814 lines
29 KiB
Plaintext
814 lines
29 KiB
Plaintext
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===============================
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FS-CACHE NETWORK FILESYSTEM API
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===============================
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There's an API by which a network filesystem can make use of the FS-Cache
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facilities. This is based around a number of principles:
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(1) Caches can store a number of different object types. There are two main
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object types: indices and files. The first is a special type used by
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FS-Cache to make finding objects faster and to make retiring of groups of
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objects easier.
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(2) Every index, file or other object is represented by a cookie. This cookie
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may or may not have anything associated with it, but the netfs doesn't
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need to care.
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(3) Barring the top-level index (one entry per cached netfs), the index
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hierarchy for each netfs is structured according the whim of the netfs.
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This API is declared in <linux/fscache.h>.
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This document contains the following sections:
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(1) Network filesystem definition
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(2) Index definition
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(3) Object definition
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(4) Network filesystem (un)registration
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(5) Cache tag lookup
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(6) Index registration
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(7) Data file registration
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(8) Miscellaneous object registration
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(9) Setting the data file size
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(10) Page alloc/read/write
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(11) Page uncaching
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(12) Index and data file update
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(13) Miscellaneous cookie operations
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(14) Cookie unregistration
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(15) Index and data file invalidation
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(16) FS-Cache specific page flags.
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=============================
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NETWORK FILESYSTEM DEFINITION
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=============================
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FS-Cache needs a description of the network filesystem. This is specified
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using a record of the following structure:
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struct fscache_netfs {
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uint32_t version;
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const char *name;
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struct fscache_cookie *primary_index;
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...
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};
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This first two fields should be filled in before registration, and the third
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will be filled in by the registration function; any other fields should just be
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ignored and are for internal use only.
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The fields are:
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(1) The name of the netfs (used as the key in the toplevel index).
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(2) The version of the netfs (if the name matches but the version doesn't, the
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entire in-cache hierarchy for this netfs will be scrapped and begun
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afresh).
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(3) The cookie representing the primary index will be allocated according to
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another parameter passed into the registration function.
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For example, kAFS (linux/fs/afs/) uses the following definitions to describe
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itself:
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struct fscache_netfs afs_cache_netfs = {
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.version = 0,
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.name = "afs",
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};
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================
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INDEX DEFINITION
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================
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Indices are used for two purposes:
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(1) To aid the finding of a file based on a series of keys (such as AFS's
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"cell", "volume ID", "vnode ID").
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(2) To make it easier to discard a subset of all the files cached based around
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a particular key - for instance to mirror the removal of an AFS volume.
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However, since it's unlikely that any two netfs's are going to want to define
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their index hierarchies in quite the same way, FS-Cache tries to impose as few
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restraints as possible on how an index is structured and where it is placed in
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the tree. The netfs can even mix indices and data files at the same level, but
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it's not recommended.
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Each index entry consists of a key of indeterminate length plus some auxiliary
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data, also of indeterminate length.
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There are some limits on indices:
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(1) Any index containing non-index objects should be restricted to a single
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cache. Any such objects created within an index will be created in the
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first cache only. The cache in which an index is created can be
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controlled by cache tags (see below).
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(2) The entry data must be atomically journallable, so it is limited to about
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400 bytes at present. At least 400 bytes will be available.
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(3) The depth of the index tree should be judged with care as the search
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function is recursive. Too many layers will run the kernel out of stack.
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=================
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OBJECT DEFINITION
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=================
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To define an object, a structure of the following type should be filled out:
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struct fscache_cookie_def
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{
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uint8_t name[16];
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uint8_t type;
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struct fscache_cache_tag *(*select_cache)(
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const void *parent_netfs_data,
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const void *cookie_netfs_data);
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uint16_t (*get_key)(const void *cookie_netfs_data,
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void *buffer,
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uint16_t bufmax);
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void (*get_attr)(const void *cookie_netfs_data,
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uint64_t *size);
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uint16_t (*get_aux)(const void *cookie_netfs_data,
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void *buffer,
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uint16_t bufmax);
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enum fscache_checkaux (*check_aux)(void *cookie_netfs_data,
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const void *data,
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uint16_t datalen);
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void (*get_context)(void *cookie_netfs_data, void *context);
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void (*put_context)(void *cookie_netfs_data, void *context);
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void (*mark_pages_cached)(void *cookie_netfs_data,
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struct address_space *mapping,
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struct pagevec *cached_pvec);
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void (*now_uncached)(void *cookie_netfs_data);
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};
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This has the following fields:
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(1) The type of the object [mandatory].
