forked from Minki/linux
8cc5c54de4
Now that we implement the full remapping algorithms described in our documentation remove the section about shortcircuting them. Link: https://lore.kernel.org/r/20211123114227.3124056-6-brauner@kernel.org (v1) Link: https://lore.kernel.org/r/20211130121032.3753852-6-brauner@kernel.org (v2) Link: https://lore.kernel.org/r/20211203111707.3901969-6-brauner@kernel.org Cc: Seth Forshee <sforshee@digitalocean.com> Cc: Amir Goldstein <amir73il@gmail.com> Cc: Christoph Hellwig <hch@lst.de> Cc: Al Viro <viro@zeniv.linux.org.uk> CC: linux-fsdevel@vger.kernel.org Reviewed-by: Seth Forshee <sforshee@digitalocean.com> Signed-off-by: Christian Brauner <christian.brauner@ubuntu.com>
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ReStructuredText
955 lines
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ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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Idmappings
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==========
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Most filesystem developers will have encountered idmappings. They are used when
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reading from or writing ownership to disk, reporting ownership to userspace, or
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for permission checking. This document is aimed at filesystem developers that
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want to know how idmappings work.
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Formal notes
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------------
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An idmapping is essentially a translation of a range of ids into another or the
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same range of ids. The notational convention for idmappings that is widely used
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in userspace is::
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u:k:r
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``u`` indicates the first element in the upper idmapset ``U`` and ``k``
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indicates the first element in the lower idmapset ``K``. The ``r`` parameter
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indicates the range of the idmapping, i.e. how many ids are mapped. From now
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on, we will always prefix ids with ``u`` or ``k`` to make it clear whether
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we're talking about an id in the upper or lower idmapset.
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To see what this looks like in practice, let's take the following idmapping::
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u22:k10000:r3
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and write down the mappings it will generate::
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u22 -> k10000
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u23 -> k10001
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u24 -> k10002
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From a mathematical viewpoint ``U`` and ``K`` are well-ordered sets and an
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idmapping is an order isomorphism from ``U`` into ``K``. So ``U`` and ``K`` are
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order isomorphic. In fact, ``U`` and ``K`` are always well-ordered subsets of
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the set of all possible ids useable on a given system.
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Looking at this mathematically briefly will help us highlight some properties
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that make it easier to understand how we can translate between idmappings. For
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example, we know that the inverse idmapping is an order isomorphism as well::
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k10000 -> u22
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k10001 -> u23
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k10002 -> u24
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Given that we are dealing with order isomorphisms plus the fact that we're
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dealing with subsets we can embedd idmappings into each other, i.e. we can
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sensibly translate between different idmappings. For example, assume we've been
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given the three idmappings::
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1. u0:k10000:r10000
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2. u0:k20000:r10000
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3. u0:k30000:r10000
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and id ``k11000`` which has been generated by the first idmapping by mapping
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``u1000`` from the upper idmapset down to ``k11000`` in the lower idmapset.
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Because we're dealing with order isomorphic subsets it is meaningful to ask
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what id ``k11000`` corresponds to in the second or third idmapping. The
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straightfoward algorithm to use is to apply the inverse of the first idmapping,
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mapping ``k11000`` up to ``u1000``. Afterwards, we can map ``u1000`` down using
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either the second idmapping mapping or third idmapping mapping. The second
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idmapping would map ``u1000`` down to ``21000``. The third idmapping would map
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``u1000`` down to ``u31000``.
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If we were given the same task for the following three idmappings::
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1. u0:k10000:r10000
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2. u0:k20000:r200
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3. u0:k30000:r300
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we would fail to translate as the sets aren't order isomorphic over the full
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range of the first idmapping anymore (However they are order isomorphic over
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the full range of the second idmapping.). Neither the second or third idmapping
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contain ``u1000`` in the upper idmapset ``U``. This is equivalent to not having
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an id mapped. We can simply say that ``u1000`` is unmapped in the second and
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third idmapping. The kernel will report unmapped ids as the overflowuid
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``(uid_t)-1`` or overflowgid ``(gid_t)-1`` to userspace.
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The algorithm to calculate what a given id maps to is pretty simple. First, we
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need to verify that the range can contain our target id. We will skip this step
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for simplicity. After that if we want to know what ``id`` maps to we can do
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simple calculations:
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- If we want to map from left to right::
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u:k:r
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id - u + k = n
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- If we want to map from right to left::
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u:k:r
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id - k + u = n
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Instead of "left to right" we can also say "down" and instead of "right to
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left" we can also say "up". Obviously mapping down and up invert each other.
