1298 lines
64 KiB
Markdown
1298 lines
64 KiB
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<style> p { max-width:50em} ol, ul {max-width: 40em}</style>
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Pathname lookup in Linux.
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=========================
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This write-up is based on three articles published at lwn.net:
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- <https://lwn.net/Articles/649115/> Pathname lookup in Linux
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- <https://lwn.net/Articles/649729/> RCU-walk: faster pathname lookup in Linux
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- <https://lwn.net/Articles/650786/> A walk among the symlinks
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Written by Neil Brown with help from Al Viro and Jon Corbet.
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Introduction
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------------
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The most obvious aspect of pathname lookup, which very little
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exploration is needed to discover, is that it is complex. There are
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many rules, special cases, and implementation alternatives that all
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combine to confuse the unwary reader. Computer science has long been
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acquainted with such complexity and has tools to help manage it. One
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tool that we will make extensive use of is "divide and conquer". For
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the early parts of the analysis we will divide off symlinks - leaving
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them until the final part. Well before we get to symlinks we have
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another major division based on the VFS's approach to locking which
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will allow us to review "REF-walk" and "RCU-walk" separately. But we
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are getting ahead of ourselves. There are some important low level
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distinctions we need to clarify first.
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There are two sorts of ...
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--------------------------
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[`openat()`]: http://man7.org/linux/man-pages/man2/openat.2.html
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Pathnames (sometimes "file names"), used to identify objects in the
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filesystem, will be familiar to most readers. They contain two sorts
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of elements: "slashes" that are sequences of one or more "`/`"
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characters, and "components" that are sequences of one or more
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non-"`/`" characters. These form two kinds of paths. Those that
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start with slashes are "absolute" and start from the filesystem root.
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The others are "relative" and start from the current directory, or
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from some other location specified by a file descriptor given to a
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"xxx`at`" system call such as "[`openat()`]".
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[`execveat()`]: http://man7.org/linux/man-pages/man2/execveat.2.html
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It is tempting to describe the second kind as starting with a
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component, but that isn't always accurate: a pathname can lack both
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slashes and components, it can be empty, in other words. This is
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generally forbidden in POSIX, but some of those "xxx`at`" system calls
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in Linux permit it when the `AT_EMPTY_PATH` flag is given. For
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example, if you have an open file descriptor on an executable file you
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can execute it by calling [`execveat()`] passing the file descriptor,
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an empty path, and the `AT_EMPTY_PATH` flag.
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These paths can be divided into two sections: the final component and
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everything else. The "everything else" is the easy bit. In all cases
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it must identify a directory that already exists, otherwise an error
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such as `ENOENT` or `ENOTDIR` will be reported.
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The final component is not so simple. Not only do different system
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calls interpret it quite differently (e.g. some create it, some do
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not), but it might not even exist: neither the empty pathname nor the
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pathname that is just slashes have a final component. If it does
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exist, it could be "`.`" or "`..`" which are handled quite differently
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from other components.
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[POSIX]: http://pubs.opengroup.org/onlinepubs/9699919799/basedefs/V1_chap04.html#tag_04_12
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If a pathname ends with a slash, such as "`/tmp/foo/`" it might be
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tempting to consider that to have an empty final component. In many
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ways that would lead to correct results, but not always. In
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particular, `mkdir()` and `rmdir()` each create or remove a directory named
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by the final component, and they are required to work with pathnames
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ending in "`/`". According to [POSIX]
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> A pathname that contains at least one non- <slash> character and
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> that ends with one or more trailing <slash> characters shall not
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> be resolved successfully unless the last pathname component before
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> the trailing <slash> characters names an existing directory or a
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> directory entry that is to be created for a directory immediately
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> after the pathname is resolved.
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The Linux pathname walking code (mostly in `fs/namei.c`) deals with
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all of these issues: breaking the path into components, handling the
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"everything else" quite separately from the final component, and
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checking that the trailing slash is not used where it isn't
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permitted. It also addresses the important issue of concurrent
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access.
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While one process is looking up a pathname, another might be making
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changes that affect that lookup. One fairly extreme case is that if
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"a/b" were renamed to "a/c/b" while another process were looking up
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"a/b/..", that process might successfully resolve on "a/c".
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Most races are much more subtle, and a big part of the task of
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pathname lookup is to prevent them from having damaging effects. Many
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of the possible races are seen most clearly in the context of the
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"dcache" and an understanding of that is central to understanding
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pathname lookup.
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More than just a cache.
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-----------------------
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The "dcache" caches information about names in each filesystem to
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make them quickly available for lookup. Each entry (known as a
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"dentry") contains three significant fields: a component name, a
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pointer to a parent dentry, and a pointer to the "inode" which
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contains further information about the object in that parent with
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the given name. The inode pointer can be `NULL` indicating that the
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name doesn't exist in the parent. While there can be linkage in the
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dentry of a directory to the dentries of the children, that linkage is
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not used for pathname lookup, and so will not be considered here.
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The dcache has a number of uses apart from accelerating lookup. One
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that will be particularly relevant is that it is closely integrated
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with the mount table that records which filesystem is mounted where.
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What the mount table actually stores is which dentry is mounted on top
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of which other dentry.
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When considering the dcache, we have another of our "two types"
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distinctions: there are two types of filesystems.
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Some filesystems ensure that the information in the dcache is always
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completely accurate (though not necessarily complete). This can allow
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the VFS to determine if a particular file does or doesn't exist
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without checking with the filesystem, and means that the VFS can
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protect the filesystem against certain races and other problems.
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These are typically "local" filesystems such as ext3, XFS, and Btrfs.
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Other filesystems don't provide that guarantee because they cannot.
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These are typically filesystems that are shared across a network,
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whether remote filesystems like NFS and 9P, or cluster filesystems
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like ocfs2 or cephfs. These filesystems allow the VFS to revalidate
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cached information, and must provide their own protection against
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awkward races. The VFS can detect these filesystems by the
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`DCACHE_OP_REVALIDATE` flag being set in the dentry.
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REF-walk: simple concurrency management with refcounts and spinlocks
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--------------------------------------------------------------------
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With all of those divisions carefully classified, we can now start
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looking at the actual process of walking along a path. In particular
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we will start with the handling of the "everything else" part of a
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pathname, and focus on the "REF-walk" approach to concurrency
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management. This code is found in the `link_path_walk()` function, if
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you ignore all the places that only run when "`LOOKUP_RCU`"
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(indicating the use of RCU-walk) is set.
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[Meet the Lockers]: https://lwn.net/Articles/453685/
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REF-walk is fairly heavy-handed with locks and reference counts. Not
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as heavy-handed as in the old "big kernel lock" days, but certainly not
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afraid of taking a lock when one is needed. It uses a variety of
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different concurrency controls. A background understanding of the
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various primitives is assumed, or can be gleaned from elsewhere such
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as in [Meet the Lockers].
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The locking mechanisms used by REF-walk include:
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### dentry->d_lockref ###
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This uses the lockref primitive to provide both a spinlock and a
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reference count. The special-sauce of this primitive is that the
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conceptual sequence "lock; inc_ref; unlock;" can often be performed
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with a single atomic memory operation.
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Holding a reference on a dentry ensures that the dentry won't suddenly
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be freed and used for something else, so the values in various fields
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will behave as expected. It also protects the `->d_inode` reference
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to the inode to some extent.
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The association between a dentry and its inode is fairly permanent.
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For example, when a file is renamed, the dentry and inode move
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together to the new location. When a file is created the dentry will
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initially be negative (i.e. `d_inode` is `NULL`), and will be assigned
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to the new inode as part of the act of creation.
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When a file is deleted, this can be reflected in the cache either by
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setting `d_inode` to `NULL`, or by removing it from the hash table
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(described shortly) used to look up the name in the parent directory.
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If the dentry is still in use the second option is used as it is
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perfectly legal to keep using an open file after it has been deleted
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and having the dentry around helps. If the dentry is not otherwise in
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use (i.e. if the refcount in `d_lockref` is one), only then will
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`d_inode` be set to `NULL`. Doing it this way is more efficient for a
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very common case.
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So as long as a counted reference is held to a dentry, a non-`NULL` `->d_inode`
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value will never be changed.
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### dentry->d_lock ###
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`d_lock` is a synonym for the spinlock that is part of `d_lockref` above.
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For our purposes, holding this lock protects against the dentry being
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renamed or unlinked. In particular, its parent (`d_parent`), and its
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name (`d_name`) cannot be changed, and it cannot be removed from the
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dentry hash table.
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When looking for a name in a directory, REF-walk takes `d_lock` on
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each candidate dentry that it finds in the hash table and then checks
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that the parent and name are correct. So it doesn't lock the parent
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while searching in the cache; it only locks children.