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This is one of the following values:
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(*) FSCACHE_COOKIE_TYPE_INDEX
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This defines an index, which is a special FS-Cache type.
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(*) FSCACHE_COOKIE_TYPE_DATAFILE
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This defines an ordinary data file.
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(*) Any other value between 2 and 255
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This defines an extraordinary object such as an XATTR.
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(2) The name of the object type (NUL terminated unless all 16 chars are used)
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[optional].
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(3) A function to select the cache in which to store an index [optional].
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This function is invoked when an index needs to be instantiated in a cache
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during the instantiation of a non-index object. Only the immediate index
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parent for the non-index object will be queried. Any indices above that
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in the hierarchy may be stored in multiple caches. This function does not
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need to be supplied for any non-index object or any index that will only
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have index children.
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If this function is not supplied or if it returns NULL then the first
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cache in the parent's list will be chosen, or failing that, the first
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cache in the master list.
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(4) A function to retrieve an object's key from the netfs [mandatory].
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This function will be called with the netfs data that was passed to the
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cookie acquisition function and the maximum length of key data that it may
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provide. It should write the required key data into the given buffer and
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return the quantity it wrote.
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(5) A function to retrieve attribute data from the netfs [optional].
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This function will be called with the netfs data that was passed to the
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cookie acquisition function. It should return the size of the file if
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this is a data file. The size may be used to govern how much cache must
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be reserved for this file in the cache.
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If the function is absent, a file size of 0 is assumed.
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(6) A function to retrieve auxiliary data from the netfs [optional].
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This function will be called with the netfs data that was passed to the
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cookie acquisition function and the maximum length of auxiliary data that
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it may provide. It should write the auxiliary data into the given buffer
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and return the quantity it wrote.
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If this function is absent, the auxiliary data length will be set to 0.
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The length of the auxiliary data buffer may be dependent on the key
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length. A netfs mustn't rely on being able to provide more than 400 bytes
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for both.
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(7) A function to check the auxiliary data [optional].
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This function will be called to check that a match found in the cache for
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this object is valid. For instance with AFS it could check the auxiliary
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data against the data version number returned by the server to determine
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whether the index entry in a cache is still valid.
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If this function is absent, it will be assumed that matching objects in a
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cache are always valid.
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If present, the function should return one of the following values:
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(*) FSCACHE_CHECKAUX_OKAY - the entry is okay as is
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(*) FSCACHE_CHECKAUX_NEEDS_UPDATE - the entry requires update
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(*) FSCACHE_CHECKAUX_OBSOLETE - the entry should be deleted
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This function can also be used to extract data from the auxiliary data in
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the cache and copy it into the netfs's structures.
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(8) A pair of functions to manage contexts for the completion callback
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[optional].
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The cache read/write functions are passed a context which is then passed
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to the I/O completion callback function. To ensure this context remains
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valid until after the I/O completion is called, two functions may be
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provided: one to get an extra reference on the context, and one to drop a
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reference to it.
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If the context is not used or is a type of object that won't go out of
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scope, then these functions are not required. These functions are not
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required for indices as indices may not contain data. These functions may
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be called in interrupt context and so may not sleep.
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(9) A function to mark a page as retaining cache metadata [optional].
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This is called by the cache to indicate that it is retaining in-memory
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information for this page and that the netfs should uncache the page when
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it has finished. This does not indicate whether there's data on the disk
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or not. Note that several pages at once may be presented for marking.
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The PG_fscache bit is set on the pages before this function would be
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called, so the function need not be provided if this is sufficient.
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This function is not required for indices as they're not permitted data.
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(10) A function to unmark all the pages retaining cache metadata [mandatory].
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This is called by FS-Cache to indicate that a backing store is being
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unbound from a cookie and that all the marks on the pages should be
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cleared to prevent confusion. Note that the cache will have torn down all
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its tracking information so that the pages don't need to be explicitly
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uncached.
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This function is not required for indices as they're not permitted data.
