xref: /linux/Documentation/filesystems/idmappings.rst (revision 34f7c6e7d4396090692a09789db231e12cb4762b)
1.. SPDX-License-Identifier: GPL-2.0
2
3Idmappings
4==========
5
6Most filesystem developers will have encountered idmappings. They are used when
7reading from or writing ownership to disk, reporting ownership to userspace, or
8for permission checking. This document is aimed at filesystem developers that
9want to know how idmappings work.
10
11Formal notes
12------------
13
14An idmapping is essentially a translation of a range of ids into another or the
15same range of ids. The notational convention for idmappings that is widely used
16in userspace is::
17
18 u:k:r
19
20``u`` indicates the first element in the upper idmapset ``U`` and ``k``
21indicates the first element in the lower idmapset ``K``. The ``r`` parameter
22indicates the range of the idmapping, i.e. how many ids are mapped. From now
23on, we will always prefix ids with ``u`` or ``k`` to make it clear whether
24we're talking about an id in the upper or lower idmapset.
25
26To see what this looks like in practice, let's take the following idmapping::
27
28 u22:k10000:r3
29
30and write down the mappings it will generate::
31
32 u22 -> k10000
33 u23 -> k10001
34 u24 -> k10002
35
36From a mathematical viewpoint ``U`` and ``K`` are well-ordered sets and an
37idmapping is an order isomorphism from ``U`` into ``K``. So ``U`` and ``K`` are
38order isomorphic. In fact, ``U`` and ``K`` are always well-ordered subsets of
39the set of all possible ids useable on a given system.
40
41Looking at this mathematically briefly will help us highlight some properties
42that make it easier to understand how we can translate between idmappings. For
43example, we know that the inverse idmapping is an order isomorphism as well::
44
45 k10000 -> u22
46 k10001 -> u23
47 k10002 -> u24
48
49Given that we are dealing with order isomorphisms plus the fact that we're
50dealing with subsets we can embedd idmappings into each other, i.e. we can
51sensibly translate between different idmappings. For example, assume we've been
52given the three idmappings::
53
54 1. u0:k10000:r10000
55 2. u0:k20000:r10000
56 3. u0:k30000:r10000
57
58and id ``k11000`` which has been generated by the first idmapping by mapping
59``u1000`` from the upper idmapset down to ``k11000`` in the lower idmapset.
60
61Because we're dealing with order isomorphic subsets it is meaningful to ask
62what id ``k11000`` corresponds to in the second or third idmapping. The
63straightfoward algorithm to use is to apply the inverse of the first idmapping,
64mapping ``k11000`` up to ``u1000``. Afterwards, we can map ``u1000`` down using
65either the second idmapping mapping or third idmapping mapping. The second
66idmapping would map ``u1000`` down to ``21000``. The third idmapping would map
67``u1000`` down to ``u31000``.
68
69If we were given the same task for the following three idmappings::
70
71 1. u0:k10000:r10000
72 2. u0:k20000:r200
73 3. u0:k30000:r300
74
75we would fail to translate as the sets aren't order isomorphic over the full
76range of the first idmapping anymore (However they are order isomorphic over
77the full range of the second idmapping.). Neither the second or third idmapping
78contain ``u1000`` in the upper idmapset ``U``. This is equivalent to not having
79an id mapped. We can simply say that ``u1000`` is unmapped in the second and
80third idmapping. The kernel will report unmapped ids as the overflowuid
81``(uid_t)-1`` or overflowgid ``(gid_t)-1`` to userspace.
82
83The algorithm to calculate what a given id maps to is pretty simple. First, we
84need to verify that the range can contain our target id. We will skip this step
85for simplicity. After that if we want to know what ``id`` maps to we can do
86simple calculations:
87
88- If we want to map from left to right::
89
90   u:k:r
91   id - u + k = n
92
93- If we want to map from right to left::
94
95   u:k:r
96   id - k + u = n
97
98Instead of "left to right" we can also say "down" and instead of "right to
99left" we can also say "up". Obviously mapping down and up invert each other.
100
101To see whether the simple formulas above work, consider the following two
102idmappings::
103
104 1. u0:k20000:r10000
105 2. u500:k30000:r10000
106
107Assume we are given ``k21000`` in the lower idmapset of the first idmapping. We
108want to know what id this was mapped from in the upper idmapset of the first
109idmapping. So we're mapping up in the first idmapping::
110
111 id     - k      + u  = n
112 k21000 - k20000 + u0 = u1000
113
114Now assume we are given the id ``u1100`` in the upper idmapset of the second
115idmapping and we want to know what this id maps down to in the lower idmapset
116of the second idmapping. This means we're mapping down in the second
117idmapping::
118
119 id    - u    + k      = n
120 u1100 - u500 + k30000 = k30600
121
122General notes
123-------------
124
125In the context of the kernel an idmapping can be interpreted as mapping a range
126of userspace ids into a range of kernel ids::
127
128 userspace-id:kernel-id:range
129
130A userspace id is always an element in the upper idmapset of an idmapping of
131type ``uid_t`` or ``gid_t`` and a kernel id is always an element in the lower
132idmapset of an idmapping of type ``kuid_t`` or ``kgid_t``. From now on
133"userspace id" will be used to refer to the well known ``uid_t`` and ``gid_t``
134types and "kernel id" will be used to refer to ``kuid_t`` and ``kgid_t``.
