CITI Experience with Directory Delegations

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NOTE: this is a rough work-in-progress; please send criticism to richterd at (nospam) citi.umich.edu thank you.

[2006-8-2: I've added some rough, preliminary numbers of opcounts from doing compiles with/without directory delegations]

Contents

Directory Delegations Background

NFSv4.1 introduces read-only directory delegations, a protocol addition enabling clients to cache more aggressively. More specifically, the goal to allow clients to avoid excess GETATTR, ACCESS, and LOOKUP calls to the server by increasing the reliability of directory entry caching (READDIR), name caching (LOOKUP), and directory metadata caching (ACCESS and GETATTR).

The following quoted subsections are from Section 11 of the NFSv4.1 minor version draft:

NFSv4 client caching behavior

"Directory caching for the NFS version 4 protocol is similar to previous versions. Clients typically cache directory information for a duration determined by the client. At the end of a predefined timeout, the client will query the server to see if the directory has been updated. By caching attributes, clients reduce the number of GETATTR calls made to the server to validate attributes. Furthermore, frequently accessed files and directories, such as the current working directory, have their attributes cached on the client so that some NFS operations can be performed without having to make an RPC call. By caching name and inode information about most recently looked up entries in DNLC (Directory Name Lookup Cache), clients do not need to send LOOKUP calls to the server every time these files are accessed."

NFSv4.1 delegations extensions

"[The NFSv4] caching approach works reasonably well at reducing network traffic in many environments. However, it does not address environments where there are numerous queries for files that do not exist. In these cases of "misses", the client must make RPC calls to the server in order to provide reasonable application semantics and promptly detect the creation of new directory entries. Examples of high miss activity are compilation in software development environments. The current behavior of NFS limits its potential scalability and wide-area sharing effectiveness in these types of environments."

Furthermore, analysis of NFSv3 network traces by Brian Wickman at the University of Michigan (FIXME: need link to a copy of his prelim) show that a surprising amount of NFS traffic is made up of the periodic GETATTRs that clients send when a timeout triggers a cache revalidation.

At CITI, we are implementing directory delegations as described in Section 11 of the minor version draft. (But note that section 11 also describes a directory notification extension that we are ignoring for now.)

(basics re: the operation)

 To support directory delegations, NFSv4.1 adds the operation
 GET_DIR_DELEGATION, with which a client requests a delegation on the current
 directory.  The decision to grant the delegation, however, is solely at the
 server's discretion; for instance, the server may opt to deny the request due
 to resource pressures, frequent revocations of previously granted delegations
 on that directory, or any of a number of other criteria, which we discuss in
 Section X.  
 When a client sends to the server an operation that conflicts with the
 delegation (e.g., deleting a file), the server first sends a callback to all
 clients holding a delegation on the directory, notifying them of the recall.
 The clients must respond to the callback with the DELEGRETURN operation,
 notifying the server of their acknowledgement.  Thereafter, the conflicting
 operation can proceed.  
 It is worth noting that while NFS clients and servers are aware of their
 acquisition and recall, directory delegations are an optimization designed
 to be completely transparent to any higher-level software.

(problems and solutions)

 Common examples of the previously mentioned "high miss" cases involve the PATH
 shell variable and the loading of shared libraries.  When a user executes a
 program, the user's shell examines the list of directories in the PATH
 environment variable and looks for the program binary in each of those
 directories, in turn, until the program is found.  Often there can be 5 to 10
 (or more) PATH entries, and normally a given program binary is in only one of
 those directories.  Even when the client is searching for repeatedly-absent
 files, it must nevertheless check with the server in case they have appeared.
 /*
  * XXX: i'm going to scrap the shared library discussion and use searching
  *  header files' include paths during compilation.  i have good data there.
  */
 A case very similar to the PATH problem exists with loading shared libraries.
 When a dynamically linked binary is executed, the shared libraries upon which
 it depends must be located, which often involves serially checking in
 directories listed in ld.so.conf or in the LD_LIBRARY_PATH.  As with programs
 and PATH, shared libraries are normally located within only one of the search
 directories, which results in a similarly-high miss rate.
 With respect to the PATH and shared library cases (where no directory-mutating
 operations are being performed), directory delegations provide a significant
 advantage.  This stems from "negative dentry caching" -- that is, the caching
 of information about non-existent directory entries.  In the absence of
 directory delegations, if a client attempts to OPEN a non-existent file,
 close-to-open consistency semantics require that the operation be sent to the
 server, regardless of whether the client has a negative dentry cached.
 However, if a client holds a delegation on the directory and has a negative
 dentry stored for the missing file, it can "trust" that the file has not
 appeared, which obviates the need for the OPEN.
 Another example is if a client performs an 'ls' or a 'stat' on a non-existent
 file, three separate RPC calls are made to service an ACCESS, a LOOKUP, and a
 GETATTR -- only to find that the file still does not exist.  If the directory
 were delegated and the client has a negative dentry for the non-existent file,
 however, the client once again is assured that the file has not appeared.
 
