Your current algorithm is incorrect, but you're quite close to it. Here I will show where your algorithm might go wrong.

Consider the array `[3,2,1,2]`

.

Suppose first you call `FindMin(F, 0, 3)`

FindMin(F, 0, 3)
--mid = 1
--Check F[1] False
--Check F[1] True, call FindMin(F, 1, 3)
----mid = 2
----Check F[2] True, call FindMin(F, 1, 2)
------mid = 1
------Check F[1] False
------Check F[1] True, call FindMin(F, 1, 2)
--------mid = 1
--------Check F[1] False
--------Check F[1] True, call FindMin(F, 1, 2)
... This will continue forever until out of memory

You can change it a bit to get it correct:

```
FindMin(F, lo, hi){
if(lo==hi) return F[lo];
int mid = lo + (hi-lo)/2 // Actually you can change this into (lo+hi)/2
if(F[mid] > F[mid+1]) return FindMin(F, mid+1, hi) // Change the comparison and recursive call!
if(F[mid] > F[mid-1]) return FindMin(F, lo, mid-1) // Change the comparison and recursive call!
// If we reach here, that means F[mid-1] > F[mid] < F[mid+1]
return F[mid]
}
```

Although as @Joni said, you need to handle boundary cases. Checking only `F[mid+1]`

will do the trick. I guarantee this following code won't get any out of bounds error and correct:

```
FindMin(F, lo, hi){
if(lo==hi) return F[lo]; // Line 1
int mid = (lo+hi)/2 // Line 2
if(F[mid] > F[mid+1]) return FindMin(F, mid+1, hi) // Line 3
else return FindMin(F, lo, mid) // Line 4
}
```

Call the function with `hi`

as the last index in the array

Line 1 is the base case.

Line 2 computes the middle index. Note that `mid < hi`

here, since `mid == hi`

implies `lo == hi`

, which is already covered in Line 1. So `mid`

never points to the last index in the array. So it's safe to check `F[mid+1]`

Line 3 checks whether `F[mid] > F[mid+1]`

, if it is, then `F[mid]`

can't be the answer, since it's bigger than some number, and `F[lo..mid-1]`

will also be bigger, so the answer must be in `F[mid+1..hi]`

. So call `FindMin(F, mid+1, hi)`

. Note that `mid+1 > lo`

, and so the range `mid+1..hi`

is smaller than `lo..hi`

.

Line 4: If we get here, that means `F[mid] < F[mid+1]`

. So the answer can be anywhere in `F[lo..mid]`

. So call `FindMin(F, lo, mid)`

. Note that since `mid < hi`

, `FindMin(F, lo, mid)`

will be different from `FindMin(F, lo, hi)`

. More specifically, the range decreases, like the case in Line 3.

Combining Line 3 and Line 4, each call to `FindMin`

is made with decreasing range, so the algorithm should stop after some time, which would be in the Line 1.