Provided by: liblucy-perl_0.3.3-6build1_amd64 
NAME
Lucy::Docs::FileLocking - Manage indexes on shared volumes.
SYNOPSIS
use Sys::Hostname qw( hostname );
my $hostname = hostname() or die "Can't get unique hostname";
my $manager = Lucy::Index::IndexManager->new( host => $hostname );
# Index time:
my $indexer = Lucy::Index::Indexer->new(
index => '/path/to/index',
manager => $manager,
);
# Search time:
my $reader = Lucy::Index::IndexReader->open(
index => '/path/to/index',
manager => $manager,
);
my $searcher = Lucy::Search::IndexSearcher->new( index => $reader );
DESCRIPTION
Normally, index locking is an invisible process. Exclusive write access is controlled via
lockfiles within the index directory and problems only arise if multiple processes attempt
to acquire the write lock simultaneously; search-time processes do not ordinarily require
locking at all.
On shared volumes, however, the default locking mechanism fails, and manual intervention
becomes necessary.
Both read and write applications accessing an index on a shared volume need to identify
themselves with a unique "host" id, e.g. hostname or ip address. Knowing the host id
makes it possible to tell which lockfiles belong to other machines and therefore must not
be removed when the lockfile's pid number appears not to correspond to an active process.
At index-time, the danger is that multiple indexing processes from different machines
which fail to specify a unique "host" id can delete each others' lockfiles and then
attempt to modify the index at the same time, causing index corruption. The search-time
problem is more complex.
Once an index file is no longer listed in the most recent snapshot, Indexer attempts to
delete it as part of a post-commit() cleanup routine. It is possible that at the moment
an Indexer is deleting files which it believes no longer needed, a Searcher referencing an
earlier snapshot is in fact using them. The more often that an index is either updated or
searched, the more likely it is that this conflict will arise from time to time.
Ordinarily, the deletion attempts are not a problem. On a typical unix volume, the files
will be deleted in name only: any process which holds an open filehandle against a given
file will continue to have access, and the file won't actually get vaporized until the
last filehandle is cleared. Thanks to "delete on last close semantics", an Indexer can't
truly delete the file out from underneath an active Searcher. On Windows, where file
deletion fails whenever any process holds an open handle, the situation is different but
still workable: Indexer just keeps retrying after each commit until deletion finally
succeeds.
On NFS, however, the system breaks, because NFS allows files to be deleted out from
underneath active processes. Should this happen, the unlucky read process will crash with
a "Stale NFS filehandle" exception.
Under normal circumstances, it is neither necessary nor desirable for IndexReaders to
secure read locks against an index, but for NFS we have to make an exception.
LockFactory's make_shared_lock() method exists for this reason; supplying an IndexManager
instance to IndexReader's constructor activates an internal locking mechanism using
make_shared_lock() which prevents concurrent indexing processes from deleting files that
are needed by active readers.
Since shared locks are implemented using lockfiles located in the index directory (as are
exclusive locks), reader applications must have write access for read locking to work.
Stale lock files from crashed processes are ordinarily cleared away the next time the same
machine -- as identified by the "host" parameter -- opens another IndexReader. (The
classic technique of timing out lock files is not feasible because search processes may
lie dormant indefinitely.) However, please be aware that if the last thing a given machine
does is crash, lock files belonging to it may persist, preventing deletion of obsolete
index data.