135
136The kernel is mostly concerned with kernel ids. They are used when performing
137permission checks and are stored in an inode's ``i_uid`` and ``i_gid`` field.
138A userspace id on the other hand is an id that is reported to userspace by the
139kernel, or is passed by userspace to the kernel, or a raw device id that is
140written or read from disk.
141
142Note that we are only concerned with idmappings as the kernel stores them not
143how userspace would specify them.
144
145For the rest of this document we will prefix all userspace ids with ``u`` and
146all kernel ids with ``k``. Ranges of idmappings will be prefixed with ``r``. So
147an idmapping will be written as ``u0:k10000:r10000``.
148
149For example, the id ``u1000`` is an id in the upper idmapset or "userspace
150idmapset" starting with ``u1000``. And it is mapped to ``k11000`` which is a
151kernel id in the lower idmapset or "kernel idmapset" starting with ``k10000``.
152
153A kernel id is always created by an idmapping. Such idmappings are associated
154with user namespaces. Since we mainly care about how idmappings work we're not
155going to be concerned with how idmappings are created nor how they are used
156outside of the filesystem context. This is best left to an explanation of user
157namespaces.
158
159The initial user namespace is special. It always has an idmapping of the
160following form::
161
162 u0:k0:r4294967295
163
164which is an identity idmapping over the full range of ids available on this
165system.
166
167Other user namespaces usually have non-identity idmappings such as::
168
169 u0:k10000:r10000
170
171When a process creates or wants to change ownership of a file, or when the
172ownership of a file is read from disk by a filesystem, the userspace id is
173immediately translated into a kernel id according to the idmapping associated
174with the relevant user namespace.
175
176For instance, consider a file that is stored on disk by a filesystem as being
177owned by ``u1000``:
178
179- If a filesystem were to be mounted in the initial user namespaces (as most
180  filesystems are) then the initial idmapping will be used. As we saw this is
181  simply the identity idmapping. This would mean id ``u1000`` read from disk
182  would be mapped to id ``k1000``. So an inode's ``i_uid`` and ``i_gid`` field
183  would contain ``k1000``.
184
185- If a filesystem were to be mounted with an idmapping of ``u0:k10000:r10000``
186  then ``u1000`` read from disk would be mapped to ``k11000``. So an inode's
187  ``i_uid`` and ``i_gid`` would contain ``k11000``.
188
189Translation algorithms
190----------------------
191
192We've already seen briefly that it is possible to translate between different
193idmappings. We'll now take a closer look how that works.
194
195Crossmapping
196~~~~~~~~~~~~
197
198This translation algorithm is used by the kernel in quite a few places. For
199example, it is used when reporting back the ownership of a file to userspace
200via the ``stat()`` system call family.
201
202If we've been given ``k11000`` from one idmapping we can map that id up in
203another idmapping. In order for this to work both idmappings need to contain
204the same kernel id in their kernel idmapsets. For example, consider the
205following idmappings::
206
207 1. u0:k10000:r10000
208 2. u20000:k10000:r10000
209
210and we are mapping ``u1000`` down to ``k11000`` in the first idmapping . We can
211then translate ``k11000`` into a userspace id in the second idmapping using the
212kernel idmapset of the second idmapping::
213
214 /* Map the kernel id up into a userspace id in the second idmapping. */
215 from_kuid(u20000:k10000:r10000, k11000) = u21000
216
217Note, how we can get back to the kernel id in the first idmapping by inverting
218the algorithm::
219
220 /* Map the userspace id down into a kernel id in the second idmapping. */
221 make_kuid(u20000:k10000:r10000, u21000) = k11000
222
223 /* Map the kernel id up into a userspace id in the first idmapping. */
224 from_kuid(u0:k10000:r10000, k11000) = u1000
225
226This algorithm allows us to answer the question what userspace id a given
227kernel id corresponds to in a given idmapping. In order to be able to answer
228this question both idmappings need to contain the same kernel id in their
229respective kernel idmapsets.
230
231For example, when the kernel reads a raw userspace id from disk it maps it down
232into a kernel id according to the idmapping associated with the filesystem.
233Let's assume the filesystem was mounted with an idmapping of
234``u0:k20000:r10000`` and it reads a file owned by ``u1000`` from disk. This
235means ``u1000`` will be mapped to ``k21000`` which is what will be stored in
236the inode's ``i_uid`` and ``i_gid`` field.
