powerpc/83xx: Update ranges in gianfar node to match other dts
[linux-2.6/mini2440.git] / include / mtd / ubi-user.h
blob296efae3525efe7164a8176035cc55631f5bd59d
1 /*
2 * Copyright (c) International Business Machines Corp., 2006
4 * This program is free software; you can redistribute it and/or modify
5 * it under the terms of the GNU General Public License as published by
6 * the Free Software Foundation; either version 2 of the License, or
7 * (at your option) any later version.
9 * This program is distributed in the hope that it will be useful,
10 * but WITHOUT ANY WARRANTY; without even the implied warranty of
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See
12 * the GNU General Public License for more details.
14 * You should have received a copy of the GNU General Public License
15 * along with this program; if not, write to the Free Software
16 * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
18 * Author: Artem Bityutskiy (Битюцкий Артём)
21 #ifndef __UBI_USER_H__
22 #define __UBI_USER_H__
25 * UBI device creation (the same as MTD device attachment)
26 * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
28 * MTD devices may be attached using %UBI_IOCATT ioctl command of the UBI
29 * control device. The caller has to properly fill and pass
30 * &struct ubi_attach_req object - UBI will attach the MTD device specified in
31 * the request and return the newly created UBI device number as the ioctl
32 * return value.
34 * UBI device deletion (the same as MTD device detachment)
35 * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
37 * An UBI device maybe deleted with %UBI_IOCDET ioctl command of the UBI
38 * control device.
40 * UBI volume creation
41 * ~~~~~~~~~~~~~~~~~~~
43 * UBI volumes are created via the %UBI_IOCMKVOL ioctl command of UBI character
44 * device. A &struct ubi_mkvol_req object has to be properly filled and a
45 * pointer to it has to be passed to the ioctl.
47 * UBI volume deletion
48 * ~~~~~~~~~~~~~~~~~~~
50 * To delete a volume, the %UBI_IOCRMVOL ioctl command of the UBI character
51 * device should be used. A pointer to the 32-bit volume ID hast to be passed
52 * to the ioctl.
54 * UBI volume re-size
55 * ~~~~~~~~~~~~~~~~~~
57 * To re-size a volume, the %UBI_IOCRSVOL ioctl command of the UBI character
58 * device should be used. A &struct ubi_rsvol_req object has to be properly
59 * filled and a pointer to it has to be passed to the ioctl.
61 * UBI volumes re-name
62 * ~~~~~~~~~~~~~~~~~~~
64 * To re-name several volumes atomically at one go, the %UBI_IOCRNVOL command
65 * of the UBI character device should be used. A &struct ubi_rnvol_req object
66 * has to be properly filled and a pointer to it has to be passed to the ioctl.
68 * UBI volume update
69 * ~~~~~~~~~~~~~~~~~
71 * Volume update should be done via the %UBI_IOCVOLUP ioctl command of the
72 * corresponding UBI volume character device. A pointer to a 64-bit update
73 * size should be passed to the ioctl. After this, UBI expects user to write
74 * this number of bytes to the volume character device. The update is finished
75 * when the claimed number of bytes is passed. So, the volume update sequence
76 * is something like:
78 * fd = open("/dev/my_volume");
79 * ioctl(fd, UBI_IOCVOLUP, &image_size);
80 * write(fd, buf, image_size);
81 * close(fd);
83 * Logical eraseblock erase
84 * ~~~~~~~~~~~~~~~~~~~~~~~~
86 * To erase a logical eraseblock, the %UBI_IOCEBER ioctl command of the
87 * corresponding UBI volume character device should be used. This command
88 * unmaps the requested logical eraseblock, makes sure the corresponding
89 * physical eraseblock is successfully erased, and returns.
91 * Atomic logical eraseblock change
92 * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
94 * Atomic logical eraseblock change operation is called using the %UBI_IOCEBCH
95 * ioctl command of the corresponding UBI volume character device. A pointer to
96 * a &struct ubi_leb_change_req object has to be passed to the ioctl. Then the
97 * user is expected to write the requested amount of bytes (similarly to what
98 * should be done in case of the "volume update" ioctl).
100 * Logical eraseblock map
101 * ~~~~~~~~~~~~~~~~~~~~~
103 * To map a logical eraseblock to a physical eraseblock, the %UBI_IOCEBMAP
104 * ioctl command should be used. A pointer to a &struct ubi_map_req object is
105 * expected to be passed. The ioctl maps the requested logical eraseblock to
106 * a physical eraseblock and returns. Only non-mapped logical eraseblocks can
107 * be mapped. If the logical eraseblock specified in the request is already
108 * mapped to a physical eraseblock, the ioctl fails and returns error.