 Beyond just these "high miss" cases, analysis of NFSv3 (whose client cache
 revalidation semantics NFSv4 roughly mirrors) network traces by Brian Wickman
 at the University of Michigan shows that a significant amount of NFS traffic
 consists of the periodic GETATTRs which clients send when an attribute timeout
 triggers a cache revalidation.  Naturally, if a directory is delegated, it
 need not be revalidated until the directory is mutated.

Using Directory Delegations

While a client holds a delegation on a directory, it is assured that the directory will not be modified without the delegation first being recalled. The server must delay any operation that modifies a directory until all the clients holding delegations on that directory have returned their delegations.

However, as a special case, the server may allow the client that is modifying a directory to keep its own delegation on that directory. (Obviously, other client's delegations on that directory must still be recalled.)

Note that even though we may permit a client to modify a directory while it holds a read delegation, this is not the same as providing that client with an exclusive (write) delegation; a write delegation would also allow the client to modify the directory locally, and this is explicitly forbidden in section 11 of the minor version draft:

"The delegation is read-only and the client may not make changes to the directory other than by performing NFSv4 operations that modify the directory or the associated file attributes so that the server has knowledge of these changes."

Note that in order to make the special exception that allows a client to modify a directory without recalling its own lease, we must know which client is performing the operation.

Currently we are using the client's IP address for this. However, the NFSv4 protocol does not prohibit the client from changing IP addresses, and does not prohibit multiple clients from sharing an IP address. The final code will instead use the new sessions extensions in NFSv4.1 to identify the client.

Delegations and the Linux VFS Lease Subsystem

We have implemented directory delegations on the server by extending the Linux VFS file lease subsystem. A lease is a type of lock that gives the lease-holder the chance to perform any necessary tasks (e.g., flushing data) when an operation that conflicts with the lease-type is about to occur -- the caller who is causing the lease to break will block until the lease-holder signals that it is finished cleaning-up (or the lease is forcefully broken after a timeout).

The existing lease subsystem only works on files, and leases are only broken when a file is opened for writing or is truncated. In order to implement directory delegations, we have added support for directory leases. These will break when a leased directory is mutated by any additions, deletions, or renames, or when the directory's own metadata changes (e.g., chown(1)). Note that changes to existing files, e.g., will not break directory leases.

Our current implementation modifies the NFS server so that NFS protocol operations will break directory leases. However, it is still possible for a local process on the server to modify a directory without breaking directory leases.

The final implementation will also ensure that operations by local processes break directory leases. This will require addressing some tricky VFS locking issues: the difficulty is that, given that breaking a lease involves blocking the caller, one must ensure that no important locks -- like a directory inode's i_mutex -- are held while the calling kernel thread blocks.

UPDATE

At this point, we are testing general VFS-level directory lease-breaking -- i.e., both NFS and non-NFS operations will break leases. Our approach is described in the next section.

Leases are usually acquired via the fcntl(2) call, and a lease-holder usually receives a signal from the kernel when a lease is being broken; the lease-holder indicates that any cleanup is finished with another fcntl(2) call. NFS leases are all acquired and revoked in-kernel.

Recalling NFS Delegations vs. Breaking Linux VFS (Non-NFS) Leases

In the following I will refer to the leases used to implement delegations as "NFS leases" and all other leases as "non-NFS leases".

NFS leases and non-NFS leases differ in how they handle the case where a lease-holder is also the caller performing an operation that conflicts with the lease-type, as described above.

Any operation that breaks a lease, and hence requires delegation recalls, has to wait for delegations to be returned. There are a number of different ways to do this:

  1. Delay responding to the original operation until all recalls are complete.
  2. Immediately return NFS4ERR_DELAY to the client; the process on the client will then block while the client polls on its behalf.
  3. Delay the response from the server for a little while, to handle the (probably common) case of a quick delegation return, and only return NFS4ERR_DELAY if the delegations aren't returned quickly enough.

For now, we have implemented option number 1.

UPDATE

 The approach we're currently taking to tackle the issues of integrating NFS delegations with Linux VFS leases (i.e., all directory mutating 
 operations, whether locally on the server or over NFS, will break directory leases/delegations on the server) goes something like this:
 
 When breaking a lease where the call is coming over NFS:
 1) During processing, whenever the directory's dentry becomes available (e.g., after a lookup), disable lease-granting for its inode and try         
    break_lease() with O_NONBLOCK.  This will avoid blocking while locks are held, as well as avoid tying up server threads for (potentially)
    long periods.
 
 2) If there was not a lease, finish the operation, re-enable lease-granting on the inode, and we're done.
 
 3) If there was a lease, break_lease() will send the break signal(s) and nfsd will also fail (re-enabling lease-granting on the inode first)
    and the client gets NFS4ERR_DELAY (and should retry).  The downside to this is that a pathological case could arise wherein we break a lease,
    return NFS4ERR_DELAY, then the client retries the operation -- but another client has acquired a lease in the interim, and we could end up 
    with a cycle.
 
