diff options
Diffstat (limited to '')
-rw-r--r-- | libfdisk/src/context.c | 1536 |
1 files changed, 1536 insertions, 0 deletions
diff --git a/libfdisk/src/context.c b/libfdisk/src/context.c new file mode 100644 index 0000000..2066278 --- /dev/null +++ b/libfdisk/src/context.c @@ -0,0 +1,1536 @@ +#ifdef HAVE_LIBBLKID +# include <blkid.h> +#endif + +#include "blkdev.h" +#ifdef __linux__ +# include "partx.h" +#endif +#include "loopdev.h" +#include "fdiskP.h" + +#include "strutils.h" + +/** + * SECTION: context + * @title: Context + * @short_description: stores info about device, labels etc. + * + * The library distinguish between three types of partitioning objects. + * + * on-disk label data + * - disk label specific + * - probed and read by disklabel drivers when assign device to the context + * or when switch to another disk label type + * - only fdisk_write_disklabel() modify on-disk data + * + * in-memory label data + * - generic data and disklabel specific data stored in struct fdisk_label + * - all partitioning operations are based on in-memory data only + * + * struct fdisk_partition + * - provides abstraction to present partitions to users + * - fdisk_partition is possible to gather to fdisk_table container + * - used as unified template for new partitions + * - used (with fdisk_table) in fdisk scripts + * - the struct fdisk_partition is always completely independent object and + * any change to the object has no effect to in-memory (or on-disk) label data + * + * Don't forget to inform kernel about changes by fdisk_reread_partition_table() + * or more smart fdisk_reread_changes(). + */ + +/** + * fdisk_new_context: + * + * Returns: newly allocated libfdisk handler + */ +struct fdisk_context *fdisk_new_context(void) +{ + struct fdisk_context *cxt; + + cxt = calloc(1, sizeof(*cxt)); + if (!cxt) + return NULL; + + DBG(CXT, ul_debugobj(cxt, "alloc")); + cxt->dev_fd = -1; + cxt->refcount = 1; + + INIT_LIST_HEAD(&cxt->wipes); + + /* + * Allocate label specific structs. + * + * This is necessary (for example) to store label specific + * context setting. + */ + cxt->labels[ cxt->nlabels++ ] = fdisk_new_gpt_label(cxt); + cxt->labels[ cxt->nlabels++ ] = fdisk_new_dos_label(cxt); + cxt->labels[ cxt->nlabels++ ] = fdisk_new_bsd_label(cxt); + cxt->labels[ cxt->nlabels++ ] = fdisk_new_sgi_label(cxt); + cxt->labels[ cxt->nlabels++ ] = fdisk_new_sun_label(cxt); + + bindtextdomain(LIBFDISK_TEXTDOMAIN, LOCALEDIR); + + return cxt; +} + +static int init_nested_from_parent(struct fdisk_context *cxt, int isnew) +{ + struct fdisk_context *parent; + + assert(cxt); + assert(cxt->parent); + + parent = cxt->parent; + + INIT_LIST_HEAD(&cxt->wipes); + + cxt->alignment_offset = parent->alignment_offset; + cxt->ask_cb = parent->ask_cb; + cxt->ask_data = parent->ask_data; + cxt->dev_fd = parent->dev_fd; + cxt->first_lba = parent->first_lba; + cxt->firstsector_bufsz = parent->firstsector_bufsz; + cxt->firstsector = parent->firstsector; + cxt->geom = parent->geom; + cxt->grain = parent->grain; + cxt->io_size = parent->io_size; + cxt->last_lba = parent->last_lba; + cxt->min_io_size = parent->min_io_size; + cxt->optimal_io_size = parent->optimal_io_size; + cxt->phy_sector_size = parent->phy_sector_size; + cxt->readonly = parent->readonly; + cxt->script = parent->script; + fdisk_ref_script(cxt->script); + cxt->sector_size = parent->sector_size; + cxt->total_sectors = parent->total_sectors; + cxt->user_geom = parent->user_geom; + cxt->user_log_sector = parent->user_log_sector; + cxt->user_pyh_sector = parent->user_pyh_sector; + + /* parent <--> nested independent setting, initialize for new nested + * contexts only */ + if (isnew) { + cxt->listonly = parent->listonly; + cxt->display_details = parent->display_details; + cxt->display_in_cyl_units = parent->display_in_cyl_units; + cxt->protect_bootbits = parent->protect_bootbits; + } + + free(cxt->dev_model); + cxt->dev_model = NULL; + cxt->dev_model_probed = 0; + + return strdup_between_structs(cxt, parent, dev_path); +} + +/** + * fdisk_new_nested_context: + * @parent: parental context + * @name: optional label name (e.g. "bsd") + * + * Create a new nested fdisk context for nested disk labels (e.g. BSD or PMBR). + * The function also probes for the nested label on the device if device is + * already assigned to parent. + * + * The new context is initialized according to @parent and both context shares + * some settings and file descriptor to the device. The child propagate some + * changes (like fdisk_assign_device()) to parent, but it does not work + * vice-versa. The behavior is undefined if you assign another device to + * parent. + * + * Returns: new context