#include "c.h" #include "strutils.h" #ifdef HAVE_LIBBLKID # include #endif #include "fdiskP.h" /** * SECTION: partition * @title: Partition * @short_description: generic label independent partition abstraction * * The fdisk_partition provides label independent abstraction. The partitions * are not directly connected with partition table (label) data. Any change to * fdisk_partition does not affects in-memory or on-disk label data. * * The fdisk_partition is possible to use as a template for * fdisk_add_partition() or fdisk_set_partition() operations. */ static void init_partition(struct fdisk_partition *pa) { FDISK_INIT_UNDEF(pa->size); FDISK_INIT_UNDEF(pa->start); FDISK_INIT_UNDEF(pa->partno); FDISK_INIT_UNDEF(pa->parent_partno); FDISK_INIT_UNDEF(pa->boot); INIT_LIST_HEAD(&pa->parts); } /** * fdisk_new_partition: * * Returns: new instance. */ struct fdisk_partition *fdisk_new_partition(void) { struct fdisk_partition *pa = calloc(1, sizeof(*pa)); pa->refcount = 1; init_partition(pa); DBG(PART, ul_debugobj(pa, "alloc")); return pa; } /** * fdisk_reset_partition: * @pa: partition * * Resets partition content. */ void fdisk_reset_partition(struct fdisk_partition *pa) { int ref; if (!pa) return; DBG(PART, ul_debugobj(pa, "reset")); ref = pa->refcount; fdisk_unref_parttype(pa->type); free(pa->name); free(pa->uuid); free(pa->attrs); free(pa->fstype); free(pa->fsuuid); free(pa->fslabel); free(pa->start_chs); free(pa->end_chs); memset(pa, 0, sizeof(*pa)); pa->refcount = ref; init_partition(pa); } static struct fdisk_partition *__copy_partition(struct fdisk_partition *o) { struct fdisk_partition *n = fdisk_new_partition(); if (!n) return NULL; memcpy(n, o, sizeof(*n)); if (n->type) fdisk_ref_parttype(n->type); if (o->name) n->name = strdup(o->name); if (o->uuid) n->uuid = strdup(o->uuid); if (o->attrs) n->attrs = strdup(o->attrs); if (o->fstype) n->fstype = strdup(o->fstype); if (o->fsuuid) n->fsuuid = strdup(o->fsuuid); if (o->fslabel) n->fslabel = strdup(o->fslabel); if (o->start_chs) n->start_chs = strdup(o->start_chs); if (o->end_chs) n->end_chs = strdup(o->end_chs); return n; } /** * fdisk_ref_partition: * @pa: partition pointer * * Increments reference counter. */ void fdisk_ref_partition(struct fdisk_partition *pa) { if (pa) pa->refcount++; } /** * fdisk_unref_partition: * @pa: partition pointer * * Decrements reference counter, on zero the @pa is automatically * deallocated. */ void fdisk_unref_partition(struct fdisk_partition *pa) { if (!pa) return; pa->refcount--; if (pa->refcount <= 0) { list_del(&pa->parts); fdisk_reset_partition(pa); DBG(PART, ul_debugobj(pa, "free")); free(pa); } } /** * fdisk_partition_set_start: * @pa: partition * @off: offset in sectors, maximal is UINT64_MAX-1 * * Note that zero is valid offset too. Use fdisk_partition_unset_start() to * undefine the offset. * * Returns: 0 on success, <0 on error. */ int fdisk_partition_set_start(struct fdisk_partition *pa, fdisk_sector_t off) { if (!pa) return -EINVAL; if (FDISK_IS_UNDEF(off)) return -ERANGE; pa->start = off; pa->fs_probed = 0; return 0; } /** * fdisk_partition_unset_start: * @pa: partition * * Sets the size as undefined. See fdisk_partition_has_start(). * * Returns: 0 on success, <0 on error. */ int fdisk_partition_unset_start(struct fdisk_partition *pa) { if (!pa) return -EINVAL; FDISK_INIT_UNDEF(pa->start); pa->fs_probed = 0; return 0; } /** * fdisk_partition_get_start: * @pa: partition * * The zero is also valid offset. The function may return random undefined * value when start offset is undefined (for example after * fdisk_partition_unset_start()). Always use fdisk_partition_has_start() to be * sure that you work with valid numbers. * * Returns: start offset in sectors */ fdisk_sector_t fdisk_partition_get_start(struct fdisk_partition *pa) { return pa->start; } /** * fdisk_partition_has_start: * @pa: partition * * Returns: 1 or 0 */ int fdisk_partition_has_start(struct fdisk_partition *pa) { return pa && !FDISK_IS_UNDEF(pa->start); } /** * fdisk_partition_cmp_start: * @a: partition * @b: partition * * Compares partitions according to start offset, See fdisk_table_sort_partitions(). * * Return: 0 if the same, <0 if @b greater, >0 if @a greater. */ int fdisk_partition_cmp_start(struct fdisk_partition *a, struct fdisk_partition *b) { int no_a = FDISK_IS_UNDEF(a->start), no_b = FDISK_IS_UNDEF(b->start); if (no_a && no_b) return 0; if (no_a) return -1; if (no_b) return 1; return cmp_numbers(a->start, b->start); } /** * fdisk_partition_start_follow_default * @pa: partition * @enable: 0|1 * * When @pa used as a template for fdisk_add_partition() when force label driver * to use the first possible space for the new partition. * * Returns: 0 on success, <0 on error. */ int fdisk_partition_start_follow_default(struct fdisk_partition *pa, int enable) { if (!pa) return -EINVAL; pa->start_follow_default = enable ? 