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Chapter 3 Deadlocks TOPICS Resource Deadlocks The ostrich algorithm

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1 Chapter 3 Deadlocks TOPICS Resource Deadlocks The ostrich algorithm
Deadlock detection and recovery Deadlock prevention Deadlock avoidance Reference: Operating Systems Design and Implementation (Second Edition) by Andrew S. Tanenbaum, Albert S. Woodhull

2 Resources(1) Examples of computer resources printers tape drives
Tables

3 Resources (2) Deadlocks occur when … Preemptable resources
processes are granted exclusive access to devices we refer to these devices generally as resources Preemptable resources can be taken away from a process with no ill effects Example: process swapping form main memory Nonpreemptable resources will cause the process to fail if taken away Example: print request by more than one proceses

4 Resources (3) Sequence of events required to use a resource
request the resource use the resource release the resource Must wait if request is denied requesting process may be blocked may fail with error code

5 Deadlocks Suppose a process holds resource A and requests resource B
at same time another process holds B and requests A both are blocked and remain so

6 Deadlock Modeling Modeled with directed graphs
resource R assigned to process A process B is requesting/waiting for resource S process C and D are in deadlock over resources T and U

7 Four Conditions for Deadlock
Four conditions must hold for there to be a deadlock: Mutual exclusion condition each resource assigned to 1 process or is available Hold and wait condition process holding resources can request additional No preemption condition previously granted resources cannot forcibly taken away Circular wait condition must be a circular chain of 2 or more processes each is waiting for resource held by next member of the chain

8 How deadlock occurs A B C

9 How deadlock can be avoided
(o) (p) (q)

10 Strategy to Deal with Deadlock
Strategies for dealing with Deadlocks Just ignore the problem altogether Detection and recovery Prevention Negating one of the four necessary conditions of deadlock Dynamic avoidance Careful resource allocation

11 Strategy 1: The Ostrich Algorithm
Just ignore the problem Reasonable if deadlocks occur very rarely cost of prevention is high UNIX and Windows takes this approach It is a trade off between convenience correctness

12 Strategy 2: Detection and Recovery
Method 1: Every time a resource is requested or released, the resource graph is updated, and a check is made to see if any cycle exist. If a cycle exists, one of the process is the cycle is killed. If this does not break the deadlock, another process is killed and so on until the cycle is broken Method2 Periodically check to see if there are any processes that have been continuously blocked for more than say 1 hour. Such processes are then killed

13 Strategy 3: Deadlock Prevention a) Attacking the Mutual Exclusion Condition
Some devices (such as printer) can be spooled only the printer daemon uses printer resource thus deadlock for printer eliminated Not all devices can be spooled

14 b) Attacking the Hold and Wait Condition
Require processes to request resources before starting A process is allowed to run if all resources it needed is available. Otherwise it will just wait. Problems May not know required resources at start of run Resource will not be used optimally Variation: process must give up all resources and then request all immediately needed

15 c) Attacking the No Preemption Condition
This is not a viable option Consider a process given the printer halfway through its job now forcibly take away printer !!??

16 d) Attacking the Circular Wait Condition
Numerically ordered resources Resource Graph A process may request 1st a printer, then tape dirve. But it may not request 1st a plotter, then a scanner. Resource graph can never have cycle.

17 Deadlock Prevention Summary

18 Strategy 4: Deadlock Avoidance
Carefully analyze each resource request to see if it can be safely granted. Need an algorithm that can always avoid deadlock by making right choice all the time. Banker’s algorithm (by Dijkstra)

19 Deadlock Avoidance Resource Trajectories
Two process resource trajectories

20 Safe and Unsafe States (1)
(a) (b) (c) (d) (e) Demonstration that the state in (a) is safe

21 Safe and Unsafe States (2)
(a) (b) (c) (d) safe unsafe safe safe

22 The Banker's Algorithm for a Single Resource
(a) (b) (c) safe safe unsafe Three resource allocation states

23 Banker's Algorithm for Multiple Resources
Example of banker's algorithm with multiple resources


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