Eric Roseme
2002-Nov-01 23:43 UTC
[Samba] Oplocks Usage Recommendations Whitepaper (with attachment)
Here is Oplocks Usage Recommendations Whitepaper for Samba on HP-UX (originally was written for CIFS/9000 Server on HP-UX). Note that the intended audience is/are HP-UX customers who have questions and concerns about when to configure oplocks. This is intended as a rudimentry guide to help avoid the most obvious oplock pitfalls. Hopefully the plain text alignments hold up well for most editors. Word messes things up. Thanks, Eric Roseme Hewlett-Packard -------------- next part -------------- HP-UX Samba Opportunistic Locking Usage Recommendations Eric Roseme, Hewlett-Packard October, 2002 Contents Legal Notices 2 Chapter 1 Introduction 4 Chapter 2 Opportunistic Locking Overview 5 Chapter 3 Samba Oplock Configuration 7 Chapter 4 Opportunistic Locking Recommendations 9 4.1 Exclusively Accessed Shares 9 4.2 Multiple-Accessed Shares or Files 9 4.3 Unix or NFS Client Accessed Files 10 4.4 Slow and/or Unreliable Networks 10 4.5 Multi-User Databases 10 4.6 PDM Data Shares 10 4.7 Force User 10 4.8 Advanced Samba Opportunistic Locking Parameters 11 4.9 Mission Critical High Availability 11 Chapter 5 Summary 12 Chapter 1 Introduction Samba on HP-UX manages file access among Windows clients with Windows style file locking. It applies a very effective set of file locking features that are managed by the user-space client processes on the server, and provides excellent data security and integrity in a multi-user environment. Samba also integrates some Windows locking protocols with the underlying HP-UX operating system locking protocols, and therefore provides some interoperability with UNIX and NFS style file locking. Opportunistic Locking is a unique Windows file locking feature. It is not really file locking, but is included in most discussions of Windows file locking, so is considered a defacto locking feature. Opportunistic Locking is actually part of the Windows client file caching mechanism. It is not a particularly robust or reliable feature when implemented on the variety of customized networks that exist in enterprise computing, but can be effective in providing modest perceived performance optimization. Like Windows, Samba implements Opportunistic Locking as a server-side component of the client caching mechanism. Because of the lightweight nature of the Windows feature design, effective configuration of Opportunistic Locking requires a good understanding of its limitations, and then applying that understanding when configuring data access for each particular customized network and client usage state. Chapter 2 Opportunistic Locking Overview OPPORTUNISTIC LOCKING (Oplocks) is invoked by the Windows file system (as opposed to an API) via registry entries (on the server AND client) for the purpose of enhancing network performance when accessing a file residing on a server. Performance is enhanced by caching the file locally on the client which allows: Read-ahead: The client reads the local copy of the file, eliminating network latency Write caching: The client writes to the local copy of the file, eliminating network latency Lock caching: The client caches application locks locally, eliminating network latency The performance enhancement of oplocks is due to the opportunity of exclusive access to the file - even if it is opened with deny-none - because Windows monitors the file's status for concurrent access from other processes. Windows defines 4 kinds of Oplocks: Level1 Oplock - The redirector sees that the file was opened with deny none (allowing concurrent access), verifies that no other process is accessing the file, checks that oplocks are enabled, then grants deny-all/read-write/ex- clusive access to the file. The client now performs operations on the cached local file. If a second process attempts to open the file, the open is deferred while the redirector "breaks" the original oplock. The oplock break signals the caching client to write the local file back to the server, flush the local locks, and discard read-ahead data. The break is then complete, the deferred open is granted, and the multiple processes can enjoy concurrent file access as dictated by mandatory or byte-range locking options. However, if the original opening process opened the file with a share mode other than deny-none, then the second process is granted limited or no access, despite the oplock break. Level2 Oplock - Performs like a level1 oplock, except caching is only operative for reads. All other operations are performed on the server disk copy of the file. Filter Oplock - Does not allow write or delete file access. Batch Oplock - Manipulates file openings and closings - allows caching of file attributes. An important detail is that oplocks are invoked by the file system, not an application API. Therefore, an application can close an oplocked file, but the file system does not relinquish the oplock. When the oplock break is issued, the file system then simply closes the file in preparation for the subsequent open by the second process. Chapter 3 CIFS/9000 Oplock Configuration OPPORTUNISTIC LOCKING (Oplocks) is implemented by Samba on a per-share basis in the smb.conf file. Oplocks are enabled by default for each share, which allows the Windows client to cache a local copy of a file for: Read-ahead Write-caching Lock caching *Oplocks*are disabled on a per-share basis in the smb.conf file: [share_name] oplocks = no The default is "yes". The default oplock type is Level1. *Level2 Oplocks* are enabled on a per-share basis in the smb.conf file: [share_name] level2 oplocks = yes The default is "no". Oplocks must also be set to "yes" for the Level2 oplock parameter to function. *Kernel oplocks* is a Samba smb.conf parameter that notifies Samba (if the UNIX kernel has the capability to send a Windows client an oplock break) when a UNIX process is attempting to open the file that is cached. This parameter addresses sharing files between UNIX and Windows with