RFC 992 (rfc992) - Page 2 of 18
On communication support for fault tolerant process groups
Alternative Format: Original Text Document
RFC 992 November 1986
2. Acknowledgments
This memo was adopted from a paper presented at the Asilomar workshop
on fault-tolerant distributed computing, March 1986, and summarizes
material from a technical report that was issued by Cornell Universi-
ty, Dept. of Computer Science, in August 1985, which will appear in
ACM Transactions on Computer Systems in February 1987 [Birman-b].
Copies of these paper, and other relevant papers, are available on
request from the author: Dept. of Computer Science, Cornell Universi-
ty, Ithaca, New York 14853. (). The ISIS
project also maintains a mailing list. To be added to this list,
contact M. Schmizzi ().
This work was supported by the Defense Advanced Research Projects
Agency (DoD) under ARPA order 5378, Contract MDA903-85-C-0124, and by
the National Science Foundation under grant DCR-8412582. The views,
opinions and findings contained in this report are those of the au-
thors and should not be construed as an official Department of De-
fense position, policy, or decision.
3. Introduction
At Cornell, we recently completed a prototype of the ISIS system,
which transforms abstract type specifications into fault-tolerant
distributed implementations, while insulating users from the mechan-
isms by which fault-tolerance is achieved. This version of ISIS, re-
ported in [Birman-a], supports transactional resilient objects as a
basic programming abstraction. Our current work undertakes to pro-
vide a much broader range of fault-tolerant programming mechanisms,
including fault-tolerant distributed bulletin boards [Birman-c] and
fault-tolerant remote procedure calls on process groups [Birman-b].
The approach to communication that we report here arose as part of
this new version of the ISIS system.
Unreliable communication primitives, such as the multicast group com-
munication primitives proposed in RFC's 966 and 988 and in [Cheri-
ton], leave some uncertainty in the delivery status of a message when
failures and other exceptional events occur during communication.
Instead, a form of "best effort" delivery is provided, but with the
possibility that some member of a group of processes did not receive
the message if the group membership was changing just as communica-
tion took place. When we tried to use this sort of primitive in our
original work on ISIS, which must behave reliably in the presence of
such events, we had to address this aspect at an application level.
The resulting software was complex, difficult to reason about, and
filled with obscure bugs, and we were eventually forced to abandon
the entire approach as infeasible.
A wide range of reliable communication primitives have been proposed
in the literature, and we became convinced that by using them, the
complexity of our software could be greatly reduced. These range
Birman & Joseph