110 * Logical eraseblock unmap
111 * ~~~~~~~~~~~~~~~~~~~~~~~~
113 * To unmap a logical eraseblock to a physical eraseblock, the %UBI_IOCEBUNMAP
114 * ioctl command should be used. The ioctl unmaps the logical eraseblocks,
115 * schedules corresponding physical eraseblock for erasure, and returns. Unlike
116 * the "LEB erase" command, it does not wait for the physical eraseblock being
117 * erased. Note, the side effect of this is that if an unclean reboot happens
118 * after the unmap ioctl returns, you may find the LEB mapped again to the same
119 * physical eraseblock after the UBI is run again.
121 * Check if logical eraseblock is mapped
122 * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
124 * To check if a logical eraseblock is mapped to a physical eraseblock, the
125 * %UBI_IOCEBISMAP ioctl command should be used. It returns %0 if the LEB is
126 * not mapped, and %1 if it is mapped.
128 * Set an UBI volume property
129 * ~~~~~~~~~~~~~~~~~~~~~~~~~
131 * To set an UBI volume property the %UBI_IOCSETPROP ioctl command should be
132 * used. A pointer to a &struct ubi_set_prop_req object is expected to be
133 * passed. The object describes which property should be set, and to which value
134 * it should be set.
138 * When a new UBI volume or UBI device is created, users may either specify the
139 * volume/device number they want to create or to let UBI automatically assign
140 * the number using these constants.
142 #define UBI_VOL_NUM_AUTO (-1)
143 #define UBI_DEV_NUM_AUTO (-1)
145 /* Maximum volume name length */
146 #define UBI_MAX_VOLUME_NAME 127
148 /* ioctl commands of UBI character devices */
150 #define UBI_IOC_MAGIC 'o'
152 /* Create an UBI volume */
153 #define UBI_IOCMKVOL _IOW(UBI_IOC_MAGIC, 0, struct ubi_mkvol_req)
154 /* Remove an UBI volume */
155 #define UBI_IOCRMVOL _IOW(UBI_IOC_MAGIC, 1, int32_t)
156 /* Re-size an UBI volume */
157 #define UBI_IOCRSVOL _IOW(UBI_IOC_MAGIC, 2, struct ubi_rsvol_req)
158 /* Re-name volumes */
159 #define UBI_IOCRNVOL _IOW(UBI_IOC_MAGIC, 3, struct ubi_rnvol_req)
161 /* ioctl commands of the UBI control character device */
163 #define UBI_CTRL_IOC_MAGIC 'o'
165 /* Attach an MTD device */
166 #define UBI_IOCATT _IOW(UBI_CTRL_IOC_MAGIC, 64, struct ubi_attach_req)
167 /* Detach an MTD device */
168 #define UBI_IOCDET _IOW(UBI_CTRL_IOC_MAGIC, 65, int32_t)
170 /* ioctl commands of UBI volume character devices */
172 #define UBI_VOL_IOC_MAGIC 'O'
174 /* Start UBI volume update */
175 #define UBI_IOCVOLUP _IOW(UBI_VOL_IOC_MAGIC, 0, int64_t)
176 /* LEB erasure command, used for debugging, disabled by default */
177 #define UBI_IOCEBER _IOW(UBI_VOL_IOC_MAGIC, 1, int32_t)
178 /* Atomic LEB change command */
179 #define UBI_IOCEBCH _IOW(UBI_VOL_IOC_MAGIC, 2, int32_t)
180 /* Map LEB command */
181 #define UBI_IOCEBMAP _IOW(UBI_VOL_IOC_MAGIC, 3, struct ubi_map_req)
182 /* Unmap LEB command */
183 #define UBI_IOCEBUNMAP _IOW(UBI_VOL_IOC_MAGIC, 4, int32_t)
184 /* Check if LEB is mapped command */
185 #define UBI_IOCEBISMAP _IOR(UBI_VOL_IOC_MAGIC, 5, int32_t)
186 /* Set an UBI volume property */
187 #define UBI_IOCSETPROP _IOW(UBI_VOL_IOC_MAGIC, 6, struct ubi_set_prop_req)
189 /* Maximum MTD device name length supported by UBI */
190 #define MAX_UBI_MTD_NAME_LEN 127
192 /* Maximum amount of UBI volumes that can be re-named at one go */
193 #define UBI_MAX_RNVOL 32
196 * UBI data type hint constants.