for nested partition table. + */ +struct fdisk_context *fdisk_new_nested_context(struct fdisk_context *parent, + const char *name) +{ + struct fdisk_context *cxt; + struct fdisk_label *lb = NULL; + + assert(parent); + + cxt = calloc(1, sizeof(*cxt)); + if (!cxt) + return NULL; + + DBG(CXT, ul_debugobj(parent, "alloc nested [%p] [name=%s]", cxt, name)); + cxt->refcount = 1; + + fdisk_ref_context(parent); + cxt->parent = parent; + + if (init_nested_from_parent(cxt, 1) != 0) { + cxt->parent = NULL; + fdisk_unref_context(cxt); + return NULL; + } + + if (name) { + if (strcasecmp(name, "bsd") == 0) + lb = cxt->labels[ cxt->nlabels++ ] = fdisk_new_bsd_label(cxt); + else if (strcasecmp(name, "dos") == 0 || strcasecmp(name, "mbr") == 0) + lb = cxt->labels[ cxt->nlabels++ ] = fdisk_new_dos_label(cxt); + } + + if (lb && parent->dev_fd >= 0) { + DBG(CXT, ul_debugobj(cxt, "probing for nested %s", lb->name)); + + cxt->label = lb; + + if (lb->op->probe(cxt) == 1) + __fdisk_switch_label(cxt, lb); + else { + DBG(CXT, ul_debugobj(cxt, "not found %s label", lb->name)); + if (lb->op->deinit) + lb->op->deinit(lb); + cxt->label = NULL; + } + } + + return cxt; +} + + +/** + * fdisk_ref_context: + * @cxt: context pointer + * + * Increments reference counter. + */ +void fdisk_ref_context(struct fdisk_context *cxt) +{ + if (cxt) + cxt->refcount++; +} + +/** + * fdisk_get_label: + * @cxt: context instance + * @name: label name (e.g. "gpt") + * + * If no @name specified then returns the current context label. + * + * The label is allocated and maintained within the context #cxt. There is + * nothing like reference counting for labels, you cannot deallocate the + * label. + * + * Returns: label struct or NULL in case of error. + */ +struct fdisk_label *fdisk_get_label(struct fdisk_context *cxt, const char *name) +{ + size_t i; + + assert(cxt); + + if (!name) + return cxt->label; + + if (strcasecmp(name, "mbr") == 0) + name = "dos"; + + for (i = 0; i < cxt->nlabels; i++) + if (cxt->labels[i] + && strcasecmp(cxt->labels[i]->name, name) == 0) + return cxt->labels[i]; + + DBG(CXT, ul_debugobj(cxt, "failed to found %s label driver", name)); + return NULL; +} + +/** + * fdisk_next_label: + * @cxt: context instance + * @lb: returns pointer to the next label + * + * <informalexample> + * <programlisting> + * // print all supported labels + * struct fdisk_context *cxt = fdisk_new_context(); + * struct fdisk_label *lb = NULL; + * + * while (fdisk_next_label(cxt, &lb) == 0) + * print("label name: %s\n", fdisk_label_get_name(lb)); + * fdisk_unref_context(cxt); + * </programlisting> + * </informalexample> + * + * Returns: <0 in case of error, 0 on success, 1 at the end. + */ +int fdisk_next_label(struct fdisk_context *cxt, struct fdisk_label **lb) +{ + size_t i; + struct fdisk_label *res = NULL; + + if (!lb || !cxt) + return -EINVAL; + + if (!*lb) + res = cxt->labels[0]; + else { + for (i = 1; i < cxt->nlabels; i++) { + if (*lb == cxt->labels[i - 1]) { + res = cxt->labels[i]; + break; + } + } + } + + *lb = res; + return res ? 0 : 1; +} + +/** + * fdisk_get_nlabels: + * @cxt: context + * + * Returns: number of supported label types + */ +size_t fdisk_get_nlabels(struct fdisk_context *cxt) +{ + return cxt ? cxt->nlabels : 0; +} + +int __fdisk_switch_label(struct fdisk_context *cxt, struct fdisk_label *lb) +{ + if (!lb || !cxt) + return -EINVAL; + if (lb->disabled) { + DBG(CXT, ul_debugobj(cxt, "*** attempt to switch to disabled label %s -- ignore!", lb->name)); + return -EINVAL; + } + cxt->label = lb; + DBG(CXT, ul_debugobj(cxt, "--> switching context to %s!", lb->name)); + + fdisk_apply_label_device_properties(cxt); + return 0; +} + +/** + * fdisk_has_label: + * @cxt: fdisk context + * + * Returns: return 1 if there is label on the device. + */ +int fdisk_has_label(struct fdisk_context *cxt) +{ + return cxt && cxt->label; +} + +/** + * fdisk_has_protected_bootbits: + * @cxt: fdisk context + * + * Returns: return 1 if boot bits protection enabled. + */ +int fdisk_has_protected_bootbits(struct fdisk_context *cxt) +{ + return cxt && cxt->protect_bootbits; +} + +/** + * fdisk_enable_bootbits_protection: + * @cxt: fdisk context + * @enable: 1 or 0 + * + * The library zeroizes all the first sector when create a new disk label by + * default. This function can be used to control this behavior. For now it's + * supported for MBR and GPT. + * + * Returns: 0 on success, < 0 on error. + */ +int fdisk_enable_bootbits_protection(struct fdisk_context *cxt, int enable) +{ + if (!cxt) + return -EINVAL; + cxt->protect_bootbits = enable ? 