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To see whether the simple formulas above work, consider the following two
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idmappings::
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1. u0:k20000:r10000
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2. u500:k30000:r10000
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Assume we are given ``k21000`` in the lower idmapset of the first idmapping. We
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want to know what id this was mapped from in the upper idmapset of the first
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idmapping. So we're mapping up in the first idmapping::
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id - k + u = n
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k21000 - k20000 + u0 = u1000
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Now assume we are given the id ``u1100`` in the upper idmapset of the second
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idmapping and we want to know what this id maps down to in the lower idmapset
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of the second idmapping. This means we're mapping down in the second
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idmapping::
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id - u + k = n
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u1100 - u500 + k30000 = k30600
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General notes
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-------------
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In the context of the kernel an idmapping can be interpreted as mapping a range
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of userspace ids into a range of kernel ids::
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userspace-id:kernel-id:range
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A userspace id is always an element in the upper idmapset of an idmapping of
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type ``uid_t`` or ``gid_t`` and a kernel id is always an element in the lower
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idmapset of an idmapping of type ``kuid_t`` or ``kgid_t``. From now on
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"userspace id" will be used to refer to the well known ``uid_t`` and ``gid_t``
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types and "kernel id" will be used to refer to ``kuid_t`` and ``kgid_t``.
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The kernel is mostly concerned with kernel ids. They are used when performing
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permission checks and are stored in an inode's ``i_uid`` and ``i_gid`` field.
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A userspace id on the other hand is an id that is reported to userspace by the
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kernel, or is passed by userspace to the kernel, or a raw device id that is
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written or read from disk.
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Note that we are only concerned with idmappings as the kernel stores them not
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how userspace would specify them.
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For the rest of this document we will prefix all userspace ids with ``u`` and
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all kernel ids with ``k``. Ranges of idmappings will be prefixed with ``r``. So
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an idmapping will be written as ``u0:k10000:r10000``.
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For example, the id ``u1000`` is an id in the upper idmapset or "userspace
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idmapset" starting with ``u1000``. And it is mapped to ``k11000`` which is a
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kernel id in the lower idmapset or "kernel idmapset" starting with ``k10000``.
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A kernel id is always created by an idmapping. Such idmappings are associated
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with user namespaces. Since we mainly care about how idmappings work we're not
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going to be concerned with how idmappings are created nor how they are used
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outside of the filesystem context. This is best left to an explanation of user
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namespaces.
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The initial user namespace is special. It always has an idmapping of the
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following form::
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u0:k0:r4294967295
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which is an identity idmapping over the full range of ids available on this
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system.
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Other user namespaces usually have non-identity idmappings such as::
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u0:k10000:r10000
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When a process creates or wants to change ownership of a file, or when the
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ownership of a file is read from disk by a filesystem, the userspace id is
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immediately translated into a kernel id according to the idmapping associated
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with the relevant user namespace.
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For instance, consider a file that is stored on disk by a filesystem as being
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owned by ``u1000``:
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- If a filesystem were to be mounted in the initial user namespaces (as most
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filesystems are) then the initial idmapping will be used. As we saw this is
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simply the identity idmapping. This would mean id ``u1000`` read from disk
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would be mapped to id ``k1000``. So an inode's ``i_uid`` and ``i_gid`` field
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would contain ``k1000``.
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- If a filesystem were to be mounted with an idmapping of ``u0:k10000:r10000``
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then ``u1000`` read from disk would be mapped to ``k11000``. So an inode's
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``i_uid`` and ``i_gid`` would contain ``k11000``.
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Translation algorithms
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----------------------
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We've already seen briefly that it is possible to translate between different
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idmappings. We'll now take a closer look how that works.
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Crossmapping
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~~~~~~~~~~~~
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This translation algorithm is used by the kernel in quite a few places. For
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example, it is used when reporting back the ownership of a file to userspace
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via the ``stat()`` system call family.
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If we've been given ``k11000`` from one idmapping we can map that id up in
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another idmapping. In order for this to work both idmappings need to contain
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the same kernel id in their kernel idmapsets. For example, consider the
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following idmappings::
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1. u0:k10000:r10000
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2. u20000:k10000:r10000
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and we are mapping ``u1000`` down to ``k11000`` in the first idmapping . We can
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then translate ``k11000`` into a userspace id in the second idmapping using the
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kernel idmapset of the second idmapping::
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/* Map the kernel id up into a userspace id in the second idmapping. */
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from_kuid(u20000:k10000:r10000, k11000) = u21000
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Note, how we can get back to the kernel id in the first idmapping by inverting
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the algorithm::
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/* Map the userspace id down into a kernel id in the second idmapping. */
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make_kuid(u20000:k10000:r10000, u21000) = k11000
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/* Map the kernel id up into a userspace id in the first idmapping. */
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from_kuid(u0:k10000:r10000, k11000) = u1000
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This algorithm allows us to answer the question what userspace id a given
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kernel id corresponds to in a given idmapping. In order to be able to answer
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this question both idmappings need to contain the same kernel id in their
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respective kernel idmapsets.
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For example, when the kernel reads a raw userspace id from disk it maps it down
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into a kernel id according to the idmapping associated with the filesystem.
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Let's assume the filesystem was mounted with an idmapping of
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``u0:k20000:r10000`` and it reads a file owned by ``u1000`` from disk. This
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means ``u1000`` will be mapped to ``k21000`` which is what will be stored in
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the inode's ``i_uid`` and ``i_gid`` field.
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When someone in userspace calls ``stat()`` or a related function to get
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ownership information about the file the kernel can't simply map the id back up
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according to the filesystem's idmapping as this would give the wrong owner if
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the caller is using an idmapping.
