Q. The following pair of processes share a common variable X :

Process A
int Y;
A1: Y = X*2;
A2: X = Y;

Process B
int Z;
B1: Z = X+1;
B2: X = Z;


X is set to 5 before either process begins execution. As usual, statements within a process are executed sequentially, but statements in process A may execute in any order with respect to statements in process B.
How many different values of X are possible after both processes finish executing ?

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Q. The program follows to use a shared binary semaphore T :

Process A
int Y;
A1: Y = X*2;
A2: X = Y;
signal(T);

Process B
int Z;
B1: wait(T);
B2: Z = X+1;
X = Z;


T is set to 0 before either process begins execution and, as before, X is set to 5.
Now, how many different values of X are possible after both processes finish executing ?

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Q. All processes share a semaphore variable mutex, initialized to 1. Each process must execute wait(mutex) before entering the critical section and signal(mutex) afterward.
Suppose a process executes in the following manner :

signal(mutex);
.....
critical section
.....
wait(mutex);

In this situation :

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Q. All processes share a semaphore variable mutex, initialized to 1. Each process must execute wait(mutex) before entering the critical section and signal(mutex) afterward.
Suppose a process executes in the following manner :

wait(mutex);
.....
critical section
.....
wait(mutex);

In this situation :

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Q. Consider the methods used by processes P1 and P2 for accessing their critical sections whenever needed, as given below. The initial values of shared boolean variables S1 and S2 are randomly assigned.

Method used by P1 :
while(S1==S2);
Critical section
S1 = S2;

Method used by P2 :
while(S1!=S2);
Critical section
S2 = not(S1);

Which of the following statements describes properties achieved ?

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Q. Which of the following concurrency control protocols ensure both conflict serializability and freedom from deadlock ?

I) 2-phase locking
II) Time-stamp ordering

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Q. The initial value of the semaphore that allows only one of the many processes to enter their critical sections, is

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Q. For how many processes which are sharing common data, the Dekker's algorithm implements mutual exclusion?

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Q. Semaphores

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Q. What is the initial value of the semaphore to allow only one of the many processes to enter their critical section?

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Q. Part of a program where the shared memory is accessed and which should be executed invisibly, is called

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Q. A critical region is

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Q. For procedure, the system prevent the overlap of buffer

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Q. In implementation of Semaphores, for a single processor system, it is possible to inhibited

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Q. In message passing a process receives information by executing the

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Q. In a uniprocessor system concurrent processes cannot have overlapped

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Q. In addressing, a many to one relationship is useful for

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Q. The controller process services writes a

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Q. Using Semaphores, each process has a critical section used to access the

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Q. The global variable read count is used to keep the track of the number of

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