The last question on my algorithms final has been driving me crazy for the past month. Here is the question:

You have an array

`A[0...n]`

, write an algorithm (in "proper" pseudocode) that runs in O(n) that can determine whether this array has already been partitioned relative to some index`k`

and if so, find`k`

; if not then return -1;

To clarify, by `Partition`

:

For each element

`e`

in`A[0...n]`

, if`e < A[k]`

place`e`

to the "left" of`A[k]`

, else put`e`

to the "right" of`A[k]`

.

So an example of a partitioned array (w.r.t. k = 11):

`A = [4 2 5 3 7 4 2 6 8 4 1`

10`10 10 20 11 15 13 28 99 11]`

then

```
myAlgo(A) -> (11)
```

or

`A = [10, 20, 30, 40, 11,`

100`, 150, 101, 125]`

then

```
myAlgo(A) -> (5)
```

but not:

`A = [10, 20, 30, 40, 5]`

```
myAlgo(A) -> (-1)
```

My first thought (which was incredibly naive) was so awful I literally can't put it into words. Basically, it inadvertently checked if the array were sorted and pulled a fairly random value out of the middle.

My next thought was to scan the list and first check to find the highest number that I hit just before hitting a decreasing number and ruling all of those numbers out... basically holding a max and a min and if things fall outside of both then shifting my possible partition index to the end of my subset.

Here is where I tried (very, very badly) to implement this (with a test case):

```
int myAlgo(const int* A, int n);
int main() {
const int A[] = {10, 20, 30, 40, 11, 100, 150, 101, 125};
int index;
if((index = myAlgo(A, 9)) != -1) {
printf("A[%d] = %d", index, A[index]);
}
else {
printf("Not Partitioned >:/");
}
return 0;
}
int myAlgo(const int* A, int n) {
// the index of the smallest possible number in the remainder of the list
int minIdx = 0;
// the index of the largest number we've encountered
int maxIdx = 0;
// index of possible partition "center"
int kIdx = 0;
bool isPart = false;
for(int i=0; i < n; ++i) {
if( A[maxIdx] <= A[i] ) {
maxIdx = i;
if(isPart == false) { kIdx = i; minIdx = i;} // if we flipped then this is a good time to grab a partitioner index
isPart = true;
}
else { isPart = false; minIdx = i; }
printf("A[%d] = %d <==> A[%d]: %d : %c\n", maxIdx, A[maxIdx], i, A[i], (isPart?'T':'F'));
if( A[minIdx] > A[i] ) { isPart = false; }
printf("A[%d] = %d <==> A[%d]: %d : %c\n", minIdx, A[minIdx], i, A[i], (isPart?'T':'F'));
}
printf("A[%d] = %d : %c\n\n", kIdx, A[kIdx], (isPart?'T':'F'));
// We gotta check this to make sure it is a valid list...
if(isPart) return kIdx;
else return -1;
}
```

But, not surprisingly, my output is thus:

```
A[0] = 10 <==> A[0]: 10 : T
A[0] = 10 <==> A[0]: 10 : T
A[1] = 20 <==> A[1]: 20 : T
A[0] = 10 <==> A[1]: 20 : T
A[2] = 30 <==> A[2]: 30 : T
A[0] = 10 <==> A[2]: 30 : T
A[3] = 40 <==> A[3]: 40 : T
A[0] = 10 <==> A[3]: 40 : T
A[3] = 40 <==> A[4]: 11 : F
A[4] = 11 <==> A[4]: 11 : F
A[5] = 100 <==> A[5]: 100 : T
A[5] = 100 <==> A[5]: 100 : T
A[6] = 150 <==> A[6]: 150 : T
A[5] = 100 <==> A[6]: 150 : T
A[6] = 150 <==> A[7]: 101 : F
A[7] = 101 <==> A[7]: 101 : F
A[6] = 150 <==> A[8]: 125 : F
A[8] = 125 <==> A[8]: 125 : F
A[5] = 100 : F
```**<-- The index is right... but **`isPart`

is wrong
Not Partitioned >:/

I would *really* like to be able to sleep tonight so any tips/hints/ideas/etc would be very, very appreciated.

## Woo! @Amit helped me solve my issue, here is my updated function:

```
int partIdx2(const int* A, int n) {
int* max = malloc(n * sizeof(int));
int* min = malloc(n * sizeof(int));
for(int i=0; i < n; i++)
{
if(i==0) {
max[i] = A[i];
min[n - 1] = A[n-1];
}
else {
max[i] = MAX(max[i-1], A[i]);
min[n - 1 - i] = MIN(min[n - 1 - i + 1], A[n - 1 - i]);
}
}
for(int i=1; i < n-1; i++) {
if(A[i] >= max[i-1] && A[i] <= min[i+1]) {
free(max);
free(min);
return i;
}
}
free(max);
free(min);
return -1;
}
```

`is_partitioned(...)`

(note that we are A. checking for general partitioned-ness and B. returning pivot index) we would have to call it for every element in our list (with our predicate being`x < A[pivot]`

) ... which would result in an O(n^2) complexity. – George Mitchell Aug 8 '13 at 21:25