1 : 0; + return 0; +} +/** + * fdisk_disable_dialogs + * @cxt: fdisk context + * @disable: 1 or 0 + * + * The library uses dialog driven partitioning by default. + * + * Returns: 0 on success, < 0 on error. + * + * Since: 2.31 + */ +int fdisk_disable_dialogs(struct fdisk_context *cxt, int disable) +{ + if (!cxt) + return -EINVAL; + + cxt->no_disalogs = disable; + return 0; +} + +/** + * fdisk_has_dialogs + * @cxt: fdisk context + * + * See fdisk_disable_dialogs() + * + * Returns: 1 if dialog driven partitioning enabled (default), or 0. + * + * Since: 2.31 + */ +int fdisk_has_dialogs(struct fdisk_context *cxt) +{ + return cxt->no_disalogs == 0; +} + +/** + * fdisk_enable_wipe + * @cxt: fdisk context + * @enable: 1 or 0 + * + * The library removes all PT/filesystem/RAID signatures before it writes + * partition table. The probing area where it looks for signatures is from + * the begin of the disk. The device is wiped by libblkid. + * + * See also fdisk_wipe_partition(). + * + * Returns: 0 on success, < 0 on error. + */ +int fdisk_enable_wipe(struct fdisk_context *cxt, int enable) +{ + if (!cxt) + return -EINVAL; + + fdisk_set_wipe_area(cxt, 0, cxt->total_sectors, enable); + return 0; +} + +/** + * fdisk_has_wipe + * @cxt: fdisk context + * + * Returns the current wipe setting. See fdisk_enable_wipe(). + * + * Returns: 0 on success, < 0 on error. + */ +int fdisk_has_wipe(struct fdisk_context *cxt) +{ + if (!cxt) + return 0; + + return fdisk_has_wipe_area(cxt, 0, cxt->total_sectors); +} + + +/** + * fdisk_get_collision + * @cxt: fdisk context + * + * Returns: name of the filesystem or RAID detected on the device or NULL. + */ +const char *fdisk_get_collision(struct fdisk_context *cxt) +{ + return cxt->collision; +} + +/** + * fdisk_is_ptcollision: + * @cxt: fdisk context + * + * The collision detected by libblkid (usually another partition table). Note + * that libfdisk does not support all partitions tables, so fdisk_has_label() + * may return false, but fdisk_is_ptcollision() may return true. + * + * Since: 2.30 + * + * Returns: 0 or 1 + */ +int fdisk_is_ptcollision(struct fdisk_context *cxt) +{ + return cxt->pt_collision; +} + +/** + * fdisk_get_npartitions: + * @cxt: context + * + * The maximal number of the partitions depends on disklabel and does not + * have to describe the real limit of PT. + * + * For example the limit for MBR without extend partition is 4, with extended + * partition it's unlimited (so the function returns the current number of all + * partitions in this case). + * + * And for example for GPT it depends on space allocated on disk for array of + * entry records (usually 128). + * + * It's fine to use fdisk_get_npartitions() in loops, but don't forget that + * partition may be unused (see fdisk_is_partition_used()). + * + * <informalexample> + * <programlisting> + * struct fdisk_partition *pa = NULL; + * size_t i, nmax = fdisk_get_npartitions(cxt); + * + * for (i = 0; i < nmax; i++) { + * if (!fdisk_is_partition_used(cxt, i)) + * continue; + * ... do something ... + * } + * </programlisting> + * </informalexample> + * + * Note that the recommended way to list partitions is to use + * fdisk_get_partitions() and struct fdisk_table then ask disk driver for each + * individual partitions. + * + * Returns: maximal number of partitions for the current label. + */ +size_t fdisk_get_npartitions(struct fdisk_context *cxt) +{ + return cxt && cxt->label ? cxt->label->nparts_max : 0; +} + +/** + * fdisk_is_labeltype: + * @cxt: fdisk context + * @id: FDISK_DISKLABEL_* + * + * See also fdisk_is_label() macro in libfdisk.h. + * + * Returns: return 1 if the current label is @id + */ +int fdisk_is_labeltype(struct fdisk_context *cxt, enum fdisk_labeltype id) +{ + assert(cxt); + + return cxt->label && (unsigned)fdisk_label_get_type(cxt->label) == id; +} + +/** + * fdisk_get_parent: + * @cxt: nested fdisk context + * + * Returns: pointer to parental context, or NULL + */ +struct fdisk_context *fdisk_get_parent(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->parent; +} + +static void reset_context(struct fdisk_context *cxt) +{ + size_t i; + + DBG(CXT, ul_debugobj(cxt, "*** resetting context")); + + /* reset drives' private data */ + for (i = 0; i < cxt->nlabels; i++) + fdisk_deinit_label(cxt->labels[i]); + + if (cxt->parent) { + /* the first sector may be independent on parent */ + if (cxt->parent->firstsector != cxt->firstsector) { + DBG(CXT, ul_debugobj(cxt, " firstsector independent on parent (freeing)")); + free(cxt->firstsector); + } + } else { + /* we close device only in primary context */ + if (cxt->dev_fd > -1 && cxt->private_fd) + close(cxt->dev_fd); + DBG(CXT, ul_debugobj(cxt, " freeing firstsector")); + free(cxt->firstsector); + } + + free(cxt->dev_path); + cxt->dev_path = NULL; + + free(cxt->dev_model); + cxt->dev_model = NULL; + cxt->dev_model_probed = 0; + + free(cxt->collision); + cxt->collision = NULL; + + memset(&cxt->dev_st, 0, sizeof(cxt->dev_st)); + + cxt->dev_fd = -1; + cxt->private_fd = 0; + cxt->firstsector = NULL; + cxt->firstsector_bufsz = 0; + + fdisk_zeroize_device_properties(cxt); + + fdisk_unref_script(cxt->script); + cxt->script = NULL; + + cxt->label = NULL; + + fdisk_free_wipe_areas(cxt); +} + +/* fdisk_assign_device() body */ +static int fdisk_assign_fd(struct fdisk_context *cxt, int fd, + const char *fname, int readonly, int privfd) +{ + assert(cxt); + assert(fd >= 0); + + /* redirect request to parent */ + if (cxt->parent) { + int rc, org = fdisk_is_listonly(cxt->parent); + + /* assign_device() is sensitive to "listonly" mode, so let's + * follow the current context setting for the parent to avoid + * unwanted extra warnings. */ + fdisk_enable_listonly(cxt->parent, fdisk_is_listonly(cxt)); + + rc = fdisk_assign_fd(cxt->parent, fd, fname, readonly, privfd); + fdisk_enable_listonly(cxt->parent, org); + + if (!rc) + rc = init_nested_from_parent(cxt, 0); + if (!rc) + fdisk_probe_labels(cxt); + return rc; + } + + reset_context(cxt); + + if (fstat(fd, &cxt->dev_st) != 0) + goto fail; + + cxt->readonly = readonly; + cxt->dev_fd = fd; + cxt->private_fd = privfd; + cxt->dev_path = fname ? strdup(fname) : NULL; + if (!cxt->dev_path) + goto fail; + + fdisk_discover_topology(cxt); + fdisk_discover_geometry(cxt); + + fdisk_apply_user_device_properties(cxt); + + if (fdisk_read_firstsector(cxt) < 0) + goto fail; + + /* warn about obsolete stuff on the device if we aren't in list-only */ + if (!fdisk_is_listonly(cxt) && fdisk_check_collisions(cxt) < 0) + goto fail; + + fdisk_probe_labels(cxt); + fdisk_apply_label_device_properties(cxt); + + /* Don't report collision if there is already a valid partition table. + * The bootbits are wiped when we create a *new* partition table only. */ + if (fdisk_is_ptcollision(cxt) && fdisk_has_label(cxt)) { + cxt->pt_collision = 0; + free(cxt->collision); + cxt->collision = NULL; + } + + DBG(CXT, ul_debugobj(cxt, "initialized for %s [%s]", + fname, readonly ? "READ-ONLY" : "READ-WRITE")); + return 0; +fail: + { + int rc = -errno; + cxt->dev_fd = -1; + DBG(CXT, ul_debugobj(cxt, "failed to assign device [rc=%d]", rc)); + return rc; + } +} + +/** + * fdisk_assign_device: + * @cxt: context + * @fname: path to the device to be handled + * @readonly: how to open the device + * + * Open the device, discovery topology, geometry, detect disklabel, check for + * collisions and switch the current label driver to reflect the probing + * result. + * + * If in standard mode (!= non-listonly mode) then also detects for collisions. + * The result is accessible by fdisk_get_collision() and + * fdisk_is_ptcollision(). The collision (e.g. old obsolete PT) may be removed + * by fdisk_enable_wipe(). Note that new PT and old PT may be on different + * locations. + * + * Note that this function resets all generic setting in context. + * + * If the @cxt is nested context (necessary for example to edit BSD or PMBR) + * then the device is assigned to the parental context and necessary properties + * are copied to the @cxt. The change is propagated in child->parent direction + * only. It's impossible to use a different device for primary and nested + * contexts. + * + * Returns: 0 on success, < 0 on error. + */ +int fdisk_assign_device(struct fdisk_context *cxt, + const char *fname, int readonly) +{ + int fd, rc; + + DBG(CXT, ul_debugobj(cxt, "assigning device %s", fname)); + assert(cxt); + + fd = open(fname, (readonly ? O_RDONLY : O_RDWR ) | O_CLOEXEC); + if (fd < 0) { + rc = -errno; + DBG(CXT, ul_debugobj(cxt, "failed to assign device [rc=%d]", rc)); + return rc; + } + + rc = fdisk_assign_fd(cxt, fd, fname, readonly, 1); + if (rc) + close(fd); + return rc; +} + +/** + * fdisk_assign_device_by_fd: + * @cxt: context + * @fd: device file descriptor + * @fname: path to the device (used for dialogs, debugging, partition names, ...) + * @readonly: how to use the device + * + * Like fdisk_assign_device(), but caller is responsible to open and close the + * device. The library only fsync() the device on fdisk_deassign_device(). + * + * The device has to be open O_RDWR on @readonly=0. + * + * Returns: 0 on success, < 0 on error. + * + * Since: 2.35 + */ +int fdisk_assign_device_by_fd(struct fdisk_context *cxt, int fd, + const char *fname, int readonly) +{ + return fdisk_assign_fd(cxt, fd, fname, readonly, 0); +} + +/** + * fdisk_deassign_device: + * @cxt: context + * @nosync: disable sync() after close(). + * + * Call fsync(), close() and