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So the kernel will map the id back up in the idmapping of the caller. Let's
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assume the caller has the slighly unconventional idmapping
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``u3000:k20000:r10000`` then ``k21000`` would map back up to ``u4000``.
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Consequently the user would see that this file is owned by ``u4000``.
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Remapping
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~~~~~~~~~
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It is possible to translate a kernel id from one idmapping to another one via
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the userspace idmapset of the two idmappings. This is equivalent to remapping
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a kernel id.
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Let's look at an example. We are given the following two idmappings::
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1. u0:k10000:r10000
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2. u0:k20000:r10000
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and we are given ``k11000`` in the first idmapping. In order to translate this
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kernel id in the first idmapping into a kernel id in the second idmapping we
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need to perform two steps:
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1. Map the kernel id up into a userspace id in the first idmapping::
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/* Map the kernel id up into a userspace id in the first idmapping. */
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from_kuid(u0:k10000:r10000, k11000) = u1000
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2. Map the userspace id down into a kernel id in the second idmapping::
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/* Map the userspace id down into a kernel id in the second idmapping. */
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make_kuid(u0:k20000:r10000, u1000) = k21000
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As you can see we used the userspace idmapset in both idmappings to translate
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the kernel id in one idmapping to a kernel id in another idmapping.
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This allows us to answer the question what kernel id we would need to use to
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get the same userspace id in another idmapping. In order to be able to answer
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this question both idmappings need to contain the same userspace id in their
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respective userspace idmapsets.
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Note, how we can easily get back to the kernel id in the first idmapping by
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inverting the algorithm:
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1. Map the kernel id up into a userspace id in the second idmapping::
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/* Map the kernel id up into a userspace id in the second idmapping. */
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from_kuid(u0:k20000:r10000, k21000) = u1000
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2. Map the userspace id down into a kernel id in the first idmapping::
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/* Map the userspace id down into a kernel id in the first idmapping. */
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make_kuid(u0:k10000:r10000, u1000) = k11000
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Another way to look at this translation is to treat it as inverting one
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idmapping and applying another idmapping if both idmappings have the relevant
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userspace id mapped. This will come in handy when working with idmapped mounts.
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Invalid translations
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~~~~~~~~~~~~~~~~~~~~
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It is never valid to use an id in the kernel idmapset of one idmapping as the
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id in the userspace idmapset of another or the same idmapping. While the kernel
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idmapset always indicates an idmapset in the kernel id space the userspace
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idmapset indicates a userspace id. So the following translations are forbidden::
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/* Map the userspace id down into a kernel id in the first idmapping. */
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make_kuid(u0:k10000:r10000, u1000) = k11000
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/* INVALID: Map the kernel id down into a kernel id in the second idmapping. */
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make_kuid(u10000:k20000:r10000, k110000) = k21000
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~~~~~~~
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and equally wrong::
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/* Map the kernel id up into a userspace id in the first idmapping. */
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from_kuid(u0:k10000:r10000, k11000) = u1000
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/* INVALID: Map the userspace id up into a userspace id in the second idmapping. */
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from_kuid(u20000:k0:r10000, u1000) = k21000
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~~~~~
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Idmappings when creating filesystem objects
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-------------------------------------------
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The concepts of mapping an id down or mapping an id up are expressed in the two
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kernel functions filesystem developers are rather familiar with and which we've
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already used in this document::
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/* Map the userspace id down into a kernel id. */
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make_kuid(idmapping, uid)
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/* Map the kernel id up into a userspace id. */
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from_kuid(idmapping, kuid)
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We will take an abbreviated look into how idmappings figure into creating
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filesystem objects. For simplicity we will only look at what happens when the
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VFS has already completed path lookup right before it calls into the filesystem
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itself. So we're concerned with what happens when e.g. ``vfs_mkdir()`` is
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called. We will also assume that the directory we're creating filesystem
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objects in is readable and writable for everyone.
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When creating a filesystem object the caller will look at the caller's
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filesystem ids. These are just regular ``uid_t`` and ``gid_t`` userspace ids
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but they are exclusively used when determining file ownership which is why they
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are called "filesystem ids". They are usually identical to the uid and gid of
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the caller but can differ. We will just assume they are always identical to not
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get lost in too many details.
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When the caller enters the kernel two things happen:
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1. Map the caller's userspace ids down into kernel ids in the caller's
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idmapping.
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(To be precise, the kernel will simply look at the kernel ids stashed in the
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credentials of the current task but for our education we'll pretend this
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translation happens just in time.)
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2. Verify that the caller's kernel ids can be mapped up to userspace ids in the
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filesystem's idmapping.
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The second step is important as regular filesystem will ultimately need to map
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the kernel id back up into a userspace id when writing to disk.
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So with the second step the kernel guarantees that a valid userspace id can be
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written to disk. If it can't the kernel will refuse the creation request to not
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even remotely risk filesystem corruption.
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The astute reader will have realized that this is simply a varation of the
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crossmapping algorithm we mentioned above in a previous section. First, the
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kernel maps the caller's userspace id down into a kernel id according to the
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caller's idmapping and then maps that kernel id up according to the
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filesystem's idmapping.