198 * UBI_LONGTERM: long-term data
199 * UBI_SHORTTERM: short-term data
200 * UBI_UNKNOWN: data persistence is unknown
202 * These constants are used when data is written to UBI volumes in order to
203 * help the UBI wear-leveling unit to find more appropriate physical
204 * eraseblocks.
206 enum {
207 UBI_LONGTERM = 1,
208 UBI_SHORTTERM = 2,
209 UBI_UNKNOWN = 3,
213 * UBI volume type constants.
215 * @UBI_DYNAMIC_VOLUME: dynamic volume
216 * @UBI_STATIC_VOLUME: static volume
218 enum {
219 UBI_DYNAMIC_VOLUME = 3,
220 UBI_STATIC_VOLUME = 4,
224 * UBI set property ioctl constants
226 * @UBI_PROP_DIRECT_WRITE: allow / disallow user to directly write and
227 * erase individual eraseblocks on dynamic volumes
229 enum {
230 UBI_PROP_DIRECT_WRITE = 1,
234 * struct ubi_attach_req - attach MTD device request.
235 * @ubi_num: UBI device number to create
236 * @mtd_num: MTD device number to attach
237 * @vid_hdr_offset: VID header offset (use defaults if %0)
238 * @padding: reserved for future, not used, has to be zeroed
240 * This data structure is used to specify MTD device UBI has to attach and the
241 * parameters it has to use. The number which should be assigned to the new UBI
242 * device is passed in @ubi_num. UBI may automatically assign the number if
243 * @UBI_DEV_NUM_AUTO is passed. In this case, the device number is returned in
244 * @ubi_num.
246 * Most applications should pass %0 in @vid_hdr_offset to make UBI use default
247 * offset of the VID header within physical eraseblocks. The default offset is
248 * the next min. I/O unit after the EC header. For example, it will be offset
249 * 512 in case of a 512 bytes page NAND flash with no sub-page support. Or
250 * it will be 512 in case of a 2KiB page NAND flash with 4 512-byte sub-pages.
252 * But in rare cases, if this optimizes things, the VID header may be placed to
253 * a different offset. For example, the boot-loader might do things faster if
254 * the VID header sits at the end of the first 2KiB NAND page with 4 sub-pages.
255 * As the boot-loader would not normally need to read EC headers (unless it
256 * needs UBI in RW mode), it might be faster to calculate ECC. This is weird
257 * example, but it real-life example. So, in this example, @vid_hdr_offer would
258 * be 2KiB-64 bytes = 1984. Note, that this position is not even 512-bytes
259 * aligned, which is OK, as UBI is clever enough to realize this is 4th
260 * sub-page of the first page and add needed padding.
262 struct ubi_attach_req {
263 int32_t ubi_num;
264 int32_t mtd_num;
265 int32_t vid_hdr_offset;
266 int8_t padding[12];
270 * struct ubi_mkvol_req - volume description data structure used in
271 * volume creation requests.
272 * @vol_id: volume number
273 * @alignment: volume alignment
274 * @bytes: volume size in bytes
275 * @vol_type: volume type (%UBI_DYNAMIC_VOLUME or %UBI_STATIC_VOLUME)
276 * @padding1: reserved for future, not used, has to be zeroed
277 * @name_len: volume name length
278 * @padding2: reserved for future, not used, has to be zeroed
279 * @name: volume name
281 * This structure is used by user-space programs when creating new volumes. The
282 * @used_bytes field is only necessary when creating static volumes.
284 * The @alignment field specifies the required alignment of the volume logical
285 * eraseblock. This means, that the size of logical eraseblocks will be aligned
286 * to this number, i.e.,
287 * (UBI device logical eraseblock size) mod (@alignment) = 0.
289 * To put it differently, the logical eraseblock of this volume may be slightly
290 * shortened in order to make it properly aligned. The alignment has to be
291 * multiple of the flash minimal input/output unit, or %1 to utilize the entire
292 * available space of logical eraseblocks.
294 * The @alignment field may be useful, for example, when one wants to maintain
295 * a block device on top of an UBI volume. In this case, it is desirable to fit
296 * an integer number of blocks in logical eraseblocks of this UBI volume. With
297 * alignment it is possible to update this volume using plane UBI volume image
298 * BLOBs, without caring about how to properly align them.
