/* * partitions - partition tables parsing * * Copyright (C) 2008-2009 Karel Zak * * This file may be redistributed under the terms of the * GNU Lesser General Public License. * */ #include #include #include #include #include #include #include #include #include #include #include #include #include "partitions.h" #include "sysfs.h" /** * SECTION: partitions * @title: Partitions probing * @short_description: partitions tables detection and parsing * * This chain supports binary and NAME=value interfaces, but complete PT * description is provided by binary interface only. The libblkid prober is * compatible with kernel partition tables parser. The parser does not return * empty (size=0) partitions or special hidden partitions. * * NAME=value interface, supported tags: * * @PTTYPE: partition table type (dos, gpt, etc.). * * @PTUUID: partition table id (uuid for gpt, hex for dos). * @PART_ENTRY_SCHEME: partition table type * * @PART_ENTRY_NAME: partition name (gpt and mac only) * * @PART_ENTRY_UUID: partition UUID (gpt, or pseudo IDs for MBR) * * @PART_ENTRY_TYPE: partition type, 0xNN (e.g 0x82) or type UUID (gpt only) or type string (mac) * * @PART_ENTRY_FLAGS: partition flags (e.g. boot_ind) or attributes (e.g. gpt attributes) * * @PART_ENTRY_NUMBER: partition number * * @PART_ENTRY_OFFSET: the begin of the partition * * @PART_ENTRY_SIZE: size of the partition * * @PART_ENTRY_DISK: whole-disk maj:min * * Example: * * * * blkid_probe pr; * const char *ptname; * * pr = blkid_new_probe_from_filename(devname); * if (!pr) * err("%s: failed to open device", devname); * * blkid_probe_enable_partitions(pr, TRUE); * blkid_do_fullprobe(pr); * * blkid_probe_lookup_value(pr, "PTTYPE", &ptname, NULL); * printf("%s partition type detected\n", pttype); * * blkid_free_probe(pr); * * // don't forget to check return codes in your code! * * * * Binary interface: * * * * blkid_probe pr; * blkid_partlist ls; * int nparts, i; * * pr = blkid_new_probe_from_filename(devname); * if (!pr) * err("%s: failed to open device", devname); * * ls = blkid_probe_get_partitions(pr); * nparts = blkid_partlist_numof_partitions(ls); * * for (i = 0; i < nparts; i++) { * blkid_partition par = blkid_partlist_get_partition(ls, i); * printf("#%d: %llu %llu 0x%x", * blkid_partition_get_partno(par), * blkid_partition_get_start(par), * blkid_partition_get_size(par), * blkid_partition_get_type(par)); * } * * blkid_free_probe(pr); * * // don't forget to check return codes in your code! * * */ /* * Chain driver function */ static int partitions_probe(blkid_probe pr, struct blkid_chain *chn); static void partitions_free_data(blkid_probe pr, void *data); /* * Partitions chain probing functions */ static const struct blkid_idinfo *idinfos[] = { &aix_pt_idinfo, &sgi_pt_idinfo, &sun_pt_idinfo, &dos_pt_idinfo, &gpt_pt_idinfo, &pmbr_pt_idinfo, /* always after GPT */ &mac_pt_idinfo, &ultrix_pt_idinfo, &bsd_pt_idinfo, &unixware_pt_idinfo, &solaris_x86_pt_idinfo, &minix_pt_idinfo, &atari_pt_idinfo }; /* * Driver definition */ const struct blkid_chaindrv partitions_drv = { .id = BLKID_CHAIN_PARTS, .name = "partitions", .dflt_enabled = FALSE, .idinfos = idinfos, .nidinfos = ARRAY_SIZE(idinfos), .has_fltr = TRUE, .probe = partitions_probe, .safeprobe = partitions_probe, .free_data = partitions_free_data }; /* * For compatibility with the rest of libblkid API (with the old high-level * API) we use completely opaque typedefs for all structs. Don't forget that * the final blkid_* types are pointers! See blkid.h. * * [Just for the record, I hate typedef for pointers --kzak] */ /* exported as opaque type "blkid_parttable" */ struct blkid_struct_parttable { const char *type; /* partition table type */ uint64_t offset; /* begin of the partition table (in bytes) */ int nparts; /* number of partitions */ blkid_partition parent; /* parent of nested partition table */ char id[UUID_STR_LEN]; /* PT identifier (e.g. UUID for GPT) */ struct list_head t_tabs; /* all tables */ }; /* exported as opaque type "blkid_partition" */ struct blkid_struct_partition { uint64_t start; /* begin of the partition (512-bytes sectors) */ uint64_t size; /* size of the partitions (512-bytes sectors) */ int type; /* partition type */ char typestr[UUID_STR_LEN]; /* partition type string (GPT and Mac) */ unsigned long long flags; /* partition