. * * This is necessary for example if you erase or modify on-disk superblock * according to the current libblkid probing result. * * Note that blkid_probe_hide_range() changes semantic of this function and * cached bufferes are not reset, but library uses in-memory modified * buffers to call the next probing function. * * * wipe all superblock, but use libblkid only for probing * * pr = blkid_new_probe_from_filename(devname); * * blkid_probe_enable_superblocks(pr, 1); * blkid_probe_set_superblocks_flags(pr, BLKID_SUBLKS_MAGIC); * * blkid_probe_enable_partitions(pr, 1); * blkid_probe_set_partitions_flags(pr, BLKID_PARTS_MAGIC); * * while (blkid_do_probe(pr) == 0) { * const char *ostr = NULL; * size_t len = 0; * * // superblocks * if (blkid_probe_lookup_value(pr, "SBMAGIC_OFFSET", &ostr, NULL) == 0) * blkid_probe_lookup_value(pr, "SBMAGIC", NULL, &len); * * // partition tables * if (len == 0 && blkid_probe_lookup_value(pr, "PTMAGIC_OFFSET", &ostr, NULL) == 0) * blkid_probe_lookup_value(pr, "PTMAGIC", NULL, &len); * * if (!len || !str) * continue; * * // convert ostr to the real offset by off = strtoll(ostr, NULL, 10); * // use your stuff to erase @len bytes at the @off * .... * * // retry the last probing to check for backup superblocks ..etc. * blkid_probe_step_back(pr); * } * * * * Returns: 0 on success, and -1 in case of error. */ int blkid_probe_step_back(blkid_probe pr) { struct blkid_chain *chn; chn = pr->cur_chain; if (!chn) return -1; if (!(pr->flags & BLKID_FL_MODIF_BUFF)) blkid_probe_reset_buffers(pr); if (chn->idx >= 0) { chn->idx--; DBG(LOWPROBE, ul_debug("step back: moving %s chain index to %d", chn->driver->name, chn->idx)); } if (chn->idx == -1) { /* blkid_do_probe() goes to the next chain if the index * of the current chain is -1, so we have to set the * chain pointer to the previous chain. */ size_t idx = chn->driver->id > 0 ? chn->driver->id - 1 : 0; DBG(LOWPROBE, ul_debug("step back: moving to previous chain")); if (idx > 0) pr->cur_chain = &pr->chains[idx]; else if (idx == 0) pr->cur_chain = NULL; } return 0; } /** * blkid_do_safeprobe: * @pr: prober * * This function gathers probing results from all enabled chains and checks * for ambivalent results (e.g. more filesystems on the device). * * This is string-based NAME=value interface only. * * Note about superblocks chain -- the function does not check for filesystems * when a RAID signature is detected. The function also does not check for * collision between RAIDs. The first detected RAID is returned. The function * checks for collision between partition table and RAID signature -- it's * recommended to enable partitions chain together with superblocks chain. * * Returns: 0 on success, 1 if nothing is detected, -2 if ambivalent result is * detected and -1 on case of error. */ int blkid_do_safeprobe(blkid_probe pr) { int i, count = 0, rc = 0; if (pr->flags & BLKID_FL_NOSCAN_DEV) return 1; blkid_probe_start(pr); for (i = 0; i < BLKID_NCHAINS; i++) { struct blkid_chain *chn; chn = pr->cur_chain = &pr->chains[i]; chn->binary = FALSE; /* for sure... */ DBG(LOWPROBE, ul_debug("chain safeprobe %s %s", chn->driver->name, chn->enabled? "ENABLED" : "DISABLED")); if (!chn->enabled) continue; blkid_probe_chain_reset_position(chn); rc = chn->driver->safeprobe(pr, chn); blkid_probe_chain_reset_position(chn); /* rc: -2 ambivalent, -1 = error, 0 = success, 1 = no result */ if (rc < 0) goto done; /* error */ if (rc == 0) count++; /* success */ } done: blkid_probe_end(pr); if (rc < 0) return rc; return count ? 