A sequential scan of a dataset, looking for a maximum, can be done in O(n) time with O(1) memory usage.

You just set the current maximum to the first element then run through all the other elements, setting the current maximum to the value if the value is greater. Pseudo-code:

```
max = list[first_index]
for index = first_index+1 to last_index:
if list[index] > max:
max = list[index]
```

The *complexity* doesn't change regardless of the number of elements in the list so it doesn't matter how many there are.

The *running time* will change however (since the algorithm is O(n) time) and, if it's important to find the maximum fast, there are a number of possibilities. These all hinge on doing work when the list *changes*, not every time you want the information, hence they're better for a list that is read more often than written, so the cost can be amortised.

Option 1 is to keep the list sorted so you can just grab the last element. This is *probably* overkill for just keeping a record of the maximum.

Option 2 is to recalculate the maximum (and number of elements holding it) when you insert into, or delete from, the list. Initially set `max`

to 0 and `maxcount`

to 0 for an empty list.

For an insert:

- if
`maxcount`

is 0 (the list is empty), set `max`

to this value and `maxcount`

to 1.
- otherwise, if this value is greater than
`max`

, set `max`

to this value and `maxcount`

to 1.
- otherwise, if this value is equal to
`max`

, add 1 to `maxcount`

.

For a deletion:

- if this value is equal to
`max`

, subtract 1 from `maxcount`

.
- then, if
`maxcount`

is 0, rescan list to get new `max`

and `maxcount`

.

This way, at any time, you have the maximum value (the count is simply an extra "trick" to speed up the algorithm where there is more than one element holding the maximum value). I've used this once before in a data analysis application and it turned out to be much faster than re-sorting - I had to store both minimum and maximum in that case, but it's the same idea.