237
238When someone in userspace calls ``stat()`` or a related function to get
239ownership information about the file the kernel can't simply map the id back up
240according to the filesystem's idmapping as this would give the wrong owner if
241the caller is using an idmapping.
242
243So the kernel will map the id back up in the idmapping of the caller. Let's
244assume the caller has the slighly unconventional idmapping
245``u3000:k20000:r10000`` then ``k21000`` would map back up to ``u4000``.
246Consequently the user would see that this file is owned by ``u4000``.
247
248Remapping
249~~~~~~~~~
250
251It is possible to translate a kernel id from one idmapping to another one via
252the userspace idmapset of the two idmappings. This is equivalent to remapping
253a kernel id.
254
255Let's look at an example. We are given the following two idmappings::
256
257 1. u0:k10000:r10000
258 2. u0:k20000:r10000
259
260and we are given ``k11000`` in the first idmapping. In order to translate this
261kernel id in the first idmapping into a kernel id in the second idmapping we
262need to perform two steps:
263
2641. Map the kernel id up into a userspace id in the first idmapping::
265
266    /* Map the kernel id up into a userspace id in the first idmapping. */
267    from_kuid(u0:k10000:r10000, k11000) = u1000
268
2692. Map the userspace id down into a kernel id in the second idmapping::
270
271    /* Map the userspace id down into a kernel id in the second idmapping. */
272    make_kuid(u0:k20000:r10000, u1000) = k21000
273
274As you can see we used the userspace idmapset in both idmappings to translate
275the kernel id in one idmapping to a kernel id in another idmapping.
276
277This allows us to answer the question what kernel id we would need to use to
278get the same userspace id in another idmapping. In order to be able to answer
279this question both idmappings need to contain the same userspace id in their
280respective userspace idmapsets.
281
282Note, how we can easily get back to the kernel id in the first idmapping by
283inverting the algorithm:
284
2851. Map the kernel id up into a userspace id in the second idmapping::
286
287    /* Map the kernel id up into a userspace id in the second idmapping. */
288    from_kuid(u0:k20000:r10000, k21000) = u1000
289
2902. Map the userspace id down into a kernel id in the first idmapping::
291
292    /* Map the userspace id down into a kernel id in the first idmapping. */
293    make_kuid(u0:k10000:r10000, u1000) = k11000
294
295Another way to look at this translation is to treat it as inverting one
296idmapping and applying another idmapping if both idmappings have the relevant
297userspace id mapped. This will come in handy when working with idmapped mounts.
298
299Invalid translations
300~~~~~~~~~~~~~~~~~~~~
301
302It is never valid to use an id in the kernel idmapset of one idmapping as the
303id in the userspace idmapset of another or the same idmapping. While the kernel
304idmapset always indicates an idmapset in the kernel id space the userspace
305idmapset indicates a userspace id. So the following translations are forbidden::
306
307 /* Map the userspace id down into a kernel id in the first idmapping. */
308 make_kuid(u0:k10000:r10000, u1000) = k11000
309
310 /* INVALID: Map the kernel id down into a kernel id in the second idmapping. */
311 make_kuid(u10000:k20000:r10000, k110000) = k21000
312                                 ~~~~~~~
313
314and equally wrong::
315
316 /* Map the kernel id up into a userspace id in the first idmapping. */
317 from_kuid(u0:k10000:r10000, k11000) = u1000
318
319 /* INVALID: Map the userspace id up into a userspace id in the second idmapping. */
320 from_kuid(u20000:k0:r10000, u1000) = k21000
321                             ~~~~~
322
323Idmappings when creating filesystem objects
324-------------------------------------------
325
326The concepts of mapping an id down or mapping an id up are expressed in the two
327kernel functions filesystem developers are rather familiar with and which we've
328already used in this document::
329
330 /* Map the userspace id down into a kernel id. */
331 make_kuid(idmapping, uid)
332
333 /* Map the kernel id up into a userspace id. */
334 from_kuid(idmapping, kuid)
335
336We will take an abbreviated look into how idmappings figure into creating
337filesystem objects. For simplicity we will only look at what happens when the
338VFS has already completed path lookup right before it calls into the filesystem
339itself. So we're concerned with what happens when e.g. ``vfs_mkdir()`` is
340called. We will also assume that the directory we're creating filesystem
341objects in is readable and writable for everyone.
342
343When creating a filesystem object the caller will look at the caller's
344filesystem ids. These are just regular ``uid_t`` and ``gid_t`` userspace ids
345but they are exclusively used when determining file ownership which is why they
346are called "filesystem ids". They are usually identical to the uid and gid of
347the caller but can differ. We will just assume they are always identical to not
348get lost in too many details.
