Actor model and process calculi
In computer science, the Actor model and process calculi are two closely related approaches to the modelling of concurrent digital computation. See Actor model and process calculi history.
There are many similarities between the two approaches, but also several differences (some philosophical, some technical):
- There is only one Actor model (although it has numerous formal systems for design, analysis, verification, modeling, etc.); there are numerous process calculi, developed for reasoning about a variety of different kinds of concurrent systems at various levels of detail (including calculi that incorporate time, stochastic transitions, or constructs specific to application areas such as security analysis).
- The Actor model was inspired by the laws of physics and depends on them for its fundamental axioms, i.e. physical laws (see Actor model theory); the process calculi were originally inspired by algebra (Milner 1993).
- Processes in the process calculi are anonymous, and communicate by sending messages either through named channels (synchronous or asynchronous), or via ambients (which can also be used to model channel-like communications (Cardelli and Gordon 1998)). In contrast, actors in the Actor model possess an identity, and communicate by sending messages to the mailing addresses of other actors (this style of communication can also be used to model channel-like communications—see below).
The publications on the Actor model and on process calculi have a fair number of cross-references, acknowledgments, and reciprocal citations (see Actor model and process calculi history).
How channels work
[edit]Indirect communication using channels (e.g. Gilles Kahn and David MacQueen [1977]) has been an important issue for communication in parallel and concurrent computation affecting both semantics and performance. Some process calculi differ from the Actor model in their use of channels as opposed to direct communication.
Synchronous channels
[edit]Synchronous channels have the property that a sender putting a message in the channel must wait for a receiver to get the message out of the channel before the sender can proceed.
Simple synchronous channels
[edit]A synchronous channel can be modeled by an Actor that receives put
and get
communications. The following is the behavior of an Actor for a simple synchronous channel:
- Each
put
communication has a message and an address to which an acknowledgment is sent when the message is received by aget
communication from the channel in FIFO order. - Each
get
communication has an address to which the received message is sent.
Synchronous channels in process calculi
[edit]However, simple synchronous channels do not suffice for process calculi such as Communicating Sequential Processes (CSP) [Hoare 1978 and 1985] because use of the guarded choice (after Dijkstra) command (called the alternative command in CSP). In a guarded choice command multiple offers (called guards) can be made concurrently on multiple channels to put
and get
messages; however at most one of the guards can be chosen for each execution of the guarded choice command. Because only one guard can be chosen, a guarded choice command in general effectively requires a kind of two-phase commit protocol or perhaps even a three-phase commit protocol if time-outs are allowed in guards (as in Occam 3 [1992]).
Consider the following program written in CSP [Hoare 1978]:
[X :: Z!stop() || Y :: guard: boolean; guard := true; *[guard → Z!go(); Z?guard] || Z :: n: integer; n:= 0; *[X?stop() → Y!false; print!n; [] Y?go() → n := n+1; Y!true] ]
According to Clinger [1981], this program illustrates global nondeterminism, since the nondeterminism arises from incomplete specification of the timing of signals between the three processes X
, Y
, and Z
. The repetitive guarded command in the definition of Z
has two alternatives:
- the
stop
message is accepted fromX
, in which caseY
is sent the value false andprint
is sent the valuen
- a
go
message is accepted fromY
, in which casen
is incremented andY
is sent the value true.
If Z
ever accepts the stop
message from X
, then X
terminates. Accepting the stop
causes Y
to be sent false which when input as the value of its guard will cause Y
to terminate. When both X
and Y
have terminated, Z
terminates because it no longer has live processes providing input.
In the above program, there are synchronous channels from X
to Z
, Y
to Z
, and Z
to Y
.
Analogy with the committee coordination problem
[edit]According to Knabe [1992], Chandy and Misra [1988] characterized this as analogous to the committee coordination problem:
- Professors in a university are assigned to various committees. Occasionally a professor will decide to attend a meeting of any of her committees, and will wait until that is possible. Meetings may begin only if there is full attendance. The task is to ensure that if all the members of a committee are waiting, then at least one of them will attend some meeting.
- The crux of this problem is that two or more committees might share a professor. When that professor becomes available, she can only choose one of the meetings, while the others continue to wait.
A simple distributed protocol
[edit]This section presents a simple distributed protocol for channels in synchronous process calculi. The protocol has some problems that are addressed in the sections below.
