NAME IPC::Shareable - Use shared memory backed variables across processes SYNOPSIS use IPC::Shareable qw(:lock); my $href = IPC::Shareable->new(%options); # ...or tie SCALAR, 'IPC::Shareable', OPTIONS; tie ARRAY, 'IPC::Shareable', OPTIONS; tie HASH, 'IPC::Shareable', OPTIONS; (tied VARIABLE)->lock; (tied VARIABLE)->unlock; (tied VARIABLE)->lock(LOCK_SH|LOCK_NB) or print "Resource unavailable\n"; my $segment = (tied VARIABLE)->seg; my $semaphore = (tied VARIABLE)->sem; (tied VARIABLE)->remove; IPC::Shareable->clean_up; IPC::Shareable->clean_up_all; # Ensure only one instance of a script can be run at any time IPC::Shareable->singleton('UNIQUE SCRIPT LOCK STRING'); DESCRIPTION IPC::Shareable allows you to tie a variable to shared memory making it easy to share the contents of that variable with other Perl processes and scripts. Scalars, arrays, hashes and even objects can be tied. The variable being tied may contain arbitrarily complex data structures - including references to arrays, hashes of hashes, etc. The association between variables in distinct processes is provided by GLUE (aka "key"). This is any arbitrary string or integer that serves as a common identifier for data across process space. Hence the statement: tie my $scalar, 'IPC::Shareable', { key => 'GLUE STRING', create => 1 }; ...in program one and the statement tie my $variable, 'IPC::Shareable', { key => 'GLUE STRING' }; ...in program two will create and bind $scalar the shared memory in program one and bind it to $variable in program two. There is no pre-set limit to the number of processes that can bind to data; nor is there a pre-set limit to the complexity of the underlying data of the tied variables. The amount of data that can be shared within a single bound variable is limited by the system's maximum size for a shared memory segment (the exact value is system-dependent). The bound data structures are all linearized (using Raphael Manfredi's Storable module or optionally JSON) before being slurped into shared memory. Upon retrieval, the original format of the data structure is recovered. Semaphore flags can be used for locking data between competing processes. OPTIONS Options are specified by passing a reference to a hash as the third argument to the tie() function that enchants a variable. The following fields are recognized in the options hash: key key is the GLUE that is a direct reference to the shared memory segment that's to be tied to the variable. If this option is missing, we'll default to using IPC_PRIVATE. This default key will not allow sharing of the variable between processes. Default: IPC_PRIVATE create create is used to control whether the process creates a new shared memory segment or not. If create is set to a true value, IPC::Shareable will create a new binding associated with GLUE as needed. If create is false, IPC::Shareable will not attempt to create a new shared memory segment associated with GLUE. In this case, a shared memory segment associated with GLUE must already exist or we'll croak(). Defult: false exclusive If exclusive field is set to a true value, we will croak() if the data binding associated with GLUE already exists. If set to a false value, calls to tie() will succeed even if a shared memory segment associated with GLUE already exists. See "graceful" for a silent, non-exception exit if a second process attempts to obtain an in-use exclusive segment. Default: false graceful If exclusive is set to a true value, we normally croak() if a second process attempts to obtain the same shared memory segment. Set graceful to true and we'll exit silently and gracefully. This option does nothing if exclusive isn't set. Useful for ensuring only a single process is running at a time. Default: false warn When set to a true value, graceful will output a warning if there are process collisions. Default: false mode The mode argument is an octal number specifying the access permissions when a new data binding is being created. These access permission are the same as file access permissions in that 0666 is world readable, 0600 is readable only by the effective UID of the process creating the shared variable, etc. Default: 0666 (world read and writeable) size This field may be used to specify the size of the shared memory segment allocated. The maximum size we allow by default is ~1GB. See the "limit" option to override this default. Default: IPC::Shareable::SHM_BUFSIZ() (ie. 65536) limit This field will allow you to set a segment size larger than the default maximum which is 1,073,741,824 bytes (approximately 1 GB). If set, we will croak() if a size specified is larger than the maximum. If it's set to a false value, we'll croak() if you send in a size larger than the total system RAM. Default: true destroy If set to a true value, the shared memory segment underlying the data binding will be removed when the process that initialized the shared memory segment exits (gracefully)[1]. Only those memory segments that were created by the current process will be removed. Use this option with care. In particular you should not use this option in a program that will fork after binding the data. On the other hand, shared memory is a finite resource and should be released if it is not needed. Default: false tidy For long running processes, set this to a true value to clean up unneeded segments from nested data structures. Comes with a slight performance hit. Default: false serializer By default, we use Storable as the data serializer when writing to or reading from the shared memory segments we create. For cross-platform and cross-language purposes, you can optionally use JSON for this task. Send in either json or storable as the value to use the respective serializer. Default: storable Default Option Values Default values for options are: key => IPC_PRIVATE, create => 0, exclusive => 0, mode => 0, size => IPC::Shareable::SHM_BUFSIZ(), limit => 1, destroy => 0, graceful => 0, warn => 0, tidy => 0, serializer => 