349
350When the caller enters the kernel two things happen:
351
3521. Map the caller's userspace ids down into kernel ids in the caller's
353   idmapping.
354   (To be precise, the kernel will simply look at the kernel ids stashed in the
355   credentials of the current task but for our education we'll pretend this
356   translation happens just in time.)
3572. Verify that the caller's kernel ids can be mapped up to userspace ids in the
358   filesystem's idmapping.
359
360The second step is important as regular filesystem will ultimately need to map
361the kernel id back up into a userspace id when writing to disk.
362So with the second step the kernel guarantees that a valid userspace id can be
363written to disk. If it can't the kernel will refuse the creation request to not
364even remotely risk filesystem corruption.
365
366The astute reader will have realized that this is simply a varation of the
367crossmapping algorithm we mentioned above in a previous section. First, the
368kernel maps the caller's userspace id down into a kernel id according to the
369caller's idmapping and then maps that kernel id up according to the
370filesystem's idmapping.
371
372Example 1
373~~~~~~~~~
374
375::
376
377 caller id:            u1000
378 caller idmapping:     u0:k0:r4294967295
379 filesystem idmapping: u0:k0:r4294967295
380
381Both the caller and the filesystem use the identity idmapping:
382
3831. Map the caller's userspace ids into kernel ids in the caller's idmapping::
384
385    make_kuid(u0:k0:r4294967295, u1000) = k1000
386
3872. Verify that the caller's kernel ids can be mapped to userspace ids in the
388   filesystem's idmapping.
389
390   For this second step the kernel will call the function
391   ``fsuidgid_has_mapping()`` which ultimately boils down to calling
392   ``from_kuid()``::
393
394    from_kuid(u0:k0:r4294967295, k1000) = u1000
395
396In this example both idmappings are the same so there's nothing exciting going
397on. Ultimately the userspace id that lands on disk will be ``u1000``.
398
399Example 2
400~~~~~~~~~
401
402::
403
404 caller id:            u1000
405 caller idmapping:     u0:k10000:r10000
406 filesystem idmapping: u0:k20000:r10000
407
4081. Map the caller's userspace ids down into kernel ids in the caller's
409   idmapping::
410
411    make_kuid(u0:k10000:r10000, u1000) = k11000
412
4132. Verify that the caller's kernel ids can be mapped up to userspace ids in the
414   filesystem's idmapping::
415
416    from_kuid(u0:k20000:r10000, k11000) = u-1
417
418It's immediately clear that while the caller's userspace id could be
419successfully mapped down into kernel ids in the caller's idmapping the kernel
420ids could not be mapped up according to the filesystem's idmapping. So the
421kernel will deny this creation request.
422
423Note that while this example is less common, because most filesystem can't be
424mounted with non-initial idmappings this is a general problem as we can see in
425the next examples.
426
427Example 3
428~~~~~~~~~
429
430::
431
432 caller id:            u1000
433 caller idmapping:     u0:k10000:r10000
434 filesystem idmapping: u0:k0:r4294967295
435
4361. Map the caller's userspace ids down into kernel ids in the caller's
437   idmapping::
438
439    make_kuid(u0:k10000:r10000, u1000) = k11000
440
4412. Verify that the caller's kernel ids can be mapped up to userspace ids in the
442   filesystem's idmapping::
443
444    from_kuid(u0:k0:r4294967295, k11000) = u11000
445
446We can see that the translation always succeeds. The userspace id that the
447filesystem will ultimately put to disk will always be identical to the value of
448the kernel id that was created in the caller's idmapping. This has mainly two
449consequences.
450
451First, that we can't allow a caller to ultimately write to disk with another
452userspace id. We could only do this if we were to mount the whole fileystem
453with the caller's or another idmapping. But that solution is limited to a few
454filesystems and not very flexible. But this is a use-case that is pretty
455important in containerized workloads.
456
457Second, the caller will usually not be able to create any files or access
458directories that have stricter permissions because none of the filesystem's
459kernel ids map up into valid userspace ids in the caller's idmapping
460
4611. Map raw userspace ids down to kernel ids in the filesystem's idmapping::
462
463    make_kuid(u0:k0:r4294967295, u1000) = k1000
464
4652. Map kernel ids up to userspace ids in the caller's idmapping::
466
467    from_kuid(u0:k10000:r10000, k1000) = u-1
468
469Example 4
470~~~~~~~~~
471
472::
473
474 file id:              u1000
475 caller idmapping:     u0:k10000:r10000
476 filesystem idmapping: u0:k0:r4294967295
477
478In order to report ownership to userspace the kernel uses the crossmapping
479algorithm introduced in a previous section:
480
4811. Map the userspace id on disk down into a kernel id in the filesystem's
482   idmapping::
483
484    make_kuid(u0:k0:r4294967295, u1000) = k1000
485
4862. Map the kernel id up into a userspace id in the caller's idmapping::
487
488    from_kuid(u0:k10000:r10000, k1000) = u-1
489
490The crossmapping algorithm fails in this case because the kernel id in the
491filesystem idmapping cannot be mapped up to a userspace id in the caller's
492idmapping. Thus, the kernel will report the ownership of this file as the
493overflowid.