than sync(), but for read-only handler close the + * device only. If the @cxt is nested context then the request is redirected to + * the parent. + * + * Returns: 0 on success, < 0 on error. + */ +int fdisk_deassign_device(struct fdisk_context *cxt, int nosync) +{ + assert(cxt); + assert(cxt->dev_fd >= 0); + + if (cxt->parent) { + int rc = fdisk_deassign_device(cxt->parent, nosync); + + if (!rc) + rc = init_nested_from_parent(cxt, 0); + return rc; + } + + DBG(CXT, ul_debugobj(cxt, "de-assigning device %s", cxt->dev_path)); + + if (cxt->readonly && cxt->private_fd) + close(cxt->dev_fd); + else { + if (fsync(cxt->dev_fd)) { + fdisk_warn(cxt, _("%s: fsync device failed"), + cxt->dev_path); + return -errno; + } + if (cxt->private_fd && close(cxt->dev_fd)) { + fdisk_warn(cxt, _("%s: close device failed"), + cxt->dev_path); + return -errno; + } + if (!nosync) { + fdisk_info(cxt, _("Syncing disks.")); + sync(); + } + } + + free(cxt->dev_path); + cxt->dev_path = NULL; + cxt->dev_fd = -1; + + return 0; +} + +/** + * fdisk_reassign_device: + * @cxt: context + * + * This function is "hard reset" of the context and it does not write anything + * to the device. All in-memory changes associated with the context will be + * lost. It's recommended to use this function after some fatal problem when the + * context (and label specific driver) is in an undefined state. + * + * Returns: 0 on success, < 0 on error. + */ +int fdisk_reassign_device(struct fdisk_context *cxt) +{ + char *devname; + int rdonly, rc, fd, privfd; + + assert(cxt); + assert(cxt->dev_fd >= 0); + + DBG(CXT, ul_debugobj(cxt, "re-assigning device %s", cxt->dev_path)); + + devname = strdup(cxt->dev_path); + if (!devname) + return -ENOMEM; + + rdonly = cxt->readonly; + fd = cxt->dev_fd; + privfd = cxt->private_fd; + + fdisk_deassign_device(cxt, 1); + + if (privfd) + /* reopen and assign */ + rc = fdisk_assign_device(cxt, devname, rdonly); + else + /* assign only */ + rc = fdisk_assign_fd(cxt, fd, devname, rdonly, privfd); + + free(devname); + return rc; +} + +/** + * fdisk_reread_partition_table: + * @cxt: context + * + * Force *kernel* to re-read partition table on block devices. + * + * Returns: 0 on success, < 0 in case of error. + */ +int fdisk_reread_partition_table(struct fdisk_context *cxt) +{ + int i = 0; + + assert(cxt); + assert(cxt->dev_fd >= 0); + + if (!S_ISBLK(cxt->dev_st.st_mode)) + return 0; + + DBG(CXT, ul_debugobj(cxt, "calling re-read ioctl")); + sync(); +#ifdef BLKRRPART + fdisk_info(cxt, _("Calling ioctl() to re-read partition table.")); + i = ioctl(cxt->dev_fd, BLKRRPART); +#else + errno = ENOSYS; + i = 1; +#endif + + if (i) { + fdisk_warn(cxt, _("Re-reading the partition table failed.")); + fdisk_info(cxt, _( + "The kernel still uses the old table. The " + "new table will be used at the next reboot " + "or after you run partprobe(8) or partx(8).")); + return -errno; + } + + return 0; +} + +#ifdef __linux__ +static inline int add_to_partitions_array( + struct fdisk_partition ***ary, + struct fdisk_partition *pa, + size_t *n, size_t nmax) +{ + if (!*ary) { + *ary = calloc(nmax, sizeof(struct fdisk_partition *)); + if (!*ary) + return -ENOMEM; + } + (*ary)[*n] = pa; + (*n)++; + return 0; +} +#endif + +/** + * fdisk_reread_changes: + * @cxt: context + * @org: original layout (on disk) + * + * Like fdisk_reread_partition_table() but don't forces kernel re-read all + * partition table. The BLKPG_* ioctls are used for individual partitions. The + * advantage is that unmodified partitions maybe mounted. + * + * The function behaves like fdisk_reread_partition_table() on systems where + * are no available BLKPG_* ioctls. + * + * Returns: <0 on error, or 0. + */ +#ifdef __linux__ +int fdisk_reread_changes(struct fdisk_context *cxt, struct fdisk_table *org) +{ + struct fdisk_table *tb = NULL; + struct fdisk_iter itr; + struct fdisk_partition *pa; + struct fdisk_partition **rem = NULL, **add = NULL, **upd = NULL; + int change, rc = 0, err = 0; + size_t nparts, i, nadds = 0, nupds = 0, nrems = 0; + unsigned int ssf; + + DBG(CXT, ul_debugobj(cxt, "rereading changes")); + + fdisk_reset_iter(&itr, FDISK_ITER_FORWARD); + + /* the current layout */ + fdisk_get_partitions(cxt, &tb); + /* maximal number of partitions */ + nparts = max(fdisk_table_get_nents(tb), fdisk_table_get_nents(org)); + + while (fdisk_diff_tables(org, tb, &itr, &pa, &change) == 0) { + if (change == FDISK_DIFF_UNCHANGED) + continue; + switch (change) { + case FDISK_DIFF_REMOVED: + rc = add_to_partitions_array(&rem, pa, &nrems, nparts); + break; + case FDISK_DIFF_ADDED: + rc = add_to_partitions_array(&add, pa, &nadds, nparts); + break; + case FDISK_DIFF_RESIZED: + rc = add_to_partitions_array(&upd, pa, &nupds, nparts); + break; + case FDISK_DIFF_MOVED: + rc = add_to_partitions_array(&rem, pa, &nrems, nparts); + if (!rc) + rc = add_to_partitions_array(&add, pa, &nadds, nparts); + break; + } + if (rc != 0) + goto done; + } + + /* sector size factor -- used to recount from real to 512-byte sectors */ + ssf = cxt->sector_size / 512; + + for (i = 0; i < nrems; i++) { + pa = rem[i]; + DBG(PART, ul_debugobj(pa, "#%zu calling BLKPG_DEL_PARTITION", pa->partno)); + if (partx_del_partition(cxt->dev_fd, pa->partno + 1) != 0) { + fdisk_warn(cxt, _("Failed to remove partition %zu from system"), pa->partno + 1); + err++; + } + } + for (i = 0; i < nupds; i++) { + pa = upd[i]; + DBG(PART, ul_debugobj(pa, "#%zu calling BLKPG_RESIZE_PARTITION", pa->partno)); + if (partx_resize_partition(cxt->dev_fd, pa->partno + 1, + pa->start * ssf, pa->size * ssf) != 0) { + fdisk_warn(cxt, _("Failed to update system information about partition %zu"), pa->partno + 1); + err++; + } + } + for (i = 0; i < nadds; i++) { + uint64_t sz; + + pa = add[i]; + sz = pa->size * ssf; + + DBG(PART, ul_debugobj(pa, "#%zu calling BLKPG_ADD_PARTITION", pa->partno)); + + if (fdisk_is_label(cxt, DOS) && fdisk_partition_is_container(pa)) + /* Let's follow the Linux kernel and reduce + * DOS extended partition to 1 or 2 sectors. + */ + sz = min(sz, (uint64_t) 2); + + if (partx_add_partition(cxt->dev_fd, pa->partno + 1, + pa->start * ssf, sz) != 0) { + fdisk_warn(cxt, _("Failed to add partition %zu to system"), pa->partno + 1); + err++; + } + } + if (err) + fdisk_info(cxt, _( + "The kernel still uses the old partitions. The new " + "table will be used at the next reboot. ")); +done: + free(rem); + free(add); + free(upd); + fdisk_unref_table(tb); + return rc; +} +#else +int fdisk_reread_changes(struct fdisk_context *cxt, + struct fdisk_table *org __attribute__((__unused__))) { + return fdisk_reread_partition_table(cxt); +} +#endif + +/** + * fdisk_device_is_used: + * @cxt: context + * + * On systems where is no BLKRRPART ioctl the function returns zero and + * sets errno to ENOSYS. + * + * Returns: 1 if the device assigned to the context is used by system, or 0. + */ +int fdisk_device_is_used(struct fdisk_context *cxt) +{ + int rc = 0; + + assert(cxt); + assert(cxt->dev_fd >= 0); + + errno = 0; + +#ifdef BLKRRPART + /* it seems kernel always return EINVAL for BLKRRPART on loopdevices */ + if (S_ISBLK(cxt->dev_st.st_mode) + && major(cxt->dev_st.st_rdev) != LOOPDEV_MAJOR) { + DBG(CXT, ul_debugobj(cxt, "calling re-read ioctl")); + rc = ioctl(cxt->dev_fd, BLKRRPART) != 0; + } +#else + errno = ENOSYS; +#endif + DBG(CXT, ul_debugobj(cxt, "device used: %s [errno=%d]", rc ? "TRUE" : "FALSE", errno)); + return rc; +} + +/** + * fdisk_is_readonly: + * @cxt: context + * + * Returns: 1 if device open readonly + */ +int fdisk_is_readonly(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->readonly; +} + +/** + * fdisk_is_regfile: + * @cxt: context + * + * Since: 2.30 + * + * Returns: 1 if open file descriptor is regular file rather than a block device. + */ +int fdisk_is_regfile(struct fdisk_context *cxt) +{ + assert(cxt); + return S_ISREG(cxt->dev_st.st_mode); +} + +/** + * fdisk_unref_context: + * @cxt: fdisk context + * + * Deallocates context struct. + */ +void fdisk_unref_context(struct fdisk_context *cxt) +{ + unsigned i; + + if (!cxt) + return; + + cxt->refcount--; + if (cxt->refcount <= 0) { + DBG(CXT, ul_debugobj(cxt, "freeing context %p for %s", cxt, cxt->dev_path)); + + reset_context(cxt); /* this is sensitive to parent<->child relationship! */ + + /* deallocate label's private stuff */ + for (i = 0; i < cxt->nlabels; i++) { + if (!cxt->labels[i]) + continue; + if (cxt->labels[i]->op->free) + cxt->labels[i]->op->free(cxt->labels[i]); + else + free(cxt->labels[i]); + cxt->labels[i] = NULL; + } + + fdisk_unref_context(cxt->parent); + cxt->parent = NULL; + + free(cxt); + } +} + + +/** + * fdisk_enable_details: + * @cxt: context + * @enable: true/false + * + * Enables or disables "details" display mode. This function has effect to + * fdisk_partition_to_string() function. + * + * Returns: 0 on success, < 0 on error. + */ +int fdisk_enable_details(struct fdisk_context *cxt, int enable) +{ + assert(cxt); + cxt->display_details = enable ? 1 : 0; + return 0; +} + +/** + * fdisk_is_details: + * @cxt: context + * + * Returns: 1 if details are enabled + */ +int fdisk_is_details(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->display_details == 1; +} + +/** + * fdisk_enable_listonly: + * @cxt: context + * @enable: true/false + * + * Just list partition only, don't care about another details, mistakes, ... + * + * Returns: 0 on success, < 0 on error. + */ +int fdisk_enable_listonly(struct fdisk_context *cxt, int enable) +{ + assert(cxt); + cxt->listonly = enable ? 