1 : 0; return 0; } /** * fdisk_partition_start_is_default: * @pa: partition * * See fdisk_partition_start_follow_default(). * * Returns: 1 if the partition follows default */ int fdisk_partition_start_is_default(struct fdisk_partition *pa) { assert(pa); return pa->start_follow_default; } /** * fdisk_partition_set_size: * @pa: partition * @sz: size in sectors, maximal is UIN64_MAX-1 * * Note that zero is valid size too. Use fdisk_partition_unset_size() to * undefine the size. * * Returns: 0 on success, <0 on error. */ int fdisk_partition_set_size(struct fdisk_partition *pa, fdisk_sector_t sz) { if (!pa) return -EINVAL; if (FDISK_IS_UNDEF(sz)) return -ERANGE; pa->size = sz; pa->fs_probed = 0; return 0; } /** * fdisk_partition_unset_size: * @pa: partition * * Sets the size as undefined. See fdisk_partition_has_size(). * * Returns: 0 on success, <0 on error. */ int fdisk_partition_unset_size(struct fdisk_partition *pa) { if (!pa) return -EINVAL; FDISK_INIT_UNDEF(pa->size); pa->fs_probed = 0; return 0; } /** * fdisk_partition_get_size: * @pa: partition * * The zero is also valid size. The function may return random undefined * value when size is undefined (for example after fdisk_partition_unset_size()). * Always use fdisk_partition_has_size() to be sure that you work with valid * numbers. * * Returns: size offset in sectors */ fdisk_sector_t fdisk_partition_get_size(struct fdisk_partition *pa) { return pa->size; } /** * fdisk_partition_has_size: * @pa: partition * * Returns: 1 or 0 */ int fdisk_partition_has_size(struct fdisk_partition *pa) { return pa && !FDISK_IS_UNDEF(pa->size); } /** * fdisk_partition_size_explicit: * @pa: partition * @enable: 0|1 * * By default libfdisk aligns the size when add the new partition (by * fdisk_add_partition()). If you want to disable this functionality use * @enable = 1. * * Returns: 0 on success, <0 on error. */ int fdisk_partition_size_explicit(struct fdisk_partition *pa, int enable) { if (!pa) return -EINVAL; pa->size_explicit = enable ? 1 : 0; return 0; } /** * fdisk_partition_set_partno: * @pa: partition * @num: partition number (0 is the first partition, maximal is SIZE_MAX-1) * * Note that zero is valid partno too. Use fdisk_partition_unset_partno() to * undefine the partno. * * Returns: 0 on success, <0 on error. */ int fdisk_partition_set_partno(struct fdisk_partition *pa, size_t num) { if (!pa) return -EINVAL; if (FDISK_IS_UNDEF(num)) return -ERANGE; pa->partno = num; return 0; } /** * fdisk_partition_unset_partno: * @pa: partition * * Sets the partno as undefined. See fdisk_partition_has_partno(). * * Returns: 0 on success, <0 on error. */ int fdisk_partition_unset_partno(struct fdisk_partition *pa) { if (!pa) return -EINVAL; FDISK_INIT_UNDEF(pa->partno); return 0; } /** * fdisk_partition_get_partno: * @pa: partition * * The zero is also valid partition number. The function may return random * value when partno is undefined (for example after fdisk_partition_unset_partno()). * Always use fdisk_partition_has_partno() to be sure that you work with valid * numbers. * * Returns: partition number (0 is the first partition) */ size_t fdisk_partition_get_partno(struct fdisk_partition *pa) { return pa->partno; } /** * fdisk_partition_has_partno: * @pa: partition * * Returns: 1 or 0 */ int fdisk_partition_has_partno(struct fdisk_partition *pa) { return pa && !FDISK_IS_UNDEF(pa->partno); } /** * fdisk_partition_cmp_partno: * @a: partition * @b: partition * * Compares partitions according to partition number See fdisk_table_sort_partitions(). * * Return: 0 if the same, <0 if @b greater, >0 if @a greater. */ int fdisk_partition_cmp_partno(struct fdisk_partition *a, struct fdisk_partition *b) { return a->partno - b->partno; } /** * fdisk_partition_partno_follow_default * @pa: partition * @enable: 0|1 * * When @pa used as a template for fdisk_add_partition() when force label driver * to add a new partition to the default (next) position. * * Returns: 0 on success, <0 on error. */ int fdisk_partition_partno_follow_default(struct fdisk_partition *pa, int enable) { if (!pa) return -EINVAL; pa->partno_follow_default = enable ? 