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===================================
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NETWORK FILESYSTEM (UN)REGISTRATION
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===================================
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The first step is to declare the network filesystem to the cache. This also
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involves specifying the layout of the primary index (for AFS, this would be the
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"cell" level).
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The registration function is:
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int fscache_register_netfs(struct fscache_netfs *netfs);
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It just takes a pointer to the netfs definition. It returns 0 or an error as
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appropriate.
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For kAFS, registration is done as follows:
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ret = fscache_register_netfs(&afs_cache_netfs);
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The last step is, of course, unregistration:
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void fscache_unregister_netfs(struct fscache_netfs *netfs);
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================
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CACHE TAG LOOKUP
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================
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FS-Cache permits the use of more than one cache. To permit particular index
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subtrees to be bound to particular caches, the second step is to look up cache
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representation tags. This step is optional; it can be left entirely up to
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FS-Cache as to which cache should be used. The problem with doing that is that
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FS-Cache will always pick the first cache that was registered.
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To get the representation for a named tag:
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struct fscache_cache_tag *fscache_lookup_cache_tag(const char *name);
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This takes a text string as the name and returns a representation of a tag. It
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will never return an error. It may return a dummy tag, however, if it runs out
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of memory; this will inhibit caching with this tag.
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Any representation so obtained must be released by passing it to this function:
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void fscache_release_cache_tag(struct fscache_cache_tag *tag);
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The tag will be retrieved by FS-Cache when it calls the object definition
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operation select_cache().
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==================
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INDEX REGISTRATION
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==================
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The third step is to inform FS-Cache about part of an index hierarchy that can
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be used to locate files. This is done by requesting a cookie for each index in
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the path to the file:
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struct fscache_cookie *
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fscache_acquire_cookie(struct fscache_cookie *parent,
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const struct fscache_object_def *def,
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void *netfs_data);
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This function creates an index entry in the index represented by parent,
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filling in the index entry by calling the operations pointed to by def.
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Note that this function never returns an error - all errors are handled
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internally. It may, however, return NULL to indicate no cookie. It is quite
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acceptable to pass this token back to this function as the parent to another
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acquisition (or even to the relinquish cookie, read page and write page
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functions - see below).
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Note also that no indices are actually created in a cache until a non-index
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object needs to be created somewhere down the hierarchy. Furthermore, an index
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may be created in several different caches independently at different times.
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This is all handled transparently, and the netfs doesn't see any of it.
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For example, with AFS, a cell would be added to the primary index. This index
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entry would have a dependent inode containing a volume location index for the
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volume mappings within this cell:
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cell->cache =
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fscache_acquire_cookie(afs_cache_netfs.primary_index,
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&afs_cell_cache_index_def,
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cell);
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Then when a volume location was accessed, it would be entered into the cell's
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index and an inode would be allocated that acts as a volume type and hash chain
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combination:
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vlocation->cache =
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fscache_acquire_cookie(cell->cache,
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&afs_vlocation_cache_index_def,
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vlocation);
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And then a particular flavour of volume (R/O for example) could be added to
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that index, creating another index for vnodes (AFS inode equivalents):
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volume->cache =
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fscache_acquire_cookie(vlocation->cache,
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&afs_volume_cache_index_def,
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volume);
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======================
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DATA FILE REGISTRATION
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======================
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The fourth step is to request a data file be created in the cache. This is
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identical to index cookie acquisition. The only difference is that the type in
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the object definition should be something other than index type.
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vnode->cache =
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fscache_acquire_cookie(volume->cache,
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&afs_vnode_cache_object_def,
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vnode);
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=================================
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MISCELLANEOUS OBJECT REGISTRATION
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=================================
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An optional step is to request an object of miscellaneous type be created in
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the cache. This is almost identical to index cookie acquisition. The only
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difference is that the type in the object definition should be something other
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than index type. Whilst the parent object could be an index, it's more likely
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it would be some other type of object such as a data file.
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xattr->cache =
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fscache_acquire_cookie(vnode->cache,
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&afs_xattr_cache_object_def,
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xattr);
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Miscellaneous objects might be used to store extended attributes or directory
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entries for example.
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==========================
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SETTING THE DATA FILE SIZE
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==========================
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The fifth step is to set the physical attributes of the file, such as its size.