494
495Example 5
496~~~~~~~~~
497
498::
499
500 file id:              u1000
501 caller idmapping:     u0:k10000:r10000
502 filesystem idmapping: u0:k20000:r10000
503
504In order to report ownership to userspace the kernel uses the crossmapping
505algorithm introduced in a previous section:
506
5071. Map the userspace id on disk down into a kernel id in the filesystem's
508   idmapping::
509
510    make_kuid(u0:k20000:r10000, u1000) = k21000
511
5122. Map the kernel id up into a userspace id in the caller's idmapping::
513
514    from_kuid(u0:k10000:r10000, k21000) = u-1
515
516Again, the crossmapping algorithm fails in this case because the kernel id in
517the filesystem idmapping cannot be mapped to a userspace id in the caller's
518idmapping. Thus, the kernel will report the ownership of this file as the
519overflowid.
520
521Note how in the last two examples things would be simple if the caller would be
522using the initial idmapping. For a filesystem mounted with the initial
523idmapping it would be trivial. So we only consider a filesystem with an
524idmapping of ``u0:k20000:r10000``:
525
5261. Map the userspace id on disk down into a kernel id in the filesystem's
527   idmapping::
528
529    make_kuid(u0:k20000:r10000, u1000) = k21000
530
5312. Map the kernel id up into a userspace id in the caller's idmapping::
532
533    from_kuid(u0:k0:r4294967295, k21000) = u21000
534
535Idmappings on idmapped mounts
536-----------------------------
537
538The examples we've seen in the previous section where the caller's idmapping
539and the filesystem's idmapping are incompatible causes various issues for
540workloads. For a more complex but common example, consider two containers
541started on the host. To completely prevent the two containers from affecting
542each other, an administrator may often use different non-overlapping idmappings
543for the two containers::
544
545 container1 idmapping:  u0:k10000:r10000
546 container2 idmapping:  u0:k20000:r10000
547 filesystem idmapping:  u0:k30000:r10000
548
549An administrator wanting to provide easy read-write access to the following set
550of files::
551
552 dir id:       u0
553 dir/file1 id: u1000
554 dir/file2 id: u2000
555
556to both containers currently can't.
557
558Of course the administrator has the option to recursively change ownership via
559``chown()``. For example, they could change ownership so that ``dir`` and all
560files below it can be crossmapped from the filesystem's into the container's
561idmapping. Let's assume they change ownership so it is compatible with the
562first container's idmapping::
563
564 dir id:       u10000
565 dir/file1 id: u11000
566 dir/file2 id: u12000
567
568This would still leave ``dir`` rather useless to the second container. In fact,
569``dir`` and all files below it would continue to appear owned by the overflowid
570for the second container.
571
572Or consider another increasingly popular example. Some service managers such as
573systemd implement a concept called "portable home directories". A user may want
574to use their home directories on different machines where they are assigned
575different login userspace ids. Most users will have ``u1000`` as the login id
576on their machine at home and all files in their home directory will usually be
577owned by ``u1000``. At uni or at work they may have another login id such as
578``u1125``. This makes it rather difficult to interact with their home directory
579on their work machine.
580
581In both cases changing ownership recursively has grave implications. The most
582obvious one is that ownership is changed globally and permanently. In the home
583directory case this change in ownership would even need to happen everytime the
584user switches from their home to their work machine. For really large sets of
585files this becomes increasingly costly.
586
587If the user is lucky, they are dealing with a filesystem that is mountable
588inside user namespaces. But this would also change ownership globally and the
589change in ownership is tied to the lifetime of the filesystem mount, i.e. the
590superblock. The only way to change ownership is to completely unmount the
591filesystem and mount it again in another user namespace. This is usually
592impossible because it would mean that all users currently accessing the
593filesystem can't anymore. And it means that ``dir`` still can't be shared
594between two containers with different idmappings.
595But usually the user doesn't even have this option since most filesystems
596aren't mountable inside containers. And not having them mountable might be
597desirable as it doesn't require the filesystem to deal with malicious
598filesystem images.
599
600But the usecases mentioned above and more can be handled by idmapped mounts.
601They allow to expose the same set of dentries with different ownership at
602different mounts. This is achieved by marking the mounts with a user namespace
603through the ``mount_setattr()`` system call. The idmapping associated with it
604is then used to translate from the caller's idmapping to the filesystem's
605idmapping and vica versa using the remapping algorithm we introduced above.