The behavior of a guarded choice command is as follows:
- The command sends a message to each of its guards to
prepare
. - When it receives the first response from one of its guards that it is prepared, then it sends a message to that guard to
prepare to commit
and sends messages to all of the other guards toabort
.- When it receives a message from the guard that it is
prepared to commit
, then it sends the guard acommit
message. However, if the guard throws an exception that it cannotprepare to commit
, then guarded choice command starts the whole process all over again.
- When it receives a message from the guard that it is
- If all of its guards respond that they cannot
prepare
, then the guarded command does nothing.
The behavior of a guard is as follows:
- When a message to
prepare
is received, then the guard sends aprepare
message to each of the channels with which it is offering to communicate. If the guard has booleans such that it cannotprepare
or if any of the channels respond that they cannotprepare
, then it sendsabort
messages to the other channels and then responds that it cannotprepare
.- When a message to
prepare to commit
is received, then the guard sends aprepare to commit
message to each of the channels. If any of the channels respond that they cannotprepare to commit
, then it sendsabort
messages to the other channels and then throws an exception that it cannotprepare to commit
. - When a message to
commit
is received, then the guard sends acommit
message to each of the channels. - When a message to
abort
is received, then the guard sends anabort
message to each of the channels.
- When a message to
The behavior of a channel is as follows:
- When a
prepare to put
communication is received, then respond that it is prepared if there is aprepare to get
communication pending unless aterminate
communication has been received, in which case throw an exception that it cannotprepare to put
. - When a
prepare to get
communication is received, then respond that it is prepared if there is aprepare to put
communication pending unless aterminate
communication has been received, in which case throw an exception that it cannotprepare to get
.- When a
prepare to commit to put
communication is received, then respond that it is prepared if there is aprepare to commit to get
communication pending unless aterminate
communication has been received, in which case throw an exception that it cannotprepare to commit to put
. - When a
prepare to commit to get
communication is received, then respond that it is prepared if there is aprepare to commit to put
communication pending unless aterminate
communication has been received, in which case throw an exception that it cannotprepare to commit to get
.- When a
commit put
communication is received, then depending on which of the following is received:- When a
commit get
communication is received, then if not already done perform theput
andget
and clean up the preparations. - When an
abort get
communication is received, then cancel the preparations
- When a
- When a
commit get
communication is received, then depending on which of the following is received:- When a
commit put
communication is received, then if not already done perform theget
andput
and clean up the preparations. - When an
abort put
communication is received, then cancel the preparations.
- When a
- When an
abort put
communication is received, then cancel the preparations. - When an
abort get
communication is received, then cancel the preparations.
- When a
- When a
Starvation on getting from multiple channels
[edit]Again consider the program written in CSP (discussed in Synchronous channels in process calculi above):
[X :: Z!stop() || Y :: guard: boolean; guard := true; *[guard → Z!go(); Z?guard] || Z :: n: integer; n:= 0; *[X?stop() → Y!false; print!n; [] Y?go() → n := n+1; Y!true] ]
As pointed out in Knabe [1992], a problem with the above protocol (A simple distributed protocol) is that the process Z
might never accept the stop
message from X
(a phenomenon called starvation) and consequently the above program might never print anything.
In contrast consider, a simple Actor system that consists of Actors X, Y, Z, and print where
- the Actor X is created with the following behavior:
- If the message
"start"
is received, then send Z the message"stop"
- If the message
- the Actor Y is created with the following behavior:
- If the message
"start"
is received, then send Z the message"go"
- If the message true is received, then send Z the message
"go"
- If the message false is received, then do nothing
- If the message
- the Actor Z is created with the following behavior that has a count
n
that is initially 0:- If the message
"start"
is received, then do nothing. - If the message
"stop"
is received, then send Y the message false and send print the message the countn
. - If the message
"go"
is received, then send Y the message true and process the next message received with countn
beingn+1
.
- If the message
By the laws of Actor semantics, the above Actor system will always halt when the Actors X, Y, are Z are each sent a "start"
message resulting in sending print a number that can be unbounded large.
The difference between the CSP program and the Actor system is that the Actor Z does not get messages using a guarded choice command from multiple channels. Instead it processes messages in arrival ordering, and by the laws for Actor systems, the stop
message is guaranteed to arrive.
Livelock on getting from multiple channels
[edit]Consider the following program written in CSP [Hoare 1978]:
[Bidder1 :: b: bid; *[Bids1?b → process1!b; [] Bids2?b → process1!b;] || Bidder2 :: b: bid; *[Bids1?b → process2!b; [] Bids2?b → process2!b;] ]
As pointed out in Knabe [1992], an issue with the above protocol (A simple distributed protocol) is that the process Bidder2
might never accept a bid from Bid1
or Bid2
(a phenomenon called livelock) and consequently process2
might never be sent anything. In each attempt to accept a message, Bidder2
is thwarted because the bid that was offered by Bids1
or Bids2
is snatched away by Bidder1
because it turns out that Bidder1
has much faster access than Bidder2
to Bids1
and Bids2
. Consequently, Bidder1
can accept a bid, process it and accept another bid before Bidder2
can commit to accepting a bid.