0 : 1; } /** * blkid_do_fullprobe: * @pr: prober * * This function gathers probing results from all enabled chains. Same as * blkid_do_safeprobe() but does not check for collision between probing * result. * * This is string-based NAME=value interface only. * * Returns: 0 on success, 1 if nothing is detected or -1 on case of error. */ int blkid_do_fullprobe(blkid_probe pr) { int i, count = 0, rc = 0; if (pr->flags & BLKID_FL_NOSCAN_DEV) return 1; blkid_probe_start(pr); for (i = 0; i < BLKID_NCHAINS; i++) { struct blkid_chain *chn; chn = pr->cur_chain = &pr->chains[i]; chn->binary = FALSE; /* for sure... */ DBG(LOWPROBE, ul_debug("chain fullprobe %s: %s", chn->driver->name, chn->enabled? "ENABLED" : "DISABLED")); if (!chn->enabled) continue; blkid_probe_chain_reset_position(chn); rc = chn->driver->probe(pr, chn); blkid_probe_chain_reset_position(chn); /* rc: -1 = error, 0 = success, 1 = no result */ if (rc < 0) goto done; /* error */ if (rc == 0) count++; /* success */ } done: blkid_probe_end(pr); if (rc < 0) return rc; return count ? 0 : 1; } /* same sa blkid_probe_get_buffer() but works with 512-sectors */ unsigned char *blkid_probe_get_sector(blkid_probe pr, unsigned int sector) { return blkid_probe_get_buffer(pr, ((uint64_t) sector) << 9, 0x200); } struct blkid_prval *blkid_probe_assign_value(blkid_probe pr, const char *name) { struct blkid_prval *v; v = calloc(1, sizeof(struct blkid_prval)); if (!v) return NULL; INIT_LIST_HEAD(&v->prvals); v->name = name; v->chain = pr->cur_chain; list_add_tail(&v->prvals, &pr->values); DBG(LOWPROBE, ul_debug("assigning %s [%s]", name, v->chain->driver->name)); return v; } /* Note that value data is always terminated by zero to keep things robust, * this extra zero is not count to the value length. It's caller responsibility * to set proper value length (for strings we count terminator to the length, * for binary data it's without terminator). */ int blkid_probe_value_set_data(struct blkid_prval *v, unsigned char *data, size_t len) { v->data = calloc(1, len + 1); /* always terminate by \0 */ if (!v->data) return -ENOMEM; memcpy(v->data, data, len); v->len = len; return 0; } int blkid_probe_set_value(blkid_probe pr, const char *name, unsigned char *data, size_t len) { struct blkid_prval *v; v = blkid_probe_assign_value(pr, name); if (!v) return -1; return blkid_probe_value_set_data(v, data, len); } int blkid_probe_vsprintf_value(blkid_probe pr, const char *name, const char *fmt, va_list ap) { struct blkid_prval *v; ssize_t len; v = blkid_probe_assign_value(pr, name); if (!v) return -ENOMEM; len = vasprintf((char **) &v->data, fmt, ap); if (len <= 0) { blkid_probe_free_value(v); return len == 0 ? -EINVAL : -ENOMEM; } v->len = len + 1; return 0; } int blkid_probe_sprintf_value(blkid_probe pr, const char *name, const char *fmt, ...) { int rc; va_list ap; va_start(ap, fmt); rc = blkid_probe_vsprintf_value(pr, name, fmt, ap); va_end(ap); return rc; } int blkid_probe_set_magic(blkid_probe pr, uint64_t offset, size_t len, unsigned char *magic) { int rc = 0; struct blkid_chain *chn = blkid_probe_get_chain(pr); if (!chn || !len || chn->binary) return 0; switch (chn->driver->id) { case BLKID_CHAIN_SUBLKS: if (!(chn->flags & BLKID_SUBLKS_MAGIC)) return 0; rc = blkid_probe_set_value(pr, "SBMAGIC", magic, len); if (!rc) rc = blkid_probe_sprintf_value(pr, "SBMAGIC_OFFSET", "%llu", (unsigned long long)offset); break; case BLKID_CHAIN_PARTS: if (!