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Example 1
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~~~~~~~~~
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::
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caller id: u1000
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caller idmapping: u0:k0:r4294967295
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filesystem idmapping: u0:k0:r4294967295
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Both the caller and the filesystem use the identity idmapping:
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1. Map the caller's userspace ids into kernel ids in the caller's idmapping::
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make_kuid(u0:k0:r4294967295, u1000) = k1000
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2. Verify that the caller's kernel ids can be mapped to userspace ids in the
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filesystem's idmapping.
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For this second step the kernel will call the function
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``fsuidgid_has_mapping()`` which ultimately boils down to calling
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``from_kuid()``::
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from_kuid(u0:k0:r4294967295, k1000) = u1000
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In this example both idmappings are the same so there's nothing exciting going
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on. Ultimately the userspace id that lands on disk will be ``u1000``.
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Example 2
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~~~~~~~~~
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::
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caller id: u1000
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caller idmapping: u0:k10000:r10000
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filesystem idmapping: u0:k20000:r10000
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1. Map the caller's userspace ids down into kernel ids in the caller's
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idmapping::
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make_kuid(u0:k10000:r10000, u1000) = k11000
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2. Verify that the caller's kernel ids can be mapped up to userspace ids in the
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filesystem's idmapping::
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from_kuid(u0:k20000:r10000, k11000) = u-1
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It's immediately clear that while the caller's userspace id could be
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successfully mapped down into kernel ids in the caller's idmapping the kernel
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ids could not be mapped up according to the filesystem's idmapping. So the
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kernel will deny this creation request.
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Note that while this example is less common, because most filesystem can't be
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mounted with non-initial idmappings this is a general problem as we can see in
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the next examples.
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Example 3
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~~~~~~~~~
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::
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caller id: u1000
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caller idmapping: u0:k10000:r10000
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filesystem idmapping: u0:k0:r4294967295
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1. Map the caller's userspace ids down into kernel ids in the caller's
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idmapping::
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make_kuid(u0:k10000:r10000, u1000) = k11000
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2. Verify that the caller's kernel ids can be mapped up to userspace ids in the
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filesystem's idmapping::
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from_kuid(u0:k0:r4294967295, k11000) = u11000
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We can see that the translation always succeeds. The userspace id that the
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filesystem will ultimately put to disk will always be identical to the value of
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the kernel id that was created in the caller's idmapping. This has mainly two
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consequences.
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First, that we can't allow a caller to ultimately write to disk with another
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userspace id. We could only do this if we were to mount the whole fileystem
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with the caller's or another idmapping. But that solution is limited to a few
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filesystems and not very flexible. But this is a use-case that is pretty
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important in containerized workloads.
|
|
|
|
Second, the caller will usually not be able to create any files or access
|
|
directories that have stricter permissions because none of the filesystem's
|
|
kernel ids map up into valid userspace ids in the caller's idmapping
|
|
|
|
1. Map raw userspace ids down to kernel ids in the filesystem's idmapping::
|
|
|
|
make_kuid(u0:k0:r4294967295, u1000) = k1000
|
|
|
|
2. Map kernel ids up to userspace ids in the caller's idmapping::
|
|
|
|
from_kuid(u0:k10000:r10000, k1000) = u-1
|
|
|
|
Example 4
|
|
~~~~~~~~~
|
|
|
|
::
|
|
|
|
file id: u1000
|
|
caller idmapping: u0:k10000:r10000
|
|
filesystem idmapping: u0:k0:r4294967295
|
|
|
|
In order to report ownership to userspace the kernel uses the crossmapping
|
|
algorithm introduced in a previous section:
|
|
|
|
1. Map the userspace id on disk down into a kernel id in the filesystem's
|
|
idmapping::
|
|
|
|
make_kuid(u0:k0:r4294967295, u1000) = k1000
|
|
|
|
2. Map the kernel id up into a userspace id in the caller's idmapping::
|
|
|
|
from_kuid(u0:k10000:r10000, k1000) = u-1
|
|
|
|
The crossmapping algorithm fails in this case because the kernel id in the
|
|
filesystem idmapping cannot be mapped up to a userspace id in the caller's
|
|
idmapping. Thus, the kernel will report the ownership of this file as the
|
|
overflowid.
|
|
|
|
Example 5
|
|
~~~~~~~~~
|
|
|
|
::
|
|
|
|
file id: u1000
|
|
caller idmapping: u0:k10000:r10000
|
|
filesystem idmapping: u0:k20000:r10000
|
|
|
|
In order to report ownership to userspace the kernel uses the crossmapping
|
|
algorithm introduced in a previous section:
|
|
|
|
1. Map the userspace id on disk down into a kernel id in the filesystem's
|
|
idmapping::
|
|
|
|
make_kuid(u0:k20000:r10000, u1000) = k21000
|
|
|
|
2. Map the kernel id up into a userspace id in the caller's idmapping::
|
|
|
|
from_kuid(u0:k10000:r10000, k21000) = u-1
|
|
|
|
Again, the crossmapping algorithm fails in this case because the kernel id in
|
|
the filesystem idmapping cannot be mapped to a userspace id in the caller's
|
|
idmapping. Thus, the kernel will report the ownership of this file as the
|
|
overflowid.