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This doesn't automatically reserve any space in the cache, but permits the
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cache to adjust its metadata for data tracking appropriately:
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int fscache_attr_changed(struct fscache_cookie *cookie);
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The cache will return -ENOBUFS if there is no backing cache or if there is no
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space to allocate any extra metadata required in the cache. The attributes
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will be accessed with the get_attr() cookie definition operation.
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Note that attempts to read or write data pages in the cache over this size may
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be rebuffed with -ENOBUFS.
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This operation schedules an attribute adjustment to happen asynchronously at
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some point in the future, and as such, it may happen after the function returns
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to the caller. The attribute adjustment excludes read and write operations.
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=====================
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PAGE READ/ALLOC/WRITE
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=====================
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And the sixth step is to store and retrieve pages in the cache. There are
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three functions that are used to do this.
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Note:
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(1) A page should not be re-read or re-allocated without uncaching it first.
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(2) A read or allocated page must be uncached when the netfs page is released
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from the pagecache.
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|
||
|
(3) A page should only be written to the cache if previous read or allocated.
|
||
|
|
||
|
This permits the cache to maintain its page tracking in proper order.
|
||
|
|
||
|
|
||
|
PAGE READ
|
||
|
---------
|
||
|
|
||
|
Firstly, the netfs should ask FS-Cache to examine the caches and read the
|
||
|
contents cached for a particular page of a particular file if present, or else
|
||
|
allocate space to store the contents if not:
|
||
|
|
||
|
typedef
|
||
|
void (*fscache_rw_complete_t)(struct page *page,
|
||
|
void *context,
|
||
|
int error);
|
||
|
|
||
|
int fscache_read_or_alloc_page(struct fscache_cookie *cookie,
|
||
|
struct page *page,
|
||
|
fscache_rw_complete_t end_io_func,
|
||
|
void *context,
|
||
|
gfp_t gfp);
|
||
|
|
||
|
The cookie argument must specify a cookie for an object that isn't an index,
|
||
|
the page specified will have the data loaded into it (and is also used to
|
||
|
specify the page number), and the gfp argument is used to control how any
|
||
|
memory allocations made are satisfied.
|
||
|
|
||
|
If the cookie indicates the inode is not cached:
|
||
|
|
||
|
(1) The function will return -ENOBUFS.
|
||
|
|
||
|
Else if there's a copy of the page resident in the cache:
|
||
|
|
||
|
(1) The mark_pages_cached() cookie operation will be called on that page.
|
||
|
|
||
|
(2) The function will submit a request to read the data from the cache's
|
||
|
backing device directly into the page specified.
|
||
|
|
||
|
(3) The function will return 0.
|
||
|
|
||
|
(4) When the read is complete, end_io_func() will be invoked with:
|
||
|
|
||
|
(*) The netfs data supplied when the cookie was created.
|
||
|
|
||
|
(*) The page descriptor.
|
||
|
|
||
|
(*) The context argument passed to the above function. This will be
|
||
|
maintained with the get_context/put_context functions mentioned above.
|
||
|
|
||
|
(*) An argument that's 0 on success or negative for an error code.
|
||
|
|
||
|
If an error occurs, it should be assumed that the page contains no usable
|
||
|
data.
|
||
|
|
||
|
end_io_func() will be called in process context if the read is results in
|
||
|
an error, but it might be called in interrupt context if the read is
|
||
|
successful.
|
||
|
|
||
|
Otherwise, if there's not a copy available in cache, but the cache may be able
|
||
|
to store the page:
|
||
|
|
||
|
(1) The mark_pages_cached() cookie operation will be called on that page.
|
||
|
|
||
|
(2) A block may be reserved in the cache and attached to the object at the
|
||
|
appropriate place.
|
||
|
|
||
|
(3) The function will return -ENODATA.
|
||
|
|
||
|
This function may also return -ENOMEM or -EINTR, in which case it won't have
|
||
|
read any data from the cache.
|
||
|
|
||
|
|
||
|
PAGE ALLOCATE
|
||
|
-------------
|
||
|
|
||
|
Alternatively, if there's not expected to be any data in the cache for a page
|
||
|
because the file has been extended, a block can simply be allocated instead:
|
||
|
|
||
|
int fscache_alloc_page(struct fscache_cookie *cookie,
|
||
|
struct page *page,
|
||
|
gfp_t gfp);
|
||
|
|
||
|
This is similar to the fscache_read_or_alloc_page() function, except that it
|
||
|
never reads from the cache. It will return 0 if a block has been allocated,
|
||
|
rather than -ENODATA as the other would. One or the other must be performed
|
||
|
before writing to the cache.