Efficiency
[edit]As pointed out in Knabe [1992], an issue with the above protocol (A simple distributed protocol) is the large number of communications that must be sent in order to perform the handshaking in order to send a message through a synchronous channel. Indeed, as shown in the previous section (Livelock), the number of communications can be unbounded.
Summary of Issues
[edit]The subsections above have articulated the following three issues concerned with the use of synchronous channels for process calculi:
- Starvation. The use of synchronous channels can cause starvation when a process attempts to get messages from multiple channels in a guarded choice command.
- Livelock. The use of synchronous channels can cause a process to be caught in livelock when it attempts to get messages from multiple channels in a guarded choice command.
- Efficiency. The use of synchronous channels can require a large number of communications in order to get messages from multiple channels in a guarded choice command.
It is notable that in all of the above, issues arise from the use of a guarded choice command to get messages from multiple channels.
Asynchronous channels
[edit]Asynchronous channels have the property that a sender putting a message in the channel need not wait for a receiver to get the message out of the channel.
Simple asynchronous channels
[edit]An asynchronous channel can be modeled by an Actor that receives put
and get
communications. The following is the behavior of an Actor for a simple asynchronous channel:
- Each
put
communication has a message and an address to which an acknowledgment is sent immediately (without waiting for the message to be gotten by aget
communication). - Each
get
communication has an address to which the gotten message is sent.
Asynchronous channels in process calculi
[edit]The Join-calculus programming language (published in 1996) implemented local and distributed concurrent computations. It incorporated asynchronous channels as well as a kind of synchronous channel that is used for procedure calls. Agha's Aπ Actor calculus (Agha and Thati 2004) is based on a typed version of the asynchronous π-calculus.
Algebras
[edit]The use of algebraic techniques was pioneered in the process calculi. Subsequently, several different process calculi intended to provide algebraic reasoning about Actor systems have been developed in (Gaspari and Zavattaro 1997), (Gaspari and Zavattaro 1999), (Agha and Thati 2004).
Denotational semantics
[edit]Will Clinger (building on the work of Irene Greif [1975], Gordon Plotkin [1976], Henry Baker [1978], Michael Smyth [1978], and Francez, Hoare, Lehmann, and de Roever [1979]) published the first satisfactory mathematical denotational theory of the Actor model using domain theory in his dissertation in 1981. His semantics contrasted the unbounded nondeterminism of the Actor model with the bounded nondeterminism of CSP [Hoare 1978] and Concurrent Processes [Milne and Milner 1979] (see denotational semantics). Roscoe [2005] has developed a denotational semantics with unbounded nondeterminism for a subsequent version of Communicating Sequential Processes Hoare [1985]. More recently Carl Hewitt [2006b] developed a denotational semantics for Actors based on timed diagrams.
Ugo Montanari and Carolyn Talcott [1998] have contributed to attempting to reconcile Actors with process calculi.
References
[edit]- Carl Hewitt, Peter Bishop and Richard Steiger. A Universal Modular Actor Formalism for Artificial Intelligence IJCAI 1973.
- Robin Milner. Processes: A Mathematical Model of Computing Agents in Logic Colloquium 1973.
- Irene Greif and Carl Hewitt. Actor Semantics of PLANNER-73 Conference Record of ACM Symposium on Principles of Programming Languages. January 1975.
- Irene Greif. Semantics of Communicating Parallel Processes MIT EECS Doctoral Dissertation. August 1975.
- Gordon Plotkin. A powerdomain construction SIAM Journal on Computing September 1976.
- Carl Hewitt and Henry Baker Actors and Continuous Functionals Proceeding of IFIP Working Conference on Formal Description of Programming Concepts. August 1–5, 1977.
- Gilles Kahn and David MacQueen. Coroutines and networks of parallel processes IFIP. 1977
- Aki Yonezawa Specification and Verification Techniques for Parallel Programs Based on Message Passing Semantics MIT EECS Doctoral Dissertation. December 1977.
- Michael Smyth. Power domains Journal of Computer and System Sciences. 1978.
- George Milne and Robin Milner. Concurrent processes and their syntax JACM. April, 1979.
