Tuple space
A tuple space is an implementation of the associative memory paradigm for parallel/distributed computing. It provides a repository of tuples that can be accessed concurrently. As an illustrative example, consider that there are a group of processors that produce pieces of data and a group of processors that use the data. Producers post their data as tuples in the space, and the consumers then retrieve data from the space that match a certain pattern. This is also known as the blackboard metaphor. Tuple space may be thought as a form of distributed shared memory.
Tuple spaces were the theoretical underpinning of the Linda language developed by David Gelernter and at Yale University in 1986.
Implementations of tuple spaces have also been developed for Java (JavaSpaces), Lisp, Lua, Prolog, Python, Ruby, Smalltalk, Tcl, and the .NET Framework.
Object Spaces[]
Object Spaces is a paradigm for development of distributed computing applications. It is characterized by the existence of logical entities, called Object Spaces. All the participants of the distributed application share an Object Space. A provider of a service encapsulates the service as an Object, and puts it in the Object Space. Clients of a service then access the Object Space, find out which object provides the needed service, and have the request serviced by the object.
Object Spaces, as a computing paradigm, was put forward in the 1980s by David Gelernter at Yale University. Gelernter developed a language called Linda to support the concept of global object coordination.
Object Space can be thought of as a virtual repository, shared amongst providers and accessors of network services, which are themselves abstracted as objects. Processes communicate among each other using these shared objects — by updating the state of the objects as and when needed.
An object, when deposited into a space, needs to be registered with an Object Directory in the Object Space. Any processes can then identify the object from the Object Directory, using properties lookup, where the property specifying the criteria for the lookup of the object is its name or some other property which uniquely identifies it. A process may choose to wait for an object to be placed in the Object Space, if the needed object is not already present.
Objects, when deposited in an Object Space are passive, i.e., their methods cannot be invoked while the objects are in the Object Space. Instead, the accessing process must retrieve it from the Object Space into its local memory, use the service provided by the object, update the state of the object and place it back into the Object Space.
This paradigm inherently provides mutual exclusion. Because once an object is accessed, it has to be removed from the Object Space, and is placed back only after it has been released. This means that no other process can access an object while it is being used by one process, thereby ensuring mutual exclusion.
JavaSpaces[]
JavaSpaces is a service specification providing a distributed object exchange and coordination mechanism (which may or may not be persistent) for Java objects. It is used to store the distributed system state and implement distributed algorithms. In a JavaSpace, all communication partners (peers) communicate and coordinate by sharing state.
JavaSpaces can be used to achieve scalability through parallel processing, it can also be used to provide reliable storage of objects through distributed replication, although this won't survive a total power failure like a disk; it is regarded by many to be reliable as long as the power is reliable. Distribution can also be to remote locations; however, this is rare as JavaSpaces are usually used for low-latency, high-performance applications rather than reliable object caching.
The most common software pattern used in JavaSpaces is the Master-Worker pattern. The Master hands out units of work to the "space", and these are read, processed and written back to the space by the workers. In a typical environment there are several "spaces", several masters and many workers; the workers are usually designed to be generic, i.e. they can take any unit of work from the space and process the task.
JavaSpaces is part of the Java Jini technology, which on its own has not been a commercial success.[1] The technology has found and kept new users over the years and some vendors are offering JavaSpaces-based products. JavaSpaces remains a niche technology mostly used in the financial services and telco industries where it continues to maintain a faithful following. The announcement of Jini/JavaSpaces created quite some hype although Sun co-founder and chief Jini architect Bill Joy put it straight that this distributed systems dream will take "a quantum leap in thinking".[2]
GigaSpaces, a developer of In-Memory-Computing data fabric, implements JavaSpaces as part of its In-Memory Data Grid.
Example usage[]
The following example shows an application made using JavaSpaces. First, an object to be shared in the Object Space is made. Such an object is called an Entry in JavaSpace terminology. Here, the Entry is used to encapsulate a service which returns a Hello World! string, and keeps track of how many times it was used. The server which provides this service will create an Object Space, or JavaSpace. The Entry is then written into the JavaSpace. The client reads the entry from the JavaSpace and invokes its method to access the service, updating its usage count by doing so. The updated Entry is written back to the JavaSpace.
// An Entry class
public class SpaceEntry implements Entry {
public final String message = "Hello World!";
public Integer count = 0;
public String service() {
++count;
return message;
}
public String toString() {
return "Count: " + count;
}
}
// Hello World! server
public class Server {
public static void main(String[] args) throws Exception {
SpaceEntry entry = new SpaceEntry(); // Create the Entry object
JavaSpace space = (JavaSpace)space(); // Create an Object Space
// Register and write the Entry into the Space
space.write(entry, null, Lease.FOREVER);
// Pause for 10 seconds and then retrieve the Entry and check its state.