|
||
|
|
||
|
The mark_pages_cached() cookie operation will be called on the page if
|
||
|
successful.
|
||
|
|
||
|
|
||
|
PAGE WRITE
|
||
|
----------
|
||
|
|
||
|
Secondly, if the netfs changes the contents of the page (either due to an
|
||
|
initial download or if a user performs a write), then the page should be
|
||
|
written back to the cache:
|
||
|
|
||
|
int fscache_write_page(struct fscache_cookie *cookie,
|
||
|
struct page *page,
|
||
|
gfp_t gfp);
|
||
|
|
||
|
The cookie argument must specify a data file cookie, the page specified should
|
||
|
contain the data to be written (and is also used to specify the page number),
|
||
|
and the gfp argument is used to control how any memory allocations made are
|
||
|
satisfied.
|
||
|
|
||
|
The page must have first been read or allocated successfully and must not have
|
||
|
been uncached before writing is performed.
|
||
|
|
||
|
If the cookie indicates the inode is not cached then:
|
||
|
|
||
|
(1) The function will return -ENOBUFS.
|
||
|
|
||
|
Else if space can be allocated in the cache to hold this page:
|
||
|
|
||
|
(1) PG_fscache_write will be set on the page.
|
||
|
|
||
|
(2) The function will submit a request to write the data to cache's backing
|
||
|
device directly from the page specified.
|
||
|
|
||
|
(3) The function will return 0.
|
||
|
|
||
|
(4) When the write is complete PG_fscache_write is cleared on the page and
|
||
|
anyone waiting for that bit will be woken up.
|
||
|
|
||
|
Else if there's no space available in the cache, -ENOBUFS will be returned. It
|
||
|
is also possible for the PG_fscache_write bit to be cleared when no write took
|
||
|
place if unforeseen circumstances arose (such as a disk error).
|
||
|
|
||
|
Writing takes place asynchronously.
|
||
|
|
||
|
|
||
|
MULTIPLE PAGE READ
|
||
|
------------------
|
||
|
|
||
|
A facility is provided to read several pages at once, as requested by the
|
||
|
readpages() address space operation:
|
||
|
|
||
|
int fscache_read_or_alloc_pages(struct fscache_cookie *cookie,
|
||
|
struct address_space *mapping,
|
||
|
struct list_head *pages,
|
||
|
int *nr_pages,
|
||
|
fscache_rw_complete_t end_io_func,
|
||
|
void *context,
|
||
|
gfp_t gfp);
|
||
|
|
||
|
This works in a similar way to fscache_read_or_alloc_page(), except:
|
||
|
|
||
|
(1) Any page it can retrieve data for is removed from pages and nr_pages and
|
||
|
dispatched for reading to the disk. Reads of adjacent pages on disk may
|
||
|
be merged for greater efficiency.
|
||
|
|
||
|
(2) The mark_pages_cached() cookie operation will be called on several pages
|
||
|
at once if they're being read or allocated.
|
||
|
|
||
|
(3) If there was an general error, then that error will be returned.
|
||
|
|
||
|
Else if some pages couldn't be allocated or read, then -ENOBUFS will be
|
||
|
returned.
|
||
|
|
||
|
Else if some pages couldn't be read but were allocated, then -ENODATA will
|
||
|
be returned.
|
||
|
|
||
|
Otherwise, if all pages had reads dispatched, then 0 will be returned, the
|
||
|
list will be empty and *nr_pages will be 0.
|
||
|
|
||
|
(4) end_io_func will be called once for each page being read as the reads
|
||
|
complete. It will be called in process context if error != 0, but it may
|
||
|
be called in interrupt context if there is no error.
|
||
|
|
||
|
Note that a return of -ENODATA, -ENOBUFS or any other error does not preclude
|
||
|
some of the pages being read and some being allocated. Those pages will have
|
||
|
been marked appropriately and will need uncaching.