(chn->flags & BLKID_PARTS_MAGIC)) return 0; rc = blkid_probe_set_value(pr, "PTMAGIC", magic, len); if (!rc) rc = blkid_probe_sprintf_value(pr, "PTMAGIC_OFFSET", "%llu", (unsigned long long)offset); break; default: break; } return rc; } int blkid_probe_verify_csum(blkid_probe pr, uint64_t csum, uint64_t expected) { if (csum != expected) { struct blkid_chain *chn = blkid_probe_get_chain(pr); DBG(LOWPROBE, ul_debug( "incorrect checksum for type %s," " got %"PRIX64", expected %"PRIX64"", blkid_probe_get_probername(pr), csum, expected)); /* * Accept bad checksum if BLKID_SUBLKS_BADCSUM flags is set */ if (chn->driver->id == BLKID_CHAIN_SUBLKS && (chn->flags & BLKID_SUBLKS_BADCSUM)) { blkid_probe_set_value(pr, "SBBADCSUM", (unsigned char *) "1", 2); goto accept; } return 0; /* bad checksum */ } accept: return 1; } /** * blkid_probe_get_devno: * @pr: probe * * Returns: block device number, or 0 for regular files. */ dev_t blkid_probe_get_devno(blkid_probe pr) { return pr->devno; } /** * blkid_probe_get_wholedisk_devno: * @pr: probe * * Returns: device number of the wholedisk, or 0 for regular files. */ dev_t blkid_probe_get_wholedisk_devno(blkid_probe pr) { if (!pr->disk_devno) { dev_t devno, disk_devno = 0; devno = blkid_probe_get_devno(pr); if (!devno) return 0; if (blkid_devno_to_wholedisk(devno, NULL, 0, &disk_devno) == 0) pr->disk_devno = disk_devno; } return pr->disk_devno; } /** * blkid_probe_is_wholedisk: * @pr: probe * * Returns: 1 if the device is whole-disk or 0. */ int blkid_probe_is_wholedisk(blkid_probe pr) { dev_t devno, disk_devno; devno = blkid_probe_get_devno(pr); if (!devno) return 0; disk_devno = blkid_probe_get_wholedisk_devno(pr); if (!disk_devno) return 0; return devno == disk_devno; } blkid_probe blkid_probe_get_wholedisk_probe(blkid_probe pr) { dev_t disk; if (blkid_probe_is_wholedisk(pr)) return NULL; /* this is not partition */ if (pr->parent) /* this is cloned blkid_probe, use parent's stuff */ return blkid_probe_get_wholedisk_probe(pr->parent); disk = blkid_probe_get_wholedisk_devno(pr); if (pr->disk_probe && pr->disk_probe->devno != disk) { /* we have disk prober, but for another disk... close it */ blkid_free_probe(pr->disk_probe); pr->disk_probe = NULL; } if (!pr->disk_probe) { /* Open a new disk prober */ char *disk_path = blkid_devno_to_devname(disk); if (!disk_path) return NULL; DBG(LOWPROBE, ul_debug("allocate a wholedisk probe")); pr->disk_probe = blkid_new_probe_from_filename(disk_path); free(disk_path); if (!pr->disk_probe) return NULL; /* ENOMEM? */ } return pr->disk_probe; } /** * blkid_probe_get_size: * @pr: probe * * This function returns size of probing area as defined by blkid_probe_set_device(). * If the size of the probing area is unrestricted then this function returns * the real size of device. See also blkid_get_dev_size(). * * Returns: size in bytes or -1 in case of error. */ blkid_loff_t blkid_probe_get_size(blkid_probe pr) { return (blkid_loff_t) pr->size; } /** * blkid_probe_get_offset: * @pr: probe * * This function returns offset of probing area as defined by blkid_probe_set_device(). * * Returns: offset in bytes or -1 in case of error. */ blkid_loff_t blkid_probe_get_offset(blkid_probe pr) { return (blkid_loff_t) pr->off; } /** * blkid_probe_get_fd: * @pr: probe * * Returns: file descriptor for assigned device/file or -1 in case of error. */ int blkid_probe_get_fd(blkid_probe pr) { return pr->fd; } /** * blkid_probe_get_sectorsize: * @pr: probe or NULL (for NULL returns 512) * * Returns: block device logical sector size (BLKSSZGET ioctl, default 512). */ unsigned