flags / attributes */ int partno; /* partition number */ char uuid[UUID_STR_LEN]; /* UUID (when supported by PT), e.g GPT */ unsigned char name[128]; /* Partition in UTF8 name (when supported by PT), e.g. Mac */ blkid_parttable tab; /* partition table */ }; /* exported as opaque type "blkid_partlist" */ struct blkid_struct_partlist { int next_partno; /* next partition number */ blkid_partition next_parent; /* next parent if parsing nested PT */ int nparts; /* number of partitions */ int nparts_max; /* max.number of partitions */ blkid_partition parts; /* array of partitions */ struct list_head l_tabs; /* list of partition tables */ }; static int blkid_partitions_probe_partition(blkid_probe pr); /** * blkid_probe_enable_partitions: * @pr: probe * @enable: TRUE/FALSE * * Enables/disables the partitions probing for non-binary interface. * * Returns: 0 on success, or -1 in case of error. */ int blkid_probe_enable_partitions(blkid_probe pr, int enable) { pr->chains[BLKID_CHAIN_PARTS].enabled = enable; return 0; } /** * blkid_probe_set_partitions_flags: * @pr: prober * @flags: BLKID_PARTS_* flags * * Sets probing flags to the partitions prober. This function is optional. * * Returns: 0 on success, or -1 in case of error. */ int blkid_probe_set_partitions_flags(blkid_probe pr, int flags) { pr->chains[BLKID_CHAIN_PARTS].flags = flags; return 0; } /** * blkid_probe_reset_partitions_filter: * @pr: prober * * Resets partitions probing filter * * Returns: 0 on success, or -1 in case of error. */ int blkid_probe_reset_partitions_filter(blkid_probe pr) { return __blkid_probe_reset_filter(pr, BLKID_CHAIN_PARTS); } /** * blkid_probe_invert_partitions_filter: * @pr: prober * * Inverts partitions probing filter * * Returns: 0 on success, or -1 in case of error. */ int blkid_probe_invert_partitions_filter(blkid_probe pr) { return __blkid_probe_invert_filter(pr, BLKID_CHAIN_PARTS); } /** * blkid_probe_filter_partitions_type: * @pr: prober * @flag: filter BLKID_FLTR_{NOTIN,ONLYIN} flag * @names: NULL terminated array of probing function names (e.g. "vfat"). * * %BLKID_FLTR_NOTIN - probe for all items which are NOT IN @names * * %BLKID_FLTR_ONLYIN - probe for items which are IN @names * * Returns: 0 on success, or -1 in case of error. */ int blkid_probe_filter_partitions_type(blkid_probe pr, int flag, char *names[]) { return __blkid_probe_filter_types(pr, BLKID_CHAIN_PARTS, flag, names); } /** * blkid_probe_get_partitions: * @pr: probe * * This is a binary interface for partitions. See also blkid_partlist_* * functions. * * This function is independent on blkid_do_[safe,full]probe() and * blkid_probe_enable_partitions() calls. * * WARNING: the returned object will be overwritten by the next * blkid_probe_get_partitions() call for the same @pr. If you want to * use more blkid_partlist objects in the same time you have to create * more blkid_probe handlers (see blkid_new_probe()). * * Returns: list of partitions, or NULL in case of error. */ blkid_partlist blkid_probe_get_partitions(blkid_probe pr) { return (blkid_partlist) blkid_probe_get_binary_data(pr, &pr->chains[BLKID_CHAIN_PARTS]); } /* for internal usage only */ blkid_partlist blkid_probe_get_partlist(blkid_probe pr) { return (blkid_partlist) pr->chains[BLKID_CHAIN_PARTS].data; } static void blkid_probe_set_partlist(blkid_probe pr, blkid_partlist ls) { pr->chains[BLKID_CHAIN_PARTS].data = ls; } static void ref_parttable(blkid_parttable tab) { tab->nparts++; } static void unref_parttable(blkid_parttable tab) { tab->nparts--; if (tab->nparts <= 0) { list_del(&tab->t_tabs); free(tab); } } /* free all allocated parttables */ static void free_parttables(blkid_partlist ls) { if (!ls || !ls->l_tabs.next) return; /* remove unassigned partition tables */ while (!list_empty(&ls->l_tabs)) { blkid_parttable tab = list_entry(ls->l_tabs.next, struct blkid_struct_parttable, t_tabs); unref_parttable(tab); } } static void reset_partlist(blkid_partlist ls) { if (!ls) return; free_parttables(ls); if (ls->next_partno) { /* already initialized - reset */ int tmp_nparts = ls->nparts_max; blkid_partition tmp_parts = ls->parts; memset(ls, 0, sizeof(struct blkid_struct_partlist)); ls->nparts_max = tmp_nparts; ls->parts = tmp_parts; } ls->nparts = 0; ls->next_partno = 1; INIT_LIST_HEAD(&ls->l_tabs); DBG(LOWPROBE, ul_debug("partlist