|
|
|
|
Note how in the last two examples things would be simple if the caller would be
|
|
using the initial idmapping. For a filesystem mounted with the initial
|
|
idmapping it would be trivial. So we only consider a filesystem with an
|
|
idmapping of ``u0:k20000:r10000``:
|
|
|
|
1. Map the userspace id on disk down into a kernel id in the filesystem's
|
|
idmapping::
|
|
|
|
make_kuid(u0:k20000:r10000, u1000) = k21000
|
|
|
|
2. Map the kernel id up into a userspace id in the caller's idmapping::
|
|
|
|
from_kuid(u0:k0:r4294967295, k21000) = u21000
|
|
|
|
Idmappings on idmapped mounts
|
|
-----------------------------
|
|
|
|
The examples we've seen in the previous section where the caller's idmapping
|
|
and the filesystem's idmapping are incompatible causes various issues for
|
|
workloads. For a more complex but common example, consider two containers
|
|
started on the host. To completely prevent the two containers from affecting
|
|
each other, an administrator may often use different non-overlapping idmappings
|
|
for the two containers::
|
|
|
|
container1 idmapping: u0:k10000:r10000
|
|
container2 idmapping: u0:k20000:r10000
|
|
filesystem idmapping: u0:k30000:r10000
|
|
|
|
An administrator wanting to provide easy read-write access to the following set
|
|
of files::
|
|
|
|
dir id: u0
|
|
dir/file1 id: u1000
|
|
dir/file2 id: u2000
|
|
|
|
to both containers currently can't.
|
|
|
|
Of course the administrator has the option to recursively change ownership via
|
|
``chown()``. For example, they could change ownership so that ``dir`` and all
|
|
files below it can be crossmapped from the filesystem's into the container's
|
|
idmapping. Let's assume they change ownership so it is compatible with the
|
|
first container's idmapping::
|
|
|
|
dir id: u10000
|
|
dir/file1 id: u11000
|
|
dir/file2 id: u12000
|
|
|
|
This would still leave ``dir`` rather useless to the second container. In fact,
|
|
``dir`` and all files below it would continue to appear owned by the overflowid
|
|
for the second container.
|
|
|
|
Or consider another increasingly popular example. Some service managers such as
|
|
systemd implement a concept called "portable home directories". A user may want
|
|
to use their home directories on different machines where they are assigned
|
|
different login userspace ids. Most users will have ``u1000`` as the login id
|
|
on their machine at home and all files in their home directory will usually be
|
|
owned by ``u1000``. At uni or at work they may have another login id such as
|
|
``u1125``. This makes it rather difficult to interact with their home directory
|
|
on their work machine.
|
|
|
|
In both cases changing ownership recursively has grave implications. The most
|
|
obvious one is that ownership is changed globally and permanently. In the home
|
|
directory case this change in ownership would even need to happen everytime the
|
|
user switches from their home to their work machine. For really large sets of
|
|
files this becomes increasingly costly.
|
|
|
|
If the user is lucky, they are dealing with a filesystem that is mountable
|
|
inside user namespaces. But this would also change ownership globally and the
|
|
change in ownership is tied to the lifetime of the filesystem mount, i.e. the
|
|
superblock. The only way to change ownership is to completely unmount the
|
|
filesystem and mount it again in another user namespace. This is usually
|
|
impossible because it would mean that all users currently accessing the
|
|
filesystem can't anymore. And it means that ``dir`` still can't be shared
|
|
between two containers with different idmappings.
|
|
But usually the user doesn't even have this option since most filesystems
|
|
aren't mountable inside containers. And not having them mountable might be
|
|
desirable as it doesn't require the filesystem to deal with malicious
|
|
filesystem images.
|
|
|
|
But the usecases mentioned above and more can be handled by idmapped mounts.
|
|
They allow to expose the same set of dentries with different ownership at
|
|
different mounts. This is achieved by marking the mounts with a user namespace
|
|
through the ``mount_setattr()`` system call. The idmapping associated with it
|
|
is then used to translate from the caller's idmapping to the filesystem's
|
|
idmapping and vica versa using the remapping algorithm we introduced above.
|
|
|
|
Idmapped mounts make it possible to change ownership in a temporary and
|
|
localized way. The ownership changes are restricted to a specific mount and the
|
|
ownership changes are tied to the lifetime of the mount. All other users and
|
|
locations where the filesystem is exposed are unaffected.
|
|
|
|
Filesystems that support idmapped mounts don't have any real reason to support
|
|
being mountable inside user namespaces. A filesystem could be exposed
|
|
completely under an idmapped mount to get the same effect. This has the
|
|
advantage that filesystems can leave the creation of the superblock to
|
|
privileged users in the initial user namespace.
|
|
|
|
However, it is perfectly possible to combine idmapped mounts with filesystems
|
|
mountable inside user namespaces. We will touch on this further below.