- CAR Hoare. Communicating Sequential Processes CACM. August, 1978.
- Nissim Francez, C.A.R. Hoare, Daniel Lehmann, and Willem de Roever. Semantics of nondeterminism, concurrency, and communication Journal of Computer and System Sciences. December 1979.
- Mathew Hennessy and Robin Milner. On Observing Nondeterminism and Concurrency LNCS 85. 1980.
- Will Clinger. Foundations of Actor Semantics MIT Mathematics Doctoral Dissertation. June 1981.
- Mathew Hennessy. A Term Model for Synchronous Processes Computer Science Dept. Edinburgh University. CSR-77-81. 1981.
- J.A. Bergstra and J.W. Klop. Process algebra for synchronous communication Information and Control. 1984.
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- Robert van Glabbeek. Bounded nondeterminism and the approximation induction principle in process algebra Symposium on Theoretical Aspects of Computer Sciences on STACS 1987.
- K. Mani Chandy and Jayadev Misra. Parallel Program Design: A Foundation Addison-Wesley 1988.
- Robin Milner, Joachim Parrow and David Walker. A calculus of mobile processes Computer Science Dept. Edinburgh. Reports ECS-LFCS-89-85 and ECS-LFCS-89-86. June 1989. Revised Sept. 1990 and Oct. 1990 respectively.
- Robin Milner. The Polyadic pi-Calculus: A Tutorial Edinburgh University. LFCS report ECS-LFCS-91-180. 1991.
- Kohei Honda and Mario Tokoro. An Object Calculus for Asynchronous Communication ECOOP 91.
- José Meseguer. Conditional rewriting logic as a unified model of concurrency in Selected papers of the Second Workshop on Concurrency and compositionality. 1992.
- Frederick Knabe. A Distributed Protocol for Channel-Based Communication with Choice PARLE 1992.
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- Benjamin Pierce, Didier Rémy and David Turner. A typed higher-order programming language based on the pi-calculus Workshop on type Theory and its application to computer Systems. Kyoto University. July 1993.
- Milner, Robin (January 1993), "Elements of interaction: Turing award lecture", Communications of the ACM, 36, CACM: 78–89, doi:10.1145/151233.151240.
- R. Amadio and S. Prasad. Locations and failures Foundations of Software Technology and Theoretical Computer Science Conference. 1994.
- Cédric Fournet and Georges Gonthier. The reflexive chemical abstract machine and the join-calculus POPL 1996.
- Cédric Fournet, Georges Gonthier, Jean-Jacques Lévy, Luc Maranget, and Didier Rémy. A Calculus of Mobile Agents CONCUR 1996.
- Tatsurou Sekiguchi and Akinori Yonezawa. A Calculus with Code Mobility FMOODS 1997.
- Gaspari, Mauro; Zavattaro, Gianluigi (May 1997), An Algebra of Actors (Technical Report), University of Bologna
- Luca Cardelli and Andrew Gordon (1998), Maurice Nivat (ed.), "Mobile Ambients", Foundations of Software Science and Computational Structures, Lecture Notes in Computer Science, 1378, Springer
- Ugo Montanari and Carolyn Talcott. Can Actors and Pi-Agents Live Together? Electronic Notes in Theoretical Computer Science. 1998.
- Robin Milner. Communicating and Mobile Systems: the Pi-Calculus Cambridge University Press. 1999.
- M. Gaspari and G. Zavattaro (1999), "An Algebra of Actors", Formal Methods for Open Object Based Systems: 3–18, doi:10.1007/978-0-387-35562-7_2, ISBN 978-1-4757-5266-3
- Davide Sangiorgi and David Walker. The Pi-Calculus : A Theory of Mobile Processes Cambridge University Press. 2001.
- P. Thati, R. Ziaei, and G. Agha. A theory of may testing for asynchronous calculi with locality and no name matching Algebraic Methodology and Software Technology. Springer Verlag. September 2002. LNCS 2422.
- Gul Agha and Prasanna Thati (2004), "An Algebraic Theory of Actors and Its Application to a Simple Object-Based Language" (PDF), OO to FM (Dahl Festschrift) LNCS, 2635, Springer-Verlag, archived from the original (PDF) on 2004-04-20, retrieved 2005-12-15
- J.C.M. Baeten, T. Basten, and M.A. Reniers. Algebra of Communicating Processes Cambridge University Press. 2005.
- He Jifeng and C.A.R. Hoare. Linking Theories of Concurrency United Nations University International Institute for Software Technology UNU-IIST Report No. 328. July, 2005.
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