606
607Idmapped mounts make it possible to change ownership in a temporary and
608localized way. The ownership changes are restricted to a specific mount and the
609ownership changes are tied to the lifetime of the mount. All other users and
610locations where the filesystem is exposed are unaffected.
611
612Filesystems that support idmapped mounts don't have any real reason to support
613being mountable inside user namespaces. A filesystem could be exposed
614completely under an idmapped mount to get the same effect. This has the
615advantage that filesystems can leave the creation of the superblock to
616privileged users in the initial user namespace.
617
618However, it is perfectly possible to combine idmapped mounts with filesystems
619mountable inside user namespaces. We will touch on this further below.
620
621Remapping helpers
622~~~~~~~~~~~~~~~~~
623
624Idmapping functions were added that translate between idmappings. They make use
625of the remapping algorithm we've introduced earlier. We're going to look at
626two:
627
628- ``i_uid_into_mnt()`` and ``i_gid_into_mnt()``
629
630  The ``i_*id_into_mnt()`` functions translate filesystem's kernel ids into
631  kernel ids in the mount's idmapping::
632
633   /* Map the filesystem's kernel id up into a userspace id in the filesystem's idmapping. */
634   from_kuid(filesystem, kid) = uid
635
636   /* Map the filesystem's userspace id down ito a kernel id in the mount's idmapping. */
637   make_kuid(mount, uid) = kuid
638
639- ``mapped_fsuid()`` and ``mapped_fsgid()``
640
641  The ``mapped_fs*id()`` functions translate the caller's kernel ids into
642  kernel ids in the filesystem's idmapping. This translation is achieved by
643  remapping the caller's kernel ids using the mount's idmapping::
644
645   /* Map the caller's kernel id up into a userspace id in the mount's idmapping. */
646   from_kuid(mount, kid) = uid
647
648   /* Map the mount's userspace id down into a kernel id in the filesystem's idmapping. */
649   make_kuid(filesystem, uid) = kuid
650
651Note that these two functions invert each other. Consider the following
652idmappings::
653
654 caller idmapping:     u0:k10000:r10000
655 filesystem idmapping: u0:k20000:r10000
656 mount idmapping:      u0:k10000:r10000
657
658Assume a file owned by ``u1000`` is read from disk. The filesystem maps this id
659to ``k21000`` according to it's idmapping. This is what is stored in the
660inode's ``i_uid`` and ``i_gid`` fields.
661
662When the caller queries the ownership of this file via ``stat()`` the kernel
663would usually simply use the crossmapping algorithm and map the filesystem's
664kernel id up to a userspace id in the caller's idmapping.
665
666But when the caller is accessing the file on an idmapped mount the kernel will
667first call ``i_uid_into_mnt()`` thereby translating the filesystem's kernel id
668into a kernel id in the mount's idmapping::
669
670 i_uid_into_mnt(k21000):
671   /* Map the filesystem's kernel id up into a userspace id. */
672   from_kuid(u0:k20000:r10000, k21000) = u1000
673
674   /* Map the filesystem's userspace id down ito a kernel id in the mount's idmapping. */
675   make_kuid(u0:k10000:r10000, u1000) = k11000
676
677Finally, when the kernel reports the owner to the caller it will turn the
678kernel id in the mount's idmapping into a userspace id in the caller's
679idmapping::
680
681  from_kuid(u0:k10000:r10000, k11000) = u1000
682
683We can test whether this algorithm really works by verifying what happens when
684we create a new file. Let's say the user is creating a file with ``u1000``.
685
686The kernel maps this to ``k11000`` in the caller's idmapping. Usually the
687kernel would now apply the crossmapping, verifying that ``k11000`` can be
688mapped to a userspace id in the filesystem's idmapping. Since ``k11000`` can't
689be mapped up in the filesystem's idmapping directly this creation request
690fails.
691
692But when the caller is accessing the file on an idmapped mount the kernel will
693first call ``mapped_fs*id()`` thereby translating the caller's kernel id into
694a kernel id according to the mount's idmapping::
695
696 mapped_fsuid(k11000):
697    /* Map the caller's kernel id up into a userspace id in the mount's idmapping. */
698    from_kuid(u0:k10000:r10000, k11000) = u1000
699
700    /* Map the mount's userspace id down into a kernel id in the filesystem's idmapping. */
701    make_kuid(u0:k20000:r10000, u1000) = k21000
702
703When finally writing to disk the kernel will then map ``k21000`` up into a
704userspace id in the filesystem's idmapping::
705
706   from_kuid(u0:k20000:r10000, k21000) = u1000
707
708As we can see, we end up with an invertible and therefore information
709preserving algorithm. A file created from ``u1000`` on an idmapped mount will
710also be reported as being owned by ``u1000`` and vica versa.
711
712Let's now briefly reconsider the failing examples from earlier in the context
713of idmapped mounts.
