Example 2:

Input: [2,3,1,1,4]

Output: 3

Explanation:

From starting index i = 0, we make jumps to i = 1, i = 2, i = 3:

During our 1st jump (odd numbered), we first jump to i = 1 because A[1] is the smallest value in (A[1], A[2], A[3], A[4]) that is greater than or equal to A[0].

During our 2nd jump (even numbered), we jump from i = 1 to i = 2 because A[2] is the largest value in (A[2], A[3], A[4]) that is less than or equal to A[1].  A[3] is also the largest value, but 2 is a smaller index, so we can only jump to i = 2 and not i = 3.

During our 3rd jump (odd numbered), we jump from i = 2 to i = 3 because A[3] is the smallest value in (A[3], A[4]) that is greater than or equal to A[2].

We can't jump from i = 3 to i = 4, so the starting index i = 0 is not good.

In a similar manner, we can deduce that:

From starting index i = 1, we jump to i = 4, so we reach the end.

From starting index i = 2, we jump to i = 3, and then we can't jump anymore.

From starting index i = 3, we jump to i = 4, so we reach the end.

From starting index i = 4, we are already at the end.

In total, there are 3 different starting indexes (i = 1, i = 3, i = 4) where we can reach the end with some number of jumps.

Input: [5,1,3,4,2]

Output: 3

Explanation:

We can reach the end from starting indexes 1, 2, and 4.

class Solution {

private:

    unordered_map<int,bool> mpodd;

    unordered_map<int,bool> mpeven;

    vector<vector<int>> arr;

public:

    int oddEvenJumps(vector<int>& A) {

        for(int i=A.size()-; i>=; i--){

            int maxval = INT32_MAX, maxidx = -;

            int minval = INT32_MIN, minidx = -;

            for(int j=i+; j<A.size(); j++){

                if(A[j] >= A[i] && A[j] < maxval){

                    maxidx = j;

                    maxval = A[j];

                }

                if(A[j] <= A[i] && A[j] > minval){

                    minidx = j;

                    minval = A[j];

                }

            }

            vector<int> tmp = {maxidx, minidx};

            arr.push_back(tmp);

        }

        int ret = ;

        for(int i=A.size()-; i>=; i--){

            if(helper(A, i, true)) ret++;

        }

        return ret;

    }

    bool helper(vector<int>& A, int tmpidx, bool odd){

        if(tmpidx == A.size()-){

            mpodd[tmpidx] = true;

            mpeven[tmpidx] = true;

            return true;

        }else {

            if(odd){

                if(mpodd.count(tmpidx)) return mpodd[tmpidx];

                int nextidx = arr[A.size()- - tmpidx][];

                if(nextidx == -) return false;

                mpodd[tmpidx] = helper(A, nextidx, !odd);

                return mpodd[tmpidx];

            }else {

                if(mpeven.count(tmpidx)) return mpeven[tmpidx];

                int nextidx =arr[A.size()- - tmpidx][];

                if(nextidx == -) return false;

                mpeven[tmpidx] = helper(A, nextidx, !odd);

                return mpeven[tmpidx];

            }

        }

    }

};