'storable', METHODS new Instantiates and returns a reference to a hash backed by shared memory. Parameters: Hash, Optional: See the "OPTIONS" section for a list of all available options. Most often, you'll want to send in the key, create and destroy options. It is possible to get a reference to an array or scalar as well. Simply send in either var = > 'ARRAY' or var => 'SCALAR' to do so. Return: A reference to a hash (or array or scalar) which is backed by shared memory. singleton($glue, $warn) Class method that ensures that only a single instance of a script can be run at any given time. Parameters: $glue Mandatory, String: The key/glue that identifies the shared memory segment. $warn Optional, Bool: Send in a true value to have subsequent processes throw a warning that there's been a shared memory violation and that it will exit. Default: false ipcs Returns the number of instantiated shared memory segments that currently exist on the system. Return: Integer spawn(%opts) Spawns a forked process running in the background that holds the shared memory segments backing your variable open. Parameters: Paremters are sent in as a hash. key => $glue Mandatory, String/Integer: The glue that you will be accessing your data as. mode => 0666 Optional, Integer: The read/write permissions on the variable. Defaults to 0666. Example: use IPC::Shareable; # The following line sets things up and returns IPC::Shareable->spawn(key => 'GLUE STRING'); Now, either within the same script, or any other script on the system, your data will be available at the key/glue GLUE STRING. Call unspawn() to remove it. unspawn($key, $destroy) This method will kill off the background process created with spawn(). Parameters: $key Mandatory, String/Integer: The glue (aka key) used in the call to spawn(). $destroy Optional, Bool. If set to a true value, we will remove all semaphores and memory segments related to your data, thus removing the data in its entirety. If not set to a true value, we'll leave the memory segments in place, and you'll be able to re-attach to the data at any time. Defaults to false (0). lock($flags) Obtains a lock on the shared memory. $flags specifies the type of lock to acquire. If $flags is not specified, an exclusive read/write lock is obtained. Acceptable values for $flags are the same as for the flock() system call. Returns true on success, and undef on error. For non-blocking calls (see below), the method returns 0 if it would have blocked. Obtain an exclusive lock like this: tied(%var)->lock(LOCK_EX); # same as default Only one process can hold an exclusive lock on the shared memory at a given time. Obtain a shared (read) lock: tied(%var)->lock(LOCK_SH); Multiple processes can hold a shared (read) lock at a given time. If a process attempts to obtain an exclusive lock while one or more processes hold shared locks, it will be blocked until they have all finished. Either of the locks may be specified as non-blocking: tied(%var)->lock( LOCK_EX|LOCK_NB ); tied(%var)->lock( LOCK_SH|LOCK_NB ); A non-blocking lock request will return 0 if it would have had to wait to obtain the lock. Note that these locks are advisory (just like flock), meaning that all cooperating processes must coordinate their accesses to shared memory using these calls in order for locking to work. See the flock() call for details. Locks are inherited through forks, which means that two processes actually can possess an exclusive lock at the same time. Don't do that. The constants LOCK_EX, LOCK_SH, LOCK_NB, and LOCK_UN are available for import using any of the following export tags: use IPC::Shareable qw(:lock); use IPC::Shareable qw(:flock); use IPC::Shareable qw(:all); Or, just use the flock constants available in the Fcntl module. See "LOCKING" for further details. unlock Removes a lock. Takes no parameters, returns true on success. This is equivalent of calling shlock(LOCK_UN). See "LOCKING" for further details. seg Called on either the tied variable or the tie object, returns the shared memory segment object currently in use. sem Called on either the tied variable or the tie object, returns the semaphore object related to the memory segment currently in use. attributes Retrieves the list of attributes that drive the IPC::Shareable object. Parameters: $attribute Optional, String: The name of the attribute. If sent in, we'll return the value of this specific attribute. Returns undef if the attribute isn't found. Returns: A hash reference of all attributes if $attributes isn't sent in, the value of the specific attribute if it is. global_register Returns a hash reference of hashes of all in-use shared memory segments across all processes. The key is the memory segment ID, and the value is the segment and semaphore objects. process_register Returns a hash reference of hashes of all in-use shared memory segments created by the calling process. The key is the memory segment ID, and the value is the segment and semaphore objects. LOCKING IPC::Shareable provides methods to implement application-level advisory locking of the shared data structures. These methods are called shlock() and shunlock(). To use them you must first get the object underlying the tied variable, either by saving the return value of the original call to tie() or by using the built-in tied() function. To lock and subsequently unlock a variable, do this: my $knot = tie my %hash, 'IPC::Shareable', { %options }; $knot->lock; $hash{a} = 'foo'; $knot->unlock; or equivalently, if you've decided to throw away the return of tie(): tie my %hash, 'IPC::Shareable', { %options }; tied(%hash)->lock; $hash{a} = 'foo'; tied(%hash)->unlock; This will place an exclusive lock on the data of $scalar. You can also get shared locks or attempt to get a lock without blocking. IPC::Shareable makes the constants LOCK_EX, LOCK_SH, LOCK_UN, and LOCK_NB exportable to your address space with the export tags :lock, :flock, or :all. The values should be the same as the standard flock option arguments. if (tied(%hash)->lock(LOCK_SH|LOCK_NB)){ print "The value is $hash{a}\n"; tied(%hash)->unlock; } else { print "Another process has an exlusive lock.