reset")); } static blkid_partlist partitions_init_data(struct blkid_chain *chn) { blkid_partlist ls; if (chn->data) ls = (blkid_partlist) chn->data; else { /* allocate the new list of partitions */ ls = calloc(1, sizeof(struct blkid_struct_partlist)); if (!ls) return NULL; chn->data = (void *) ls; } reset_partlist(ls); DBG(LOWPROBE, ul_debug("parts: initialized partitions list (size=%d)", ls->nparts_max)); return ls; } static void partitions_free_data(blkid_probe pr __attribute__((__unused__)), void *data) { blkid_partlist ls = (blkid_partlist) data; if (!ls) return; free_parttables(ls); /* deallocate partitions and partlist */ free(ls->parts); free(ls); } blkid_parttable blkid_partlist_new_parttable(blkid_partlist ls, const char *type, uint64_t offset) { blkid_parttable tab; tab = calloc(1, sizeof(struct blkid_struct_parttable)); if (!tab) return NULL; tab->type = type; tab->offset = offset; tab->parent = ls->next_parent; INIT_LIST_HEAD(&tab->t_tabs); list_add_tail(&tab->t_tabs, &ls->l_tabs); DBG(LOWPROBE, ul_debug("parts: create a new partition table " "(type=%s, offset=%"PRId64")", type, offset)); return tab; } static blkid_partition new_partition(blkid_partlist ls, blkid_parttable tab) { blkid_partition par; if (ls->nparts + 1 > ls->nparts_max) { /* Linux kernel has DISK_MAX_PARTS=256, but it's too much for * generic Linux machine -- let start with 32 partitions. */ void *tmp = realloc(ls->parts, (ls->nparts_max + 32) * sizeof(struct blkid_struct_partition)); if (!tmp) return NULL; ls->parts = tmp; ls->nparts_max += 32; } par = &ls->parts[ls->nparts++]; memset(par, 0, sizeof(struct blkid_struct_partition)); ref_parttable(tab); par->tab = tab; par->partno = blkid_partlist_increment_partno(ls); return par; } blkid_partition blkid_partlist_add_partition(blkid_partlist ls, blkid_parttable tab, uint64_t start, uint64_t size) { blkid_partition par = new_partition(ls, tab); if (!par) return NULL; par->start = start; par->size = size; DBG(LOWPROBE, ul_debug("parts: add partition (start=%" PRIu64 ", size=%" PRIu64 ")", par->start, par->size)); return par; } /* allows to modify used partitions numbers (for example for logical partitions) */ int blkid_partlist_set_partno(blkid_partlist ls, int partno) { if (!ls) return -1; ls->next_partno = partno; return 0; } int blkid_partlist_increment_partno(blkid_partlist ls) { return ls ? ls->next_partno++ : -1; } /* allows to set "parent" for the next nested partition */ static int blkid_partlist_set_parent(blkid_partlist ls, blkid_partition par) { if (!ls) return -1; ls->next_parent = par; return 0; } blkid_partition blkid_partlist_get_parent(blkid_partlist ls) { if (!ls) return NULL; return ls->next_parent; } int blkid_partitions_need_typeonly(blkid_probe pr) { struct blkid_chain *chn = blkid_probe_get_chain(pr); return chn && chn->data && chn->binary ? FALSE : TRUE; } /* get private chain flags */ int blkid_partitions_get_flags(blkid_probe pr) { struct blkid_chain *chn = blkid_probe_get_chain(pr); return chn ? chn->flags : 0; } /* check if @start and @size are within @par partition */ int blkid_is_nested_dimension(blkid_partition par, uint64_t start, uint64_t size) { uint64_t pstart; uint64_t psize; if (!par) return 0; pstart = blkid_partition_get_start(par); psize = blkid_partition_get_size(par); if (start < pstart || start + size > pstart + psize) return 0; return 1; } static int idinfo_probe(blkid_probe pr, const struct blkid_idinfo *id, struct blkid_chain *chn) { const struct blkid_idmag *mag = NULL; uint64_t off; int rc = BLKID_PROBE_NONE; /* default is nothing */ if (pr->size <= 0 || (id->minsz && (unsigned)id->minsz > pr->size)) goto nothing; /* the device is too small */ if (pr->flags & BLKID_FL_NOSCAN_DEV) goto nothing; rc = blkid_probe_get_idmag(pr, id, &off, &mag); if (rc != BLKID_PROBE_OK) goto nothing; /* final check by probing function */ if (id->probefunc) { DBG(LOWPROBE, ul_debug( "%s: ---> call probefunc()", id->name)); rc = id->probefunc(pr, mag); if (rc < 0) { /* reset after error */ reset_partlist(blkid_probe_get_partlist(pr)); if (chn && !chn->binary) blkid_probe_chain_reset_values(pr, chn); DBG(LOWPROBE, ul_debug("%s probefunc failed, rc %d", id->name, rc)); } if (rc == BLKID_PROBE_OK && mag && chn && !chn->binary) rc = blkid_probe_set_magic(pr, off, mag->len, (unsigned