1 : 0; + return 0; +} + +/** + * fdisk_is_listonly: + * @cxt: context + * + * Returns: 1 if list-only mode enabled + */ +int fdisk_is_listonly(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->listonly == 1; +} + + +/** + * fdisk_set_unit: + * @cxt: context + * @str: "cylinder" or "sector". + * + * This is pure shit, unfortunately for example Sun addresses begin of the + * partition by cylinders... + * + * Returns: 0 on success, <0 on error. + */ +int fdisk_set_unit(struct fdisk_context *cxt, const char *str) +{ + assert(cxt); + + cxt->display_in_cyl_units = 0; + + if (!str) + return 0; + + if (strcmp(str, "cylinder") == 0 || strcmp(str, "cylinders") == 0) + cxt->display_in_cyl_units = 1; + + else if (strcmp(str, "sector") == 0 || strcmp(str, "sectors") == 0) + cxt->display_in_cyl_units = 0; + + DBG(CXT, ul_debugobj(cxt, "display unit: %s", fdisk_get_unit(cxt, 0))); + return 0; +} + +/** + * fdisk_get_unit: + * @cxt: context + * @n: FDISK_PLURAL or FDISK_SINGULAR + * + * Returns: unit name. + */ +const char *fdisk_get_unit(struct fdisk_context *cxt, int n) +{ + assert(cxt); + + if (fdisk_use_cylinders(cxt)) + return P_("cylinder", "cylinders", n); + return P_("sector", "sectors", n); +} + +/** + * fdisk_use_cylinders: + * @cxt: context + * + * Returns: 1 if user wants to display in cylinders. + */ +int fdisk_use_cylinders(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->display_in_cyl_units == 1; +} + +/** + * fdisk_get_units_per_sector: + * @cxt: context + * + * This is necessary only for brain dead situations when we use "cylinders"; + * + * Returns: number of "units" per sector, default is 1 if display unit is sector. + */ +unsigned int fdisk_get_units_per_sector(struct fdisk_context *cxt) +{ + assert(cxt); + + if (fdisk_use_cylinders(cxt)) { + assert(cxt->geom.heads); + return cxt->geom.heads * cxt->geom.sectors; + } + return 1; +} + +/** + * fdisk_get_optimal_iosize: + * @cxt: context + * + * The optimal I/O is optional and does not have to be provided by device, + * anyway libfdisk never returns zero. If the optimal I/O size is not provided + * then libfdisk returns minimal I/O size or sector size. + * + * Returns: optimal I/O size in bytes. + */ +unsigned long fdisk_get_optimal_iosize(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->optimal_io_size ? cxt->optimal_io_size : cxt->io_size; +} + +/** + * fdisk_get_minimal_iosize: + * @cxt: context + * + * Returns: minimal I/O size in bytes + */ +unsigned long fdisk_get_minimal_iosize(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->min_io_size; +} + +/** + * fdisk_get_physector_size: + * @cxt: context + * + * Returns: physical sector size in bytes + */ +unsigned long fdisk_get_physector_size(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->phy_sector_size; +} + +/** + * fdisk_get_sector_size: + * @cxt: context + * + * Returns: logical sector size in bytes + */ +unsigned long fdisk_get_sector_size(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->sector_size; +} + +/** + * fdisk_get_alignment_offset + * @cxt: context + * + * The alignment offset is offset between logical and physical sectors. For + * backward compatibility the first logical sector on 4K disks does no have to + * start on the same place like physical sectors. + * + * Returns: alignment offset in bytes + */ +unsigned long fdisk_get_alignment_offset(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->alignment_offset; +} + +/** + * fdisk_get_grain_size: + * @cxt: context + * + * Returns: grain in bytes used to align partitions (usually 1MiB) + */ +unsigned long fdisk_get_grain_size(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->grain; +} + +/** + * fdisk_get_first_lba: + * @cxt: context + * + * Returns: first possible LBA on disk for data partitions. + */ +fdisk_sector_t fdisk_get_first_lba(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->first_lba; +} + +/** + * fdisk_set_first_lba: + * @cxt: fdisk context + * @lba: first possible logical sector for data + * + * It's strongly recommended to use the default library setting. The first LBA + * is always reset by fdisk_assign_device(), fdisk_override_geometry() + * and fdisk_reset_alignment(). This is very low level function and library + * does not check if your setting makes any sense. + * + * This function is necessary only when you want to work with very unusual + * partition tables like GPT protective MBR or hybrid partition tables on + * bootable media where the first partition may start on very crazy