|
|
|
|
Remapping helpers
|
|
~~~~~~~~~~~~~~~~~
|
|
|
|
Idmapping functions were added that translate between idmappings. They make use
|
|
of the remapping algorithm we've introduced earlier. We're going to look at
|
|
two:
|
|
|
|
- ``i_uid_into_mnt()`` and ``i_gid_into_mnt()``
|
|
|
|
The ``i_*id_into_mnt()`` functions translate filesystem's kernel ids into
|
|
kernel ids in the mount's idmapping::
|
|
|
|
/* Map the filesystem's kernel id up into a userspace id in the filesystem's idmapping. */
|
|
from_kuid(filesystem, kid) = uid
|
|
|
|
/* Map the filesystem's userspace id down ito a kernel id in the mount's idmapping. */
|
|
make_kuid(mount, uid) = kuid
|
|
|
|
- ``mapped_fsuid()`` and ``mapped_fsgid()``
|
|
|
|
The ``mapped_fs*id()`` functions translate the caller's kernel ids into
|
|
kernel ids in the filesystem's idmapping. This translation is achieved by
|
|
remapping the caller's kernel ids using the mount's idmapping::
|
|
|
|
/* Map the caller's kernel id up into a userspace id in the mount's idmapping. */
|
|
from_kuid(mount, kid) = uid
|
|
|
|
/* Map the mount's userspace id down into a kernel id in the filesystem's idmapping. */
|
|
make_kuid(filesystem, uid) = kuid
|
|
|
|
Note that these two functions invert each other. Consider the following
|
|
idmappings::
|
|
|
|
caller idmapping: u0:k10000:r10000
|
|
filesystem idmapping: u0:k20000:r10000
|
|
mount idmapping: u0:k10000:r10000
|
|
|
|
Assume a file owned by ``u1000`` is read from disk. The filesystem maps this id
|
|
to ``k21000`` according to it's idmapping. This is what is stored in the
|
|
inode's ``i_uid`` and ``i_gid`` fields.
|
|
|
|
When the caller queries the ownership of this file via ``stat()`` the kernel
|
|
would usually simply use the crossmapping algorithm and map the filesystem's
|
|
kernel id up to a userspace id in the caller's idmapping.
|
|
|
|
But when the caller is accessing the file on an idmapped mount the kernel will
|
|
first call ``i_uid_into_mnt()`` thereby translating the filesystem's kernel id
|
|
into a kernel id in the mount's idmapping::
|
|
|
|
i_uid_into_mnt(k21000):
|
|
/* Map the filesystem's kernel id up into a userspace id. */
|
|
from_kuid(u0:k20000:r10000, k21000) = u1000
|
|
|
|
/* Map the filesystem's userspace id down ito a kernel id in the mount's idmapping. */
|
|
make_kuid(u0:k10000:r10000, u1000) = k11000
|
|
|
|
Finally, when the kernel reports the owner to the caller it will turn the
|
|
kernel id in the mount's idmapping into a userspace id in the caller's
|
|
idmapping::
|
|
|
|
from_kuid(u0:k10000:r10000, k11000) = u1000
|
|
|
|
We can test whether this algorithm really works by verifying what happens when
|
|
we create a new file. Let's say the user is creating a file with ``u1000``.
|
|
|
|
The kernel maps this to ``k11000`` in the caller's idmapping. Usually the
|
|
kernel would now apply the crossmapping, verifying that ``k11000`` can be
|
|
mapped to a userspace id in the filesystem's idmapping. Since ``k11000`` can't
|
|
be mapped up in the filesystem's idmapping directly this creation request
|
|
fails.
|
|
|
|
But when the caller is accessing the file on an idmapped mount the kernel will
|
|
first call ``mapped_fs*id()`` thereby translating the caller's kernel id into
|
|
a kernel id according to the mount's idmapping::
|
|
|
|
mapped_fsuid(k11000):
|
|
/* Map the caller's kernel id up into a userspace id in the mount's idmapping. */
|
|
from_kuid(u0:k10000:r10000, k11000) = u1000
|
|
|
|
/* Map the mount's userspace id down into a kernel id in the filesystem's idmapping. */
|
|
make_kuid(u0:k20000:r10000, u1000) = k21000
|
|
|
|
When finally writing to disk the kernel will then map ``k21000`` up into a
|
|
userspace id in the filesystem's idmapping::
|
|
|
|
from_kuid(u0:k20000:r10000, k21000) = u1000
|
|
|
|
As we can see, we end up with an invertible and therefore information
|
|
preserving algorithm. A file created from ``u1000`` on an idmapped mount will
|
|
also be reported as being owned by ``u1000`` and vica versa.
|
|
|
|
Let's now briefly reconsider the failing examples from earlier in the context
|
|
of idmapped mounts.
