I recently started looking at MIT's 6.006 lectures and in the first lecture the instructor presented peak-finding algorithm.

According to his definitions:

Given an array [a,b,c,d,e,f,g] where a-g are numbers, b is a peak if and only if a <= b and b>= c.

He gave a recursive approach:

```
if a[n/2] < a[n/2 -1] then look for a peak from a[1] ... a[n/2 -1]
else if a[n/2] < a[n/2+1] then look for a peak from a[n/2+1] ... a[n]
else a[n/2] is a peak
```

He said the algorithm is T(n) = T(n/2) + o(1) = o(lgn)

In his pdf he also gave a complete example: `[6,7,4,3,2,1,4,5]`

Both 7 and 5 are peaks. But doesn't the algorithm above only finds 7 as peak just because the middle element happens to satisfy the first branch?

So if we were supposed to find all the peaks, would we still be walking through the entire array? Would it mean worst case N?

Does his definition implies we just need to find a single peak?

I believe this problem can be viewed as finding the maximum and minimum element in Riverst's Introduction to Algorithm book.