char *) mag->magic); DBG(LOWPROBE, ul_debug("%s: <--- (rc = %d)", id->name, rc)); } return rc; nothing: return BLKID_PROBE_NONE; } /* * The blkid_do_probe() backend. */ static int partitions_probe(blkid_probe pr, struct blkid_chain *chn) { int rc = BLKID_PROBE_NONE; size_t i; if (!pr || chn->idx < -1) return -EINVAL; blkid_probe_chain_reset_values(pr, chn); if (pr->flags & BLKID_FL_NOSCAN_DEV) return BLKID_PROBE_NONE; if (chn->binary) partitions_init_data(chn); if (!pr->wipe_size && (pr->prob_flags & BLKID_PROBE_FL_IGNORE_PT)) goto details_only; DBG(LOWPROBE, ul_debug("--> starting probing loop [PARTS idx=%d]", chn->idx)); i = chn->idx < 0 ? 0 : chn->idx + 1U; for ( ; i < ARRAY_SIZE(idinfos); i++) { const char *name; chn->idx = i; /* apply filter */ if (chn->fltr && blkid_bmp_get_item(chn->fltr, i)) continue; /* apply checks from idinfo */ rc = idinfo_probe(pr, idinfos[i], chn); if (rc < 0) break; if (rc != BLKID_PROBE_OK) continue; name = idinfos[i]->name; if (!chn->binary) /* * Non-binary interface, set generic variables. Note * that the another variables could be set in prober * functions. */ blkid_probe_set_value(pr, "PTTYPE", (unsigned char *) name, strlen(name) + 1); DBG(LOWPROBE, ul_debug("<-- leaving probing loop (type=%s) [PARTS idx=%d]", name, chn->idx)); rc = BLKID_PROBE_OK; break; } if (rc != BLKID_PROBE_OK) { DBG(LOWPROBE, ul_debug("<-- leaving probing loop (failed=%d) [PARTS idx=%d]", rc, chn->idx)); } details_only: /* * Gather PART_ENTRY_* values if the current device is a partition. */ if ((rc == BLKID_PROBE_OK || rc == BLKID_PROBE_NONE) && !chn->binary && (blkid_partitions_get_flags(pr) & BLKID_PARTS_ENTRY_DETAILS)) { int xrc = blkid_partitions_probe_partition(pr); /* partition entry probing is optional, and "not-found" from * this sub-probing must not to overwrite previous success. */ if (xrc < 0) rc = xrc; /* always propagate errors */ else if (rc == BLKID_PROBE_NONE) rc = xrc; } DBG(LOWPROBE, ul_debug("partitions probe done [rc=%d]", rc)); return rc; } /* Probe for nested partition table within the parental partition */ int blkid_partitions_do_subprobe(blkid_probe pr, blkid_partition parent, const struct blkid_idinfo *id) { blkid_probe prc; int rc; blkid_partlist ls; uint64_t sz, off; DBG(LOWPROBE, ul_debug( "parts: ----> %s subprobe requested)", id->name)); if (!pr || !parent || !parent->size) return -EINVAL; if (pr->flags & BLKID_FL_NOSCAN_DEV) return BLKID_PROBE_NONE; /* range defined by parent */ sz = parent->size << 9; off = parent->start << 9; if (off < pr->off || pr->off + pr->size < off + sz) { DBG(LOWPROBE, ul_debug( "ERROR: parts: <---- '%s' subprobe: overflow detected.", id->name)); return -ENOSPC; } /* create private prober */ prc = blkid_clone_probe(pr); if (!prc) return -ENOMEM; blkid_probe_set_dimension(prc, off, sz); /* clone is always with reset chain, fix it */ prc->cur_chain = blkid_probe_get_chain(pr); /* * Set 'parent' to the current list of the partitions and use the list * in cloned prober (so the cloned prober will extend the current list * of partitions rather than create a new). */ ls = blkid_probe_get_partlist(pr); blkid_partlist_set_parent(ls, parent); blkid_probe_set_partlist(prc, ls); rc = idinfo_probe(prc, id, blkid_probe_get_chain(pr)); blkid_probe_set_partlist(prc, NULL); blkid_partlist_set_parent(ls, NULL); blkid_free_probe(prc); /* free cloned prober */ DBG(LOWPROBE, ul_debug( "parts: <---- %s subprobe done (rc=%d)", id->name, rc)); return rc; } static int blkid_partitions_probe_partition(blkid_probe pr) { blkid_probe disk_pr = NULL; blkid_partlist ls; blkid_partition par; dev_t devno; DBG(LOWPROBE, ul_debug("parts: start probing for partition entry")); if (pr->flags & BLKID_FL_NOSCAN_DEV) goto nothing; devno = blkid_probe_get_devno(pr); if (!devno) goto nothing; disk_pr = blkid_probe_get_wholedisk_probe(pr); if (!disk_pr) goto nothing; /* parse PT */ ls = blkid_probe_get_partitions(disk_pr); if (!ls) goto nothing; par = blkid_partlist_devno_to_partition(ls, devno); if (!par) goto nothing; else { const char *v; blkid_parttable tab = blkid_partition_get_table(par); dev_t disk = blkid_probe_get_devno(disk_pr); if (tab) { v = blkid_parttable_get_type(tab); if (v) blkid_probe_set_value(pr, "PART_ENTRY_SCHEME", (unsigned char *) v, strlen(v) + 1); } v = blkid_partition_get_name(par); if (v) blkid_probe_set_value(pr, "PART_ENTRY_NAME", (unsigned char *) v, strlen(v) + 1); v = blkid_partition_get_uuid(par); if (v) blkid_probe_set_value(pr, "PART_ENTRY_UUID", (unsigned char *) v, strlen(v) + 1); /* type */ v = blkid_partition_get_type_string(par); if (v) blkid_probe_set_value(pr, "PART_ENTRY_TYPE", (unsigned char *) v, strlen(v) + 1); else blkid_probe_sprintf_value(pr, "PART_ENTRY_TYPE", "0x%x", blkid_partition_get_type(par)); if (blkid_partition_get_flags(par)) blkid_probe_sprintf_value(pr, "PART_ENTRY_FLAGS", "0x%llx", blkid_partition_get_flags(par)); blkid_probe_sprintf_value(pr, "PART_ENTRY_NUMBER", "%d", blkid_partition_get_partno(par)); blkid_probe_sprintf_value(pr, "PART_ENTRY_OFFSET", "%jd", (intmax_t)blkid_partition_get_start(par)); blkid_probe_sprintf_value(pr, "PART_ENTRY_SIZE", "%jd", (intmax_t)blkid_partition_get_size(par)); blkid_probe_sprintf_value(pr, "PART_ENTRY_DISK", "%u:%u", major(disk), minor(disk)); } DBG(LOWPROBE, ul_debug("parts: end probing for partition entry [success]")); return BLKID_PROBE_OK; nothing: DBG(LOWPROBE, ul_debug("parts: end probing for partition entry [nothing]")); return BLKID_PROBE_NONE; } /* * Returns 1 if the device is whole-disk and the area specified by @offset and * @size is covered by any partition. */ int blkid_probe_is_covered_by_pt(blkid_probe pr, uint64_t offset, uint64_t size) { blkid_probe prc = NULL; blkid_partlist ls = NULL; uint64_t start, end; int nparts, i, rc = 0; DBG(LOWPROBE, ul_debug( "=> checking if off=%"PRIu64" size=%"PRIu64" covered by PT", offset, size)); if (pr->flags & BLKID_FL_NOSCAN_DEV) goto done; prc = blkid_clone_probe(pr); if (!prc) goto done; ls = blkid_probe_get_partitions(prc); if (!ls) goto done; nparts = blkid_partlist_numof_partitions(ls); if (!nparts) goto done; end = (offset + size) >> 9; start = offset >> 9; /* check if the partition table fits into the device */ for (i = 0; i < nparts; i++) { blkid_partition par = &ls->parts[i]; if (par->start + par->size > (pr->size >> 9)) { DBG(LOWPROBE, ul_debug("partition #%d overflows " "device (off=%" PRId64 " size=%" PRId64 ")", par->partno, par->start, par->size)); goto done; } } /* check if the requested area is covered by PT */ for (i = 0; i < nparts; i++) { blkid_partition par = &ls->parts[i]; if (start >= par->start && end <= par->start + par->size) { rc = 1; break; } } done: blkid_free_probe(prc); DBG(LOWPROBE, ul_debug("<= %s covered by PT", rc ? "IS" : "NOT")); return rc; } /** * blkid_known_pttype: * @pttype: partition name * * Returns: 1 for known or 0 for unknown partition type. */ int blkid_known_pttype(const char *pttype) { size_t i; if (!pttype) return 0; for (i = 0; i < ARRAY_SIZE(idinfos); i++) { const struct blkid_idinfo *id = idinfos[i]; if (strcmp(id->name, pttype) == 0) return 1; } return 0; } /** * blkid_partitions_get_name: * @idx: number >= 0 * @name: returns name of a supported partition * * Since: 2.30 * * Returns: -1 if @idx is out of range, or 0 on success. */ int blkid_partitions_get_name(const size_t idx, const char **name) { if (idx < ARRAY_SIZE(idinfos)) { *name = idinfos[idx]->name; return 0; } return -1; } /** * blkid_partlist_numof_partitions: * @ls: partitions list * * Returns: number of partitions in the list or -1 in case of error. */ int blkid_partlist_numof_partitions(blkid_partlist ls) { return ls->nparts; } /** * blkid_partlist_get_table: * @ls: partitions list * * Returns: top-level partition table or NULL of there is not a partition table * on the device. */ blkid_parttable blkid_partlist_get_table(blkid_partlist ls) { if (list_empty(&ls->l_tabs)) return NULL; return list_entry(ls->l_tabs.next, struct blkid_struct_parttable, t_tabs); } /** * blkid_partlist_get_partition: * @ls: partitions list * @n: partition number in range 0..N, where 'N' is blkid_partlist_numof_partitions(). * * It's possible that the list of partitions is *empty*, but there is a valid * partition table on the disk. This happen when on-disk details about * partitions are unknown or the partition table is empty. * * See also blkid_partlist_get_table(). * * Returns: partition object or NULL in case or error. */ blkid_partition blkid_partlist_get_partition(blkid_partlist ls, int n) { if (n < 0 || n >= ls->nparts) return NULL; return &ls->parts[n]; } blkid_partition blkid_partlist_get_partition_by_start(blkid_partlist ls, uint64_t start) { int i, nparts; blkid_partition par; nparts = blkid_partlist_numof_partitions(ls); for (i = 0; i < nparts; i++) { par = blkid_partlist_get_partition(ls, i); if ((uint64_t) blkid_partition_get_start(par) == start) return par; } return NULL; } /** * blkid_partlist_get_partition_by_partno * @ls: partitions list * @n: the partition number (e.g. 