Oplocks enabled on the Samba server: the UNIX process can open the file that is Oplocked (cached) by the Windows client and the smbd process will not send an oplock break, which exposes the file to the risk of data corruption. If the UNIX kernel has the ability to send an oplock break, then the kernel oplocks parameter enables Samba to send the oplock break. Kernel oplocks are enabled on a per-server basis in the smb.conf file. [global] kernel oplocks = yes The default is "no". *Veto oplocks* is a smb.conf parameter that identifies specific files for which Oplocks are disabled. When a Windows client opens a file that has been configured for veto oplocks, the client will not be granted the oplock, and all operations will be executed on the original file on disk instead of a client-cached file copy. By explicitly identifying files that are shared with UNIX processes, and disabling oplocks for those files, the server-wide Oplock configuration can be enabled to allow Windows clients to utilize the performance benefit of file caching without the risk of data corruption. Veto Oplocks can be enabled on a per-share basis, or globally for the entire server, in the smb.conf file: [global] veto oplock files = /filename.htm/*.txt/ [share_name] veto oplock files = /*.exe/filename.ext/ *Oplock break wait time" is a smb.conf parameter that adjusts the time interval for Samba to reply to an oplock break request. Samba recommends "DO NOT CHANGE THIS PARAMETER UNLESS YOU HAVE READ AND UNDERSTOOD THE SAMBA OPLOCK CODE." Oplock Break Wait Time can only be configured globally in the smb.conf file: [global] oplock break wait time = 0 (default) *Oplock break contention limit* is a smb.conf parameter that limits the response of the Samba server to grant an oplock if the configured number of contending clients reaches the limit specified by the parameter. Samba recommends "DO NOT CHANGE THIS PARAMETER UNLESS YOU HAVE READ AND UNDERSTOOD THE SAMBA OPLOCK CODE." Oplock Break Contention Limit can be enable on a per-share basis, or globally for the entire server, in the smb.conf file. [global] oplock break contention limit = 2 (default) [share_name] oplock break contention limit = 2 (default) Chapter 4 Opportunistic Locking Recommendations Opportunistic locking is a desirable feature when it can enhance the perceived performance of a networked client. However, the opportunistic locking protocol is not robust, and therefore can encounter problems when invoked beyond a simplistic configuration, or on extended, slow, or faulty networks. In these cases, operating system management of opportunistic locking and/or recovering from repetitive errors can offset the perceived performance advantage that it is intended to provide. "Opportunistic Locking" is actually an improper name for this feature. The true benefit of this feature is client-side data caching, and oplocks is merely a notification mechanism for writing data back to the networked storage disk. The limitation of opportunistic locking is the reliability of the mechanism to process an oplock break (notification) between the server and the caching client. If this exchange is faulty (usually due to timing out for any number of reasons) then the client-side caching benefit is negated. The actual decision that a user or administrator should consider is whether it is sensible to share amongst multiple users data that will be cached locally on a client. In many cases the answer is no. Deciding when to cache or not cache data is the real question, and thus "opportunistic locking" should be treated as a toggle for client-side caching. Turn it "ON" when client-side caching is desirable and reliable. Turn it "OFF" when client-side caching is redundant, unreliable, or counter-productive. Opportunistic locking is by default set to "on" by Samba on all configured shares, so careful attention should be given to each case to determine if the potential benefit is worth the potential for delays. The following recommendations will help to characterize the environment where opportunistic locking may be effectively configured. 4.1 Exclusively Accessed Shares Opportunistic locking is most effective when it is confined to shares that are exclusively accessed by a single user, or by only one user at a time. Because the true value of opportunistic locking is the local client caching of data, any operation that interrupts the caching mechanism will cause a delay. Home directories are the most obvious examples of where the performance benefit of opportunistic locking can be safely realized. 4.2 Multiple-Accessed Shares or Files As each additional user accesses a file in a share with opportunistic locking enabled, the potential for delays and resulting perceived poor performance increases. When multiple users are accessing a file on a share that has oplocks enabled, the management impact of sending and receiving oplock breaks, and the resulting latency while other clients wait for the caching client to flush data, offset the performance gains of the caching user. As each additional client attempts to access a file with oplocks set, the potential performance improvement is negated and eventually results in a performance bottleneck. 