General Filesystem Caching

Overview

This facility is a general purpose cache for network filesystems, though it could be used for caching other things such as ISO9660 filesystems too.

FS-Cache mediates between cache backends (such as CacheFS) and network filesystems:

+---------+
|         |                        +--------------+
|   NFS   |--+                     |              |
|         |  |                 +-->|   CacheFS    |
+---------+  |   +----------+  |   |  /dev/hda5   |
             |   |          |  |   +--------------+
+---------+  +-->|          |  |
|         |      |          |--+
|   AFS   |----->| FS-Cache |
|         |      |          |--+
+---------+  +-->|          |  |
             |   |          |  |   +--------------+
+---------+  |   +----------+  |   |              |
|         |  |                 +-->|  CacheFiles  |
|  ISOFS  |--+                     |  /var/cache  |
|         |                        +--------------+
+---------+

Or to look at it another way, FS-Cache is a module that provides a caching facility to a network filesystem such that the cache is transparent to the user:

+---------+
|         |
| Server  |
|         |
+---------+
     |                  NETWORK
~~~~~|~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
     |
     |           +----------+
     V           |          |
+---------+      |          |
|         |      |          |
|   NFS   |----->| FS-Cache |
|         |      |          |--+
+---------+      |          |  |   +--------------+   +--------------+
     |           |          |  |   |              |   |              |
     V           +----------+  +-->|  CacheFiles  |-->|  Ext3        |
+---------+                        |  /var/cache  |   |  /dev/sda6   |
|         |                        +--------------+   +--------------+
|   VFS   |                                ^                     ^
|         |                                |                     |
+---------+                                +--------------+      |
     |                  KERNEL SPACE                      |      |
~~~~~|~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~|~~~~~~|~~~~
     |                  USER SPACE                        |      |
     V                                                    |      |
+---------+                                           +--------------+
|         |                                           |              |
| Process |                                           | cachefilesd  |
|         |                                           |              |
+---------+                                           +--------------+

FS-Cache does not follow the idea of completely loading every netfs file opened in its entirety into a cache before permitting it to be accessed and then serving the pages out of that cache rather than the netfs inode because:

  1. It must be practical to operate without a cache.

  2. The size of any accessible file must not be limited to the size of the cache.

  3. The combined size of all opened files (this includes mapped libraries) must not be limited to the size of the cache.

  4. The user should not be forced to download an entire file just to do a one-off access of a small portion of it (such as might be done with the “file” program).

It instead serves the cache out in PAGE_SIZE chunks as and when requested by the netfs(‘s) using it.

FS-Cache provides the following facilities:

  1. More than one cache can be used at once. Caches can be selected explicitly by use of tags.

  2. Caches can be added / removed at any time.

  3. The netfs is provided with an interface that allows either party to withdraw caching facilities from a file (required for (2)).

  4. The interface to the netfs returns as few errors as possible, preferring rather to let the netfs remain oblivious.

  5. Cookies are used to represent indices, files and other objects to the netfs. The simplest cookie is just a NULL pointer - indicating nothing cached there.

  6. The netfs is allowed to propose - dynamically - any index hierarchy it desires, though it must be aware that the index search function is recursive, stack space is limited, and indices can only be children of indices.

  7. Data I/O is done direct to and from the netfs’s pages. The netfs indicates that page A is at index B of the data-file represented by cookie C, and that it should be read or written. The cache backend may or may not start I/O on that page, but if it does, a netfs callback will be invoked to indicate completion. The I/O may be either synchronous or asynchronous.

  8. Cookies can be “retired” upon release. At this point FS-Cache will mark them as obsolete and the index hierarchy rooted at that point will get recycled.

  9. The netfs provides a “match” function for index searches. In addition to saying whether a match was made or not, this can also specify that an entry should be updated or deleted.

