# What is the difference between an “on line” and “off line” algorithm?

These terms were used in my data structures textbook, but the explanation was very terse and unclear. I think it has something to know with how much knowledge the algorithm has at each stage of computation.

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## Wikipedia

What, exactly, do you not understand when looking at the Wikipedia page?

In computer science, an online algorithm is one that can process its input piece-by-piece in a serial fashion, i.e., in the order that the input is fed to the algorithm, without having the entire input available from the start. In contrast, an offline algorithm is given the whole problem data from the beginning and is required to output an answer which solves the problem at hand. (For example, selection sort requires that the entire list be given before it can sort it, while insertion sort doesn't.)

Let me expand on the above:

An offline algorithm requires all information BEFORE the algorithm starts. In the Wikipedia example, selection sort is offline because step 1 is `Find the minimum value in the list`. To do this, you need to have the entire list available - otherwise, how could you possibly know what the minimum value is? You cannot.

Insertion sort, by contrast, is online because it does not need to know anything about what values it will sort and the information is requested WHILE the algorithm is running. Simply put, it can grab new values at every iteration.

## Still not clear?

Think of the following examples (for four year olds!). David is asking you to solve two problems.

In the first problem, he says:

"I'm, going to give you two balls of different masses and you need to drop them at the same time from a tower.. just to make sure Galileo was right. You can't use a watch, we'll just eyeball it."

If I gave you only one ball, you'd probably look at me and wonder what you're supposed to be doing. After all, the instructions were pretty clear. You need both balls at the beginning of the problem. This is an offline algorithm.

For the second problem, David says

"Okay, that went pretty well, but now I need you to go ahead and kick a couple of balls across a field."

I go ahead and give you the first ball. You kick it. Then I give you the second ball and you kick that. I could also give you a third and fourth ball (without you even knowing that I was going to give them to you). This is an example of an online algorithm. As a matter of fact, you could be kicking balls all day.

I hope this was clear :D

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You'd need at least 3 balls, only two of which need to be available at the start of the online-for-4yo example. The eyeballs come in (somewhat) later :) –  sehe Jul 16 '12 at 0:07

An online algorithm processes the input only piece by piece and doesn't know about the actual input size at the beginning of the algorithm.

An often used example is scheduling: you have a set of machines, and an unknown workload. Each machine has a specific speed. You want to clear the workload as fast as possible. But since you don't know all inputs from the beginning (you can often see only the next in the queue) you can only estimate which machine is the best for the current input. This can result in non-optimal distribution of your workload since you cannot make any assumption on your input data.

An offline algorithm on the other hand works only with complete input data. All workload must be known before the algorithm starts processing the data.

### Example:

```Workload:
1. Unit (Weight: 1)
2. Unit (Weight: 1)
3. Unit (Weight: 3)
Machines:
1. Machine (1 weight/hour)
2. Machine (2 weights/hour)

Possible result (Online):
1. Unit -> 2. Machine  // 2. Machine has now a workload of 30 minutes
2. Unit -> 2. Machine  // 2. Machine has now a workload of one hour
either
3. Unit -> 1. Machine  // 1. Machine has now a workload of three hours
or
3. Unit -> 2. Machine  // 1. Machine has now a workload of 2.5 hours

==> the work is done after 2.5 hours

Possible result (Offline):
1. Unit -> 1. Machine  // 1. Machine has now a workload of one hour
2. Unit -> 1. Machine  // 1. Machine has now a workload of two hours
3. Unit -> 2. Machine  // 2. Machine has now a workload of 1.5 hours

==> the work is done after 2 hours```

Note that the better result in the offline algorithm is only possible since we don't use the better machine from the start. We know already that there will be a heavy unit (unit 3), so this unit should be processed by the fastest machine.

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How 'bout that. Exactly what the Wikipedia article says. Learned something new today. –  Robert Harvey Jul 15 '12 at 22:09
@RobertHarvey: Didn't read the Wikipedia article, don't know whether this is a good or a bad sign :D. –  Zeta Jul 15 '12 at 22:10