714
715Example 2 reconsidered
716~~~~~~~~~~~~~~~~~~~~~~
717
718::
719
720 caller id:            u1000
721 caller idmapping:     u0:k10000:r10000
722 filesystem idmapping: u0:k20000:r10000
723 mount idmapping:      u0:k10000:r10000
724
725When the caller is using a non-initial idmapping the common case is to attach
726the same idmapping to the mount. We now perform three steps:
727
7281. Map the caller's userspace ids into kernel ids in the caller's idmapping::
729
730    make_kuid(u0:k10000:r10000, u1000) = k11000
731
7322. Translate the caller's kernel id into a kernel id in the filesystem's
733   idmapping::
734
735    mapped_fsuid(k11000):
736      /* Map the kernel id up into a userspace id in the mount's idmapping. */
737      from_kuid(u0:k10000:r10000, k11000) = u1000
738
739      /* Map the userspace id down into a kernel id in the filesystem's idmapping. */
740      make_kuid(u0:k20000:r10000, u1000) = k21000
741
7422. Verify that the caller's kernel ids can be mapped to userspace ids in the
743   filesystem's idmapping::
744
745    from_kuid(u0:k20000:r10000, k21000) = u1000
746
747So the ownership that lands on disk will be ``u1000``.
748
749Example 3 reconsidered
750~~~~~~~~~~~~~~~~~~~~~~
751
752::
753
754 caller id:            u1000
755 caller idmapping:     u0:k10000:r10000
756 filesystem idmapping: u0:k0:r4294967295
757 mount idmapping:      u0:k10000:r10000
758
759The same translation algorithm works with the third example.
760
7611. Map the caller's userspace ids into kernel ids in the caller's idmapping::
762
763    make_kuid(u0:k10000:r10000, u1000) = k11000
764
7652. Translate the caller's kernel id into a kernel id in the filesystem's
766   idmapping::
767
768    mapped_fsuid(k11000):
769       /* Map the kernel id up into a userspace id in the mount's idmapping. */
770       from_kuid(u0:k10000:r10000, k11000) = u1000
771
772       /* Map the userspace id down into a kernel id in the filesystem's idmapping. */
773       make_kuid(u0:k0:r4294967295, u1000) = k1000
774
7752. Verify that the caller's kernel ids can be mapped to userspace ids in the
776   filesystem's idmapping::
777
778    from_kuid(u0:k0:r4294967295, k21000) = u1000
779
780So the ownership that lands on disk will be ``u1000``.
781
782Example 4 reconsidered
783~~~~~~~~~~~~~~~~~~~~~~
784
785::
786
787 file id:              u1000
788 caller idmapping:     u0:k10000:r10000
789 filesystem idmapping: u0:k0:r4294967295
790 mount idmapping:      u0:k10000:r10000
791
792In order to report ownership to userspace the kernel now does three steps using
793the translation algorithm we introduced earlier:
794
7951. Map the userspace id on disk down into a kernel id in the filesystem's
796   idmapping::
797
798    make_kuid(u0:k0:r4294967295, u1000) = k1000
799
8002. Translate the kernel id into a kernel id in the mount's idmapping::
801
802    i_uid_into_mnt(k1000):
803      /* Map the kernel id up into a userspace id in the filesystem's idmapping. */
804      from_kuid(u0:k0:r4294967295, k1000) = u1000
805
806      /* Map the userspace id down into a kernel id in the mounts's idmapping. */
807      make_kuid(u0:k10000:r10000, u1000) = k11000
808
8093. Map the kernel id up into a userspace id in the caller's idmapping::
810
811    from_kuid(u0:k10000:r10000, k11000) = u1000
812
813Earlier, the caller's kernel id couldn't be crossmapped in the filesystems's
814idmapping. With the idmapped mount in place it now can be crossmapped into the
815filesystem's idmapping via the mount's idmapping. The file will now be created
816with ``u1000`` according to the mount's idmapping.
817
818Example 5 reconsidered
819~~~~~~~~~~~~~~~~~~~~~~
820
821::
822
823 file id:              u1000
824 caller idmapping:     u0:k10000:r10000
825 filesystem idmapping: u0:k20000:r10000
826 mount idmapping:      u0:k10000:r10000
827
828Again, in order to report ownership to userspace the kernel now does three
829steps using the translation algorithm we introduced earlier:
830
8311. Map the userspace id on disk down into a kernel id in the filesystem's
832   idmapping::
833
834    make_kuid(u0:k20000:r10000, u1000) = k21000
835
8362. Translate the kernel id into a kernel id in the mount's idmapping::
837
838    i_uid_into_mnt(k21000):
839      /* Map the kernel id up into a userspace id in the filesystem's idmapping. */
840      from_kuid(u0:k20000:r10000, k21000) = u1000
841
842      /* Map the userspace id down into a kernel id in the mounts's idmapping. */
843      make_kuid(u0:k10000:r10000, u1000) = k11000
844
8453. Map the kernel id up into a userspace id in the caller's idmapping::
846
847    from_kuid(u0:k10000:r10000, k11000) = u1000
848
849Earlier, the file's kernel id couldn't be crossmapped in the filesystems's
850idmapping. With the idmapped mount in place it now can be crossmapped into the
851filesystem's idmapping via the mount's idmapping. The file is now owned by
852``u1000`` according to the mount's idmapping.
