Chapter 6: Concurrency: Mutual Exclusion and Synchronization

Chapter 6:Concurrency: Mutual Exclusion and Synchronization Operating System Spring 2007 Chapter 6 of textbook

Concurrency • An OS has many concurrent processes that run in parallel but share common access • Race Condition: A situation where several processes access and manipulate the same data concurrently and the outcome of the execution depends on the particular order in which the access takes place.

UAL 56: #-of-seats=12 Main memory … Terminal Terminal Terminal Ticket Agent 1 Ticket Agent n Ticket Agent 2 Example for Race condition • Suppose a customer wants to book a seat on UAL 56. Ticket agent will check the #-of-seats. If it is greater than 0, he will grab a seat and decrement #-of-seats by 1.

Example for Race condition(cont.) Ticket Agent 1 P1: LOAD #-of-seats P2: DEC 1 P3: STORE #-of-seats Ticket Agent 2 Q1: LOAD #-of-seats Q2: DEC 1 Q3: STORE #-of-seats Ticket Agent 3 R1: LOAD #-of-seats R2: DEC 1 R3: STORE #-of-seats Suppose, initially, #-of-seats=12 Suppose instructions are interleaved as P1,Q1,R1,P2,Q2,R2,P3,Q3,R3 The result would be #-of-seats=11, instead of 9 To solve the above problem, we must make sure that: P1,P2,P3 must be completely executed before we execute Q1 or R1, or Q1,Q2,Q3 must be completely executed before we execute P1 or R1, or R1,R2,R3 must be completely executed before we execute P1 or Q1.

P0 P1 Pn-1 Prefix0 Prefix1 Prefixn-1 … CS0 CS1 CSn-1 Suffix0 Suffix1 Suffixn-1 Critical Section Problem Critical section: a segment of code in which the process may be changing common variables, updating a table, writing a file, and so on. Goal: To program the processes so that, at any moment of time, at most one of the processes is in its critical section.

Solution to Critical-Section Problem • Any facility to provide support for mutual exclusion should meet the following requirements: • Mutual exclusion must be enforced: Only one process at a time is allowed into its critical section • A process that halts in its noncritical section must do so without interfering with other processes. • A process waiting to enter its critical section cannot be delayed indefinitely • When no process is in a critical section, any process that requests entry to its critical section must be permitted to enter without delay. • No assumption are made about the relative process speeds or the number of processors. • A process remains inside its critical section for a finite time only.

Three Environments • There is no central program to coordinate the processes. The processes communicate with each other through global variable. • Solution: Peterson’s algorithm • not covered in this class • Special hardware instructions • TS • Exchange(not covered in this class) • There is a central program to coordinate the processes. • Semaphore

Special Machine Instructions • Modern machines provide special atomic hardware instructions • Atomic = non-interruptable • Either test memory word and set value • Or swap contents of two memory words

TS – Test and Set Boolean TS(i)= true if i=0; it will also set i to 1 false if i=1 Initially, lock=0 Pi Prefixi While(¬ TS(lock)) do {} CSi Lock=0 suffixi Problem of this program: It is possible that a process may starve if 2 processes enter the critical section arbitrarily often. Solution for the starvation won’t be covered in this class.

Semaphores • A variable that has an integer value upon which 3 operations are defined. • Three operations: • A semaphore may be initialized to a nonnegative value • The wait operation decrements the semaphore value. If the value becomes negative, then the process executing the wait is blocked • The signal operation increments the semaphore value. If the value is not positive, then a process blocked by a wait operation is unblocked. • Other than these 3 operations, there is no way to inspect or manipulate semaphores.

Wait(s) and Signal(s) • Wait(s) – is also called P(s) { s=s-1; if (s<0) {place this process in a waiting queue} } • Signal(s) – is also called V(s) { s=s+1; if(s0) {remove a process from the waiting queue} }

Semaphore as General Synchronization Tool • Counting semaphore – integer value can range over an unrestricted domain • Binary semaphore – integer value can range only between 0 and 1; can be simpler to implement • Also known as mutex locks • Wait B(s) s is a binary semaphore { if s=1 then s=0 else block this process } • Signal B(s) { if there is a blocked process then unblock a process else s=1 } • Can implement a counting semaphore S as a binary semaphore

Note • The wait and signal primitives are assumed to be atomic; they cannot be interrupted and each routine can be treated as an indivisible step.

Mutual Exclusion provided by Semaphores • Semaphore S; // initialized to 1 Pi prefixi wait (S); CSi signal (S); suffixi • Wait B(s) s is a binary semaphore { if s=1 then s=0 else block this process } • Signal B(s) { if there is a blocked process then unblock a process else s=1 }

Two classical examples • Producer and Consumer Problem • Readers/Writers Problem

Producer and Consumer Problem • Producer can only put something in when there is an empty buffer • Consumer can only take something out when there is a full buffer • Producer and consumer are concurrent processes 0 consumer producer N buffers N-1

Producer Process producer: produce(w) wait(p) B[in]=w in=(in+1)mod N signal(c) goto producer Consumer Process consumer: wait(c) w=B[out] out=(out+1)mod N signal(p) consume(w) goto consumer W is a local buffer used by the consumer to store the item to be consumed W is a local buffer used by the producer to produce Producer and Consumer Problem(cont.) • Global Variable • B[0..N-1] – an array of size N (Buffer) • P – a semaphore, initialized to N • C – a semaphore, initialized to 0 • Local Variable • In – a ptr(integer) used by the producer, in=0 initially • Out – a ptr(integer) used by the consumer, out=0 initially

Two classical examples • Producer and Consumer Problem • Readers/Writers Problem

Readers/Writers Problem • Suppose a data object is to be shared among several concurrent processes. Some of these processes want only to read the data object, while others want to update (both read and write) • Readers – Processes that read only • Writers – processes that read and write • If a reader process is using the data object, then other reader processes are allowed to use it at the same time. • If a writer process is using the data object, then no other process (reader or writer) is allowed to use it simultaneously.

Reader Processes Wait(mutex) Readcount=readcount+1 If readcount=1 then wait(wrt) Signal(mutex); … Reading is performed … Wait(mutex) Readcount=readcount-1 If readcount=0 then signal(wrt) Signal(mutex) Writer Processes Wait(wrt) … Writing is performed … Signal(wrt) Solve Readers/Writers Problem using wait and signal primitives(cont.) • Global Variable: • Wrt is a binary semaphore, initialized to 1; Wrt is used by both readers and writers • For Reader Processes: • Mutex is a binary semaphore, initialized to 1;Readcount is an integer variable, initialized to 0 • Mutex and readcount used by readers only

End Thank you!

Chapter 6: Concurrency: Mutual Exclusion and Synchronization