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When looking for the parent for a given name (to handle "`..`"),
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REF-walk can take `d_lock` to get a stable reference to `d_parent`,
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but it first tries a more lightweight approach. As seen in
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`dget_parent()`, if a reference can be claimed on the parent, and if
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subsequently `d_parent` can be seen to have not changed, then there is
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no need to actually take the lock on the child.
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### rename_lock ###
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Looking up a given name in a given directory involves computing a hash
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from the two values (the name and the dentry of the directory),
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accessing that slot in a hash table, and searching the linked list
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that is found there.
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When a dentry is renamed, the name and the parent dentry can both
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change so the hash will almost certainly change too. This would move the
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dentry to a different chain in the hash table. If a filename search
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happened to be looking at a dentry that was moved in this way,
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it might end up continuing the search down the wrong chain,
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and so miss out on part of the correct chain.
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The name-lookup process (`d_lookup()`) does _not_ try to prevent this
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from happening, but only to detect when it happens.
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`rename_lock` is a seqlock that is updated whenever any dentry is
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renamed. If `d_lookup` finds that a rename happened while it
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unsuccessfully scanned a chain in the hash table, it simply tries
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again.
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### inode->i_mutex ###
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`i_mutex` is a mutex that serializes all changes to a particular
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directory. This ensures that, for example, an `unlink()` and a `rename()`
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cannot both happen at the same time. It also keeps the directory
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stable while the filesystem is asked to look up a name that is not
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currently in the dcache.
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This has a complementary role to that of `d_lock`: `i_mutex` on a
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directory protects all of the names in that directory, while `d_lock`
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on a name protects just one name in a directory. Most changes to the
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dcache hold `i_mutex` on the relevant directory inode and briefly take
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`d_lock` on one or more the dentries while the change happens. One
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exception is when idle dentries are removed from the dcache due to
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memory pressure. This uses `d_lock`, but `i_mutex` plays no role.
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The mutex affects pathname lookup in two distinct ways. Firstly it
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serializes lookup of a name in a directory. `walk_component()` uses
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`lookup_fast()` first which, in turn, checks to see if the name is in the cache,
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using only `d_lock` locking. If the name isn't found, then `walk_component()`
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falls back to `lookup_slow()` which takes `i_mutex`, checks again that
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the name isn't in the cache, and then calls in to the filesystem to get a
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definitive answer. A new dentry will be added to the cache regardless of
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the result.
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Secondly, when pathname lookup reaches the final component, it will
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sometimes need to take `i_mutex` before performing the last lookup so
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that the required exclusion can be achieved. How path lookup chooses
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to take, or not take, `i_mutex` is one of the
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issues addressed in a subsequent section.
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### mnt->mnt_count ###
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`mnt_count` is a per-CPU reference counter on "`mount`" structures.
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Per-CPU here means that incrementing the count is cheap as it only
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uses CPU-local memory, but checking if the count is zero is expensive as
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it needs to check with every CPU. Taking a `mnt_count` reference
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prevents the mount structure from disappearing as the result of regular
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unmount operations, but does not prevent a "lazy" unmount. So holding
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`mnt_count` doesn't ensure that the mount remains in the namespace and,
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in particular, doesn't stabilize the link to the mounted-on dentry. It
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does, however, ensure that the `mount` data structure remains coherent,
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and it provides a reference to the root dentry of the mounted
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filesystem. So a reference through `->mnt_count` provides a stable
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reference to the mounted dentry, but not the mounted-on dentry.
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### mount_lock ###
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`mount_lock` is a global seqlock, a bit like `rename_lock`. It can be used to
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check if any change has been made to any mount points.
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While walking down the tree (away from the root) this lock is used when
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crossing a mount point to check that the crossing was safe. That is,
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the value in the seqlock is read, then the code finds the mount that
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is mounted on the current directory, if there is one, and increments
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the `mnt_count`. Finally the value in `mount_lock` is checked against
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the old value. If there is no change, then the crossing was safe. If there
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was a change, the `mnt_count` is decremented and the whole process is
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retried.
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When walking up the tree (towards the root) by following a ".." link,
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a little more care is needed. In this case the seqlock (which
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contains both a counter and a spinlock) is fully locked to prevent
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any changes to any mount points while stepping up. This locking is
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needed to stabilize the link to the mounted-on dentry, which the
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refcount on the mount itself doesn't ensure.
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### RCU ###
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Finally the global (but extremely lightweight) RCU read lock is held
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from time to time to ensure certain data structures don't get freed
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unexpectedly.
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In particular it is held while scanning chains in the dcache hash
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table, and the mount point hash table.
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Bringing it together with `struct nameidata`
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--------------------------------------------
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[First edition Unix]: http://minnie.tuhs.org/cgi-bin/utree.pl?file=V1/u2.s
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Throughout the process of walking a path, the current status is stored
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in a `struct nameidata`, "namei" being the traditional name - dating
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all the way back to [First Edition Unix] - of the function that
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converts a "name" to an "inode". `struct nameidata` contains (among
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other fields):
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### `struct path path` ###
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A `path` contains a `struct vfsmount` (which is
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embedded in a `struct mount`) and a `struct dentry`. Together these
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record the current status of the walk. They start out referring to the
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starting point (the current working directory, the root directory, or some other
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directory identified by a file descriptor), and are updated on each
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step. A reference through `d_lockref` and `mnt_count` is always
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held.
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### `struct qstr last` ###
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This is a string together with a length (i.e. _not_ `nul` terminated)
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that is the "next" component in the pathname.
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### `int last_type` ###
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This is one of `LAST_NORM`, `LAST_ROOT`, `LAST_DOT`, `LAST_DOTDOT`, or
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`LAST_BIND`. The `last` field is only valid if the type is
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|
`LAST_NORM`. `LAST_BIND` is used when following a symlink and no
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components of the symlink have been processed yet. Others should be
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fairly self-explanatory.
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### `struct path root` ###
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This is used to hold a reference to the effective root of the
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filesystem. Often that reference won't be needed, so this field is
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only assigned the first time it is used, or when a non-standard root
|
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is requested. Keeping a reference in the `nameidata` ensures that
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only one root is in effect for the entire path walk, even if it races
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with a `chroot()` system call.
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The root is needed when either of two conditions holds: (1) either the
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pathname or a symbolic link starts with a "'/'", or (2) a "`..`"
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component is being handled, since "`..`" from the root must always stay
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at the root. The value used is usually the current root directory of
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the calling process. An alternate root can be provided as when
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`sysctl()` calls `file_open_root()`, and when NFSv4 or Btrfs call
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`mount_subtree()`. In each case a pathname is being looked up in a very
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specific part of the filesystem, and the lookup must not be allowed to
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escape that subtree. It works a bit like a local `chroot()`.
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Ignoring the handling of symbolic links, we can now describe the
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"`link_path_walk()`" function, which handles the lookup of everything
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||
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except the final component as:
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||
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|
||
|
> Given a path (`name`) and a nameidata structure (`nd`), check that the
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> current directory has execute permission and then advance `name`
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> over one component while updating `last_type` and `last`. If that
|
||
|
> was the final component, then return, otherwise call
|
||
|
> `walk_component()` and repeat from the top.
|
||
|
|
||
|
`walk_component()` is even easier. If the component is `LAST_DOTS`,
|
||
|
it calls `handle_dots()` which does the necessary locking as already
|
||
|
described. If it finds a `LAST_NORM` component it first calls
|
||
|
"`lookup_fast()`" which only looks in the dcache, but will ask the
|
||
|
filesystem to revalidate the result if it is that sort of filesystem.
|
||
|
If that doesn't get a good result, it calls "`lookup_slow()`" which
|
||
|
takes the `i_mutex`, rechecks the cache, and then asks the filesystem
|
||
|
to find a definitive answer. Each of these will call
|
||
|
`follow_managed()` (as described below) to handle any mount points.
|
||
|
|
||
|
In the absence of symbolic links, `walk_component()` creates a new
|
||
|
`struct path` containing a counted reference to the new dentry and a
|
||
|
reference to the new `vfsmount` which is only counted if it is
|
||
|
different from the previous `vfsmount`. It then calls
|
||
|
`path_to_nameidata()` to install the new `struct path` in the
|
||
|
`struct nameidata` and drop the unneeded references.
|
||
|
|
||
|
This "hand-over-hand" sequencing of getting a reference to the new
|
||
|
dentry before dropping the reference to the previous dentry may
|
||
|
seem obvious, but is worth pointing out so that we will recognize its
|
||
|
analogue in the "RCU-walk" version.
|
||
|
|
||
|
Handling the final component.