'N' from sda'N') * * This does not assume any order of the input blkid_partlist. And correctly * handles "out of order" partition tables. partition N is located after * partition N+1 on the disk. * * Returns: partition object or NULL in case or error. */ blkid_partition blkid_partlist_get_partition_by_partno(blkid_partlist ls, int n) { int i, nparts; blkid_partition par; nparts = blkid_partlist_numof_partitions(ls); for (i = 0; i < nparts; i++) { par = blkid_partlist_get_partition(ls, i); if (n == blkid_partition_get_partno(par)) return par; } return NULL; } /** * blkid_partlist_devno_to_partition: * @ls: partitions list * @devno: requested partition * * This function tries to get start and size for @devno from sysfs and * returns a partition from @ls which matches with the values from sysfs. * * This function is necessary when you want to make a relation between an entry * in the partition table (@ls) and block devices in your system. * * Returns: partition object or NULL in case or error. */ blkid_partition blkid_partlist_devno_to_partition(blkid_partlist ls, dev_t devno) { struct sysfs_cxt sysfs; uint64_t start, size; int i, rc, partno = 0; DBG(LOWPROBE, ul_debug("trying to convert devno 0x%llx to partition", (long long) devno)); if (sysfs_init(&sysfs, devno, NULL)) { DBG(LOWPROBE, ul_debug("failed t init sysfs context")); return NULL; } rc = sysfs_read_u64(&sysfs, "size", &size); if (!rc) { rc = sysfs_read_u64(&sysfs, "start", &start); if (rc) { /* try to get partition number from DM uuid. */ char *uuid = sysfs_strdup(&sysfs, "dm/uuid"); char *tmp = uuid; char *prefix = uuid ? strsep(&tmp, "-") : NULL; if (prefix && strncasecmp(prefix, "part", 4) == 0) { char *end = NULL; partno = strtol(prefix + 4, &end, 10); if (prefix == end || (end && *end)) partno = 0; else rc = 0; /* success */ } free(uuid); } } sysfs_deinit(&sysfs); if (rc) return NULL; if (partno) { DBG(LOWPROBE, ul_debug("mapped by DM, using partno %d", partno)); /* * Partition mapped by kpartx does not provide "start" offset * in /sys, but if we know partno and size of the partition * that we can probably make the relation between the device * and an entry in partition table. */ for (i = 0; i < ls->nparts; i++) { blkid_partition par = &ls->parts[i]; if (partno != blkid_partition_get_partno(par)) continue; if (size == (uint64_t)blkid_partition_get_size(par) || (blkid_partition_is_extended(par) && size <= 1024ULL)) return par; } return NULL; } DBG(LOWPROBE, ul_debug("searching by offset/size")); for (i = 0; i < ls->nparts; i++) { blkid_partition par = &ls->parts[i]; if ((uint64_t)blkid_partition_get_start(par) == start && (uint64_t)blkid_partition_get_size(par) == size) return par; /* exception for extended dos partitions */ if ((uint64_t)blkid_partition_get_start(par) == start && blkid_partition_is_extended(par) && size <= 1024ULL) return par; } DBG(LOWPROBE, ul_debug("not found partition for device")); return NULL; } int blkid_parttable_set_uuid(blkid_parttable tab, const unsigned char *id) { if (!tab) return -1; blkid_unparse_uuid(id, tab->id, sizeof(tab->id)); return 0; } int blkid_parttable_set_id(blkid_parttable tab, const unsigned char *id) { if (!tab) return -1; strncpy(tab->id, (const char *) id, sizeof(tab->id)); return 0; } /* set PTUUID variable for non-binary API */ int blkid_partitions_set_ptuuid(blkid_probe pr, unsigned char *uuid) { struct blkid_chain *chn = blkid_probe_get_chain(pr); struct blkid_prval *v; if (chn->binary || blkid_uuid_is_empty(uuid, 16)) return 0; v = blkid_probe_assign_value(pr, "PTUUID"); if (!v) return -ENOMEM; v->len = UUID_STR_LEN; v->data = calloc(1, v->len); if (v->data) { blkid_unparse_uuid(uuid, (char *) v->data, v->len); return 0; } blkid_probe_free_value(v); return -ENOMEM; } /* set PTUUID variable for non-binary API for tables where * the ID is just a string */ int blkid_partitions_strcpy_ptuuid(blkid_probe pr, char *str) { struct blkid_chain *chn = blkid_probe_get_chain(pr); if (chn->binary || !str || !