1 : 0; return 0; } /** * fdisk_partition_set_type: * @pa: partition * @type: partition type * * Sets partition type. * * Returns: 0 on success, <0 on error. */ int fdisk_partition_set_type(struct fdisk_partition *pa, struct fdisk_parttype *type) { if (!pa) return -EINVAL; fdisk_ref_parttype(type); fdisk_unref_parttype(pa->type); pa->type = type; return 0; } /** * fdisk_partition_get_type: * @pa: partition * * Returns: pointer to partition type. */ struct fdisk_parttype *fdisk_partition_get_type(struct fdisk_partition *pa) { return pa ? pa->type : NULL; } int fdisk_partition_set_name(struct fdisk_partition *pa, const char *name) { char *p = NULL; if (!pa) return -EINVAL; if (name) { p = strdup(name); if (!p) return -ENOMEM; } free(pa->name); pa->name = p; return 0; } const char *fdisk_partition_get_name(struct fdisk_partition *pa) { return pa ? pa->name : NULL; } int fdisk_partition_set_uuid(struct fdisk_partition *pa, const char *uuid) { char *p = NULL; if (!pa) return -EINVAL; if (uuid) { p = strdup(uuid); if (!p) return -ENOMEM; } free(pa->uuid); pa->uuid = p; return 0; } /** * fdisk_partition_has_end: * @pa: partition * * Returns: 1 if the partition has defined last sector */ int fdisk_partition_has_end(struct fdisk_partition *pa) { return pa && !FDISK_IS_UNDEF(pa->start) && !FDISK_IS_UNDEF(pa->size); } /** * fdisk_partition_get_end: * @pa: partition * * This function may returns absolute non-sense, always check * fdisk_partition_has_end(). * * Note that partition end is defined by fdisk_partition_set_start() and * fdisk_partition_set_size(). * * Returns: last partition sector LBA. */ fdisk_sector_t fdisk_partition_get_end(struct fdisk_partition *pa) { return pa->start + pa->size - (pa->size == 0 ? 0 : 1); } /** * fdisk_partition_end_follow_default * @pa: partition * @enable: 0|1 * * When @pa used as a template for fdisk_add_partition() when force label * driver to use all the possible space for the new partition. * * Returns: 0 on success, <0 on error. */ int fdisk_partition_end_follow_default(struct fdisk_partition *pa, int enable) { if (!pa) return -EINVAL; pa->end_follow_default = enable ? 1 : 0; return 0; } /** * fdisk_partition_end_is_default: * @pa: partition * * Returns: 1 if the partition follows default */ int fdisk_partition_end_is_default(struct fdisk_partition *pa) { assert(pa); return pa->end_follow_default; } /** * fdisk_partition_get_uuid: * @pa: partition * * Returns: partition UUID as string */ const char *fdisk_partition_get_uuid(struct fdisk_partition *pa) { return pa ? pa->uuid : NULL; } /** * fdisk_partition_get_attrs: * @pa: partition * * Returns: partition attributes in string format */ const char *fdisk_partition_get_attrs(struct fdisk_partition *pa) { return pa ? pa->attrs : NULL; } /** * fdisk_partition_set_attrs: * @pa: partition * @attrs: attributes * * Sets @attrs to @pa. * * Return: 0 on success, <0 on error. */ int fdisk_partition_set_attrs(struct fdisk_partition *pa, const char *attrs) { char *p = NULL; if (!pa) return -EINVAL; if (attrs) { p = strdup(attrs); if (!p) return -ENOMEM; } free(pa->attrs); pa->attrs = p; return 0; } /** * fdisk_partition_is_nested: * @pa: partition * * Returns: 1 if the partition is nested (e.g. MBR logical partition) */ int fdisk_partition_is_nested(struct fdisk_partition *pa) { return pa && !FDISK_IS_UNDEF(pa->parent_partno); } /** * fdisk_partition_is_container: * @pa: partition * * Returns: 1 if the partition is container (e.g. MBR extended partition) */ int fdisk_partition_is_container(struct fdisk_partition *pa) { return pa && pa->container; } /** * fdisk_partition_get_parent: * @pa: partition * @parent: parent parno * * Returns: returns devno of the parent */ int fdisk_partition_get_parent(struct fdisk_partition *pa, size_t *parent) { if (pa && parent) *parent = pa->parent_partno; else return -EINVAL; return 0; } /** * fdisk_partition_is_used: * @pa: partition * * Returns: 1 if the partition points to some area */ int fdisk_partition_is_used(struct fdisk_partition *pa) { return pa && pa->used; } /** * fdisk_partition_is_bootable: * @pa: partition * * Returns: 1 if the partition has enabled boot flag */ int