|
||
|
-----------------------------
|
||
|
|
||
|
`link_path_walk()` only walks as far as setting `nd->last` and
|
||
|
`nd->last_type` to refer to the final component of the path. It does
|
||
|
not call `walk_component()` that last time. Handling that final
|
||
|
component remains for the caller to sort out. Those callers are
|
||
|
`path_lookupat()`, `path_parentat()`, `path_mountpoint()` and
|
||
|
`path_openat()` each of which handles the differing requirements of
|
||
|
different system calls.
|
||
|
|
||
|
`path_parentat()` is clearly the simplest - it just wraps a little bit
|
||
|
of housekeeping around `link_path_walk()` and returns the parent
|
||
|
directory and final component to the caller. The caller will be either
|
||
|
aiming to create a name (via `filename_create()`) or remove or rename
|
||
|
a name (in which case `user_path_parent()` is used). They will use
|
||
|
`i_mutex` to exclude other changes while they validate and then
|
||
|
perform their operation.
|
||
|
|
||
|
`path_lookupat()` is nearly as simple - it is used when an existing
|
||
|
object is wanted such as by `stat()` or `chmod()`. It essentially just
|
||
|
calls `walk_component()` on the final component through a call to
|
||
|
`lookup_last()`. `path_lookupat()` returns just the final dentry.
|
||
|
|
||
|
`path_mountpoint()` handles the special case of unmounting which must
|
||
|
not try to revalidate the mounted filesystem. It effectively
|
||
|
contains, through a call to `mountpoint_last()`, an alternate
|
||
|
implementation of `lookup_slow()` which skips that step. This is
|
||
|
important when unmounting a filesystem that is inaccessible, such as
|
||
|
one provided by a dead NFS server.
|
||
|
|
||
|
Finally `path_openat()` is used for the `open()` system call; it
|
||
|
contains, in support functions starting with "`do_last()`", all the
|
||
|
complexity needed to handle the different subtleties of O_CREAT (with
|
||
|
or without O_EXCL), final "`/`" characters, and trailing symbolic
|
||
|
links. We will revisit this in the final part of this series, which
|
||
|
focuses on those symbolic links. "`do_last()`" will sometimes, but
|
||
|
not always, take `i_mutex`, depending on what it finds.
|
||
|
|
||
|
Each of these, or the functions which call them, need to be alert to
|
||
|
the possibility that the final component is not `LAST_NORM`. If the
|
||
|
goal of the lookup is to create something, then any value for
|
||
|
`last_type` other than `LAST_NORM` will result in an error. For
|
||
|
example if `path_parentat()` reports `LAST_DOTDOT`, then the caller
|
||
|
won't try to create that name. They also check for trailing slashes
|
||
|
by testing `last.name[last.len]`. If there is any character beyond
|
||
|
the final component, it must be a trailing slash.
|
||
|
|
||
|
Revalidation and automounts
|
||
|
---------------------------
|
||
|
|
||
|
Apart from symbolic links, there are only two parts of the "REF-walk"
|
||
|
process not yet covered. One is the handling of stale cache entries
|
||
|
and the other is automounts.
|
||
|
|
||
|
On filesystems that require it, the lookup routines will call the
|
||
|
`->d_revalidate()` dentry method to ensure that the cached information
|
||
|
is current. This will often confirm validity or update a few details
|
||
|
from a server. In some cases it may find that there has been change
|
||
|
further up the path and that something that was thought to be valid
|
||
|
previously isn't really. When this happens the lookup of the whole
|
||
|
path is aborted and retried with the "`LOOKUP_REVAL`" flag set. This
|
||
|
forces revalidation to be more thorough. We will see more details of
|
||
|
this retry process in the next article.
|
||
|
|
||
|
Automount points are locations in the filesystem where an attempt to
|
||
|
lookup a name can trigger changes to how that lookup should be
|
||
|
handled, in particular by mounting a filesystem there. These are
|
||
|
covered in greater detail in autofs.txt in the Linux documentation
|
||
|
tree, but a few notes specifically related to path lookup are in order
|
||
|
here.
|
||
|
|
||
|
The Linux VFS has a concept of "managed" dentries which is reflected
|
||
|
in function names such as "`follow_managed()`". There are three
|
||
|
potentially interesting things about these dentries corresponding
|
||
|
to three different flags that might be set in `dentry->d_flags`:
|
||
|
|
||
|
### `DCACHE_MANAGE_TRANSIT` ###
|
||
|
|
||
|
If this flag has been set, then the filesystem has requested that the
|
||
|
`d_manage()` dentry operation be called before handling any possible
|
||
|
mount point. This can perform two particular services:
|
||
|
|
||
|
It can block to avoid races. If an automount point is being
|
||
|
unmounted, the `d_manage()` function will usually wait for that
|
||
|
process to complete before letting the new lookup proceed and possibly
|
||
|
trigger a new automount.
|
||
|
|
||
|
It can selectively allow only some processes to transit through a
|
||
|
mount point. When a server process is managing automounts, it may
|
||
|
need to access a directory without triggering normal automount
|
||
|
processing. That server process can identify itself to the `autofs`
|
||
|
filesystem, which will then give it a special pass through
|
||
|
`d_manage()` by returning `-EISDIR`.
|
||
|
|
||
|
### `DCACHE_MOUNTED` ###
|
||
|
|
||
|
This flag is set on every dentry that is mounted on. As Linux
|
||
|
supports multiple filesystem namespaces, it is possible that the
|
||
|
dentry may not be mounted on in *this* namespace, just in some
|
||
|
other. So this flag is seen as a hint, not a promise.
|
||
|
|
||
|
If this flag is set, and `d_manage()` didn't return `-EISDIR`,
|
||
|
`lookup_mnt()` is called to examine the mount hash table (honoring the
|
||
|
`mount_lock` described earlier) and possibly return a new `vfsmount`
|
||
|
and a new `dentry` (both with counted references).
|
||
|
|
||
|
### `DCACHE_NEED_AUTOMOUNT` ###
|
||
|
|
||
|
If `d_manage()` allowed us to get this far, and `lookup_mnt()` didn't
|
||
|
find a mount point, then this flag causes the `d_automount()` dentry
|
||
|
operation to be called.
|
||
|
|
||
|
The `d_automount()` operation can be arbitrarily complex and may
|
||
|
communicate with server processes etc. but it should ultimately either
|
||
|
report that there was an error, that there was nothing to mount, or
|
||
|
should provide an updated `struct path` with new `dentry` and `vfsmount`.
|
||
|
|
||
|
In the latter case, `finish_automount()` will be called to safely
|
||
|
install the new mount point into the mount table.
|
||
|
|
||
|
There is no new locking of import here and it is important that no
|
||
|
locks (only counted references) are held over this processing due to
|
||
|
the very real possibility of extended delays.
|
||
|
This will become more important next time when we examine RCU-walk
|
||
|
which is particularly sensitive to delays.
|
||
|
|
||
|
RCU-walk - faster pathname lookup in Linux
|
||
|
==========================================
|
||
|
|
||
|
RCU-walk is another algorithm for performing pathname lookup in Linux.
|
||
|
It is in many ways similar to REF-walk and the two share quite a bit
|
||
|
of code. The significant difference in RCU-walk is how it allows for
|
||
|
the possibility of concurrent access.
|
||
|
|
||
|
We noted that REF-walk is complex because there are numerous details
|
||
|
and special cases. RCU-walk reduces this complexity by simply
|
||
|
refusing to handle a number of cases -- it instead falls back to
|
||
|
REF-walk. The difficulty with RCU-walk comes from a different
|
||
|
direction: unfamiliarity. The locking rules when depending on RCU are
|
||
|
quite different from traditional locking, so we will spend a little extra
|
||
|
time when we come to those.
|
||
|
|
||
|
Clear demarcation of roles
|
||
|
--------------------------
|
||
|
|
||
|
The easiest way to manage concurrency is to forcibly stop any other
|
||
|
thread from changing the data structures that a given thread is
|
||
|
looking at. In cases where no other thread would even think of
|
||
|
changing the data and lots of different threads want to read at the
|
||
|
same time, this can be very costly. Even when using locks that permit
|
||
|
multiple concurrent readers, the simple act of updating the count of
|
||
|
the number of current readers can impose an unwanted cost. So the
|
||
|
goal when reading a shared data structure that no other process is
|
||
|
changing is to avoid writing anything to memory at all. Take no
|
||
|
locks, increment no counts, leave no footprints.
|
||
|
|
||
|
The REF-walk mechanism already described certainly doesn't follow this
|
||
|
principle, but then it is really designed to work when there may well
|
||
|
be other threads modifying the data. RCU-walk, in contrast, is
|
||
|
designed for the common situation where there are lots of frequent
|
||
|
readers and only occasional writers. This may not be common in all
|
||
|
parts of the filesystem tree, but in many parts it will be. For the
|
||
|
other parts it is important that RCU-walk can quickly fall back to
|
||
|
using REF-walk.