int blkid_probe_get_sectorsize(blkid_probe pr) { if (pr->blkssz) return pr->blkssz; if (S_ISBLK(pr->mode) && blkdev_get_sector_size(pr->fd, (int *) &pr->blkssz) == 0) return pr->blkssz; pr->blkssz = DEFAULT_SECTOR_SIZE; return pr->blkssz; } /** * blkid_probe_set_sectorsize: * @pr: probe * @sz: new size (to overwrite system default) * * Note that blkid_probe_set_device() resets this setting. Use it after * blkid_probe_set_device() and before any probing call. * * Since: 2.30 * * Returns: 0 or <0 in case of error */ int blkid_probe_set_sectorsize(blkid_probe pr, unsigned int sz) { pr->blkssz = sz; return 0; } /** * blkid_probe_get_sectors: * @pr: probe * * Returns: 512-byte sector count or -1 in case of error. */ blkid_loff_t blkid_probe_get_sectors(blkid_probe pr) { return (blkid_loff_t) (pr->size >> 9); } /** * blkid_probe_numof_values: * @pr: probe * * Returns: number of values in probing result or -1 in case of error. */ int blkid_probe_numof_values(blkid_probe pr) { int i = 0; struct list_head *p; list_for_each(p, &pr->values) ++i; return i; } /** * blkid_probe_get_value: * @pr: probe * @num: wanted value in range 0..N, where N is blkid_probe_numof_values() - 1 * @name: pointer to return value name or NULL * @data: pointer to return value data or NULL * @len: pointer to return value length or NULL * * Note, the @len returns length of the @data, including the terminating * '\0' character. * * Returns: 0 on success, or -1 in case of error. */ int blkid_probe_get_value(blkid_probe pr, int num, const char **name, const char **data, size_t *len) { struct blkid_prval *v = __blkid_probe_get_value(pr, num); if (!v) return -1; if (name) *name = v->name; if (data) *data = (char *) v->data; if (len) *len = v->len; DBG(LOWPROBE, ul_debug("returning %s value", v->name)); return 0; } /** * blkid_probe_lookup_value: * @pr: probe * @name: name of value * @data: pointer to return value data or NULL * @len: pointer to return value length or NULL * * Note, the @len returns length of the @data, including the terminating * '\0' character. * * Returns: 0 on success, or -1 in case of error. */ int blkid_probe_lookup_value(blkid_probe pr, const char *name, const char **data, size_t *len) { struct blkid_prval *v = __blkid_probe_lookup_value(pr, name); if (!v) return -1; if (data) *data = (char *) v->data; if (len) *len = v->len; return 0; } /** * blkid_probe_has_value: * @pr: probe * @name: name of value * * Returns: 1 if value exist in probing result, otherwise 0. */ int blkid_probe_has_value(blkid_probe pr, const char *name) { if (blkid_probe_lookup_value(pr, name, NULL, NULL) == 0) return 1; return 0; } struct blkid_prval *__blkid_probe_get_value(blkid_probe pr, int num) { int i = 0; struct list_head *p; if (num < 0) return NULL; list_for_each(p, &pr->values) { if (i++ != num) continue; return list_entry(p, struct blkid_prval, prvals); } return NULL; } struct blkid_prval *__blkid_probe_lookup_value(blkid_probe pr, const char *name) { struct list_head *p; if (list_empty(&pr->values)) return NULL; list_for_each(p, &pr->values) { struct blkid_prval *v = list_entry(p, struct blkid_prval, prvals); if (v->name && strcmp(name, v->name) == 0) { DBG(LOWPROBE, ul_debug("returning %s value", v->name)); return v; } } return NULL; } /* converts DCE UUID (uuid[16]) to human readable string * - the @len should be always 37 */ #ifdef HAVE_LIBUUID void blkid_unparse_uuid(const unsigned char *uuid, char *str, size_t len __attribute__((__unused__))) { uuid_unparse(uuid, str); } #else