# How to calculate average waiting time of Round robin scheduling?

Given this table :

Those are the time lines (time slice = 4) :

``````|p1|p1|p2|p3|p4|p5|p1|p2|p3|p4|p5|p2|p3|p4|p5|p2|p3|p4|p5|p2|p3|p3|
0  4  8 12 16  20 24 28 32 36 40 44 48 52 56 60 64 68 69 72 75 79 80
``````

Is there a simple way to calculate the average waiting time ?

Thanks

Note: that there are several finish times for each process !

Note2 : This question also involved priority algorithm as a side exercise , please disregard the priority column for the Round robin algorithm

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Isn't there a textbook formula for that? –  user166390 Jul 25 '12 at 7:36
@pst: There is , but here every process has several running times , hence there are several finish-times , for each process –  ron Jul 25 '12 at 7:37
basic round robin does not take into account priorities? furhtermore basic round robin should always be deterministic? and how did you get your sequence? part of the question? –  Osama Javed Jul 25 '12 at 12:36
@OsamaJaved: This question also involved `priority` algorithm as a side exercise , please disregard the priority column for the Round robin algorithm –  ron Jul 25 '12 at 12:42
@ron: so p1 always ends at 28 , p2 always ends at 75 , p3 ends at 80, p4 ends at 69 and p5 at 72?. Essentially in this system there is only one finish time possible for each process? (Your first note contradicts this statement.) If not then how? –  Osama Javed Jul 25 '12 at 13:24

Let's first try to solve the simple version of this problem where all process arrive at time 0. Assume we have `n` processes each with execution time as `ei`. Let the time slice be `s`. Let the number of time slices needed for each process be `NSPi`. Now we have `NSPi = ceiling(ei/s)`. Time needed for a process i = `NSPi * s`. Length of the schedule = `sum over i from 1 to n (NSPi)`. Waiting time for process i = `finish time of i - execution time of i`. But computing finish time of each process is complicated as each process has a different execution time. But since you just need the avg waiting time of RR algorithm for a specific instance, you could compute that as: `(Length of the schedule - sum of execution time of all processes)/num of processes`.

I guess by now you would have got an idea of how this formula has evolved. Ideally one would like the length of the schedule to be equal to the sum of execution time of all processes. But not all the execution times are a factor of the time slices. So in some time slice we get holes where no process is scheduled. So in practice, the length of the schedule is greater than the sum of execution times. Now we have their difference as the total waiting time.

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For different arrival times it is easier to draw out the schedule and then compute the total waiting time by hand. For each process compute `finish time - arrival time - execution time`. Then take avg over all processes. –  arunmoezhi Jul 25 '12 at 20:52

You can calculate Waiting time by drawing `Gantt chart` so waiting time of ith process is equal to `Completion time - (Arrival time + Burst time )` .

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|H |I |J |K |L | H| J| K|L |J |K|L |J |L |L | Its too lengthy, your answer in short is this: 0 4 8 12 16 20 24 28 32 36 40 44 48 52 56 60 average waiting time = ((H - arrival time) + (I - arrival time) + (J - arrival time) + (K - arrival time) + (L - arrival time))/ 5 =(24- 0) + (8-5) + (52 - 8) + (44-11) + (60 - 15)/ 5= 29.8 m sec Its too lengthy, your answer in short is this: Here it the Gantt chart of RR scheduling algorithm Process[burst time, time quantum, arrival time] H[8, 4, 0] I[4, 4, 5] J[16, 4, 8] k[12, 4, 11] L[20, constant = 4, 15]

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For RR, Waiting time = Last start time - arrival time - (preemption * quantum)

P1's last start time is 24 (when P1 running for 3rd time in Gannt chart) P1 preempted 2 times in it's lifetime Quantum = 4, Arrival = 0.

WaitingTime of P1 = 24 - 0 - (2 * 4) = 16 :)

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My answer is for the waiting time and turnaround time is

Waiting time: (16+51+51+45+42)/5=41 Turnaround time : (28+70+72+58+57)/5=57

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Maybe explain why it so. –  Numbers May 12 '14 at 15:45
Could you please elaborate on your answer? Where do you get the values you use to calculate from, always try to at least add a minimal explanation, otherwise your answer might not be of much use to other people looking for a answer to this question. –  Xaver Kapeller May 12 '14 at 15:46