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Journal ArticleDOI

A real-time locking protocol

Lui Sha1, Ragunathan Rajkumar2, Sang H. Son3, C.-H. Chang4
Software Engineering Institute1, IBM2, University of Virginia3, Konkuk University4
01 Jul 1991-IEEE Transactions on Computers (IEEE Computer Society)-Vol. 40, Iss: 7, pp 793-800
TL;DR: It is shown that this protocol leads to freedom from mutual deadlock and can be used by schedulability analysis to guarantee that a set of periodic transactions using this protocol can always meet its deadlines.
Abstract: The authors examine a priority driven two-phase lock protocol called the read/write priority ceiling protocol. It is shown that this protocol leads to freedom from mutual deadlock. In addition, a high-priority transactions can be blocked by lower priority transactions for at most the duration of a single embedded transaction. These properties can be used by schedulability analysis to guarantee that a set of periodic transactions using this protocol can always meet its deadlines. Finally, the performance of this protocol is examined for randomly arriving transactions using simulation studies. >

Summary (2 min read)

Jump to: [1. Introduction][2.1. Basic Concepts][2.2. Definitions and Properties][3. Performance Evaluation] and [4. Conclusions]

1. Introduction

  • In a real-time database context, concurrency control protocols must not only maintain the consistency constraints of the database but also satisfy the timing requirements of the transactions accessing the database.
  • Next, the authors process transactions in priority order.
  • The preemption of T3, and hence the blocking of T1, will continue until T2 and any other pending intermediate-priority level transactions are completed.
  • An objective of this paper is to design an appropriate priority management protocol for a given concurrency control protocol so that deadlocks can be avoided and the duration of blocking can be tightly bounded.

2.1. Basic Concepts

  • Real-time databases are often used by applications such as tracking.
  • The authors assume that an embedded transaction consists of a sequence of read and write operations operating upon the database.
  • Task τ0 will therefore continue and execute its transaction, thereby effectively preempting T2 in its transaction and not encountering any blocking.

2.2. Definitions and Properties

  • Having reviewed the basic concepts, the authors now review their assumptions and state the notation used.
  • The authors also assume that a transaction does not attempt to lock an object that it has already locked and thus deadlock with itself.
  • Under the read- or write-priority ceiling protocol, mutual deadlock of transactions cannot occur and each task can be blocked by at most one embedded transaction until it completes or suspends itself.
  • The authors now develop a set of sufficient conditions under which a set of periodic tasks with hard deadlines at the end of the periods can be scheduled by the rate-monotonic algorithm [15] when the read- or write-priority ceiling protocol is used.

3. Performance Evaluation

  • In the previous section, the authors have assumed that all the tasks are periodic and that all the database objects are in the main memory.
  • For each experiment and for each algorithm tested, the authors collected performance statistics and averaged over 10 runs.
  • The two important factors affecting the performance of locking protocols are their abilities to resolve the locking conflicts and to perform the I/O and transactions in parallel.
  • The main weakness of the read- or write-priority ceiling protocol is its inability to perform I/O and transactions in parallel.
  • In their experiments, each transaction’s deadline is set proportional to its size and system workload (number of transactions), and the transaction with the shorter deadline is assigned a higher priority.

4. Conclusions

  • Real-time database is an important area of research, with applications ranging from surveillance to reliable manufacturing and production control.
  • The authors have investigated the read- or write-priority ceiling protocol, which integrates the two-phase lock protocol with priority-driven real-time scheduling.
  • The authors have also developed schedulability bounds for periodic tasks in a centralized in-core database.
  • Finally, the authors experimentally evaluated the performance of this protocol when the tasks are invoked aperiodically and the database is no longer in-core.