|
|
|
|
Example 2 reconsidered
|
|
~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
::
|
|
|
|
caller id: u1000
|
|
caller idmapping: u0:k10000:r10000
|
|
filesystem idmapping: u0:k20000:r10000
|
|
mount idmapping: u0:k10000:r10000
|
|
|
|
When the caller is using a non-initial idmapping the common case is to attach
|
|
the same idmapping to the mount. We now perform three steps:
|
|
|
|
1. Map the caller's userspace ids into kernel ids in the caller's idmapping::
|
|
|
|
make_kuid(u0:k10000:r10000, u1000) = k11000
|
|
|
|
2. Translate the caller's kernel id into a kernel id in the filesystem's
|
|
idmapping::
|
|
|
|
mapped_fsuid(k11000):
|
|
/* Map the kernel id up into a userspace id in the mount's idmapping. */
|
|
from_kuid(u0:k10000:r10000, k11000) = u1000
|
|
|
|
/* Map the userspace id down into a kernel id in the filesystem's idmapping. */
|
|
make_kuid(u0:k20000:r10000, u1000) = k21000
|
|
|
|
2. Verify that the caller's kernel ids can be mapped to userspace ids in the
|
|
filesystem's idmapping::
|
|
|
|
from_kuid(u0:k20000:r10000, k21000) = u1000
|
|
|
|
So the ownership that lands on disk will be ``u1000``.
|
|
|
|
Example 3 reconsidered
|
|
~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
::
|
|
|
|
caller id: u1000
|
|
caller idmapping: u0:k10000:r10000
|
|
filesystem idmapping: u0:k0:r4294967295
|
|
mount idmapping: u0:k10000:r10000
|
|
|
|
The same translation algorithm works with the third example.
|
|
|
|
1. Map the caller's userspace ids into kernel ids in the caller's idmapping::
|
|
|
|
make_kuid(u0:k10000:r10000, u1000) = k11000
|
|
|
|
2. Translate the caller's kernel id into a kernel id in the filesystem's
|
|
idmapping::
|
|
|
|
mapped_fsuid(k11000):
|
|
/* Map the kernel id up into a userspace id in the mount's idmapping. */
|
|
from_kuid(u0:k10000:r10000, k11000) = u1000
|
|
|
|
/* Map the userspace id down into a kernel id in the filesystem's idmapping. */
|
|
make_kuid(u0:k0:r4294967295, u1000) = k1000
|
|
|
|
2. Verify that the caller's kernel ids can be mapped to userspace ids in the
|
|
filesystem's idmapping::
|
|
|
|
from_kuid(u0:k0:r4294967295, k21000) = u1000
|
|
|
|
So the ownership that lands on disk will be ``u1000``.
|
|
|
|
Example 4 reconsidered
|
|
~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
::
|
|
|
|
file id: u1000
|
|
caller idmapping: u0:k10000:r10000
|
|
filesystem idmapping: u0:k0:r4294967295
|
|
mount idmapping: u0:k10000:r10000
|
|
|
|
In order to report ownership to userspace the kernel now does three steps using
|
|
the translation algorithm we introduced earlier:
|
|
|
|
1. Map the userspace id on disk down into a kernel id in the filesystem's
|
|
idmapping::
|
|
|
|
make_kuid(u0:k0:r4294967295, u1000) = k1000
|
|
|
|
2. Translate the kernel id into a kernel id in the mount's idmapping::
|
|
|
|
i_uid_into_mnt(k1000):
|
|
/* Map the kernel id up into a userspace id in the filesystem's idmapping. */
|
|
from_kuid(u0:k0:r4294967295, k1000) = u1000
|
|
|
|
/* Map the userspace id down into a kernel id in the mounts's idmapping. */
|
|
make_kuid(u0:k10000:r10000, u1000) = k11000
|
|
|
|
3. Map the kernel id up into a userspace id in the caller's idmapping::
|
|
|
|
from_kuid(u0:k10000:r10000, k11000) = u1000
|
|
|
|
Earlier, the caller's kernel id couldn't be crossmapped in the filesystems's
|
|
idmapping. With the idmapped mount in place it now can be crossmapped into the
|
|
filesystem's idmapping via the mount's idmapping. The file will now be created
|
|
with ``u1000`` according to the mount's idmapping.
|
|
|
|
Example 5 reconsidered
|
|
~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
::
|
|
|
|
file id: u1000
|
|
caller idmapping: u0:k10000:r10000
|
|
filesystem idmapping: u0:k20000:r10000
|
|
mount idmapping: u0:k10000:r10000
|
|
|
|
Again, in order to report ownership to userspace the kernel now does three
|
|
steps using the translation algorithm we introduced earlier:
|
|
|
|
1. Map the userspace id on disk down into a kernel id in the filesystem's
|
|
idmapping::
|
|
|
|
make_kuid(u0:k20000:r10000, u1000) = k21000
|
|
|
|
2. Translate the kernel id into a kernel id in the mount's idmapping::
|
|
|
|
i_uid_into_mnt(k21000):
|
|
/* Map the kernel id up into a userspace id in the filesystem's idmapping. */
|
|
from_kuid(u0:k20000:r10000, k21000) = u1000
|
|
|
|
/* Map the userspace id down into a kernel id in the mounts's idmapping. */
|
|
make_kuid(u0:k10000:r10000, u1000) = k11000
|
|
|
|
3. Map the kernel id up into a userspace id in the caller's idmapping::
|
|
|
|
from_kuid(u0:k10000:r10000, k11000) = u1000
|
|
|
|
Earlier, the file's kernel id couldn't be crossmapped in the filesystems's
|
|
idmapping. With the idmapped mount in place it now can be crossmapped into the
|
|
filesystem's idmapping via the mount's idmapping. The file is now owned by
|
|
``u1000`` according to the mount's idmapping.