|
||
|
|
||
|
|
||
|
==============
|
||
|
PAGE UNCACHING
|
||
|
==============
|
||
|
|
||
|
To uncache a page, this function should be called:
|
||
|
|
||
|
void fscache_uncache_page(struct fscache_cookie *cookie,
|
||
|
struct page *page);
|
||
|
|
||
|
This function permits the cache to release any in-memory representation it
|
||
|
might be holding for this netfs page. This function must be called once for
|
||
|
each page on which the read or write page functions above have been called to
|
||
|
make sure the cache's in-memory tracking information gets torn down.
|
||
|
|
||
|
Note that pages can't be explicitly deleted from the a data file. The whole
|
||
|
data file must be retired (see the relinquish cookie function below).
|
||
|
|
||
|
Furthermore, note that this does not cancel the asynchronous read or write
|
||
|
operation started by the read/alloc and write functions, so the page
|
||
|
invalidation functions must use:
|
||
|
|
||
|
bool fscache_check_page_write(struct fscache_cookie *cookie,
|
||
|
struct page *page);
|
||
|
|
||
|
to see if a page is being written to the cache, and:
|
||
|
|
||
|
void fscache_wait_on_page_write(struct fscache_cookie *cookie,
|
||
|
struct page *page);
|
||
|
|
||
|
to wait for it to finish if it is.
|
||
|
|
||
|
|
||
|
When releasepage() is being implemented, a special FS-Cache function exists to
|
||
|
manage the heuristics of coping with vmscan trying to eject pages, which may
|
||
|
conflict with the cache trying to write pages to the cache (which may itself
|
||
|
need to allocate memory):
|
||
|
|
||
|
bool fscache_maybe_release_page(struct fscache_cookie *cookie,
|
||
|
struct page *page,
|
||
|
gfp_t gfp);
|
||
|
|
||
|
This takes the netfs cookie, and the page and gfp arguments as supplied to
|
||
|
releasepage(). It will return false if the page cannot be released yet for
|
||
|
some reason and if it returns true, the page has been uncached and can now be
|
||
|
released.
|
||
|
|
||
|
To make a page available for release, this function may wait for an outstanding
|
||
|
storage request to complete, or it may attempt to cancel the storage request -
|
||
|
in which case the page will not be stored in the cache this time.
|
||
|
|
||
|
|
||
|
BULK INODE PAGE UNCACHE
|
||
|
-----------------------
|
||
|
|
||
|
A convenience routine is provided to perform an uncache on all the pages
|
||
|
attached to an inode. This assumes that the pages on the inode correspond on a
|
||
|
1:1 basis with the pages in the cache.
|
||
|
|
||
|
void fscache_uncache_all_inode_pages(struct fscache_cookie *cookie,
|
||
|
struct inode *inode);
|
||
|
|
||
|
This takes the netfs cookie that the pages were cached with and the inode that
|
||
|
the pages are attached to. This function will wait for pages to finish being
|
||
|
written to the cache and for the cache to finish with the page generally. No
|
||
|
error is returned.
|
||
|
|
||
|
|
||
|
==========================
|
||
|
INDEX AND DATA FILE UPDATE
|
||
|
==========================
|
||
|
|
||
|
To request an update of the index data for an index or other object, the
|
||
|
following function should be called:
|
||
|
|
||
|
void fscache_update_cookie(struct fscache_cookie *cookie);
|
||
|
|
||
|
This function will refer back to the netfs_data pointer stored in the cookie by
|
||
|
the acquisition function to obtain the data to write into each revised index
|
||
|
entry. The update method in the parent index definition will be called to
|
||
|
transfer the data.
|
||
|
|
||
|
Note that partial updates may happen automatically at other times, such as when
|
||
|
data blocks are added to a data file object.
|
||
|
|
||
|
|
||
|
===============================
|
||
|
MISCELLANEOUS COOKIE OPERATIONS
|
||
|
===============================
|
||
|
|
||
|
There are a number of operations that can be used to control cookies:
|
||
|
|
||
|
(*) Cookie pinning:
|
||
|
|
||
|
int fscache_pin_cookie(struct fscache_cookie *cookie);
|
||
|
void fscache_unpin_cookie(struct fscache_cookie *cookie);
|
||
|
|
||
|
These operations permit data cookies to be pinned into the cache and to
|
||
|
have the pinning removed. They are not permitted on index cookies.