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Technical Report
CMU/SEI-89-TR-018
ESD-89-TR-026
A Real-Time Locking Protocol
Lui Sha
Ragunathan Rajkumar
Sang Son
Chun-Hyon Chang
April 1989
A Real-Time Locking Protocol
AB
Software Engineering Institute
Carnegie Mellon University
Pittsburgh, Pennsylvania 15213
Technical Report
CMU/SEI-89-TR-018
ESD-89-TR-026
April 1989
Lui Sha
Real-Time Scheduling in Ada Project
Ragunathan Rajkumar
Carnegie Mellon University
Sang Son
University of Virginia
Chun-Hyon Chang
Kon Kuk University, Seoul, Korea
Unlimited distribution subject to the copyright.
This report was prepared for the SEI Joint Program Office HQ ESC/AXS
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The ideas and findings in this report should not be construed as an official DoD position. It is
published in the interest of scientific and technical information exchange.
FOR THE COMMANDER
(signature on file)
Thomas R. Miller, Lt Col, USAF, SEI Joint Program Office
This work is sponsored by the U.S. Department of Defense.
Copyright 1989 by Carnegie Mellon University.
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CMU/SEI-89-TR-18 1
A Real-Time
Locking Protocol
Abstract: When a database system is used in a real-time application, the concur-
rency control protocol must satisfy not only the consistency of shared data but
also the timing constraints of the application. In this paper, we examine a priority-
driven two-phase lock protocol called the read- or write-priority ceiling protocol.
We show that this protocol is free of deadlock, and in addition a high-priority trans-
action can be blocked by lower priority transactions for at most the duration of a
single embedded transaction. We then evaluate system performance experimen-
tally.
1. Introduction
In a real-time database context, concurrency control protocols must not only maintain the
consistency constraints of the database but also satisfy the timing requirements of the trans-
actions accessing the database.
Both concurrency control [2, 3, 4, 5, 7, 16, 17, 18, 20, 21, 23, 26] and real-time scheduling
algorithms [10, 11, 13, 14, 15, 19, 22, 27] are active areas of research in their own right. It
may seem that the development of a real-time locking protocol is a simple matter of combin-
ing priority scheduling with a locking protocol. For example, we may require each trans-
action to use a well-known concurrency protocol such as the two-phase lock protocol [6] and
assign priorities to transactions according to some well-known scheduling algorithms such
as the earliest deadline algorithm [19]. Next, we process transactions in priority order. Un-
fortunately, such an approach may lead to unbounded priority inversion, in which a high-
priority task would wait for lower priority tasks for an indefinite period of time.
Example 1: Suppose T
1
, T
2
, and T
3
are three transactions arranged in descending order of
priority, with T
1
having the highest priority. Assume that transaction T
1
and T
3
share the
same data object O. Suppose that at time
t
1
transaction T
3
obtains a write-lock on O.
During the execution of T
3
, the high-priority task T
1
arrives and attempts to read-lock the
object O. Transaction T
1
will be blocked, since O is already write-locked. We would expect
that T
1
, being the highest priority transaction, will be blocked no longer than the time for T
3
to complete and unlock O. However, the duration of blocking may, in fact, be unbounded.
This is because transaction T
3
can be preempted by the intermediate-priority transaction T
2
that does not need to access O. The preemption of T
3
, and hence the blocking of T
1
, will
continue until T
2
and any other pending intermediate-priority level transactions are com-
pleted.
The blocking duration in Example 1 can be arbitrarily long. This situation can be partially
remedied if transactions are not allowed to be preempted; however, this solution is only ap-
propriate for very short transactions, because it creates unnecessary blocking. For instance,
Citations
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Real-Time Database Systems: Concepts and Design

[...]

Saud A. Aldarmi
01 Jan 1998
TL;DR: This qualifying dissertation is intended to review the state-of-the-art of Real-Time Database Systems under a uniprocessor and centralized environments with the most important issues believed to include Concurrency Control and Conflict Resolution protocols.
Abstract: This qualifying dissertation is intended to review the state-of-the-art of Real-Time Database Systems under a uniprocessor and centralized environments. Due to the heterogeneity of the issues, the large amounts of information , and space limitation, we limit our presentation to the most important issues to the overall design, construction , and advancement of Real-Time Database Systems. Such topics are believed to include Transaction these issues, the most emphasis is placed on Concurrency Control and Conflict Resolution protocols due to their severe role on the overall systems performance. Other important issues that were not included in our presentation include Fault Tolerance and Failure Recovery, Predictability, and most important of all, Minimizing Transaction Support; i.e., Relaxing Atomicity and Serializability. Various solutions to many of the included topics are listed in chronological order along with their advantages, disadvantages, and limitations. While we took the liberty to debate some solutions, we list the debates of other researchers as well. The presentation concludes with the identification of five research areas, all of which are believed to be very important to the advancement of Real-Time Database Systems.

25 citations

Journal ArticleDOI
A temporal blackboard for a multi-agent environment

[...]

Vicente Botti1, Federico Barber1, Alfons Crespo1, Eva Onaindia1, Ana García-Fornes1, Ismael Ripoll1, Domingo Gallardo1, Luis Hernandez1 
Polytechnic University of Valencia1
01 Jun 1995
TL;DR: This paper presents a framework for agent communication based on the blackboard paradigm which is able to manage temporal information, and it provides its multiple access and coherence management protocols.
Abstract: The multi-agent system paradigm emerges as an interesting approach in the Knowledge Based System (KBS) field, when distributed problem-solving techniques are required for solving problems that can be represented as a collection of groups of cooperating intelligent individuals. A key concept in the multi-agent systems is the interaction between agents. On the other hand time plays a crucial role in a wide range of KBS applications. Temporal reasoning and representations consists of formalizing the notion of time and providing means to represent and reason about the temporal aspects of knowledge. This paper presents a framework for agent communication based on the blackboard paradigm which is able to manage temporal information, and it provides its multiple access and coherence management protocols.