|
|
|
|
Changing ownership on a home directory
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
We've seen above how idmapped mounts can be used to translate between
|
|
idmappings when either the caller, the filesystem or both uses a non-initial
|
|
idmapping. A wide range of usecases exist when the caller is using
|
|
a non-initial idmapping. This mostly happens in the context of containerized
|
|
workloads. The consequence is as we have seen that for both, filesystem's
|
|
mounted with the initial idmapping and filesystems mounted with non-initial
|
|
idmappings, access to the filesystem isn't working because the kernel ids can't
|
|
be crossmapped between the caller's and the filesystem's idmapping.
|
|
|
|
As we've seen above idmapped mounts provide a solution to this by remapping the
|
|
caller's or filesystem's idmapping according to the mount's idmapping.
|
|
|
|
Aside from containerized workloads, idmapped mounts have the advantage that
|
|
they also work when both the caller and the filesystem use the initial
|
|
idmapping which means users on the host can change the ownership of directories
|
|
and files on a per-mount basis.
|
|
|
|
Consider our previous example where a user has their home directory on portable
|
|
storage. At home they have id ``u1000`` and all files in their home directory
|
|
are owned by ``u1000`` whereas at uni or work they have login id ``u1125``.
|
|
|
|
Taking their home directory with them becomes problematic. They can't easily
|
|
access their files, they might not be able to write to disk without applying
|
|
lax permissions or ACLs and even if they can, they will end up with an annoying
|
|
mix of files and directories owned by ``u1000`` and ``u1125``.
|
|
|
|
Idmapped mounts allow to solve this problem. A user can create an idmapped
|
|
mount for their home directory on their work computer or their computer at home
|
|
depending on what ownership they would prefer to end up on the portable storage
|
|
itself.
|
|
|
|
Let's assume they want all files on disk to belong to ``u1000``. When the user
|
|
plugs in their portable storage at their work station they can setup a job that
|
|
creates an idmapped mount with the minimal idmapping ``u1000:k1125:r1``. So now
|
|
when they create a file the kernel performs the following steps we already know
|
|
from above:::
|
|
|
|
caller id: u1125
|
|
caller idmapping: u0:k0:r4294967295
|
|
filesystem idmapping: u0:k0:r4294967295
|
|
mount idmapping: u1000:k1125:r1
|
|
|
|
1. Map the caller's userspace ids into kernel ids in the caller's idmapping::
|
|
|
|
make_kuid(u0:k0:r4294967295, u1125) = k1125
|
|
|
|
2. Translate the caller's kernel id into a kernel id in the filesystem's
|
|
idmapping::
|
|
|
|
mapped_fsuid(k1125):
|
|
/* Map the kernel id up into a userspace id in the mount's idmapping. */
|
|
from_kuid(u1000:k1125:r1, k1125) = u1000
|
|
|
|
/* Map the userspace id down into a kernel id in the filesystem's idmapping. */
|
|
make_kuid(u0:k0:r4294967295, u1000) = k1000
|
|
|
|
2. Verify that the caller's kernel ids can be mapped to userspace ids in the
|
|
filesystem's idmapping::
|
|
|
|
from_kuid(u0:k0:r4294967295, k1000) = u1000
|
|
|
|
So ultimately the file will be created with ``u1000`` on disk.
|
|
|
|
Now let's briefly look at what ownership the caller with id ``u1125`` will see
|
|
on their work computer:
|
|
|
|
::
|
|
|
|
file id: u1000
|
|
caller idmapping: u0:k0:r4294967295
|
|
filesystem idmapping: u0:k0:r4294967295
|
|
mount idmapping: u1000:k1125:r1
|
|
|
|
1. Map the userspace id on disk down into a kernel id in the filesystem's
|
|
idmapping::
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make_kuid(u0:k0:r4294967295, u1000) = k1000
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2. Translate the kernel id into a kernel id in the mount's idmapping::
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i_uid_into_mnt(k1000):
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/* Map the kernel id up into a userspace id in the filesystem's idmapping. */
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from_kuid(u0:k0:r4294967295, k1000) = u1000
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/* Map the userspace id down into a kernel id in the mounts's idmapping. */
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make_kuid(u1000:k1125:r1, u1000) = k1125
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3. Map the kernel id up into a userspace id in the caller's idmapping::
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from_kuid(u0:k0:r4294967295, k1125) = u1125
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So ultimately the caller will be reported that the file belongs to ``u1125``
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which is the caller's userspace id on their workstation in our example.
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The raw userspace id that is put on disk is ``u1000`` so when the user takes
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their home directory back to their home computer where they are assigned
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``u1000`` using the initial idmapping and mount the filesystem with the initial
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idmapping they will see all those files owned by ``u1000``.
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