4.3 Unix or NFS Client Accessed Files Local HP-UX (Unix) and NFS clients access files without a mandatory file locking mechanism. Thus, these client platforms are incapable of initiating an oplock break request from the server to a Windows client that has a file cached. Local HP-UX or NFS file access can therefore write to a file that has been cached by a Windows client, which exposes the file to likely data corruption. If files are shared between Windows clients, and either local HP-UX (Unix) or NFS users, then turn opportunistic locking off. 4.4 Slow and/or Unreliable Networks The biggest potential performance improvement for opportunistic locking occurs when the client-side caching of reads and writes delivers the most differential over sending those reads and writes over the wire. This is most likely to occur when the network is extremely slow, congested, or distributed (as in a WAN). However, network latency also has a very high impact on the reliability of the oplock break mechanism, and thus increases the likelihood of encountering oplock problems that more than offset the potential perceived performance gain. Of course, if an oplock break never has to be sent, then this is the most advantageous scenario to utilize opportunistic locking. If the network is slow, unreliable, or a WAN, then do not configure opportunistic locking if there is any chance of multiple users regularly opening the same file. 4.5 Multi-User Databases Multi-user databases clearly pose a risk due to their very nature - they are typically heavily accessed by numerous users at random intervals. Placing a multi-user database on a share with opportunistic locking enabled will likely result in a locking management bottleneck on the Samba server. Whether the database application is developed in-house or a commercially available product, ensure that the share has opportunistic locking disabled. 4.6 PDM Data Shares Process Data Management (PDM) applications such as IMAN, Enovia, and Clearcase, are increasing in usage with Windows client platforms, and therefore SMB data stores. PDM applications manage multi-user environments for critical data security and access. The typical PDM environment is usually associated with sophisticated client design applications that will load data locally as demanded. In addition, the PDM application will usually monitor the data-state of each client. In this case, client-side data caching is best left to the local application and PDM server to negotiate and maintain. It is appropriate to eliminate the client OS from any caching tasks, and the server from any oplock management, by disabling opportunistic locking on the share. 4.7 Force User Samba includes an smb.conf parameter called "force user" that changes the user accessing a share from the incoming user to whatever user is defined by the smb.conf variable. If opportunistic locking is enabled on a share, the change in user access causes an oplock break to be sent to the client, even if the user has not explicitly loaded a file. In cases where the network is slow or unreliable, an oplock break can become lost without the user even accessing a file. This can cause apparent performance degradation as the client continually reconnects to overcome the lost oplock break. So avoid the following combination: * "force user" in smb.conf share configuration, and * Slow or unreliable networks, and * Opportunistic locking 4.8 Advanced Samba Opportunistic Locking Parameters Samba provides opportunistic locking parameters that allow the administrator to adjust various properties of the oplock mechanism to account for timing and usage levels. These parameters provide good versatility for implementing oplocks in environments where they would likely cause problems. The parameters are: * oplock break wait time * oplock contention limit For most users, administrators, and environments, if these parameters are required, then the better option is to simply turn oplocks off. The samba SWAT help text for both parameters reads "DO NOT CHANGE THIS PARAMETER UNLESS YOU HAVE READ AND UNDERSTOOD THE SAMBA OPLOCK CODE." This is good advice. 4.9 Mission Critical High Availability In mission critical high availability environments, data integrity is often a priority. Complex and expensive configurations are implemented to ensure that if a client loses connectivity with a file server, a failover replacement will be available immediately to provide continuous data availability. Windows client failover behavior is more at risk of application interruption than other platforms because it is dependant upon an established TCP transport connection. If the connection is interrupted - as in a file server failover - a new session must be established. It is rare for Windows client applications to be coded to recover correctly from a transport connection loss, therefore most applications will experience some sort of interruption - at worst, abort and require restarting. If a client session has been caching writes and reads locally due to opportunistic locking, it is likely that the data will be lost when the application restarts, or recovers from the TCP interrupt. When the TCP connection drops, the client state is lost. When the file server recovers, an oplock break is not sent to the client. In this case, the work from the prior session is lost. Observing this scenario with oplocks disabled, and the client was writing data to the file server real-time, then the failover will provide the data on disk as it existed at the time of the disconnect. In mission critical high availability environments, careful attention should be given to opportunistic locking. Ideally, comprehensive testing should be done with all affected applications with oplocks enabled and disabled. Chapter 5 Summary Windows Opportunistic Locking is a lightweight performance-enhancing feature. It is not a robust and reliable protocol. Every implementation of Opportunistic Locking should be evaluated as a tradeoff between perceived performance and reliability. Reliability decreases as each successive rule above is not enforced. Consider a share with oplocks enabled, over a wide area network, to a client on a South Pacific atoll, on a high-availability server, serving a mission-critical multi-user corporate database, during a tropical storm. This configuration will likely encounter problems with oplocks. Oplocks can be beneficial to perceived client performance when treated as a configuration toggle for client-side data caching. If the data caching is likely to be interrupted, then oplock usage should be reviewed. Samba enables opportunistic locking by default on all shares. Careful attention should be given to the client usage of shared data on the server, the server network reliability, and the opportunistic locking configuration of each share.