fdisk_partition_is_bootable(struct fdisk_partition *pa) { return pa && pa->boot == 1; } /** * fdisk_partition_is_freespace: * @pa: partition * * Returns: 1 if @pa points to freespace */ int fdisk_partition_is_freespace(struct fdisk_partition *pa) { return pa && pa->freespace; } /** * fdisk_partition_is_wholedisk: * @pa: partition * * Returns: 1 if the partition is special whole-disk (e.g. SUN) partition */ int fdisk_partition_is_wholedisk(struct fdisk_partition *pa) { return pa && pa->wholedisk; } /** * fdisk_partition_next_partno: * @pa: partition * @cxt: context * @n: returns partition number * * If @pa specified and partno-follow-default (see fdisk_partition_partno_follow_default()) * enabled then returns next expected partno or -ERANGE on error. * * If @pa is NULL, or @pa does not specify any semantic for the next partno * then use Ask API to ask user for the next partno. In this case returns 1 if * no free partition available. If fdisk dialogs are disabled then returns -EINVAL. * * Returns: 0 on success, <0 on error, or 1 for non-free partno by Ask API. */ int fdisk_partition_next_partno( struct fdisk_partition *pa, struct fdisk_context *cxt, size_t *n) { if (!cxt || !n) return -EINVAL; if (pa && pa->partno_follow_default) { size_t i; DBG(PART, ul_debugobj(pa, "next partno (follow default)")); for (i = 0; i < cxt->label->nparts_max; i++) { if (!fdisk_is_partition_used(cxt, i)) { *n = i; return 0; } } return -ERANGE; } else if (pa && fdisk_partition_has_partno(pa)) { DBG(PART, ul_debugobj(pa, "next partno (specified=%zu)", pa->partno)); if (pa->partno >= cxt->label->nparts_max || fdisk_is_partition_used(cxt, pa->partno)) return -ERANGE; *n = pa->partno; return 0; } else if (fdisk_has_dialogs(cxt)) return fdisk_ask_partnum(cxt, n, 1); return -EINVAL; } static int probe_partition_content(struct fdisk_context *cxt, struct fdisk_partition *pa) { int rc = 1; /* nothing */ DBG(PART, ul_debugobj(pa, "start probe #%zu partition [cxt %p] >>>", pa->partno, cxt)); /* zeroize the current setting */ strdup_to_struct_member(pa, fstype, NULL); strdup_to_struct_member(pa, fsuuid, NULL); strdup_to_struct_member(pa, fslabel, NULL); if (!fdisk_partition_has_start(pa) || !fdisk_partition_has_size(pa)) goto done; #ifdef HAVE_LIBBLKID else { uintmax_t start, size; blkid_probe pr = blkid_new_probe(); if (!pr) goto done; DBG(PART, ul_debugobj(pa, "blkid prober: %p", pr)); start = fdisk_partition_get_start(pa) * fdisk_get_sector_size(cxt); size = fdisk_partition_get_size(pa) * fdisk_get_sector_size(cxt); if (blkid_probe_set_device(pr, cxt->dev_fd, start, size) == 0 && blkid_do_fullprobe(pr) == 0) { const char *data; rc = 0; if (!blkid_probe_lookup_value(pr, "TYPE", &data, NULL)) rc = strdup_to_struct_member(pa, fstype, data); if (!rc && !blkid_probe_lookup_value(pr, "LABEL", &data, NULL)) rc = strdup_to_struct_member(pa, fslabel, data); if (!rc && !blkid_probe_lookup_value(pr, "UUID", &data, NULL)) rc = strdup_to_struct_member(pa, fsuuid, data); } blkid_free_probe(pr); pa->fs_probed = 1; } #endif /* HAVE_LIBBLKID */ done: DBG(PART, ul_debugobj(pa, "<<< end probe #%zu partition[cxt %p, rc=%d]", pa->partno, cxt, rc)); return rc; } /** * fdisk_partition_to_string: * @pa: partition * @cxt: context * @id: field (FDISK_FIELD_*) * @data: returns string with allocated data * * Returns info about partition converted to printable string. * * For example * * * struct fdisk_partition *pa; * * fdisk_get_partition(cxt, 0, &pa); * fdisk_partition_to_string(pa, FDISK_FIELD_UUID, &data); * printf("first partition uuid: %s\n", data); * free(data); * fdisk_unref_partition(pa); * * * * returns UUID for the first partition. * * Returns: 0 on success, otherwise, a corresponding error. */ int fdisk_partition_to_string(struct fdisk_partition *pa, struct fdisk_context *cxt, int id, char **data) { char *p = NULL; int rc = 0; uint64_t x; if (!pa || !cxt || !data) return -EINVAL; switch (id) { case FDISK_FIELD_DEVICE: if (pa->freespace) p = strdup(_("Free space")); else if (fdisk_partition_has_partno(pa) && cxt->dev_path) { if (cxt->label->flags & FDISK_LABEL_FL_INCHARS_PARTNO) rc = asprintf(&p, "%c", (int) pa->partno + 'a'); else p = fdisk_partname(cxt->dev_path, pa->partno + 1); } break; case FDISK_FIELD_BOOT: p = fdisk_partition_is_bootable(pa) ? strdup("*") : NULL; break; case FDISK_FIELD_START: if (fdisk_partition_has_start(pa)) { x = fdisk_cround(cxt, pa->start); rc = pa->start_post ? asprintf(&p, "%"PRIu64"%c", x, pa->start_post) : asprintf(&p, "%"PRIu64, x); } break; case FDISK_FIELD_END: if (fdisk_partition_has_end(pa)) { x = fdisk_cround(cxt, fdisk_partition_get_end(pa)); rc = pa->end_post ? asprintf(&p, "%"PRIu64"%c", x, pa->end_post) : asprintf(&p, "%"PRIu64, x); } break; case FDISK_FIELD_SIZE: if (fdisk_partition_has_size(pa)) { uint64_t sz = pa->size * cxt->sector_size; switch (cxt->sizeunit) { case FDISK_SIZEUNIT_BYTES: rc = asprintf(&p, "%"PRIu64"", sz); break; case FDISK_SIZEUNIT_HUMAN: if (fdisk_is_details(cxt)) rc = pa->size_post ? asprintf(&p, "%"PRIu64"%c", sz, pa->size_post) : asprintf(&p, "%"PRIu64, sz); else { p = size_to_human_string(SIZE_SUFFIX_1LETTER, sz); if (!p) rc = -ENOMEM; } break; } } break; case FDISK_FIELD_CYLINDERS: { uintmax_t sz = fdisk_partition_has_size(pa) ? pa->size : 0; if (sz) /* Why we need to cast that to uintmax_t? */ rc = asprintf(&p, "%ju", (uintmax_t)(sz / (cxt->geom.heads * cxt->geom.sectors)) + 1); break; } case FDISK_FIELD_SECTORS: rc = asprintf(&p, "%ju", fdisk_partition_has_size(pa) ? (uintmax_t) pa->size : 0); break; case FDISK_FIELD_BSIZE: rc = asprintf(&p, "%"PRIu64, pa->bsize); break; case FDISK_FIELD_FSIZE: rc = asprintf(&p, "%"PRIu64, pa->fsize); break; case FDISK_FIELD_CPG: rc = asprintf(&p, "%"PRIu64, pa->cpg); break; case FDISK_FIELD_TYPE: p = pa->type && pa->type->name ? strdup(_(pa->type->name)) : NULL; break; case FDISK_FIELD_TYPEID: if (pa->type && fdisk_parttype_get_string(pa->type)) rc = asprintf(&p, "%s", fdisk_parttype_get_string(pa->type)); else if (pa->type) rc = asprintf(&p, "%x", fdisk_parttype_get_code(pa->type)); break; case FDISK_FIELD_UUID: p = pa->uuid && *pa->uuid? strdup(pa->uuid) : NULL; break; case FDISK_FIELD_NAME: p = pa->name && *pa->name ? strdup(pa->name) : NULL; break; case FDISK_FIELD_ATTR: p = pa->attrs && *pa->attrs ? strdup(pa->attrs) : NULL; break; case FDISK_FIELD_SADDR: p = pa->start_chs && *pa->start_chs ? strdup(pa->start_chs) : NULL; break; case FDISK_FIELD_EADDR: p = pa->end_chs && *pa->end_chs? strdup(pa->end_chs) : NULL; break; case FDISK_FIELD_FSUUID: if (pa->fs_probed || probe_partition_content(cxt, pa) == 0) p = pa->fsuuid && *pa->fsuuid ? strdup(pa->fsuuid) : NULL; break; case FDISK_FIELD_FSLABEL: if (pa->fs_probed || probe_partition_content(cxt, pa) == 0) p = pa->fslabel && *pa->fslabel ? strdup(pa->fslabel) : NULL; break; case FDISK_FIELD_FSTYPE: if (pa->fs_probed || probe_partition_content(cxt, pa) == 0) p = pa->fstype && *pa->fstype ? strdup(pa->fstype) : NULL; break; default: return -EINVAL; } if (rc < 0) { rc = -ENOMEM; free(p); p = NULL; } else if (rc > 0) rc = 0; *data = p; return rc; } /** * fdisk_get_partition: * @cxt: context * @partno: partition number (0 is the first partition) * @pa: returns data about partition * * Reads disklabel and fills in @pa with data about partition @n. * * Note that partno may address unused partition and then this function does * not fill anything to @pa. See fdisk_is_partition_used(). If @pa points to * NULL then the function allocates a newly allocated fdisk_partition struct, * use fdisk_unref_partition() to deallocate. * * Returns: 0 on success, otherwise, a corresponding error. */ int fdisk_get_partition(struct fdisk_context *cxt, size_t partno, struct fdisk_partition **pa) { int rc; struct fdisk_partition *np = NULL; if (!cxt || !cxt->label || !pa) return -EINVAL; if (!cxt->label->op->get_part) return -ENOSYS; if (!fdisk_is_partition_used(cxt, partno)) return -EINVAL; if (!*pa) { np = *pa = fdisk_new_partition(); if (!*pa) return -ENOMEM; } else fdisk_reset_partition(*pa); (*pa)->partno = partno; rc = cxt->label->op->get_part(cxt, partno, *pa); if (rc) { if (np) { fdisk_unref_partition(np); *pa = NULL; } else fdisk_reset_partition(*pa); } else (*pa)->size_explicit = 1; return rc; } static struct fdisk_partition *resize_get_by_offset( struct fdisk_table *tb, struct fdisk_partition *cur, fdisk_sector_t off) { struct fdisk_partition *pa = NULL; struct fdisk_iter itr; fdisk_reset_iter(&itr, FDISK_ITER_FORWARD); while (fdisk_table_next_partition(tb, &itr, &pa) == 0) { if (!fdisk_partition_has_start(pa) || !fdisk_partition_has_size(pa)) continue; if (fdisk_partition_is_nested(cur) && pa->parent_partno != cur->parent_partno) continue; if (off >= pa->start && off < pa->start + pa->size) return pa; } return NULL; } /* * Verify