300 struct ubi_mkvol_req {
301 int32_t vol_id;
302 int32_t alignment;
303 int64_t bytes;
304 int8_t vol_type;
305 int8_t padding1;
306 int16_t name_len;
307 int8_t padding2[4];
308 char name[UBI_MAX_VOLUME_NAME + 1];
309 } __attribute__ ((packed));
312 * struct ubi_rsvol_req - a data structure used in volume re-size requests.
313 * @vol_id: ID of the volume to re-size
314 * @bytes: new size of the volume in bytes
316 * Re-sizing is possible for both dynamic and static volumes. But while dynamic
317 * volumes may be re-sized arbitrarily, static volumes cannot be made to be
318 * smaller than the number of bytes they bear. To arbitrarily shrink a static
319 * volume, it must be wiped out first (by means of volume update operation with
320 * zero number of bytes).
322 struct ubi_rsvol_req {
323 int64_t bytes;
324 int32_t vol_id;
325 } __attribute__ ((packed));
328 * struct ubi_rnvol_req - volumes re-name request.
329 * @count: count of volumes to re-name
330 * @padding1: reserved for future, not used, has to be zeroed
331 * @vol_id: ID of the volume to re-name
332 * @name_len: name length
333 * @padding2: reserved for future, not used, has to be zeroed
334 * @name: new volume name
336 * UBI allows to re-name up to %32 volumes at one go. The count of volumes to
337 * re-name is specified in the @count field. The ID of the volumes to re-name
338 * and the new names are specified in the @vol_id and @name fields.
340 * The UBI volume re-name operation is atomic, which means that should power cut
341 * happen, the volumes will have either old name or new name. So the possible
342 * use-cases of this command is atomic upgrade. Indeed, to upgrade, say, volumes
343 * A and B one may create temporary volumes %A1 and %B1 with the new contents,
344 * then atomically re-name A1->A and B1->B, in which case old %A and %B will
345 * be removed.
347 * If it is not desirable to remove old A and B, the re-name request has to
348 * contain 4 entries: A1->A, A->A1, B1->B, B->B1, in which case old A1 and B1
349 * become A and B, and old A and B will become A1 and B1.
351 * It is also OK to request: A1->A, A1->X, B1->B, B->Y, in which case old A1
352 * and B1 become A and B, and old A and B become X and Y.
354 * In other words, in case of re-naming into an existing volume name, the
355 * existing volume is removed, unless it is re-named as well at the same
356 * re-name request.
358 struct ubi_rnvol_req {
359 int32_t count;
360 int8_t padding1[12];
361 struct {
362 int32_t vol_id;
363 int16_t name_len;
364 int8_t padding2[2];
365 char name[UBI_MAX_VOLUME_NAME + 1];
366 } ents[UBI_MAX_RNVOL];
367 } __attribute__ ((packed));
370 * struct ubi_leb_change_req - a data structure used in atomic LEB change
371 * requests.
372 * @lnum: logical eraseblock number to change
373 * @bytes: how many bytes will be written to the logical eraseblock
374 * @dtype: data type (%UBI_LONGTERM, %UBI_SHORTTERM, %UBI_UNKNOWN)
375 * @padding: reserved for future, not used, has to be zeroed
377 struct ubi_leb_change_req {
378 int32_t lnum;
379 int32_t bytes;
380 int8_t dtype;
381 int8_t padding[7];
382 } __attribute__ ((packed));
385 * struct ubi_map_req - a data structure used in map LEB requests.
386 * @lnum: logical eraseblock number to unmap
387 * @dtype: data type (%UBI_LONGTERM, %UBI_SHORTTERM, %UBI_UNKNOWN)
388 * @padding: reserved for future, not used, has to be zeroed
390 struct ubi_map_req {
391 int32_t lnum;
392 int8_t dtype;
393 int8_t padding[3];
394 } __attribute__ ((packed));
398 * struct ubi_set_prop_req - a data structure used to set an ubi volume
399 * property.
400 * @property: property to set (%UBI_PROP_DIRECT_WRITE)
401 * @padding: reserved for future, not used, has to be zeroed
402 * @value: value to set
404 struct ubi_set_prop_req {
405 uint8_t property;
406 uint8_t padding[7];
407 uint64_t value;
408 } __attribute__ ((packed));
410 #endif /* __UBI_USER_H__ */