25 citations

Journal ArticleDOI
Reducing the variance of point-to-point transfers for parallel real-time programs

[...]

Ronald Mraz1
IBM1
01 Dec 1994-IEEE Parallel & Distributed Technology: Systems & Applications
TL;DR: This article examines how to reduce the difference between worst-case and average-case message latency that can contribute to variance in fine-grain parallel programs.
Abstract: Investigations that analyze the time an operating system takes to schedule, interrupt and "context-switch" to another process or job have helped developers produce highly optimized and tuned operating systems that can provide more than 99% sustained processor use for most uniprocessor applications. However, when these operating systems are installed on CPUs that are interconnected with a low-latency (user-space) communication mechanism, large variances typically occur in the time it takes to send a point-to-point message. In this article, we examine how to reduce the difference between worst-case and average-case message latency that can contribute to variance in fine-grain parallel programs. Changing how the operating system handles interrupt processing and scheduling can greatly reduce the difference between these latencies, thus increasing a program's performance. >

24 citations

Proceedings ArticleDOI
Real-time lock-based concurrency control in distributed database systems

[...]

O. Ulusoy1, G.G. Belford1
University of Illinois at Urbana–Champaign1
09 Jun 1992
TL;DR: Several distributed, lock-based, real-time, concurrency control protocols are described and the relative performance of the protocols in a nonreplicated database environment is reported.
Abstract: In a real-time database system, it is difficult to meet all timing constraints due to the consistency requirements of the underlying database. Real-time database transaction scheduling requires the development of efficient concurrency control protocols that try to maximize the number of transactions satisfying their real-time constraints. Several distributed, lock-based, real-time, concurrency control protocols are described. The relative performance of the protocols in a nonreplicated database environment is reported. The protocols take the real-time requirements of the transactions into account in ordering data accesses, while maintaining data consistency by enforcing serializability. >

23 citations

Proceedings ArticleDOI
A mixed locking/abort protocol for hard real-time systems

[...]

LihcChyun Shu1, Michal Young1
Purdue University1
18 May 1994
TL;DR: This research addresses concurrency control protocols that accommodate analytic guarantees of schedulability, can be implemented with small bounded overheads and blocking, and ensure serializable execution of entire tasks including complete read/compute/write cycles.
Abstract: Serializability greatly simplifies reasoning about correctness in concurrent systems, including real-time systems. Our research addresses concurrency control protocols that accommodate analytic guarantees of schedulability, can be implemented with small bounded overheads and blocking, and ensure serializable execution of entire tasks including complete read/compute/write cycles (as opposed to serializable execution only of short embedded transactions without computation.) One such protocol which combines locking and abort is described. Among its interesting properties are that transactions scheduled by locking are never aborted, tasks are aborted only due to conflict with higher priority tasks, and the cost of abortion can be bounded for the purpose of schedulability analysis. The protocol is illustrated with an avionics example. The priority ceiling protocol can ensure schedulability of 8 tasks if serializability of only short sequences of data accesses is required, but cannot schedule even the first 2 tasks if serializability is required for whole tasks. Under reasonable assumptions our protocol achieves schedulability of the first 6 tasks while guaranteeing serializability of entire tasks. >

22 citations

References
More filters
Book
Scheduling algorithms for multiprogramming in a hard real-time environment

[...]

C. L. Liu, James W. Layland
03 Jan 1989
TL;DR: In this paper, the problem of multiprogram scheduling on a single processor is studied from the viewpoint of the characteristics peculiar to the program functions that need guaranteed service, and it is shown that an optimum fixed priority scheduler possesses an upper bound to processor utilization which may be as low as 70 percent for large task sets.
Abstract: The problem of multiprogram scheduling on a single processor is studied from the viewpoint of the characteristics peculiar to the program functions that need guaranteed service. It is shown that an optimum fixed priority scheduler possesses an upper bound to processor utilization which may be as low as 70 percent for large task sets. It is also shown that full processor utilization can be achieved by dynamically assigning priorities on the basis of their current deadlines. A combination of these two scheduling techniques is also discussed.

5,397 citations

Book
Concurrency Control and Recovery in Database Systems

[...]