void blkid_unparse_uuid(const unsigned char *uuid, char *str, size_t len) { snprintf(str, len, "%02x%02x%02x%02x-%02x%02x-%02x%02x-%02x%02x-%02x%02x%02x%02x%02x%02x", uuid[0], uuid[1], uuid[2], uuid[3], uuid[4], uuid[5], uuid[6], uuid[7], uuid[8], uuid[9], uuid[10], uuid[11], uuid[12], uuid[13], uuid[14],uuid[15]); } #endif /* like uuid_is_null() from libuuid, but works with arbitrary size of UUID */ int blkid_uuid_is_empty(const unsigned char *buf, size_t len) { size_t i; for (i = 0; i < len; i++) if (buf[i]) return 0; return 1; } /* Removes whitespace from the right-hand side of a string (trailing * whitespace). * * Returns size of the new string (without \0). */ size_t blkid_rtrim_whitespace(unsigned char *str) { return rtrim_whitespace(str); } /* Removes whitespace from the left-hand side of a string. * * Returns size of the new string (without \0). */ size_t blkid_ltrim_whitespace(unsigned char *str) { return ltrim_whitespace(str); } /* * Some mkfs-like utils wipe some parts (usually begin) of the device. * For example LVM (pvcreate) or mkswap(8). This information could be used * for later resolution to conflicts between superblocks. * * For example we found valid LVM superblock, LVM wipes 8KiB at the begin of * the device. If we found another signature (for example MBR) within the * wiped area then the signature has been added later and LVM superblock * should be ignore. * * Note that this heuristic is not 100% reliable, for example "pvcreate --zero * n" allows to keep the begin of the device unmodified. It's probably better * to use this heuristic for conflicts between superblocks and partition tables * than for conflicts between filesystem superblocks -- existence of unwanted * partition table is very unusual, because PT is pretty visible (parsed and * interpreted by kernel). * * Note that we usually expect only one signature on the device, it means that * we have to remember only one wiped area from previously successfully * detected signature. * * blkid_probe_set_wiper() -- defines wiped area (e.g. LVM) * blkid_probe_use_wiper() -- try to use area (e.g. MBR) * * Note that there is not relation between _wiper and blkid_to_wipe(). * */ void blkid_probe_set_wiper(blkid_probe pr, uint64_t off, uint64_t size) { struct blkid_chain *chn; if (!size) { DBG(LOWPROBE, ul_debug("zeroize wiper")); pr->wipe_size = pr->wipe_off = 0; pr->wipe_chain = NULL; return; } chn = pr->cur_chain; if (!chn || !chn->driver || chn->idx < 0 || (size_t) chn->idx >= chn->driver->nidinfos) return; pr->wipe_size = size; pr->wipe_off = off; pr->wipe_chain = chn; DBG(LOWPROBE, ul_debug("wiper set to %s::%s off=%"PRIu64" size=%"PRIu64"", chn->driver->name, chn->driver->idinfos[chn->idx]->name, pr->wipe_off, pr->wipe_size)); return; } /* * Returns 1 if the <@off,@size> area was wiped */ int blkid_probe_is_wiped(blkid_probe pr, struct blkid_chain **chn, uint64_t off, uint64_t size) { if (!size) return 0; if (pr->wipe_off <= off && off + size <= pr->wipe_off + pr->wipe_size) { *chn = pr->wipe_chain; return 1; } return 0; } /* * Try to use any area -- if the area has been previously wiped then the * previous probing result should be ignored (reset). */ void blkid_probe_use_wiper(blkid_probe pr, uint64_t off, uint64_t size) { struct blkid_chain *chn = NULL; if (blkid_probe_is_wiped(pr, &chn, off, size) && chn) { DBG(LOWPROBE, ul_debug("previously wiped area modified " " -- ignore previous results")); blkid_probe_set_wiper(pr, 0, 0); blkid_probe_chain_reset_values(pr, chn); } }