In some regards this seems like a homework problem, which I hate to do for people. On the other hand, the answers above are not totally accurate and I feel should be corrected.
First, while in this example both the shared and private clauses are not needed, I disagree with Konrad that they shouldn't be used. One of the most common problems with people parallelizing code, is that they don't take the time to understand how the variables are being used. Not privatizing and/or protecting shared variables that should be, accounts for the largest number of problems that I see. Going through the exercise of examining how variables are used and putting them into the appropriate shared, private, etc. clauses will greatly reduce the number of problems you have.
As for the question about the barriers, the first loop can have a nowait clause, because there is no use of the value computed (a) in the second loop. The second loop can have a nowait clause only if the value computed (c) is not used before the values are calculated (i.e., there is no dependency). In the original example code there is a nowait on the second loop, but an explicit barrier before the third loop. This is fine, since your professor was trying to show the use of an explicit barrier - though leaving off the nowait on the second loop would make the explicit barrier redundant (since there is an implicit barrier at the end of a loop).
On the other hand, the nowait on the second loop and the explicit barrier may not be needed at all. Prior to the OpenMP V3.0 specification, many people assumed that something was true that was not clarified in the specification. With the OpenMP V3.0 specification the following was added to section 2.5.1 Loop Construct, Table 2-1 schedule clause kind values, static (schedule):
A compliant implementation of static schedule must ensure that the same
assignment of logical iteration numbers to threads will be used in two loop
regions if the following conditions are satisfied: 1) both loop regions have the
same number of loop iterations, 2) both loop regions have the same value of
chunk_size specified, or both loop regions have no chunk_size specified, and 3)
both loop regions bind to the same parallel region. A data dependence between
the same logical iterations in two such loops is guaranteed to be satisfied
allowing safe use of the nowait clause (see Section A.9 on page 170 for
Now in your example, no schedule was shown on any of the loops, so this may or may not hold. The reason is, that the default schedule is implementation defined and while most implementations currently define the default schedule to be static, there is no guarantee of that. If your professor had put on a schedule type of static without a chunk-size on all three loops, then nowait could be used on the first and second loop and no barrier (either implicit or explicit) would be needed between the second and third loops at all.
Now we get to the third loop and your question about nowait and reduction. As Michy pointed out, the OpenMP specification allows both (reduction and nowait) to be specified. However, it is not true that no synchronization is needed for the reduction to be complete. In the example, the implicit barrier (at the end of the third loop) can be removed with the nowait. This is because the reduction (sum) is not being used before the implicit barrier of the parallel region has been encountered.
If you look at the OpenMP V3.0 specification, section 18.104.22.168 reduction clause, you will find the following:
If nowait is not used, the reduction computation will be complete at the end of the
construct; however, if the reduction clause is used on a construct to which nowait is
also applied, accesses to the original list item will create a race and, thus, have
unspecified effect unless synchronization ensures that they occur after all threads have
executed all of their iterations or section constructs, and the reduction computation
has completed and stored the computed value of that list item. This can most simply be
ensured through a barrier synchronization.
This means that if you wanted to use the sum variable in the parallel region after the third loop, then you would need a barrier (either implicit or explicit) before you used it. As the example stands now, it is correct.