Philip A. Bernstein1, Vassco Hadzilacos2, Nathan Goodman
Wang Institute of Graduate Studies1, University of Toronto2
01 Feb 1987
TL;DR: In this article, the design and implementation of concurrency control and recovery mechanisms for transaction management in centralized and distributed database systems is described. But this can lead to interference between queries and updates.
Abstract: This book is an introduction to the design and implementation of concurrency control and recovery mechanisms for transaction management in centralized and distributed database systems. Concurrency control and recovery have become increasingly important as businesses rely more and more heavily on their on-line data processing activities. For high performance, the system must maximize concurrency by multiprogramming transactions. But this can lead to interference between queries and updates, which concurrency control mechanisms must avoid. In addition, a satisfactory recovery system is necessary to ensure that inevitable transaction and database system failures do not corrupt the database.

3,891 citations

Journal ArticleDOI
Priority inheritance protocols: an approach to real-time synchronization

[...]

Lui Sha1, Ragunathan Rajkumar2, John P. Lehoczky1
Carnegie Mellon University1, IBM2
01 Sep 1990-IEEE Transactions on Computers
TL;DR: An investigation is conducted of two protocols belonging to the priority inheritance protocols class; the two are called the basic priority inheritance protocol and the priority ceiling protocol, both of which solve the uncontrolled priority inversion problem.
Abstract: An investigation is conducted of two protocols belonging to the priority inheritance protocols class; the two are called the basic priority inheritance protocol and the priority ceiling protocol. Both protocols solve the uncontrolled priority inversion problem. The priority ceiling protocol solves this uncontrolled priority inversion problem particularly well; it reduces the worst-case task-blocking time to at most the duration of execution of a single critical section of a lower-priority task. This protocol also prevents the formation of deadlocks. Sufficient conditions under which a set of periodic tasks using this protocol may be scheduled is derived. >

2,443 citations

"A real-time locking protocol" refers background in this paper

  • ...With only two-phase locking and priority assignment, we can encounter the problem of unbounded priority inversion as illustrated in Example 1. However, the idea of priority inheritance [ 24 ] solves the unbounded priority inversion problem....

    [...]

Journal ArticleDOI
The notions of consistency and predicate locks in a database system

[...]

Kapali P. Eswaran1, Jim Gray1, Raymond A. Lorie1, Irving L. Traiger1
IBM1
01 Nov 1976-Communications of The ACM
TL;DR: It is argued that a transaction needs to lock a logical rather than a physical subset of the database, and an implementation of predicate locks which satisfies the consistency condition is suggested.
Abstract: In database systems, users access shared data under the assumption that the data satisfies certain consistency constraints. This paper defines the concepts of transaction, consistency and schedule and shows that consistency requires that a transaction cannot request new locks after releasing a lock. Then it is argued that a transaction needs to lock a logical rather than a physical subset of the database. These subsets may be specified by predicates. An implementation of predicate locks which satisfies the consistency condition is suggested.

2,031 citations

"A real-time locking protocol" refers methods in this paper

  • ...Each embedded transaction will follow the two-phase lock protocol [ 6 ], which requires a transaction to acquire all the locks before it releases any lock....

    [...]

  • ...For example, we may require each transaction to use a well-known concurrency protocol such as the two-phase lock protocol [ 6 ] and assign priorities to transactions according to some well-known scheduling algorithms such as the earliest deadline algorithm [19]....

    [...]

Proceedings ArticleDOI
The rate monotonic scheduling algorithm: exact characterization and average case behavior

[...]

John P. Lehoczky1, Lui Sha1, Y. Ding1
Carnegie Mellon University1
05 Dec 1989
TL;DR: An exact characterization of the ability of the rate monotonic scheduling algorithm to meet the deadlines of a periodic task set and a stochastic analysis which gives the probability distribution of the breakdown utilization of randomly generated task sets are represented.
Abstract: An exact characterization of the ability of the rate monotonic scheduling algorithm to meet the deadlines of a periodic task set is represented. In addition, a stochastic analysis which gives the probability distribution of the breakdown utilization of randomly generated task sets is presented. It is shown that as the task set size increases, the task computation times become of little importance, and the breakdown utilization converges to a constant determined by the task periods. For uniformly distributed tasks, a breakdown utilization of 88% is a reasonable characterization. A case is shown in which the average-case breakdown utilization reaches the worst-case lower bound of C.L. Liu and J.W. Layland (1973). >

1,582 citations

"A real-time locking protocol" refers background in this paper

  • ...An exact characterization of rate-monotonic schedulability can be found in [ 12 ]....

    [...]

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Frequently Asked Questions (1)
Q1. What are the contributions mentioned in the paper "A real-time locking protocol" ?

In this paper, the authors examine a prioritydriven two-phase lock protocol called the reador write-priority ceiling protocol. The authors show that this protocol is free of deadlock, and in addition a high-priority transaction can be blocked by lower priority transactions for at most the duration of a single embedded transaction. The authors then evaluate system performance experimentally.