\n"; } If no argument is provided to lock, it defaults to LOCK_EX. There are some pitfalls regarding locking and signals about which you should make yourself aware; these are discussed in "NOTES". Note that in the background, we perform lock optimization when reading and writing to the shared storage even if the advisory locks aren't being used. Using the advisory locks can speed up processes that are doing several writes/ reads at the same time. REFERENCES Although references can reside within a shared data structure, the tied variable can not be a reference itself. DESTRUCTION perl(1) will destroy the object underlying a tied variable when then tied variable goes out of scope. Unfortunately for IPC::Shareable, this may not be desirable: other processes may still need a handle on the relevant shared memory segment. IPC::Shareable therefore provides several options to control the timing of removal of shared memory segments. destroy Option As described in "OPTIONS", specifying the destroy option when tie()ing a variable coerces IPC::Shareable to remove the underlying shared memory segment when the process calling tie() exits gracefully. NOTE: The destruction is handled in an END block. Only those memory segments that are tied to the current process will be removed. remove tied($var)->remove; # or $knot->remove; Calling remove() on the object underlying a tie()d variable removes the associated shared memory segments. The segment is removed irrespective of whether it has the destroy option set or not and irrespective of whether the calling process created the segment. clean_up IPC::Shareable->clean_up; # or tied($var)->clean_up; # or $knot->clean_up; This is a class method that provokes IPC::Shareable to remove all shared memory segments created by the process. Segments not created by the calling process are not removed. clean_up_all IPC::Shareable->clean_up_all; # or tied($var)->clean_up_all; # or $knot->clean_up_all This is a class method that provokes IPC::Shareable to remove all shared memory segments encountered by the process. Segments are removed even if they were not created by the calling process. RETURN VALUES Calls to tie() that try to implement IPC::Shareable will return an instance of IPC::Shareable on success, and undef otherwise. AUTHOR Benjamin Sugars MAINTAINED BY Steve Bertrand NOTES Footnotes from the above sections 1. If the process has been smoked by an untrapped signal, the binding will remain in shared memory. If you're cautious, you might try $SIG{INT} = \&catch_int; sub catch_int { die; } ... tie $variable, IPC::Shareable, { key => 'GLUE', create => 1, 'destroy' => 1 }; which will at least clean up after your user hits CTRL-C because IPC::Shareable's END method will be called. Or, maybe you'd like to leave the binding in shared memory, so subsequent process can recover the data... General Notes o When using lock() to lock a variable, be careful to guard against signals. Under normal circumstances, IPC::Shareable's END method unlocks any locked variables when the process exits. However, if an untrapped signal is received while a process holds an exclusive lock, DESTROY will not be called and the lock may be maintained even though the process has exited. If this scares you, you might be better off implementing your own locking methods. One advantage of using flock on some known file instead of the locking implemented with semaphores in IPC::Shareable is that when a process dies, it automatically releases any locks. This only happens with IPC::Shareable if the process dies gracefully. The alternative is to attempt to account for every possible calamitous ending for your process (robust signal handling in Perl is a source of much debate, though it usually works just fine) or to become familiar with your system's tools for removing shared memory and semaphores. This concern should be balanced against the significant performance improvements you can gain for larger data structures by using the locking mechanism implemented in IPC::Shareable. o There is a program called ipcs(1/8) (and ipcrm(1/8)) that is available on at least Solaris and Linux that might be useful for cleaning moribund shared memory segments or semaphore sets produced by bugs in either IPC::Shareable or applications using it. Examples: # List all semaphores and memory segments in use on the system ipcs -a # List all memory segments and semaphores along with each one's associated process ID ipcs -ap # List just the shared memory segments ipcs -m # List the details of an individual memory segment ipcs -i 12345678 # Remove *all* semaphores and memory segments ipcrm -a o This version of IPC::Shareable does not understand the format of shared memory segments created by versions prior to 0.60. If you try to tie to such segments, you will get an error. The only work around is to clear the shared memory segments and start with a fresh set. o Iterating over a hash causes a special optimization if you have not obtained a lock (it is better to obtain a read (or write) lock before iterating over a hash tied to IPC::Shareable, but we attempt this optimization if you do not). The fetch/thaw operation is performed when the first key is accessed. Subsequent key and and value accesses are done without accessing shared memory. Doing an assignment to the hash or fetching another value between key accesses causes the hash to be replaced from shared memory. The state of the iterator in this case is not defined by the Perl documentation. Caveat Emptor. CREDITS Thanks to all those with comments or bug fixes, especially Maurice Aubrey Stephane Bortzmeyer Doug MacEachern Robert Emmery Mohammed J. Kabir Terry Ewing Tim Fries Joe Thomas Paul Makepeace Raphael Manfredi Lee Lindley Dave Rolsky Steve Bertrand SEE ALSO perltie, Storable, shmget, ipcs, ipcrm and other SysV IPC manual pages.