|
||
|
|
||
|
Pathname lookup always starts in RCU-walk mode but only remains there
|
||
|
as long as what it is looking for is in the cache and is stable. It
|
||
|
dances lightly down the cached filesystem image, leaving no footprints
|
||
|
and carefully watching where it is, to be sure it doesn't trip. If it
|
||
|
notices that something has changed or is changing, or if something
|
||
|
isn't in the cache, then it tries to stop gracefully and switch to
|
||
|
REF-walk.
|
||
|
|
||
|
This stopping requires getting a counted reference on the current
|
||
|
`vfsmount` and `dentry`, and ensuring that these are still valid -
|
||
|
that a path walk with REF-walk would have found the same entries.
|
||
|
This is an invariant that RCU-walk must guarantee. It can only make
|
||
|
decisions, such as selecting the next step, that are decisions which
|
||
|
REF-walk could also have made if it were walking down the tree at the
|
||
|
same time. If the graceful stop succeeds, the rest of the path is
|
||
|
processed with the reliable, if slightly sluggish, REF-walk. If
|
||
|
RCU-walk finds it cannot stop gracefully, it simply gives up and
|
||
|
restarts from the top with REF-walk.
|
||
|
|
||
|
This pattern of "try RCU-walk, if that fails try REF-walk" can be
|
||
|
clearly seen in functions like `filename_lookup()`,
|
||
|
`filename_parentat()`, `filename_mountpoint()`,
|
||
|
`do_filp_open()`, and `do_file_open_root()`. These five
|
||
|
correspond roughly to the four `path_`* functions we met earlier,
|
||
|
each of which calls `link_path_walk()`. The `path_*` functions are
|
||
|
called using different mode flags until a mode is found which works.
|
||
|
They are first called with `LOOKUP_RCU` set to request "RCU-walk". If
|
||
|
that fails with the error `ECHILD` they are called again with no
|
||
|
special flag to request "REF-walk". If either of those report the
|
||
|
error `ESTALE` a final attempt is made with `LOOKUP_REVAL` set (and no
|
||
|
`LOOKUP_RCU`) to ensure that entries found in the cache are forcibly
|
||
|
revalidated - normally entries are only revalidated if the filesystem
|
||
|
determines that they are too old to trust.
|
||
|
|
||
|
The `LOOKUP_RCU` attempt may drop that flag internally and switch to
|
||
|
REF-walk, but will never then try to switch back to RCU-walk. Places
|
||
|
that trip up RCU-walk are much more likely to be near the leaves and
|
||
|
so it is very unlikely that there will be much, if any, benefit from
|
||
|
switching back.
|
||
|
|
||
|
RCU and seqlocks: fast and light
|
||
|
--------------------------------
|
||
|
|
||
|
RCU is, unsurprisingly, critical to RCU-walk mode. The
|
||
|
`rcu_read_lock()` is held for the entire time that RCU-walk is walking
|
||
|
down a path. The particular guarantee it provides is that the key
|
||
|
data structures - dentries, inodes, super_blocks, and mounts - will
|
||
|
not be freed while the lock is held. They might be unlinked or
|
||
|
invalidated in one way or another, but the memory will not be
|
||
|
repurposed so values in various fields will still be meaningful. This
|
||
|
is the only guarantee that RCU provides; everything else is done using
|
||
|
seqlocks.
|
||
|
|
||
|
As we saw above, REF-walk holds a counted reference to the current
|
||
|
dentry and the current vfsmount, and does not release those references
|
||
|
before taking references to the "next" dentry or vfsmount. It also
|
||
|
sometimes takes the `d_lock` spinlock. These references and locks are
|
||
|
taken to prevent certain changes from happening. RCU-walk must not
|
||
|
take those references or locks and so cannot prevent such changes.
|
||
|
Instead, it checks to see if a change has been made, and aborts or
|
||
|
retries if it has.
|
||
|
|
||
|
To preserve the invariant mentioned above (that RCU-walk may only make
|
||
|
decisions that REF-walk could have made), it must make the checks at
|
||
|
or near the same places that REF-walk holds the references. So, when
|
||
|
REF-walk increments a reference count or takes a spinlock, RCU-walk
|
||
|
samples the status of a seqlock using `read_seqcount_begin()` or a
|
||
|
similar function. When REF-walk decrements the count or drops the
|
||
|
lock, RCU-walk checks if the sampled status is still valid using
|
||
|
`read_seqcount_retry()` or similar.
|
||
|
|
||
|
However, there is a little bit more to seqlocks than that. If
|
||
|
RCU-walk accesses two different fields in a seqlock-protected
|
||
|
structure, or accesses the same field twice, there is no a priori
|
||
|
guarantee of any consistency between those accesses. When consistency
|
||
|
is needed - which it usually is - RCU-walk must take a copy and then
|
||
|
use `read_seqcount_retry()` to validate that copy.
|
||
|
|
||
|
`read_seqcount_retry()` not only checks the sequence number, but also
|
||
|
imposes a memory barrier so that no memory-read instruction from
|
||
|
*before* the call can be delayed until *after* the call, either by the
|
||
|
CPU or by the compiler. A simple example of this can be seen in
|
||
|
`slow_dentry_cmp()` which, for filesystems which do not use simple
|
||
|
byte-wise name equality, calls into the filesystem to compare a name
|
||
|
against a dentry. The length and name pointer are copied into local
|
||
|
variables, then `read_seqcount_retry()` is called to confirm the two
|
||
|
are consistent, and only then is `->d_compare()` called. When
|
||
|
standard filename comparison is used, `dentry_cmp()` is called
|
||
|
instead. Notably it does _not_ use `read_seqcount_retry()`, but
|
||
|
instead has a large comment explaining why the consistency guarantee
|
||
|
isn't necessary. A subsequent `read_seqcount_retry()` will be
|
||
|
sufficient to catch any problem that could occur at this point.
|
||
|
|
||
|
With that little refresher on seqlocks out of the way we can look at
|
||
|
the bigger picture of how RCU-walk uses seqlocks.
|
||
|
|
||
|
### `mount_lock` and `nd->m_seq` ###
|
||
|
|
||
|
We already met the `mount_lock` seqlock when REF-walk used it to
|
||
|
ensure that crossing a mount point is performed safely. RCU-walk uses
|
||
|
it for that too, but for quite a bit more.
|
||
|
|
||
|
Instead of taking a counted reference to each `vfsmount` as it
|
||
|
descends the tree, RCU-walk samples the state of `mount_lock` at the
|
||
|
start of the walk and stores this initial sequence number in the
|
||
|
`struct nameidata` in the `m_seq` field. This one lock and one
|
||
|
sequence number are used to validate all accesses to all `vfsmounts`,
|
||
|
and all mount point crossings. As changes to the mount table are
|
||
|
relatively rare, it is reasonable to fall back on REF-walk any time
|
||
|
that any "mount" or "unmount" happens.
|
||
|
|
||
|
`m_seq` is checked (using `read_seqretry()`) at the end of an RCU-walk
|
||
|
sequence, whether switching to REF-walk for the rest of the path or
|
||
|
when the end of the path is reached. It is also checked when stepping
|
||
|
down over a mount point (in `__follow_mount_rcu()`) or up (in
|
||
|
`follow_dotdot_rcu()`). If it is ever found to have changed, the
|
||
|
whole RCU-walk sequence is aborted and the path is processed again by
|
||
|
REF-walk.
|
||
|
|
||
|
If RCU-walk finds that `mount_lock` hasn't changed then it can be sure
|
||
|
that, had REF-walk taken counted references on each vfsmount, the
|
||
|
results would have been the same. This ensures the invariant holds,
|
||
|
at least for vfsmount structures.
|
||
|
|
||
|
### `dentry->d_seq` and `nd->seq`. ###
|
||
|
|
||
|
In place of taking a count or lock on `d_reflock`, RCU-walk samples
|
||
|
the per-dentry `d_seq` seqlock, and stores the sequence number in the
|
||
|
`seq` field of the nameidata structure, so `nd->seq` should always be
|
||
|
the current sequence number of `nd->dentry`. This number needs to be
|
||
|
revalidated after copying, and before using, the name, parent, or
|
||
|
inode of the dentry.
|
||
|
|
||
|
The handling of the name we have already looked at, and the parent is
|
||
|
only accessed in `follow_dotdot_rcu()` which fairly trivially follows
|
||
|
the required pattern, though it does so for three different cases.