*str) return 0; if (!blkid_probe_set_value(pr, "PTUUID", (unsigned char *) str, strlen(str) + 1)) return -ENOMEM; return 0; } /** * blkid_parttable_get_id: * @tab: partition table * * The ID is GPT disk UUID or DOS disk ID (in hex format). * * Returns: partition table ID (for example GPT disk UUID) or NULL */ const char *blkid_parttable_get_id(blkid_parttable tab) { return *tab->id ? tab->id : NULL; } int blkid_partition_set_type(blkid_partition par, int type) { par->type = type; return 0; } /** * blkid_parttable_get_type: * @tab: partition table * * Returns: partition table type (type name, e.g. "dos", "gpt", ...) */ const char *blkid_parttable_get_type(blkid_parttable tab) { return tab->type; } /** * blkid_parttable_get_parent: * @tab: partition table * * Returns: parent for nested partition tables or NULL. */ blkid_partition blkid_parttable_get_parent(blkid_parttable tab) { return tab->parent; } /** * blkid_parttable_get_offset: * @tab: partition table * * Note the position is relative to begin of the device as defined by * blkid_probe_set_device() for primary partition table, and relative * to parental partition for nested partition tables. * * * * off_t offset; * blkid_partition parent = blkid_parttable_get_parent(tab); * * offset = blkid_parttable_get_offset(tab); * * if (parent) * / * 'tab' is nested partition table * / * offset += blkid_partition_get_start(parent); * * * Returns: position (in bytes) of the partition table or -1 in case of error. * */ blkid_loff_t blkid_parttable_get_offset(blkid_parttable tab) { return (blkid_loff_t)tab->offset; } /** * blkid_partition_get_table: * @par: partition * * The "parttable" describes partition table. The table is usually the same for * all partitions -- except nested partition tables. * * For example bsd, solaris, etc. use a nested partition table within * standard primary dos partition: * * * * * -- dos partition table * 0: sda1 dos primary partition * 1: sda2 dos primary partition * -- bsd partition table (with in sda2) * 2: sda5 bds partition * 3: sda6 bds partition * * * * * The library does not to use a separate partition table object for dos logical * partitions (partitions within extended partition). It's possible to * differentiate between logical, extended and primary partitions by * * blkid_partition_is_{extended,primary,logical}(). * * Returns: partition table object or NULL in case of error. */ blkid_parttable blkid_partition_get_table(blkid_partition par) { return par->tab; } static int partition_get_logical_type(blkid_partition par) { blkid_parttable tab; if (!par) return -1; tab = blkid_partition_get_table(par); if (!tab || !tab->type) return -1; if (tab->parent) return 'L'; /* report nested partitions as logical */ if (!strcmp(tab->type, "dos")) { if (par->partno > 4) return 'L'; /* logical */ if(par->type == MBR_DOS_EXTENDED_PARTITION || par->type == MBR_W95_EXTENDED_PARTITION || par->type == MBR_LINUX_EXTENDED_PARTITION) return 'E'; } return 'P'; } /** * blkid_partition_is_primary: * @par: partition * * Note, this function returns FALSE for DOS extended partitions and * all partitions in nested partition tables. * * Returns: 1 if the partitions is primary partition or 0 if not. */ int blkid_partition_is_primary(blkid_partition par) { return partition_get_logical_type(par) == 'P' ? TRUE : FALSE; } /** * blkid_partition_is_extended: * @par: partition * * Returns: 1 if the partitions is extended (dos, windows or linux) * partition or 0 if not. */ int blkid_partition_is_extended(blkid_partition par) { return partition_get_logical_type(par) == 'E' ? TRUE : FALSE; } /** * blkid_partition_is_logical: * @par: partition * * Note that this function returns TRUE for all partitions in all * nested partition tables (e.g. BSD labels). * * Returns: 1 if the partitions is logical partition or 0 if not. */ int blkid_partition_is_logical(blkid_partition par) { return partition_get_logical_type(par) == 'L' ? TRUE : FALSE; } static void set_string(unsigned char *item, size_t max, const unsigned char *data, size_t len) { if (len >= max) len = max - 1; memcpy(item, data, len); item[len] = '\0'; blkid_rtrim_whitespace(item); } int blkid_partition_set_name(blkid_partition par, const unsigned char *name, size_t len) { if (!par) return -1; set_string(par->name, sizeof(par->name), name, len); return 0; } int blkid_partition_set_utf8name(blkid_partition par, const unsigned char *name, size_t len, int enc) { if (!par) return -1; blkid_encode_to_utf8(enc, par->name, sizeof(par->name), name, len); blkid_rtrim_whitespace(par->name); return 0; } int blkid_partition_set_uuid(blkid_partition par, const unsigned char *uuid) { if (!par) return -1; blkid_unparse_uuid(uuid, par->uuid, sizeof(par->uuid)); return 0; } int blkid_partition_gen_uuid(blkid_partition par) { if (!par || !par->tab || !