Differences between revisions 4 and 5
Revision 4 as of 2007-04-05 16:40:51
Size: 3077
Editor: ?Eduard Bloch
Revision 5 as of 2007-04-05 16:42:36
Size: 3112
Editor: ?Eduard Bloch
Deletions are marked like this. Additions are marked like this.
Line 65: Line 65:

Currently, following mechanisms can be considered:
=== Advanced Linux-specific locking mechanisms ===
Line 74: Line 73:
    - reliable for a device accessible through one driver
  * reliable for a device accessible through one driver
  * requires kernel 2.6.x (x>=7 or so)

On Locking Schemes on Linux Device Drivers

Hello fellow application developer or maintainer,

recently we (cdrkit and cdrskin developers) came accross increasing problems with reliable and safe device locking. This paper enlightens the issues behind the scenes and presents possible future solutions.


Our original concern is the influence of even read-only operations on optical media drives (recorders) during their duty as recorders -- depending on the device model such read-only work may interrupt the process badly practically destroying the medium.

Since many programs already do act on such devices in an unsafe manner, either willingly (e.g. liblkid) or accidentally (e.g. hald, opening with O_EXCL but still clashing with cdr applications working on the competing sg driver), we see the need for reliable communication in order to ensure proper device locking where appropriate, in a way which is appropriate for the particular application. In the following document, first the currently possible mechanisms are itemized with their advantages and their problems, followed by a draft of a locking scheme which shall cope with the particular requirements and which may be implemented in a library shared by our applications later.

State of the practice

There are various locking techniques used in other areas which are more or less applicable in our case.

General inter-process locking mechanisms

  • Lock files associated with target file Principle: an additional file is created during the action on the real target file. Pros: regular filesystem operation, no additional infrastructure required Cons:
    • Possible races unless OS mechanisms are used for exclusive operation on the lock file, see below
    • The location and name of the lock file need to be known and discussed upfront among all application developers, or be documented excessively
    • Permission problems may disallow the creation of lock files (security issues), especially for self-compiled applications and having no root permissions to install them in a required way
  • fcntl(2) exclusive file locking Principle: lock applied on open file handles. Internally associated with a path, see fcntl(2) for details. Pros:
    • known (POSIX.1-2001), usually reliable mechanism
    • diverges from flock() implementation on Linux, see below. Results in independent locking.
    • possible problems on network file systems
  • flock(2) exclusive file locking Principle: similar to fcntl locks, applied with a different system function. Pros: see fcntl(2) locking above Cons: see fcntl(2) locking above

Advanced Linux-specific locking mechanisms

  • O_EXCL locking
    • Principle: passing of the O_EXCL flag to the open call. The device is locked exclusively for the calling PID, the lock is maintained in the device driver to the particular major/minor combination.
    • reliable for a device accessible through one driver
    • requires kernel 2.6.x (x>=7 or so)