|
||
|
|
||
|
When not at a mount point, `d_parent` is followed and its `d_seq` is
|
||
|
collected. When we are at a mount point, we instead follow the
|
||
|
`mnt->mnt_mountpoint` link to get a new dentry and collect its
|
||
|
`d_seq`. Then, after finally finding a `d_parent` to follow, we must
|
||
|
check if we have landed on a mount point and, if so, must find that
|
||
|
mount point and follow the `mnt->mnt_root` link. This would imply a
|
||
|
somewhat unusual, but certainly possible, circumstance where the
|
||
|
starting point of the path lookup was in part of the filesystem that
|
||
|
was mounted on, and so not visible from the root.
|
||
|
|
||
|
The inode pointer, stored in `->d_inode`, is a little more
|
||
|
interesting. The inode will always need to be accessed at least
|
||
|
twice, once to determine if it is NULL and once to verify access
|
||
|
permissions. Symlink handling requires a validated inode pointer too.
|
||
|
Rather than revalidating on each access, a copy is made on the first
|
||
|
access and it is stored in the `inode` field of `nameidata` from where
|
||
|
it can be safely accessed without further validation.
|
||
|
|
||
|
`lookup_fast()` is the only lookup routine that is used in RCU-mode,
|
||
|
`lookup_slow()` being too slow and requiring locks. It is in
|
||
|
`lookup_fast()` that we find the important "hand over hand" tracking
|
||
|
of the current dentry.
|
||
|
|
||
|
The current `dentry` and current `seq` number are passed to
|
||
|
`__d_lookup_rcu()` which, on success, returns a new `dentry` and a
|
||
|
new `seq` number. `lookup_fast()` then copies the inode pointer and
|
||
|
revalidates the new `seq` number. It then validates the old `dentry`
|
||
|
with the old `seq` number one last time and only then continues. This
|
||
|
process of getting the `seq` number of the new dentry and then
|
||
|
checking the `seq` number of the old exactly mirrors the process of
|
||
|
getting a counted reference to the new dentry before dropping that for
|
||
|
the old dentry which we saw in REF-walk.
|
||
|
|
||
|
### No `inode->i_mutex` or even `rename_lock` ###
|
||
|
|
||
|
A mutex is a fairly heavyweight lock that can only be taken when it is
|
||
|
permissible to sleep. As `rcu_read_lock()` forbids sleeping,
|
||
|
`inode->i_mutex` plays no role in RCU-walk. If some other thread does
|
||
|
take `i_mutex` and modifies the directory in a way that RCU-walk needs
|
||
|
to notice, the result will be either that RCU-walk fails to find the
|
||
|
dentry that it is looking for, or it will find a dentry which
|
||
|
`read_seqretry()` won't validate. In either case it will drop down to
|
||
|
REF-walk mode which can take whatever locks are needed.
|
||
|
|
||
|
Though `rename_lock` could be used by RCU-walk as it doesn't require
|
||
|
any sleeping, RCU-walk doesn't bother. REF-walk uses `rename_lock` to
|
||
|
protect against the possibility of hash chains in the dcache changing
|
||
|
while they are being searched. This can result in failing to find
|
||
|
something that actually is there. When RCU-walk fails to find
|
||
|
something in the dentry cache, whether it is really there or not, it
|
||
|
already drops down to REF-walk and tries again with appropriate
|
||
|
locking. This neatly handles all cases, so adding extra checks on
|
||
|
rename_lock would bring no significant value.
|
||
|
|
||
|
`unlazy walk()` and `complete_walk()`
|
||
|
-------------------------------------
|
||
|
|
||
|
That "dropping down to REF-walk" typically involves a call to
|
||
|
`unlazy_walk()`, so named because "RCU-walk" is also sometimes
|
||
|
referred to as "lazy walk". `unlazy_walk()` is called when
|
||
|
following the path down to the current vfsmount/dentry pair seems to
|
||
|
have proceeded successfully, but the next step is problematic. This
|
||
|
can happen if the next name cannot be found in the dcache, if
|
||
|
permission checking or name revalidation couldn't be achieved while
|
||
|
the `rcu_read_lock()` is held (which forbids sleeping), if an
|
||
|
automount point is found, or in a couple of cases involving symlinks.
|
||
|
It is also called from `complete_walk()` when the lookup has reached
|
||
|
the final component, or the very end of the path, depending on which
|
||
|
particular flavor of lookup is used.
|
||
|
|
||
|
Other reasons for dropping out of RCU-walk that do not trigger a call
|
||
|
to `unlazy_walk()` are when some inconsistency is found that cannot be
|
||
|
handled immediately, such as `mount_lock` or one of the `d_seq`
|
||
|
seqlocks reporting a change. In these cases the relevant function
|
||
|
will return `-ECHILD` which will percolate up until it triggers a new
|
||
|
attempt from the top using REF-walk.
|
||
|
|
||
|
For those cases where `unlazy_walk()` is an option, it essentially
|
||
|
takes a reference on each of the pointers that it holds (vfsmount,
|
||
|
dentry, and possibly some symbolic links) and then verifies that the
|
||
|
relevant seqlocks have not been changed. If there have been changes,
|
||
|
it, too, aborts with `-ECHILD`, otherwise the transition to REF-walk
|
||
|
has been a success and the lookup process continues.
|
||
|
|
||
|
Taking a reference on those pointers is not quite as simple as just
|
||
|
incrementing a counter. That works to take a second reference if you
|
||
|
already have one (often indirectly through another object), but it
|
||
|
isn't sufficient if you don't actually have a counted reference at
|
||
|
all. For `dentry->d_lockref`, it is safe to increment the reference
|
||
|
counter to get a reference unless it has been explicitly marked as
|
||
|
"dead" which involves setting the counter to `-128`.
|
||
|
`lockref_get_not_dead()` achieves this.
|
||
|
|
||
|
For `mnt->mnt_count` it is safe to take a reference as long as
|
||
|
`mount_lock` is then used to validate the reference. If that
|
||
|
validation fails, it may *not* be safe to just drop that reference in
|
||
|
the standard way of calling `mnt_put()` - an unmount may have
|
||
|
progressed too far. So the code in `legitimize_mnt()`, when it
|
||
|
finds that the reference it got might not be safe, checks the
|
||
|
`MNT_SYNC_UMOUNT` flag to determine if a simple `mnt_put()` is
|
||
|
correct, or if it should just decrement the count and pretend none of
|
||
|
this ever happened.
|
||
|
|
||
|
Taking care in filesystems
|
||
|
---------------------------
|
||
|
|
||
|
RCU-walk depends almost entirely on cached information and often will
|
||
|
not call into the filesystem at all. However there are two places,
|
||
|
besides the already-mentioned component-name comparison, where the
|
||
|
file system might be included in RCU-walk, and it must know to be
|
||
|
careful.
|
||
|
|
||
|
If the filesystem has non-standard permission-checking requirements -
|
||
|
such as a networked filesystem which may need to check with the server
|
||
|
- the `i_op->permission` interface might be called during RCU-walk.
|
||
|
In this case an extra "`MAY_NOT_BLOCK`" flag is passed so that it
|
||
|
knows not to sleep, but to return `-ECHILD` if it cannot complete
|
||
|
promptly. `i_op->permission` is given the inode pointer, not the
|
||
|
dentry, so it doesn't need to worry about further consistency checks.
|
||
|
However if it accesses any other filesystem data structures, it must
|
||
|
ensure they are safe to be accessed with only the `rcu_read_lock()`
|
||
|
held. This typically means they must be freed using `kfree_rcu()` or
|
||
|
similar.
|
||
|
|
||
|
[`READ_ONCE()`]: https://lwn.net/Articles/624126/
|
||
|
|
||
|
If the filesystem may need to revalidate dcache entries, then
|
||
|
`d_op->d_revalidate` may be called in RCU-walk too. This interface
|
||
|
*is* passed the dentry but does not have access to the `inode` or the
|
||
|
`seq` number from the `nameidata`, so it needs to be extra careful
|
||
|
when accessing fields in the dentry. This "extra care" typically
|
||
|
involves using [`READ_ONCE()`] to access fields, and verifying the
|
||
|
result is not NULL before using it. This pattern can be seen in
|
||
|
`nfs_lookup_revalidate()`.
|
||
|
|
||
|
A pair of patterns
|
||
|
------------------
|
||
|
|
||
|
In various places in the details of REF-walk and RCU-walk, and also in
|
||
|
the big picture, there are a couple of related patterns that are worth
|
||
|
being aware of.
|
||
|
|
||
|
The first is "try quickly and check, if that fails try slowly". We
|
||
|
can see that in the high-level approach of first trying RCU-walk and
|
||
|
then trying REF-walk, and in places where `unlazy_walk()` is used to
|
||
|
switch to REF-walk for the rest of the path. We also saw it earlier
|
||
|
in `dget_parent()` when following a "`..`" link. It tries a quick way
|
||
|
to get a reference, then falls back to taking locks if needed.