  1. As much as possible is done asynchronously.

FS-Cache maintains a virtual indexing tree in which all indices, files, objects and pages are kept. Bits of this tree may actually reside in one or more caches:

                                           FSDEF
                                             |
                        +------------------------------------+
                        |                                    |
                       NFS                                  AFS
                        |                                    |
           +--------------------------+                +-----------+
           |                          |                |           |
        homedir                     mirror          afs.org   redhat.com
           |                          |                            |
     +------------+           +---------------+              +----------+
     |            |           |               |              |          |
   00001        00002       00007           00125        vol00001   vol00002
     |            |           |               |                         |
 +---+---+     +-----+      +---+      +------+------+            +-----+----+
 |   |   |     |     |      |   |      |      |      |            |     |    |
PG0 PG1 PG2   PG0  XATTR   PG0 PG1   DIRENT DIRENT DIRENT        R/W   R/O  Bak
                     |                                            |
                    PG0                                       +-------+
                                                              |       |
                                                            00001   00003
                                                              |
                                                          +---+---+
                                                          |   |   |
                                                         PG0 PG1 PG2

In the example above, you can see two netfs’s being backed: NFS and AFS. These have different index hierarchies:

  • The NFS primary index contains per-server indices. Each server index is indexed by NFS file handles to get data file objects. Each data file objects can have an array of pages, but may also have further child objects, such as extended attributes and directory entries. Extended attribute objects themselves have page-array contents.

  • The AFS primary index contains per-cell indices. Each cell index contains per-logical-volume indices. Each of volume index contains up to three indices for the read-write, read-only and backup mirrors of those volumes. Each of these contains vnode data file objects, each of which contains an array of pages.

The very top index is the FS-Cache master index in which individual netfs’s have entries.

Any index object may reside in more than one cache, provided it only has index children. Any index with non-index object children will be assumed to only reside in one cache.

The netfs API to FS-Cache can be found in:

The cache backend API to FS-Cache can be found in:

A description of the internal representations and object state machine can be found in:

Statistical Information

If FS-Cache is compiled with the following options enabled:

CONFIG_FSCACHE_STATS=y
CONFIG_FSCACHE_HISTOGRAM=y

then it will gather certain statistics and display them through a number of proc files.

/proc/fs/fscache/stats

This shows counts of a number of events that can happen in FS-Cache:

CLASS

EVENT

MEANING

Cookies

idx=N

Number of index cookies allocated

dat=N

Number of data storage cookies allocated

spc=N

Number of special cookies allocated

Objects

alc=N

Number of objects allocated

nal=N

Number of object allocation failures

avl=N

Number of objects that reached the available state

ded=N

Number of objects that reached the dead state

ChkAux

non=N

Number of objects that didn’t have a coherency check

ok=N

Number of objects that passed a coherency check

upd=N

Number of objects that needed a coherency data update

obs=N

Number of objects that were declared obsolete

Pages

mrk=N unc=N

Number of pages marked as being cached Number of uncache page requests seen

Acquire

n=N

Number of acquire cookie requests seen

nul=N

Number of acq reqs given a NULL parent

noc=N

Number of acq reqs rejected due to no cache available

ok=N

Number of acq reqs succeeded

nbf=N

Number of acq reqs rejected due to error

oom=N

Number of acq reqs failed on ENOMEM

Lookups

n=N

Number of lookup calls made on cache backends

neg=N

Number of negative lookups made

pos=N

Number of positive lookups made

crt=N

Number of objects created by lookup

tmo=N

Number of lookups timed out and requeued

Updates

n=N

Number of update cookie requests seen

nul=N

Number of upd reqs given a NULL parent

run=N

Number of upd reqs granted CPU time

Relinqs

n=N

Number of relinquish cookie requests seen

nul=N

Number of rlq reqs given a NULL parent

wcr=N

Number of rlq reqs waited on completion of creation

AttrChg

n=N

Number of attribute changed requests seen

ok=N

Number of attr changed requests queued

nbf=N

Number of attr changed rejected -ENOBUFS

oom=N

Number of attr changed failed -ENOMEM

run=N

Number of attr changed ops given CPU time

Allocs

n=N

Number of allocation requests seen

ok=N

Number of successful alloc reqs

wt=N

Number of alloc reqs that waited on lookup completion

nbf=N

Number of alloc reqs rejected -ENOBUFS

int=N

Number of alloc reqs aborted -ERESTARTSYS

ops=N

Number of alloc reqs submitted

owt=N

Number of alloc reqs waited for CPU time

abt=N

Number of alloc reqs aborted due to object death

Retrvls

n=N

Number of retrieval (read) requests seen

ok=N

Number of successful retr reqs

wt=N

Number of retr reqs that waited on lookup completion

nod=N

Number of retr reqs returned -ENODATA

nbf=N

Number of retr reqs rejected -ENOBUFS

int=N

Number of retr reqs aborted -ERESTARTSYS

oom=N

Number of retr reqs failed -ENOMEM

ops=N

Number of retr reqs submitted

owt=N

Number of retr reqs waited for CPU time

abt=N

Number of retr reqs aborted due to object death

Stores

n=N

Number of storage (write) requests seen

ok=N

Number of successful store reqs

agn=N

Number of store reqs on a page already pending storage

nbf=N

Number of store reqs rejected -ENOBUFS

oom=N

Number of store reqs failed -ENOMEM

ops=N

Number of store reqs submitted

run=N

Number of store reqs granted CPU time

pgs=N

Number of pages given store req processing time

rxd=N

Number of store reqs deleted from tracking tree

olm=N

Number of store reqs over store limit

VmScan

nos=N

Number of release reqs against pages with no pending store

gon=N

Number of release reqs against pages stored by time lock granted

bsy=N

Number of release reqs ignored due to in-progress store

can=N

Number of page stores cancelled due to release req

Ops

pend=N

Number of times async ops added to pending queues

run=N

Number of times async ops given CPU time

enq=N

Number of times async ops queued for processing

can=N

Number of async ops cancelled

rej=N

Number of async ops rejected due to object lookup/create failure

ini=N

Number of async ops initialised

dfr=N

Number of async ops queued for deferred release

rel=N

Number of async ops released (should equal ini=N when idle)

gc=N

Number of deferred-release async ops garbage collected

CacheOp

alo=N

Number of in-progress alloc_object() cache ops

luo=N

Number of in-progress lookup_object() cache ops

luc=N

Number of in-progress lookup_complete() cache ops

gro=N

Number of in-progress grab_object() cache ops

upo=N

Number of in-progress update_object() cache ops

dro=N

Number of in-progress drop_object() cache ops

pto=N

Number of in-progress put_object() cache ops

syn=N

Number of in-progress sync_cache() cache ops

atc=N

Number of in-progress attr_changed() cache ops

rap=N

Number of in-progress read_or_alloc_page() cache ops

ras=N

Number of in-progress read_or_alloc_pages() cache ops

alp=N

Number of in-progress allocate_page() cache ops

als=N

Number of in-progress allocate_pages() cache ops

wrp=N

Number of in-progress write_page() cache ops

ucp=N

Number of in-progress uncache_page() cache ops

dsp=N

Number of in-progress dissociate_pages() cache ops

CacheEv

nsp=N

Number of object lookups/creations rejected due to lack of space

stl=N

Number of stale objects deleted

rtr=N

Number of objects retired when relinquished

cul=N

Number of objects culled

/proc/fs/fscache/histogram

cat /proc/fs/fscache/histogram
JIFS  SECS  OBJ INST  OP RUNS   OBJ RUNS  RETRV DLY RETRIEVLS
===== ===== ========= ========= ========= ========= =========

This shows the breakdown of the number of times each amount of time between 0 jiffies and HZ-1 jiffies a variety of tasks took to run. The columns are as follows:

COLUMN

TIME MEASUREMENT

OBJ INST

Length of time to instantiate an object

OP RUNS

Length of time a call to process an operation took

OBJ RUNS

Length of time a call to process an object event took

RETRV DLY

Time between an requesting a read and lookup completing

RETRIEVLS

Time between beginning and end of a retrieval

Each row shows the number of events that took a particular range of times. Each step is 1 jiffy in size. The JIFS column indicates the particular jiffy range covered, and the SECS field the equivalent number of seconds.