that area addressed by @start is freespace or the @cur[rent] * partition and continue to the next table entries until it's freespace, and * counts size of all this space. * * This is core of the partition start offset move operation. We can move the * start within the current partition of to the another free space. It's * forbidden to move start of the partition to another already defined * partition. */ static int resize_get_last_possible( struct fdisk_table *tb, struct fdisk_partition *cur, fdisk_sector_t start, fdisk_sector_t *maxsz) { struct fdisk_partition *pa = NULL, *last = NULL; struct fdisk_iter itr; fdisk_reset_iter(&itr, FDISK_ITER_FORWARD); *maxsz = 0; DBG(TAB, ul_debugobj(tb, "checking last possible for start=%ju", (uintmax_t) start)); while (fdisk_table_next_partition(tb, &itr, &pa) == 0) { DBG(TAB, ul_debugobj(tb, " checking entry %p [partno=%zu start=%ju, end=%ju, size=%ju%s%s%s]", pa, fdisk_partition_get_partno(pa), (uintmax_t) fdisk_partition_get_start(pa), (uintmax_t) fdisk_partition_get_end(pa), (uintmax_t) fdisk_partition_get_size(pa), fdisk_partition_is_freespace(pa) ? " freespace" : "", fdisk_partition_is_nested(pa) ? " nested" : "", fdisk_partition_is_container(pa) ? " container" : "")); if (!fdisk_partition_has_start(pa) || !fdisk_partition_has_size(pa) || (fdisk_partition_is_container(pa) && pa != cur)) { DBG(TAB, ul_debugobj(tb, " ignored (no start/size or container)")); continue; } if (fdisk_partition_is_nested(pa) && fdisk_partition_is_container(cur) && pa->parent_partno == cur->partno) { DBG(TAB, ul_debugobj(tb, " ignore (nested child of the current partition)")); continue; } /* The current is nested, free space has to be nested within the same parent */ if (fdisk_partition_is_nested(cur) && pa->parent_partno != cur->parent_partno) { DBG(TAB, ul_debugobj(tb, " ignore (nested required)")); continue; } if (!last) { if (start >= pa->start && start < pa->start + pa->size) { if (fdisk_partition_is_freespace(pa) || pa == cur) { DBG(TAB, ul_debugobj(tb, " accepted as last")); last = pa; } else { DBG(TAB, ul_debugobj(tb, " failed to set last")); break; } *maxsz = pa->size - (start - pa->start); DBG(TAB, ul_debugobj(tb, " new max=%ju", (uintmax_t) *maxsz)); } } else if (!fdisk_partition_is_freespace(pa) && pa != cur) { DBG(TAB, ul_debugobj(tb, " no free space behind current")); break; } else { last = pa; *maxsz = pa->size - (start - pa->start); DBG(TAB, ul_debugobj(tb, " new max=%ju (last updated)", (uintmax_t) *maxsz)); } } if (last) DBG(PART, ul_debugobj(cur, "resize: max size=%ju", (uintmax_t) *maxsz)); else DBG(PART, ul_debugobj(cur, "resize: nothing usable after %ju", (uintmax_t) start)); return last ? 0 : -1; } /* * Uses template @tpl to recount start and size change of the partition @res. The * @tpl->size and @tpl->start are interpreted as relative to the current setting. */ static int recount_resize( struct fdisk_context *cxt, size_t partno, struct fdisk_partition *res, struct fdisk_partition *tpl) { fdisk_sector_t start, size, xsize; struct fdisk_partition *cur = NULL; struct fdisk_table *tb = NULL; int rc; DBG(PART, ul_debugobj(tpl, ">>> resize requested")); FDISK_INIT_UNDEF(start); FDISK_INIT_UNDEF(size); rc = fdisk_get_partitions(cxt, &tb); if (!rc) rc = fdisk_get_freespaces(cxt, &tb); if (rc) { fdisk_unref_table(tb); return rc; } fdisk_table_sort_partitions(tb, fdisk_partition_cmp_start); DBG(PART, ul_debugobj(tpl, "resize partition partno=%zu in table:", partno)); ON_DBG(PART, fdisk_debug_print_table(tb)); cur = fdisk_table_get_partition_by_partno(tb, partno); if (!cur) { fdisk_unref_table(tb); return -EINVAL; } /* 1a) set new start - change relative to the current on-disk setting */ if (tpl->movestart && fdisk_partition_has_start(tpl)) { start = fdisk_partition_get_start(cur); if (tpl->movestart == FDISK_MOVE_DOWN) { if (fdisk_partition_get_start(tpl) > start) goto erange; start -= fdisk_partition_get_start(tpl); } else start += fdisk_partition_get_start(tpl); DBG(PART, ul_debugobj(tpl, "resize: moving start %s relative, new start: %ju", tpl->movestart == FDISK_MOVE_DOWN ? "DOWN" : "UP", (uintmax_t)start)); /* 1b) set new start - absolute number */ } else if (fdisk_partition_has_start(tpl)) { start = fdisk_partition_get_start(tpl); DBG(PART, ul_debugobj(tpl, "resize: moving start to absolute offset: %ju", (uintmax_t)start)); } /* 2) verify that start is within the current