Thread.sleep(10 * 1000);
SpaceEntry e = space.read(entry, null, Long.MAX_VALUE);
System.out.println(e);
}
}
// Client
public class Client {
public static void main(String[] args) throws Exception {
JavaSpace space = (JavaSpace) space();
SpaceEntry e = space.take(new SpaceEntry(), null, Long.MAX_VALUE);
System.out.println(e.service());
space.write(e, null, Lease.FOREVER);
}
}
Books[]
- Eric Freeman, , Ken Arnold: JavaSpaces Principles, Patterns, and Practice. Addison-Wesley Professional, 1. June 1999, ISBN 0-201-30955-6
- Phil Bishop, Nigel Warren: JavaSpaces in Practice. Addison Wesley, 2002, ISBN 0-321-11231-8
- Max K. Goff: Network Distributed Computing: Fitscapes and Fallacies, 2004, Prentice Hall, ISBN 0-13-100152-3
- Sing Li, et al.: Professional Java Server Programming, 1999, Wrox Press, ISBN 1-86100-277-7
- Steven Halter: JavaSpaces Example by Example, 2002, Prentice Hall PTR, ISBN 0-13-061916-7
Interviews[]
- Gelernter, David (2009). "Lord of the Cloud". John Brockman, Editor and Publisher Russell Weinberger, Associate Publisher, Edge Foundation, Inc.
- Heiss, Janice J. (2003). "Computer Visions: A Conversation with David Gelernter". Sun Developer Network (SDN).
- Venners, Bill (2003). "Designing as if Programmers are People (Interview with Ken Arnold)". java.net.
Articles[]
- Brogden, William (2007). "How Web services can use JavaSpaces". SearchWebServices.com. Retrieved 2007-04-18.
- Brogden, William (2007). "Grid computing and Web services (Beowulf, BOINC, Javaspaces)". SearchWebServices.com. Retrieved 2007-03-20.
- White, Tom (2005). "How To Build a ComputeFarm". java.net. Retrieved 2005-05-21.
- Ottinger, Joseph (2007). "Understanding JavaSpaces". theserverside. Retrieved 2007-01-31.
- Angerer, Bernhard; Erlacher, Andreas (2005). "Loosely Coupled Communication and Coordination in Next-Generation Java Middleware". java.net. Retrieved 2006-06-03.
- Angerer, Bernhard (2003). "Space-Based Programming". onjava.com. Retrieved 2003-03-19.
- Sing, Li (2003). "High-impact Web tier clustering, Part 2: Building adaptive, scalable solutions with JavaSpaces". IBM developerworks.
- Mamoud, Qusay H. (2005). "Getting Started With JavaSpaces Technology: Beyond Conventional Distributed Programming Paradigms". Sun Developer Network (SDN).
- Freeman, Eric; Hupfer, Susanne (November 20, 1999). "Make room for Javaspaces, Part 1 (from 5)". JavaWorld. Retrieved 2020-07-17.
- Löffler, Dr. Gerald (2004). "JavaSpaces und ihr Platz im Enterprise Java Universum, Das Modell zum Objektaustausch: JavaSpaces vorgestellt". Entwickler.com. Retrieved 2004-02-01.
- Arango, Mauricio (2009). "Coordination in parallel event-based systems". blogs.sun.com.
- Nemlekar, Milind (2001). "Scalable Distributed Tuplespaces". NCSU, Dept of ECE.
See also[]
- Space-based architecture
- Linda (coordination language)
- Ken Arnold, lead engineer on JavaSpaces at Sun Microsystems
- Rinda, a JavaSpaces analog for Ruby
References[]
- ^ Lee Gomes: "Sun Microsystems' Predictions For Jxta System Sound Familiar". The Wall Street Journal, June 4th 2001
- ^ Rob Guth: "More than just another pretty name: Sun's Jini opens up a new world of distributed computer systems". SunWorld, August 1998 [15 January 2006]
Sources[]
- Gelernter, David. "Generative communication in Linda". ACM Transactions on Programming Languages and Systems, volume 7, number 1, January 1985
- Distributed Computing (First Indian reprint, 2004), M. L. Liu
External links[]
- "TupleSpace" at c2.com
- "JavaSpace Specification" at jini.org
- Parallel computing
- Distributed computing architecture
- Programming languages
- Java platform