*par->tab->id) return -1; snprintf(par->uuid, sizeof(par->uuid), "%.33s-%02x", par->tab->id, par->partno); return 0; } /** * blkid_partition_get_name: * @par: partition * * Returns: partition name string if supported by PT (e.g. Mac) or NULL. */ const char *blkid_partition_get_name(blkid_partition par) { return *par->name ? (char *) par->name : NULL; } /** * blkid_partition_get_uuid: * @par: partition * * Returns: partition UUID string if supported by PT (e.g. GPT) or NULL. */ const char *blkid_partition_get_uuid(blkid_partition par) { return *par->uuid ? par->uuid : NULL; } /** * blkid_partition_get_partno: * @par: partition * * Returns: proposed partition number (e.g. 'N' from sda'N') or -1 in case of * error. Note that the number is generate by library independently on your OS. */ int blkid_partition_get_partno(blkid_partition par) { return par->partno; } /** * blkid_partition_get_start: * @par: partition * * Be careful if you _not_ probe whole disk: * * 1) the offset is usually relative to begin of the disk -- but if you probe a * fragment of the disk only -- then the offset could be still relative to * the begin of the disk rather that relative to the fragment. * * 2) the offset for nested partitions could be relative to parent (e.g. Solaris) * _or_ relative to the begin of the whole disk (e.g. bsd). * * You don't have to care about such details if you probe whole disk. In such * a case libblkid always returns the offset relative to the begin of the disk. * * Returns: start of the partition (in 512-sectors). */ blkid_loff_t blkid_partition_get_start(blkid_partition par) { return (blkid_loff_t)par->start; } /** * blkid_partition_get_size: * @par: partition * * WARNING: be very careful when you work with MS-DOS extended partitions. The * library always returns full size of the partition. If you want add * the partition to the Linux system (BLKPG_ADD_PARTITION ioctl) you * need to reduce the size of the partition to 1 or 2 blocks. The * rest of the partition has to be inaccessible for mkfs or mkswap * programs, we need a small space for boot loaders only. * * For some unknown reason this (safe) practice is not to used for * nested BSD, Solaris, ..., partition tables in Linux kernel. * * Returns: size of the partition (in 512-sectors). */ blkid_loff_t blkid_partition_get_size(blkid_partition par) { return (blkid_loff_t)par->size; } /** * blkid_partition_get_type: * @par: partition * * Returns: partition type. */ int blkid_partition_get_type(blkid_partition par) { return par->type; } /* Sets partition 'type' for PT where the type is defined by string rather * than by number */ int blkid_partition_set_type_string(blkid_partition par, const unsigned char *type, size_t len) { set_string((unsigned char *) par->typestr, sizeof(par->typestr), type, len); return 0; } /* Sets partition 'type' for PT where the type is defined by UUIDrather * than by number */ int blkid_partition_set_type_uuid(blkid_partition par, const unsigned char *uuid) { blkid_unparse_uuid(uuid, par->typestr, sizeof(par->typestr)); return 0; } /** * blkid_partition_get_type_string: * @par: partition * * The type string is supported by a small subset of partition tables (e.g Mac * and EFI GPT). Note that GPT uses type UUID and this function returns this * UUID as string. * * Returns: partition type string or NULL. */ const char *blkid_partition_get_type_string(blkid_partition par) { return *par->typestr ? par->typestr : NULL; } int blkid_partition_set_flags(blkid_partition par, unsigned long long flags) { par->flags = flags; return 0; } /** * blkid_partition_get_flags * @par: partition * * Returns: partition flags (or attributes for gpt). */ unsigned long long blkid_partition_get_flags(blkid_partition par) { return par->flags; }