 
 When breaking a lease where the call is server-local:
 1) Again, whenever a directory's dentry becomes available, disable lease-granting for its inode.
 
 2) If locks (e.g., an i_mutex) are not held, call break_lease() and, as per normal lease-semantics, block the breaker until leases are returned,
    after which the breaker is unblocked and its operation succeeds.
 
 3) If locks are held, call break_lease() with O_NONBLOCK; we assume the common-case to be that no lease is present.  If break_lease() returns
    -EWOULDBLOCK, drop the locks and call break_lease() and allow it to block.  Once the caller unblocks, restart the operation by reacquiring
    the locks and, e.g., redoing a lookup to make sure the file system object(s) still exist(s).  Since lease-granting was disabled early-on, 
    the operation will succeed in one pass.
 
 4) Regardless of whether 2) or 3) happened, at the end lease-granting is naturally re-enabled for the inode(s) in question.

Negative Caching

One opportunity offered by directory delegations is the chance to significantly extend the usefulness of negative dentry caching on the client. Currently, close-to-open consistency requires that, e.g., all OPENs are sent to the server (i.e., negative caching provides no benefit in that case). With directory delegations, one is assured that no new entries or removals have occurred while a delegation is in-effect; this implies that negative dentries in a delegated directory actually can be "trusted".

This could translate into a marked decrease in the number of unnecessary and repeated checks for non-existent files, e.g. when searching for an executable in PATH or a shared library in LD_LIBRARY_PATH. Knowing just when to acquire those delegations may be a matter to address in client-side policy.


Status

At the moment, working on coming up with reasonably representative tests that show the benefits of directory delegations (in terms of OP-counts); pynfs tests are also being written.

The client

  • The client currently requests a delegation just prior to issuing a READDIR on an undelegated directory, or when it has done "a few" parent directory revalidations and noticed that it hasn't changed during that span.
  • As long as the client has such a delegation, it will generally refrain from issuing ACCESS, GETATTR, and READDIR calls on the directory (see below) ...
  • .. in some cases, though, the client's cache(s) may be deliberately invalidated and require a refresh (e.g., a client creates a file in a directory delegated to it, which won't break its delegation; however, in order to see the file, the client must revalidate its pagecache and send a READDIR on the wire).
  • TODO: get more opcounts! (hosting a webserver's docroot off an nfs mount? PATH or LD_LIBRARY_PATH stuff?)
  • TODO: redo existing opcount tests and instead tally bandwidth savings ...
    • getting real NFSv4 workload network traces would be great -- can you help? (richterd AT citi.umich.edu)
  • When should/can we decide to voluntarily return delegations (other than when we have no more active open-state)?

The server

  • Differentiate between turning file/directory delegations on/off at runtime (done) and enabling/disabling the capability itself (not done; would prevent our client from ever asking for delegations in the first place, independent of its requesting policy).
  • The following NFS operations currently break directory delegations: CREATE, LINK, REMOVE, RENAME, and OPEN(w/create). SETATTR on directories is pending.
  • An NFS SETATTR breaks file delegations when the file size is changing. Breaking on metadata changes is pending.
  • The corresponding VFS-level operations also break delegations and are being tested.
  • How to acknowledge/when to act upon resource pressures? --> e.g., after compiling the linux kernel, a client holds ~750 delegations -- that's like 50KB of state on the server, and nearly as much on the client.
  • TODO: get NFSv2/NFSv3 operations to break (file and directory) delegations at all of the right times, too.
  • TODO: also -- policy, look at dir deleg/file deleg interactions, ..


Some preliminary numbers

We have some very rough numbers in terms of opcounts with vs. without directory (not file) delegations enabled. We used a very naive client policy of simply requesting delegations prior to a READDIR (note that make(1) periodically calls getdents(2) on its own). ACCESS, GETATTR, and LOOKUP are where the real savings are; the other opcounts are just included for context. Again, these numbers are rough, but indicate that compilation environments stand to benefit from directory delegations.

Doing make(1) on cscope-15.5 (first without, then with directory delegations):

READ:            136       124
WRITE:           137       136
OPEN:           1576      1576
ACCESS:         1169       161  (86% reduction)
GETATTR:         903       628  (30% reduction)
LOOKUP:         1494       496  (67% reduction)
GET_DIR_DELEG:               7
DELEGRETURN:                 1

Doing make(1) on the 2.6.16 linux kernel (first without, then with directory delegations):

READ:          19803     19892
WRITE:         21921     21869
OPEN:         497472    494648
ACCESS:        20638      3406  (83.5% reduction)
GETATTR:       41794     24563  (41.0% reduction)
LOOKUP:        45063     17447  (61.3% reduction)
READDIR:        1016       884  (13.0% reduction)
GET_DIR_DELEG:             750
DELEGRETURN:              none
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