offsets. + * + * Note that this function changes only runtime information. It does not update + * any range in on-disk partition table. For example GPT Header contains First + * and Last usable LBA fields. These fields are not updated by this function. + * Be careful. + * + * Returns: 0 on success, <0 on error. + */ +fdisk_sector_t fdisk_set_first_lba(struct fdisk_context *cxt, fdisk_sector_t lba) +{ + assert(cxt); + DBG(CXT, ul_debugobj(cxt, "setting first LBA from %ju to %ju", + (uintmax_t) cxt->first_lba, (uintmax_t) lba)); + cxt->first_lba = lba; + return 0; +} + +/** + * fdisk_get_last_lba: + * @cxt: fdisk context + * + * Note that the device has to be already assigned. + * + * Returns: last possible LBA on device + */ +fdisk_sector_t fdisk_get_last_lba(struct fdisk_context *cxt) +{ + return cxt->last_lba; +} + +/** + * fdisk_set_last_lba: + * @cxt: fdisk context + * @lba: last possible logical sector + * + * It's strongly recommended to use the default library setting. The last LBA + * is always reset by fdisk_assign_device(), fdisk_override_geometry() and + * fdisk_reset_alignment(). + * + * The default is number of sectors on the device, but maybe modified by the + * current disklabel driver (for example GPT uses the end of disk for backup + * header, so last_lba is smaller than total number of sectors). + * + * Returns: 0 on success, <0 on error. + */ +fdisk_sector_t fdisk_set_last_lba(struct fdisk_context *cxt, fdisk_sector_t lba) +{ + assert(cxt); + + if (lba > cxt->total_sectors - 1 || lba < 1) + return -ERANGE; + cxt->last_lba = lba; + return 0; +} + +/** + * fdisk_set_size_unit: + * @cxt: fdisk context + * @unit: FDISK_SIZEUNIT_* + * + * Sets unit for SIZE output field (see fdisk_partition_to_string()). + * + * Returns: 0 on success, <0 on error. + */ +int fdisk_set_size_unit(struct fdisk_context *cxt, int unit) +{ + assert(cxt); + cxt->sizeunit = unit; + return 0; +} + +/** + * fdisk_get_size_unit: + * @cxt: fdisk context + * + * Gets unit for SIZE output field (see fdisk_partition_to_string()). + * + * Returns: unit + */ +int fdisk_get_size_unit(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->sizeunit; +} + +/** + * fdisk_get_nsectors: + * @cxt: context + * + * Returns: size of the device in logical sectors. + */ +fdisk_sector_t fdisk_get_nsectors(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->total_sectors; +} + +/** + * fdisk_get_devname: + * @cxt: context + * + * Returns: device name. + */ +const char *fdisk_get_devname(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->dev_path; +} + +/** + * fdisk_get_devno: + * @cxt: context + * + * Returns: device number or zero for non-block devices + * + * Since: 2.33 + */ +dev_t fdisk_get_devno(struct fdisk_context *cxt) +{ + assert(cxt); + return S_ISBLK(cxt->dev_st.st_mode) ? cxt->dev_st.st_rdev : 0; +} + +/** + * fdisk_get_devmodel: + * @cxt: context + * + * Returns: device model string or NULL. + * + * Since: 2.33 + */ +#ifdef __linux__ +const char *fdisk_get_devmodel(struct fdisk_context *cxt) +{ + assert(cxt); + + if (cxt->dev_model_probed) + return cxt->dev_model; + + if (fdisk_get_devno(cxt)) { + struct path_cxt *pc = ul_new_sysfs_path(fdisk_get_devno(cxt), NULL, NULL); + + if (pc) { + ul_path_read_string(pc, &cxt->dev_model, "device/model"); + ul_unref_path(pc); + } + } + cxt->dev_model_probed = 1; + return cxt->dev_model; +} +#else +const char *fdisk_get_devmodel(struct fdisk_context *cxt __attribute__((__unused__))) +{ + return NULL; +} +#endif + +/** + * fdisk_get_devfd: + * @cxt: context + * + * Returns: device file descriptor. + */ +int fdisk_get_devfd(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->dev_fd; +} + +/** + * fdisk_get_geom_heads: + * @cxt: context + * + * Returns: number of geometry heads. + */ +unsigned int fdisk_get_geom_heads(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->geom.heads; +} +/** + * fdisk_get_geom_sectors: + * @cxt: context + * + * Returns: number of geometry sectors. + */ +fdisk_sector_t fdisk_get_geom_sectors(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->geom.sectors; + +} + +/** + * fdisk_get_geom_cylinders: + * @cxt: context + * + * Returns: number of geometry cylinders + */ +fdisk_sector_t fdisk_get_geom_cylinders(struct fdisk_context *cxt) +{ + assert(cxt); + return cxt->geom.cylinders; +} + +int fdisk_missing_geometry(struct fdisk_context *cxt) +{ + int rc; + + if (!cxt || !cxt->label) + return 0; + + rc = (fdisk_label_require_geometry(cxt->label) && + (!cxt->geom.heads || !cxt->geom.sectors + || !cxt->geom.cylinders)); + + if (rc && !fdisk_is_listonly(cxt)) + fdisk_warnx(cxt, _("Incomplete geometry setting.")); + + return rc; +} + |