partition or any freespace area */ if (!FDISK_IS_UNDEF(start)) { struct fdisk_partition *area = resize_get_by_offset(tb, cur, start); if (area == cur) DBG(PART, ul_debugobj(tpl, "resize: start points to the current partition")); else if (area && fdisk_partition_is_freespace(area)) DBG(PART, ul_debugobj(tpl, "resize: start points to freespace")); else if (!area && start >= cxt->first_lba && start < cxt->first_lba + (cxt->grain / cxt->sector_size)) DBG(PART, ul_debugobj(tpl, "resize: start points before first partition")); else { DBG(PART, ul_debugobj(tpl, "resize: start verification failed")); goto erange; } } else { /* no change, start points to the current partition */ DBG(PART, ul_debugobj(tpl, "resize: start unchanged")); start = fdisk_partition_get_start(cur); } /* 3a) set new size -- reduce */ if (tpl->resize == FDISK_RESIZE_REDUCE && fdisk_partition_has_size(tpl)) { DBG(PART, ul_debugobj(tpl, "resize: reduce")); size = fdisk_partition_get_size(cur); if (fdisk_partition_get_size(tpl) > size) goto erange; size -= fdisk_partition_get_size(tpl); /* 3b) set new size -- enlarge */ } else if (tpl->resize == FDISK_RESIZE_ENLARGE && fdisk_partition_has_size(tpl)) { DBG(PART, ul_debugobj(tpl, "resize: enlarge")); size = fdisk_partition_get_size(cur); size += fdisk_partition_get_size(tpl); /* 3c) set new size -- no size specified, enlarge to all freespace */ } else if (tpl->resize == FDISK_RESIZE_ENLARGE) { DBG(PART, ul_debugobj(tpl, "resize: enlarge to all possible")); if (resize_get_last_possible(tb, cur, start, &size)) goto erange; /* 3d) set new size -- absolute number */ } else if (fdisk_partition_has_size(tpl)) { DBG(PART, ul_debugobj(tpl, "resize: new absolute size")); size = fdisk_partition_get_size(tpl); } /* 4) verify that size is within the current partition or next free space */ xsize = !FDISK_IS_UNDEF(size) ? size : fdisk_partition_get_size(cur); if (fdisk_partition_has_size(cur)) { fdisk_sector_t maxsz; if (resize_get_last_possible(tb, cur, start, &maxsz)) goto erange; DBG(PART, ul_debugobj(tpl, "resize: size=%ju, max=%ju", (uintmax_t) xsize, (uintmax_t) maxsz)); if (xsize > maxsz) goto erange; } if (!FDISK_IS_UNDEF(size)) { DBG(PART, ul_debugobj(tpl, "resize: size unchanged (undefined)")); } DBG(PART, ul_debugobj(tpl, "<<< resize: SUCCESS: start %ju->%ju; size %ju->%ju", (uintmax_t) fdisk_partition_get_start(cur), (uintmax_t) start, (uintmax_t) fdisk_partition_get_size(cur), (uintmax_t) size)); res->start = start; res->size = size; fdisk_unref_table(tb); return 0; erange: DBG(PART, ul_debugobj(tpl, "<<< resize: FAILED")); fdisk_warnx(cxt, _("Failed to resize partition #%zu."), partno + 1); fdisk_unref_table(tb); return -ERANGE; } /** * fdisk_set_partition: * @cxt: context * @partno: partition number (0 is the first partition) * @pa: new partition setting * * Modifies disklabel according to setting with in @pa. * * Returns: 0 on success, <0 on error. */ int fdisk_set_partition(struct fdisk_context *cxt, size_t partno, struct fdisk_partition *pa) { struct fdisk_partition *xpa = pa, *tmp = NULL; int rc, wipe = 0; if (!cxt || !cxt->label || !pa) return -EINVAL; if (!cxt->label->op->set_part) return -ENOSYS; pa->fs_probed = 0; if (!fdisk_is_partition_used(cxt, partno)) { pa->partno = partno; return fdisk_add_partition(cxt, pa, NULL); } if (pa->resize || fdisk_partition_has_start(pa) || fdisk_partition_has_size(pa)) { xpa = __copy_partition(pa); if (!xpa) { rc = -ENOMEM; goto done; } xpa->movestart = 0; xpa->resize = 0; FDISK_INIT_UNDEF(xpa->size); FDISK_INIT_UNDEF(xpa->start); rc = recount_resize(cxt, partno, xpa, pa); if (rc) goto done; } DBG(CXT, ul_debugobj(cxt, "setting partition %zu %p (start=%ju, end=%ju, size=%ju)", partno, xpa, (uintmax_t) fdisk_partition_get_start(xpa), (uintmax_t) fdisk_partition_get_end(xpa), (uintmax_t) fdisk_partition_get_size(xpa))); /* disable wipe for old offset/size setting */ if (fdisk_get_partition(cxt, partno, &tmp) == 0 && tmp) { wipe = fdisk_set_wipe_area(cxt, fdisk_partition_get_start(tmp), fdisk_partition_get_size(tmp), FALSE); fdisk_unref_partition(tmp); } /* call label driver */ rc = cxt->label->op->set_part(cxt, partno, xpa); /* enable wipe for new offset/size */ if (!rc && wipe) fdisk_wipe_partition(cxt, partno, TRUE); done: DBG(CXT, ul_debugobj(cxt, "set_partition() rc=%d", rc)); if (xpa != pa) fdisk_unref_partition(xpa); return rc; } /** * fdisk_wipe_partition: * @cxt: fdisk context * @partno: partition number * @enable: 0 or 1 * * Enable/disable filesystems/RAIDs wiping in area defined by partition start and size. * * Returns: <0 in case of error, 0 on success * Since: 2.29 */ int fdisk_wipe_partition(struct fdisk_context *cxt, size_t partno, int enable) { struct fdisk_partition *pa = NULL; int rc; rc = fdisk_get_partition(cxt, partno, &pa); if (rc) return rc; rc = fdisk_set_wipe_area(cxt, fdisk_partition_get_start(pa), fdisk_partition_get_size(pa), enable); fdisk_unref_partition(pa); return rc < 0 ? rc : 0; } /** * fdisk_partition_has_wipe: * @cxt: fdisk context * @pa: partition * * Since: 2.30 * * Returns: 1 if the area specified by @pa will be wiped by write command, or 0. */ int fdisk_partition_has_wipe(struct fdisk_context *cxt, struct fdisk_partition *pa) { return fdisk_has_wipe_area(cxt, fdisk_partition_get_start(pa), fdisk_partition_get_size(pa)); } /** * fdisk_add_partition: * @cxt: fdisk context * @pa: template for the partition (or NULL) * @partno: NULL or returns new partition number * * If @pa is not specified or any @pa item is missing the libfdisk will ask by * fdisk_ask_ API. * * The @pa template is is important for non-interactive partitioning, * especially for MBR where is necessary to differentiate between * primary/logical; this is done by start offset or/and partno. * The rules for MBR: * * A) template specifies start within extended partition: add logical * B) template specifies start out of extended partition: add primary * C) template specifies start (or default), partno < 4: add primary * D) template specifies default start, partno >= 4: add logical * * otherwise MBR driver uses Ask-API to get missing information. * * Adds a new partition to disklabel. * * Returns: 0 on success, <0 on error. */ int fdisk_add_partition(struct fdisk_context *cxt, struct fdisk_partition *pa, size_t *partno) { int rc; if (!cxt || !cxt->label) return -EINVAL; if (!cxt->label->op->add_part) return -ENOSYS; if (fdisk_missing_geometry(cxt)) return -EINVAL; if (pa) { pa->fs_probed = 0; DBG(CXT, ul_debugobj(cxt, "adding new partition %p", pa)); if (fdisk_partition_has_start(pa)) DBG(CXT, ul_debugobj(cxt, " start: %ju", (uintmax_t) fdisk_partition_get_start(pa))); if (fdisk_partition_has_end(pa)) DBG(CXT, ul_debugobj(cxt, " end: %ju", (uintmax_t) fdisk_partition_get_end(pa))); if (fdisk_partition_has_size(pa)) DBG(CXT, ul_debugobj(cxt, " size: %ju", (uintmax_t) fdisk_partition_get_size(pa))); DBG(CXT, ul_debugobj(cxt, " defaults: start=%s, end=%s, partno=%s", pa->start_follow_default ? "yes" : "no", pa->end_follow_default ? "yes" : "no", pa->partno_follow_default ? "yes" : "no")); } else DBG(CXT, ul_debugobj(cxt, "adding partition")); rc = cxt->label->op->add_part(cxt, pa, partno); DBG(CXT, ul_debugobj(cxt, "add partition done (rc=%d)", rc)); return rc; } /** * fdisk_delete_partition: * @cxt: fdisk context * @partno: partition number to delete (0 is the first partition) * * Deletes a @partno partition from disklabel. * * Returns: 0 on success, <0 on error */ int fdisk_delete_partition(struct fdisk_context *cxt, size_t partno) { if (!cxt || !cxt->label) return -EINVAL; if (!cxt->label->op->del_part) return -ENOSYS; fdisk_wipe_partition(cxt, partno, 0); DBG(CXT, ul_debugobj(cxt, "deleting %s partition number %zd", cxt->label->name, partno)); return cxt->label->op->del_part(cxt, partno); } /** * fdisk_delete_all_partitions: * @cxt: fdisk context * * Delete all used partitions from disklabel. * * Returns: 0 on success, otherwise, a corresponding error. */ int fdisk_delete_all_partitions(struct fdisk_context *cxt) { size_t i; int rc = 0; if (!cxt || !cxt->label) return -EINVAL; for (i = 0; i < cxt->label->nparts_max; i++) { if (!fdisk_is_partition_used(cxt, i)) continue; rc = fdisk_delete_partition(cxt, i); if (rc) break; } return rc; } /** * fdisk_is_partition_used: * @cxt: context * @n: partition number (0 is the first partition) * * Check if the partition number @n is used by partition table. This function * does not check if the device is used (e.g. mounted) by system! * * This is faster than fdisk_get_partition() + fdisk_partition_is_used(). * * Returns: 0 or 1 */ int fdisk_is_partition_used(struct fdisk_context *cxt, size_t n) { if (!cxt || !cxt->label) return -EINVAL; if (!cxt->label->op->part_is_used) return -ENOSYS; return cxt->label->op->part_is_used(cxt, n); }