Object List

If CONFIG_FSCACHE_OBJECT_LIST is enabled, the FS-Cache facility will maintain a list of all the objects currently allocated and allow them to be viewed through:

/proc/fs/fscache/objects

This will look something like:

[root@andromeda ~]# head /proc/fs/fscache/objects
OBJECT   PARENT   STAT CHLDN OPS OOP IPR EX READS EM EV F S | NETFS_COOKIE_DEF TY FL NETFS_DATA       OBJECT_KEY, AUX_DATA
======== ======== ==== ===== === === === == ===== == == = = | ================ == == ================ ================
   17e4b        2 ACTV     0   0   0   0  0     0 7b  4 0 0 | NFS.fh           DT  0 ffff88001dd82820 010006017edcf8bbc93b43298fdfbe71e50b57b13a172c0117f38472, e567634700000000000000000000000063f2404a000000000000000000000000c9030000000000000000000063f2404a
   1693a        2 ACTV     0   0   0   0  0     0 7b  4 0 0 | NFS.fh           DT  0 ffff88002db23380 010006017edcf8bbc93b43298fdfbe71e50b57b1e0162c01a2df0ea6, 420ebc4a000000000000000000000000420ebc4a0000000000000000000000000e1801000000000000000000420ebc4a

where the first set of columns before the ‘|’ describe the object:

COLUMN

DESCRIPTION

OBJECT

Object debugging ID (appears as OBJ%x in some debug messages)

PARENT

Debugging ID of parent object

STAT

Object state

CHLDN

Number of child objects of this object

OPS

Number of outstanding operations on this object

OOP

Number of outstanding child object management operations

IPR

EX

Number of outstanding exclusive operations

READS

Number of outstanding read operations

EM

Object’s event mask

EV

Events raised on this object

F

Object flags

S

Object work item busy state mask (1:pending 2:running)

and the second set of columns describe the object’s cookie, if present:

COLUMN

DESCRIPTION

NETFS_COOKIE_DEF

Name of netfs cookie definition

TY

Cookie type (IX - index, DT - data, hex - special)

FL

Cookie flags

NETFS_DATA

Netfs private data stored in the cookie

OBJECT_KEY

Object key } 1 column, with separating comma

AUX_DATA

Object aux data } presence may be configured

The data shown may be filtered by attaching the a key to an appropriate keyring before viewing the file. Something like:

keyctl add user fscache:objlist <restrictions> @s

where <restrictions> are a selection of the following letters:

K

Show hexdump of object key (don’t show if not given)

A

Show hexdump of object aux data (don’t show if not given)

and the following paired letters:

C

Show objects that have a cookie

c

Show objects that don’t have a cookie

B

Show objects that are busy

b

Show objects that aren’t busy

W

Show objects that have pending writes

w

Show objects that don’t have pending writes

R

Show objects that have outstanding reads

r

Show objects that don’t have outstanding reads

S

Show objects that have work queued

s

Show objects that don’t have work queued

If neither side of a letter pair is given, then both are implied. For example:

keyctl add user fscache:objlist KB @s

shows objects that are busy, and lists their object keys, but does not dump their auxiliary data. It also implies “CcWwRrSs”, but as ‘B’ is given, ‘b’ is not implied.

By default all objects and all fields will be shown.

Debugging

If CONFIG_FSCACHE_DEBUG is enabled, the FS-Cache facility can have runtime debugging enabled by adjusting the value in:

/sys/module/fscache/parameters/debug

This is a bitmask of debugging streams to enable:

BIT

VALUE

STREAM

POINT

0

1

Cache management

Function entry trace

1

2

Function exit trace

2

4

General

3

8

Cookie management

Function entry trace

4

16

Function exit trace

5

32

General

6

64

Page handling

Function entry trace

7

128

Function exit trace

8

256

General

9

512

Operation management

Function entry trace

10

1024

Function exit trace

11

2048

General

The appropriate set of values should be OR’d together and the result written to the control file. For example:

echo $((1|8|64)) >/sys/module/fscache/parameters/debug

will turn on all function entry debugging.