|
||
|
|
||
|
The second pattern is "try quickly and check, if that fails try
|
||
|
again - repeatedly". This is seen with the use of `rename_lock` and
|
||
|
`mount_lock` in REF-walk. RCU-walk doesn't make use of this pattern -
|
||
|
if anything goes wrong it is much safer to just abort and try a more
|
||
|
sedate approach.
|
||
|
|
||
|
The emphasis here is "try quickly and check". It should probably be
|
||
|
"try quickly _and carefully,_ then check". The fact that checking is
|
||
|
needed is a reminder that the system is dynamic and only a limited
|
||
|
number of things are safe at all. The most likely cause of errors in
|
||
|
this whole process is assuming something is safe when in reality it
|
||
|
isn't. Careful consideration of what exactly guarantees the safety of
|
||
|
each access is sometimes necessary.
|
||
|
|
||
|
A walk among the symlinks
|
||
|
=========================
|
||
|
|
||
|
There are several basic issues that we will examine to understand the
|
||
|
handling of symbolic links: the symlink stack, together with cache
|
||
|
lifetimes, will help us understand the overall recursive handling of
|
||
|
symlinks and lead to the special care needed for the final component.
|
||
|
Then a consideration of access-time updates and summary of the various
|
||
|
flags controlling lookup will finish the story.
|
||
|
|
||
|
The symlink stack
|
||
|
-----------------
|
||
|
|
||
|
There are only two sorts of filesystem objects that can usefully
|
||
|
appear in a path prior to the final component: directories and symlinks.
|
||
|
Handling directories is quite straightforward: the new directory
|
||
|
simply becomes the starting point at which to interpret the next
|
||
|
component on the path. Handling symbolic links requires a bit more
|
||
|
work.
|
||
|
|
||
|
Conceptually, symbolic links could be handled by editing the path. If
|
||
|
a component name refers to a symbolic link, then that component is
|
||
|
replaced by the body of the link and, if that body starts with a '/',
|
||
|
then all preceding parts of the path are discarded. This is what the
|
||
|
"`readlink -f`" command does, though it also edits out "`.`" and
|
||
|
"`..`" components.
|
||
|
|
||
|
Directly editing the path string is not really necessary when looking
|
||
|
up a path, and discarding early components is pointless as they aren't
|
||
|
looked at anyway. Keeping track of all remaining components is
|
||
|
important, but they can of course be kept separately; there is no need
|
||
|
to concatenate them. As one symlink may easily refer to another,
|
||
|
which in turn can refer to a third, we may need to keep the remaining
|
||
|
components of several paths, each to be processed when the preceding
|
||
|
ones are completed. These path remnants are kept on a stack of
|
||
|
limited size.
|
||
|
|
||
|
There are two reasons for placing limits on how many symlinks can
|
||
|
occur in a single path lookup. The most obvious is to avoid loops.
|
||
|
If a symlink referred to itself either directly or through
|
||
|
intermediaries, then following the symlink can never complete
|
||
|
successfully - the error `ELOOP` must be returned. Loops can be
|
||
|
detected without imposing limits, but limits are the simplest solution
|
||
|
and, given the second reason for restriction, quite sufficient.
|
||
|
|
||
|
[outlined recently]: http://thread.gmane.org/gmane.linux.kernel/1934390/focus=1934550
|
||
|
|
||
|
The second reason was [outlined recently] by Linus:
|
||
|
|
||
|
> Because it's a latency and DoS issue too. We need to react well to
|
||
|
> true loops, but also to "very deep" non-loops. It's not about memory
|
||
|
> use, it's about users triggering unreasonable CPU resources.
|
||
|
|
||
|
Linux imposes a limit on the length of any pathname: `PATH_MAX`, which
|
||
|
is 4096. There are a number of reasons for this limit; not letting the
|
||
|
kernel spend too much time on just one path is one of them. With
|
||
|
symbolic links you can effectively generate much longer paths so some
|
||
|
sort of limit is needed for the same reason. Linux imposes a limit of
|
||
|
at most 40 symlinks in any one path lookup. It previously imposed a
|
||
|
further limit of eight on the maximum depth of recursion, but that was
|
||
|
raised to 40 when a separate stack was implemented, so there is now
|
||
|
just the one limit.
|
||
|
|
||
|
The `nameidata` structure that we met in an earlier article contains a
|
||
|
small stack that can be used to store the remaining part of up to two
|
||
|
symlinks. In many cases this will be sufficient. If it isn't, a
|
||
|
separate stack is allocated with room for 40 symlinks. Pathname
|
||
|
lookup will never exceed that stack as, once the 40th symlink is
|
||
|
detected, an error is returned.
|
||
|
|
||
|
It might seem that the name remnants are all that needs to be stored on
|
||
|
this stack, but we need a bit more. To see that, we need to move on to
|
||
|
cache lifetimes.
|
||
|
|
||
|
Storage and lifetime of cached symlinks
|
||
|
---------------------------------------
|
||
|
|
||
|
Like other filesystem resources, such as inodes and directory
|
||
|
entries, symlinks are cached by Linux to avoid repeated costly access
|
||
|
to external storage. It is particularly important for RCU-walk to be
|
||
|
able to find and temporarily hold onto these cached entries, so that
|
||
|
it doesn't need to drop down into REF-walk.
|
||
|
|
||
|
[object-oriented design pattern]: https://lwn.net/Articles/446317/
|
||
|
|
||
|
While each filesystem is free to make its own choice, symlinks are
|
||
|
typically stored in one of two places. Short symlinks are often
|
||
|
stored directly in the inode. When a filesystem allocates a `struct
|
||
|
inode` it typically allocates extra space to store private data (a
|
||
|
common [object-oriented design pattern] in the kernel). This will
|
||
|
sometimes include space for a symlink. The other common location is
|
||
|
in the page cache, which normally stores the content of files. The
|
||
|
pathname in a symlink can be seen as the content of that symlink and
|
||
|
can easily be stored in the page cache just like file content.
|
||
|
|
||
|
When neither of these is suitable, the next most likely scenario is
|
||
|
that the filesystem will allocate some temporary memory and copy or
|
||
|
construct the symlink content into that memory whenever it is needed.
|
||
|
|
||
|
When the symlink is stored in the inode, it has the same lifetime as
|
||
|
the inode which, itself, is protected by RCU or by a counted reference
|
||
|
on the dentry. This means that the mechanisms that pathname lookup
|
||
|
uses to access the dcache and icache (inode cache) safely are quite
|
||
|
sufficient for accessing some cached symlinks safely. In these cases,
|
||
|
the `i_link` pointer in the inode is set to point to wherever the
|
||
|
symlink is stored and it can be accessed directly whenever needed.
|
||
|
|
||
|
When the symlink is stored in the page cache or elsewhere, the
|
||
|
situation is not so straightforward. A reference on a dentry or even
|
||
|
on an inode does not imply any reference on cached pages of that
|
||
|
inode, and even an `rcu_read_lock()` is not sufficient to ensure that
|
||
|
a page will not disappear. So for these symlinks the pathname lookup
|
||
|
code needs to ask the filesystem to provide a stable reference and,
|
||
|
significantly, needs to release that reference when it is finished
|
||
|
with it.
|
||
|
|
||
|
Taking a reference to a cache page is often possible even in RCU-walk
|
||
|
mode. It does require making changes to memory, which is best avoided,
|
||
|
but that isn't necessarily a big cost and it is better than dropping
|
||
|
out of RCU-walk mode completely. Even filesystems that allocate
|
||
|
space to copy the symlink into can use `GFP_ATOMIC` to often successfully
|
||
|
allocate memory without the need to drop out of RCU-walk. If a
|
||
|
filesystem cannot successfully get a reference in RCU-walk mode, it
|
||
|
must return `-ECHILD` and `unlazy_walk()` will be called to return to
|
||
|
REF-walk mode in which the filesystem is allowed to sleep.
|
||
|
|
||
|
The place for all this to happen is the `i_op->follow_link()` inode
|
||
|
method. In the present mainline code this is never actually called in
|
||
|
RCU-walk mode as the rewrite is not quite complete. It is likely that
|
||
|
in a future release this method will be passed an `inode` pointer when
|
||
|
called in RCU-walk mode so it both (1) knows to be careful, and (2) has the
|
||
|
validated pointer. Much like the `i_op->permission()` method we
|
||
|
looked at previously, `->follow_link()` would need to be careful that
|
||
|
all the data structures it references are safe to be accessed while
|
||
|
holding no counted reference, only the RCU lock. Though getting a
|
||
|
reference with `->follow_link()` is not yet done in RCU-walk mode, the
|
||
|
code is ready to release the reference when that does happen.