853
854Changing ownership on a home directory
855~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
856
857We've seen above how idmapped mounts can be used to translate between
858idmappings when either the caller, the filesystem or both uses a non-initial
859idmapping. A wide range of usecases exist when the caller is using
860a non-initial idmapping. This mostly happens in the context of containerized
861workloads. The consequence is as we have seen that for both, filesystem's
862mounted with the initial idmapping and filesystems mounted with non-initial
863idmappings, access to the filesystem isn't working because the kernel ids can't
864be crossmapped between the caller's and the filesystem's idmapping.
865
866As we've seen above idmapped mounts provide a solution to this by remapping the
867caller's or filesystem's idmapping according to the mount's idmapping.
868
869Aside from containerized workloads, idmapped mounts have the advantage that
870they also work when both the caller and the filesystem use the initial
871idmapping which means users on the host can change the ownership of directories
872and files on a per-mount basis.
873
874Consider our previous example where a user has their home directory on portable
875storage. At home they have id ``u1000`` and all files in their home directory
876are owned by ``u1000`` whereas at uni or work they have login id ``u1125``.
877
878Taking their home directory with them becomes problematic. They can't easily
879access their files, they might not be able to write to disk without applying
880lax permissions or ACLs and even if they can, they will end up with an annoying
881mix of files and directories owned by ``u1000`` and ``u1125``.
882
883Idmapped mounts allow to solve this problem. A user can create an idmapped
884mount for their home directory on their work computer or their computer at home
885depending on what ownership they would prefer to end up on the portable storage
886itself.
887
888Let's assume they want all files on disk to belong to ``u1000``. When the user
889plugs in their portable storage at their work station they can setup a job that
890creates an idmapped mount with the minimal idmapping ``u1000:k1125:r1``. So now
891when they create a file the kernel performs the following steps we already know
892from above:::
893
894 caller id:            u1125
895 caller idmapping:     u0:k0:r4294967295
896 filesystem idmapping: u0:k0:r4294967295
897 mount idmapping:      u1000:k1125:r1
898
8991. Map the caller's userspace ids into kernel ids in the caller's idmapping::
900
901    make_kuid(u0:k0:r4294967295, u1125) = k1125
902
9032. Translate the caller's kernel id into a kernel id in the filesystem's
904   idmapping::
905
906    mapped_fsuid(k1125):
907      /* Map the kernel id up into a userspace id in the mount's idmapping. */
908      from_kuid(u1000:k1125:r1, k1125) = u1000
909
910      /* Map the userspace id down into a kernel id in the filesystem's idmapping. */
911      make_kuid(u0:k0:r4294967295, u1000) = k1000
912
9132. Verify that the caller's kernel ids can be mapped to userspace ids in the
914   filesystem's idmapping::
915
916    from_kuid(u0:k0:r4294967295, k1000) = u1000
917
918So ultimately the file will be created with ``u1000`` on disk.
919
920Now let's briefly look at what ownership the caller with id ``u1125`` will see
921on their work computer:
922
923::
924
925 file id:              u1000
926 caller idmapping:     u0:k0:r4294967295
927 filesystem idmapping: u0:k0:r4294967295
928 mount idmapping:      u1000:k1125:r1
929
9301. Map the userspace id on disk down into a kernel id in the filesystem's
931   idmapping::
932
933    make_kuid(u0:k0:r4294967295, u1000) = k1000
934
9352. Translate the kernel id into a kernel id in the mount's idmapping::
936
937    i_uid_into_mnt(k1000):
938      /* Map the kernel id up into a userspace id in the filesystem's idmapping. */
939      from_kuid(u0:k0:r4294967295, k1000) = u1000
940
941      /* Map the userspace id down into a kernel id in the mounts's idmapping. */
942      make_kuid(u1000:k1125:r1, u1000) = k1125
943
9443. Map the kernel id up into a userspace id in the caller's idmapping::
945
946    from_kuid(u0:k0:r4294967295, k1125) = u1125
947
948So ultimately the caller will be reported that the file belongs to ``u1125``
949which is the caller's userspace id on their workstation in our example.
950
951The raw userspace id that is put on disk is ``u1000`` so when the user takes
952their home directory back to their home computer where they are assigned
953``u1000`` using the initial idmapping and mount the filesystem with the initial
954idmapping they will see all those files owned by ``u1000``.
955