In practice, is there any case that an already lineartime algorithm need to be parallelized? My teacher argues that it is not worth it but I don't believe so.

that would depend on the number of elements to be usually processed by that algorithm, and the dependency these elements have between each other, and of course also on whether there's even a parallel processor available to get some speedup– codelingCommented Dec 22, 2011 at 13:27

1I would say it's entirely the wrong level of thinking. If it's too slow (however fast that may be), and it can be parallelized, then it's worth it. Regardless of any time complexities and whatnot. In the real world, the real time matters. And if it's not too slow, then it doesn't matter. Not even if it's actually an exponentialtime algorithm.– user555045Commented Dec 22, 2011 at 13:43
5 Answers
Your teacher is mistaken. The runtime complexity (O(n), O(log n), etc.) of the singleCPU algorithm has no bearing on whether or not it will benefit from parallelization.
Changing your code from using 1 CPU to using K CPUs will at best divide the run time by a factor of K. Since you can't arbitrarily create CPUs out of thin air, K is effectively a constant. So, the runtime complexity is not affected by parallelization. All you can hope to do is get a constant factor improvement.
Which isn't to say that it's not worth doing  in some cases, a twofold improvement is hugely beneficial. Plus, in a massively parallel system of thousands of CPUs, that constant gets pretty big.

+1, but K is only a constant if your referring to a single system. If your talking about the performance of an algorithm over a range of differing systems, K becomes a variable.– SmacLCommented Dec 22, 2011 at 14:06

@Shane MacLaughlin  K is still a constant as far as runtime complexity is concerned, because it is not a function of n (the length of the input).– mbeckishCommented Dec 22, 2011 at 14:12

4"Changing your code from using 1 CPU to using K CPUs will at best divide the run time by a factor of K."  not necessarily true. While it doesn't often occur in reallife problems, there is the possibility of superlinear speedup (see e.g. en.wikipedia.org/wiki/Speedup)– codelingCommented Dec 22, 2011 at 14:16

1@mbeckish, you're right of course, but the original question related to the algorithm, so I'd tend to think of the answer in terms of algorithmic complexity, in which K is a variable.– SmacLCommented Dec 22, 2011 at 18:04

1Yep, the speedup may be superlinear, consider search space traversal with prunning (constraint satisfaction problem DFS solver (optimization problem) + prunning + shaving). With multiple cores/threads you are able from one thread prune/shave the search space of other threads... Commented Dec 23, 2011 at 8:50
Definite YES. Graphic cards offer parallelism, and switching from CPU to parallel computation on GPU can save a lot of time. A linear time algorithm can have a monumental speedup when executed in parallel. See GPGPU and "applications" section, or google for "graphic card computation".
Although you did not ask, the answer in theory is also definite yes, there is a complexity class NC for problems that can be "effectively parallelized" (can be solved in logarithmic time given polynomial number of processors), and "Pcomplete" problems which can be solved in polynomial time, but are suspected not to be in NC. (just like there are P problems and NPcomplete problems, and NPcomplete are suspected not to be in P)
I disagree with your teacher as well. My argument is that many of the algorithms that are run on MapReduce are linear time algorithms.
For example, indexing, going over many html pages (for example all the pages in wikipedia) and looking for specific words, is an algorithm that is linear in the input. However, you can't really run it without parallelism.
Given a singlecore, single CPU, single machine environment, and a task which is CPUbound, your teacher is correct. (although it could be argued that in that case, even though you might be running multiple threads, they are not truly running in parallel, just given the illusion of running in parallel)
These days however, single core systems are rare, even many smartphones are moving to multicore, so in practice, you will likely benefit from parallelization. I say likely because if the tasks are small, the cost of thread creation is going to be higher than the benefits, likewise there's also contextswitching that costs processor cycles. If not done smartly, there's always the chance that making an operation parallel will in fact make it slower.
Given a large enough input, it is worth it. Always.
Example:
A naive algorithm to find the largest number in an unordered 'List' will just traverse the list. This will take time of the order O(n)
to find the record.
This is okay if you have a 100, or a 1000 records.
What if you had a billion records? You split the list amongst multiple CPUs, each finds a maximum, then you have a new smaller list to work with. You can split this again => Parallel, and faster. I believe it is O(log(n))
if you split and reduce efficiently, and have n CPUs.
The point being: If your input is big enough, O(n)
is not good enough anymore. Depending on what needs to be done O(n) could grow to too many seconds, minutes, hours compared to what you would like.
Note: When I say O(n)
or O(log(n))
above, I am referring to the time taken to finish the search. i.e. not the 'total work' performed by all the CPUs. Usually, parallelizing an algorithm increases the total work done by the CPUs somewhat.

It can't get to better than O(n) if the problem requires checking every element. Parallelizing can however make it faster by making checks simultaneous.– Don RobyCommented Dec 22, 2011 at 13:42

2@ArjunShankar, I think it is a mistake to say O(log(n)) where n is the number of input elements, unless you are guaranteed n CPUs. Better to say if you have m CPUs your performance will approach O(n/m).– SmacLCommented Dec 22, 2011 at 14:02

1@ArjunShankar  We may just be misunderstanding each other. When computing the runtime complexity of parallel algorithms, the number of threads/CPUs (m) and the size of the input (n) are usually treated as independent variables. In that case, you cannot use parallelization to change an O(n) algorithm to O(log n). The only way to achieve this is to consider m to be a function of n. For example, if m = n/log(n), then O(n/m) is equivalent to O(log n).– mbeckishCommented Dec 22, 2011 at 14:50

1@ArjunShankar  My point is that, when talking about runtime complexity, it makes no sense to say "with a machine that happens to have >= n/2 processors". People just don't consider the number of processors to be a function of the input size when determining runtime complexity.– mbeckishCommented Dec 22, 2011 at 15:52

1@ArjunShankar, if you we're allowed n CPUs, and shared memory with no overhead for read, you're theoretical best of log(n) seems rather slow for this simple problem. Say each cpu looks at the current highest value, compares it to each value in its input array, and updates the highest value if bigger, the run time approaches O(1). I'm sticking with O(n/m), where n and m are independent variables. I'd say for any non trivial algorithm the number of variables is far greater as is an expression for runtime complexity.– SmacLCommented Dec 22, 2011 at 17:52