|
||
|
|
||
|
This need to drop the reference to a symlink adds significant
|
||
|
complexity. It requires a reference to the inode so that the
|
||
|
`i_op->put_link()` inode operation can be called. In REF-walk, that
|
||
|
reference is kept implicitly through a reference to the dentry, so
|
||
|
keeping the `struct path` of the symlink is easiest. For RCU-walk,
|
||
|
the pointer to the inode is kept separately. To allow switching from
|
||
|
RCU-walk back to REF-walk in the middle of processing nested symlinks
|
||
|
we also need the seq number for the dentry so we can confirm that
|
||
|
switching back was safe.
|
||
|
|
||
|
Finally, when providing a reference to a symlink, the filesystem also
|
||
|
provides an opaque "cookie" that must be passed to `->put_link()` so that it
|
||
|
knows what to free. This might be the allocated memory area, or a
|
||
|
pointer to the `struct page` in the page cache, or something else
|
||
|
completely. Only the filesystem knows what it is.
|
||
|
|
||
|
In order for the reference to each symlink to be dropped when the walk completes,
|
||
|
whether in RCU-walk or REF-walk, the symlink stack needs to contain,
|
||
|
along with the path remnants:
|
||
|
|
||
|
- the `struct path` to provide a reference to the inode in REF-walk
|
||
|
- the `struct inode *` to provide a reference to the inode in RCU-walk
|
||
|
- the `seq` to allow the path to be safely switched from RCU-walk to REF-walk
|
||
|
- the `cookie` that tells `->put_path()` what to put.
|
||
|
|
||
|
This means that each entry in the symlink stack needs to hold five
|
||
|
pointers and an integer instead of just one pointer (the path
|
||
|
remnant). On a 64-bit system, this is about 40 bytes per entry;
|
||
|
with 40 entries it adds up to 1600 bytes total, which is less than
|
||
|
half a page. So it might seem like a lot, but is by no means
|
||
|
excessive.
|
||
|
|
||
|
Note that, in a given stack frame, the path remnant (`name`) is not
|
||
|
part of the symlink that the other fields refer to. It is the remnant
|
||
|
to be followed once that symlink has been fully parsed.
|
||
|
|
||
|
Following the symlink
|
||
|
---------------------
|
||
|
|
||
|
The main loop in `link_path_walk()` iterates seamlessly over all
|
||
|
components in the path and all of the non-final symlinks. As symlinks
|
||
|
are processed, the `name` pointer is adjusted to point to a new
|
||
|
symlink, or is restored from the stack, so that much of the loop
|
||
|
doesn't need to notice. Getting this `name` variable on and off the
|
||
|
stack is very straightforward; pushing and popping the references is
|
||
|
a little more complex.
|
||
|
|
||
|
When a symlink is found, `walk_component()` returns the value `1`
|
||
|
(`0` is returned for any other sort of success, and a negative number
|
||
|
is, as usual, an error indicator). This causes `get_link()` to be
|
||
|
called; it then gets the link from the filesystem. Providing that
|
||
|
operation is successful, the old path `name` is placed on the stack,
|
||
|
and the new value is used as the `name` for a while. When the end of
|
||
|
the path is found (i.e. `*name` is `'\0'`) the old `name` is restored
|
||
|
off the stack and path walking continues.
|
||
|
|
||
|
Pushing and popping the reference pointers (inode, cookie, etc.) is more
|
||
|
complex in part because of the desire to handle tail recursion. When
|
||
|
the last component of a symlink itself points to a symlink, we
|
||
|
want to pop the symlink-just-completed off the stack before pushing
|
||
|
the symlink-just-found to avoid leaving empty path remnants that would
|
||
|
just get in the way.
|
||
|
|
||
|
It is most convenient to push the new symlink references onto the
|
||
|
stack in `walk_component()` immediately when the symlink is found;
|
||
|
`walk_component()` is also the last piece of code that needs to look at the
|
||
|
old symlink as it walks that last component. So it is quite
|
||
|
convenient for `walk_component()` to release the old symlink and pop
|
||
|
the references just before pushing the reference information for the
|
||
|
new symlink. It is guided in this by two flags; `WALK_GET`, which
|
||
|
gives it permission to follow a symlink if it finds one, and
|
||
|
`WALK_PUT`, which tells it to release the current symlink after it has been
|
||
|
followed. `WALK_PUT` is tested first, leading to a call to
|
||
|
`put_link()`. `WALK_GET` is tested subsequently (by
|
||
|
`should_follow_link()`) leading to a call to `pick_link()` which sets
|
||
|
up the stack frame.
|
||
|
|
||
|
### Symlinks with no final component ###
|
||
|
|
||
|
A pair of special-case symlinks deserve a little further explanation.
|
||
|
Both result in a new `struct path` (with mount and dentry) being set
|
||
|
up in the `nameidata`, and result in `get_link()` returning `NULL`.
|
||
|
|
||
|
The more obvious case is a symlink to "`/`". All symlinks starting
|
||
|
with "`/`" are detected in `get_link()` which resets the `nameidata`
|
||
|
to point to the effective filesystem root. If the symlink only
|
||
|
contains "`/`" then there is nothing more to do, no components at all,
|
||
|
so `NULL` is returned to indicate that the symlink can be released and
|
||
|
the stack frame discarded.
|
||
|
|
||
|
The other case involves things in `/proc` that look like symlinks but
|
||
|
aren't really.
|
||
|
|
||
|
> $ ls -l /proc/self/fd/1
|
||
|
> lrwx------ 1 neilb neilb 64 Jun 13 10:19 /proc/self/fd/1 -> /dev/pts/4
|
||
|
|
||
|
Every open file descriptor in any process is represented in `/proc` by
|
||
|
something that looks like a symlink. It is really a reference to the
|
||
|
target file, not just the name of it. When you `readlink` these
|
||
|
objects you get a name that might refer to the same file - unless it
|
||
|
has been unlinked or mounted over. When `walk_component()` follows
|
||
|
one of these, the `->follow_link()` method in "procfs" doesn't return
|
||
|
a string name, but instead calls `nd_jump_link()` which updates the
|
||
|
`nameidata` in place to point to that target. `->follow_link()` then
|
||
|
returns `NULL`. Again there is no final component and `get_link()`
|
||
|
reports this by leaving the `last_type` field of `nameidata` as
|
||
|
`LAST_BIND`.
|
||
|
|
||
|
Following the symlink in the final component
|
||
|
--------------------------------------------
|
||
|
|
||
|
All this leads to `link_path_walk()` walking down every component, and
|
||
|
following all symbolic links it finds, until it reaches the final
|
||
|
component. This is just returned in the `last` field of `nameidata`.
|
||
|
For some callers, this is all they need; they want to create that
|
||
|
`last` name if it doesn't exist or give an error if it does. Other
|
||
|
callers will want to follow a symlink if one is found, and possibly
|
||
|
apply special handling to the last component of that symlink, rather
|
||
|
than just the last component of the original file name. These callers
|
||
|
potentially need to call `link_path_walk()` again and again on
|
||
|
successive symlinks until one is found that doesn't point to another
|
||
|
symlink.
|
||
|
|
||
|
This case is handled by the relevant caller of `link_path_walk()`, such as
|
||
|
`path_lookupat()` using a loop that calls `link_path_walk()`, and then
|
||
|
handles the final component. If the final component is a symlink
|
||
|
that needs to be followed, then `trailing_symlink()` is called to set
|
||
|
things up properly and the loop repeats, calling `link_path_walk()`
|
||
|
again. This could loop as many as 40 times if the last component of
|
||
|
each symlink is another symlink.
|
||
|
|
||
|
The various functions that examine the final component and possibly
|
||
|
report that it is a symlink are `lookup_last()`, `mountpoint_last()`
|
||
|
and `do_last()`, each of which use the same convention as
|
||
|
`walk_component()` of returning `1` if a symlink was found that needs
|
||
|
to be followed.
|
||
|
|
||
|
Of these, `do_last()` is the most interesting as it is used for
|
||
|
opening a file. Part of `do_last()` runs with `i_mutex` held and this
|
||
|
part is in a separate function: `lookup_open()`.
|
||
|
|
||
|
Explaining `do_last()` completely is beyond the scope of this article,
|
||
|
but a few highlights should help those interested in exploring the
|
||
|
code.
|
||
|
|
||
|
1. Rather than just finding the target file, `do_last()` needs to open
|
||
|
it. If the file was found in the dcache, then `vfs_open()` is used for
|
||
|
this. If not, then `lookup_open()` will either call `atomic_open()` (if
|
||
|
the filesystem provides it) to combine the final lookup with the open, or
|
||
|
will perform the separate `lookup_real()` and `vfs_create()` steps
|
||
|
directly. In the later case the actual "open" of this newly found or
|
||
|
created file will be performed by `vfs_open()`, just as if the name
|
||
|
were found in the dcache.