|
||
|
|
||
|
The pinning function will return 0 if successful, -ENOBUFS in the cookie
|
||
|
isn't backed by a cache, -EOPNOTSUPP if the cache doesn't support pinning,
|
||
|
-ENOSPC if there isn't enough space to honour the operation, -ENOMEM or
|
||
|
-EIO if there's any other problem.
|
||
|
|
||
|
(*) Data space reservation:
|
||
|
|
||
|
int fscache_reserve_space(struct fscache_cookie *cookie, loff_t size);
|
||
|
|
||
|
This permits a netfs to request cache space be reserved to store up to the
|
||
|
given amount of a file. It is permitted to ask for more than the current
|
||
|
size of the file to allow for future file expansion.
|
||
|
|
||
|
If size is given as zero then the reservation will be cancelled.
|
||
|
|
||
|
The function will return 0 if successful, -ENOBUFS in the cookie isn't
|
||
|
backed by a cache, -EOPNOTSUPP if the cache doesn't support reservations,
|
||
|
-ENOSPC if there isn't enough space to honour the operation, -ENOMEM or
|
||
|
-EIO if there's any other problem.
|
||
|
|
||
|
Note that this doesn't pin an object in a cache; it can still be culled to
|
||
|
make space if it's not in use.
|
||
|
|
||
|
|
||
|
=====================
|
||
|
COOKIE UNREGISTRATION
|
||
|
=====================
|
||
|
|
||
|
To get rid of a cookie, this function should be called.
|
||
|
|
||
|
void fscache_relinquish_cookie(struct fscache_cookie *cookie,
|
||
|
int retire);
|
||
|
|
||
|
If retire is non-zero, then the object will be marked for recycling, and all
|
||
|
copies of it will be removed from all active caches in which it is present.
|
||
|
Not only that but all child objects will also be retired.
|
||
|
|
||
|
If retire is zero, then the object may be available again when next the
|
||
|
acquisition function is called. Retirement here will overrule the pinning on a
|
||
|
cookie.
|
||
|
|
||
|
One very important note - relinquish must NOT be called for a cookie unless all
|
||
|
the cookies for "child" indices, objects and pages have been relinquished
|
||
|
first.
|
||
|
|
||
|
|
||
|
================================
|
||
|
INDEX AND DATA FILE INVALIDATION
|
||
|
================================
|
||
|
|
||
|
There is no direct way to invalidate an index subtree or a data file. To do
|
||
|
this, the caller should relinquish and retire the cookie they have, and then
|
||
|
acquire a new one.
|
||
|
|
||
|
|
||
|
===========================
|
||
|
FS-CACHE SPECIFIC PAGE FLAG
|
||
|
===========================
|
||
|
|
||
|
FS-Cache makes use of a page flag, PG_private_2, for its own purpose. This is
|
||
|
given the alternative name PG_fscache.
|
||
|
|
||
|
PG_fscache is used to indicate that the page is known by the cache, and that
|
||
|
the cache must be informed if the page is going to go away. It's an indication
|
||
|
to the netfs that the cache has an interest in this page, where an interest may
|
||
|
be a pointer to it, resources allocated or reserved for it, or I/O in progress
|
||
|
upon it.
|
||
|
|
||
|
The netfs can use this information in methods such as releasepage() to
|
||
|
determine whether it needs to uncache a page or update it.
|
||
|
|
||
|
Furthermore, if this bit is set, releasepage() and invalidatepage() operations
|
||
|
will be called on a page to get rid of it, even if PG_private is not set. This
|
||
|
allows caching to attempted on a page before read_cache_pages() to be called
|
||
|
after fscache_read_or_alloc_pages() as the former will try and release pages it
|
||
|
was given under certain circumstances.
|
||
|
|
||
|
This bit does not overlap with such as PG_private. This means that FS-Cache
|
||
|
can be used with a filesystem that uses the block buffering code.
|
||
|
|
||
|
There are a number of operations defined on this flag:
|
||
|
|
||
|
int PageFsCache(struct page *page);
|
||
|
void SetPageFsCache(struct page *page)
|
||
|
void ClearPageFsCache(struct page *page)
|
||
|
int TestSetPageFsCache(struct page *page)
|
||
|
int TestClearPageFsCache(struct page *page)
|
||
|
|
||
|
These functions are bit test, bit set, bit clear, bit test and set and bit
|
||
|
test and clear operations on PG_fscache.
|