|
||
|
|
||
|
2. `vfs_open()` can fail with `-EOPENSTALE` if the cached information
|
||
|
wasn't quite current enough. Rather than restarting the lookup from
|
||
|
the top with `LOOKUP_REVAL` set, `lookup_open()` is called instead,
|
||
|
giving the filesystem a chance to resolve small inconsistencies.
|
||
|
If that doesn't work, only then is the lookup restarted from the top.
|
||
|
|
||
|
3. An open with O_CREAT **does** follow a symlink in the final component,
|
||
|
unlike other creation system calls (like `mkdir`). So the sequence:
|
||
|
|
||
|
> ln -s bar /tmp/foo
|
||
|
> echo hello > /tmp/foo
|
||
|
|
||
|
will create a file called `/tmp/bar`. This is not permitted if
|
||
|
`O_EXCL` is set but otherwise is handled for an O_CREAT open much
|
||
|
like for a non-creating open: `should_follow_link()` returns `1`, and
|
||
|
so does `do_last()` so that `trailing_symlink()` gets called and the
|
||
|
open process continues on the symlink that was found.
|
||
|
|
||
|
Updating the access time
|
||
|
------------------------
|
||
|
|
||
|
We previously said of RCU-walk that it would "take no locks, increment
|
||
|
no counts, leave no footprints." We have since seen that some
|
||
|
"footprints" can be needed when handling symlinks as a counted
|
||
|
reference (or even a memory allocation) may be needed. But these
|
||
|
footprints are best kept to a minimum.
|
||
|
|
||
|
One other place where walking down a symlink can involve leaving
|
||
|
footprints in a way that doesn't affect directories is in updating access times.
|
||
|
In Unix (and Linux) every filesystem object has a "last accessed
|
||
|
time", or "`atime`". Passing through a directory to access a file
|
||
|
within is not considered to be an access for the purposes of
|
||
|
`atime`; only listing the contents of a directory can update its `atime`.
|
||
|
Symlinks are different it seems. Both reading a symlink (with `readlink()`)
|
||
|
and looking up a symlink on the way to some other destination can
|
||
|
update the atime on that symlink.
|
||
|
|
||
|
[clearest statement]: http://pubs.opengroup.org/onlinepubs/9699919799/basedefs/V1_chap04.html#tag_04_08
|
||
|
|
||
|
It is not clear why this is the case; POSIX has little to say on the
|
||
|
subject. The [clearest statement] is that, if a particular implementation
|
||
|
updates a timestamp in a place not specified by POSIX, this must be
|
||
|
documented "except that any changes caused by pathname resolution need
|
||
|
not be documented". This seems to imply that POSIX doesn't really
|
||
|
care about access-time updates during pathname lookup.
|
||
|
|
||
|
[Linux 1.3.87]: https://git.kernel.org/cgit/linux/kernel/git/history/history.git/diff/fs/ext2/symlink.c?id=f806c6db77b8eaa6e00dcfb6b567706feae8dbb8
|
||
|
|
||
|
An examination of history shows that prior to [Linux 1.3.87], the ext2
|
||
|
filesystem, at least, didn't update atime when following a link.
|
||
|
Unfortunately we have no record of why that behavior was changed.
|
||
|
|
||
|
In any case, access time must now be updated and that operation can be
|
||
|
quite complex. Trying to stay in RCU-walk while doing it is best
|
||
|
avoided. Fortunately it is often permitted to skip the `atime`
|
||
|
update. Because `atime` updates cause performance problems in various
|
||
|
areas, Linux supports the `relatime` mount option, which generally
|
||
|
limits the updates of `atime` to once per day on files that aren't
|
||
|
being changed (and symlinks never change once created). Even without
|
||
|
`relatime`, many filesystems record `atime` with a one-second
|
||
|
granularity, so only one update per second is required.
|
||
|
|
||
|
It is easy to test if an `atime` update is needed while in RCU-walk
|
||
|
mode and, if it isn't, the update can be skipped and RCU-walk mode
|
||
|
continues. Only when an `atime` update is actually required does the
|
||
|
path walk drop down to REF-walk. All of this is handled in the
|
||
|
`get_link()` function.
|
||
|
|
||
|
A few flags
|
||
|
-----------
|
||
|
|
||
|
A suitable way to wrap up this tour of pathname walking is to list
|
||
|
the various flags that can be stored in the `nameidata` to guide the
|
||
|
lookup process. Many of these are only meaningful on the final
|
||
|
component, others reflect the current state of the pathname lookup.
|
||
|
And then there is `LOOKUP_EMPTY`, which doesn't fit conceptually with
|
||
|
the others. If this is not set, an empty pathname causes an error
|
||
|
very early on. If it is set, empty pathnames are not considered to be
|
||
|
an error.
|
||
|
|
||
|
### Global state flags ###
|
||
|
|
||
|
We have already met two global state flags: `LOOKUP_RCU` and
|
||
|
`LOOKUP_REVAL`. These select between one of three overall approaches
|
||
|
to lookup: RCU-walk, REF-walk, and REF-walk with forced revalidation.
|
||
|
|
||
|
`LOOKUP_PARENT` indicates that the final component hasn't been reached
|
||
|
yet. This is primarily used to tell the audit subsystem the full
|
||
|
context of a particular access being audited.
|
||
|
|
||
|
`LOOKUP_ROOT` indicates that the `root` field in the `nameidata` was
|
||
|
provided by the caller, so it shouldn't be released when it is no
|
||
|
longer needed.
|
||
|
|
||
|
`LOOKUP_JUMPED` means that the current dentry was chosen not because
|
||
|
it had the right name but for some other reason. This happens when
|
||
|
following "`..`", following a symlink to `/`, crossing a mount point
|
||
|
or accessing a "`/proc/$PID/fd/$FD`" symlink. In this case the
|
||
|
filesystem has not been asked to revalidate the name (with
|
||
|
`d_revalidate()`). In such cases the inode may still need to be
|
||
|
revalidated, so `d_op->d_weak_revalidate()` is called if
|
||
|
`LOOKUP_JUMPED` is set when the look completes - which may be at the
|
||
|
final component or, when creating, unlinking, or renaming, at the penultimate component.
|
||
|
|
||
|
### Final-component flags ###
|
||
|
|
||
|
Some of these flags are only set when the final component is being
|
||
|
considered. Others are only checked for when considering that final
|
||
|
component.
|
||
|
|
||
|
`LOOKUP_AUTOMOUNT` ensures that, if the final component is an automount
|
||
|
point, then the mount is triggered. Some operations would trigger it
|
||
|
anyway, but operations like `stat()` deliberately don't. `statfs()`
|
||
|
needs to trigger the mount but otherwise behaves a lot like `stat()`, so
|
||
|
it sets `LOOKUP_AUTOMOUNT`, as does "`quotactl()`" and the handling of
|
||
|
"`mount --bind`".
|
||
|
|
||
|
`LOOKUP_FOLLOW` has a similar function to `LOOKUP_AUTOMOUNT` but for
|
||
|
symlinks. Some system calls set or clear it implicitly, while
|
||
|
others have API flags such as `AT_SYMLINK_FOLLOW` and
|
||
|
`UMOUNT_NOFOLLOW` to control it. Its effect is similar to
|
||
|
`WALK_GET` that we already met, but it is used in a different way.
|
||
|
|
||
|
`LOOKUP_DIRECTORY` insists that the final component is a directory.
|
||
|
Various callers set this and it is also set when the final component
|
||
|
is found to be followed by a slash.
|
||
|
|
||
|
Finally `LOOKUP_OPEN`, `LOOKUP_CREATE`, `LOOKUP_EXCL`, and
|
||
|
`LOOKUP_RENAME_TARGET` are not used directly by the VFS but are made
|
||
|
available to the filesystem and particularly the `->d_revalidate()`
|
||
|
method. A filesystem can choose not to bother revalidating too hard
|
||
|
if it knows that it will be asked to open or create the file soon.
|
||
|
These flags were previously useful for `->lookup()` too but with the
|
||
|
introduction of `->atomic_open()` they are less relevant there.
|
||
|
|
||
|
End of the road
|
||
|
---------------
|
||
|
|
||
|
Despite its complexity, all this pathname lookup code appears to be
|
||
|
in good shape - various parts are certainly easier to understand now
|
||
|
than even a couple of releases ago. But that doesn't mean it is
|
||
|
"finished". As already mentioned, RCU-walk currently only follows
|
||
|
symlinks that are stored in the inode so, while it handles many ext4
|
||
|
symlinks, it doesn't help with NFS, XFS, or Btrfs. That support
|
||
|
is not likely to be long delayed.
|