# Linear time algorithm for Minimum number of jumps required to reach end

Problem: Minimum number of jumps to reach end

Given an array of integers where each element represents the max number of steps that can be made forward from that element. Write a function to return the minimum number of jumps to reach the end of the array (starting from the first element). If an element is 0, then cannot move through that element.

Example:

Input: arr[] = {1, 3, 5, 8, 9, 2, 6, 7, 6, 8, 9} Output: 3 (1-> 3 -> 8 ->9) First element is 1, so can only go to 3. Second element is 3, so can make at most 3 steps eg to 5 or 8 or 9.

I have made a linear time algorithm for finding Minimum number of jumps required to reach end for an array.

The source code is as below:

``````int minJumpsUpdated(int arr[], int n)
{
int *jumps = malloc(n * sizeof(int));  // jumps[n-1] will hold the result
int i =1, j = 0;

jumps[0] = 0;
for (i = 1; i < n; ) {

// if i is out of range of arr[j], then increment j
if (arr[j] + j < i && j < i) {

j++;

// else if i is within range of arr[j],
//   jumps for ith element would be jumps[j]+1
} else if (arr[j] + j >= i && j < i) {

jumps[i] = jumps[j] + 1;
i++;

} else {
printf("solution does not exist");
return -1;
}
}

printf("jumps: ");
for (i = 0; i < n; i++) {
printf("%d, ", jumps[i]);
}
return jumps[n - 1];
}
``````

Example:

1.) initially `i=1, j=0` and `arr[] = {1, 3, 6, 1, 0, 9};`

``````jumps[] = 0,0,0,0,0,0
``````

2.) as `i` is within range of `arr[j]` ie. `i<= j+arr[j]`, number of jumps required to go to ith position would be min number of jumps till jth position + 1.

``````i=2, j=0, jumps[] = 0,1,0,0,0,0
``````

3.) `i>j+arr[j]` i.e. `j++;`

``````i=2, j=1, jumps[] = 0,1,0,0,0,0
``````

4.) `i<=j+arr[j]` i.e. `jumps[i] = jumps[j]+1;`

``````i=3, j=1, jumps[] = 0,1,2,0,0,0
``````

5.) `i<=j+arr[j]` i.e. `jumps[i] = jumps[j]+1;`

``````i=4, j=1, jumps[] = 0,1,2,2,0,0
``````

6.) `i<=j+arr[j]` i.e. `jumps[i] = jumps[j]+1;`

``````i=5, j=1, jumps[] = 0,1,2,2,2,0
``````

7.) `i>j+arr[j]` i.e. `j++;`

``````i=5, j=2, jumps[] = 0,1,2,2,2,0
``````

8.) `i<=j+arr[j]` i.e. `jumps[i] = jumps[j]+1;`

``````i=6, j=2, jumps[] = 0,1,2,2,2,2
``````

------ END ------

I am not able to figure out under which test case this program will not work? I am asking this because on internet the optimized solution is using DP which is o(n^2). My solution is linear time. i.e. o(n). So I am assuming there are some cases which this algorithm will not handle. So I am curious what cases it does not handle.

Your help will be appreciated.

Thank you.

-
@Jarod42 I tried to improve a bit. –  Grijesh Chauhan Apr 25 '14 at 19:32
Thank you Grijesh. –  AlienOnEarth Apr 25 '14 at 19:36
Hm, we only have your program, and no description what it is supposed to do. If the program is just your problem description, then yes, it will always work, trivially. And since it is always linear, it can't describe the problem properly if somebody has proven a lower bound of `n²` for the original problem, obviously. So please give us a clear definition of the problem you are supposed to solve. Also: you might remove the C++ tag, this is C. Then, don't cast return of `malloc` and don't forget to `free` your array at the end. –  Jens Gustedt Apr 25 '14 at 19:42
@JensGustedt: I have added problem statement. Also, I will make sure I free memory allocated. Thank you very much for pointing it out. –  AlienOnEarth Apr 25 '14 at 19:48
You have added a link to a problem statement, not the problem statement. –  Jens Gustedt Apr 25 '14 at 20:25

I think your code is only correct if there is a solution, what if there is no solution for example what if the input is [0, 2 , 3 , 4] ?

Other than that I think your algorithm is correct, here is my solution when I solved this problem, it only need constant space, and still linear time. Basically for each step, you only jump to the position that could jump most steps in next step.

``````int jump(int A[], int n) {
int jumps = 0;
if(n < 2){
return jumps;
}
int cur = 0; // current index,
int cur_step;// number of step you can jump in current index
int last;    // last index
int temp_max = cur; // temporary max jump distance
int temp_index = cur;// temporary index.

while(cur < n){
last = cur;
cur_step = A[cur];
if((cur + cur_step) >= n-1){ // if reached end of the array, return.
jumps++;
return jumps;
}
for(int ii = cur + 1; ii <= cur + cur_step; ii++){//go thru all the possible next position, and find the one that could jump most steps.
if(A[ii] == 0){
continue;
}
if(A[ii] + ii > temp_max){ // find the one that could jump most steps.
temp_index = ii;
temp_max = A[ii] + ii;
}
}
cur = temp_index; // jump to this position, temp index holds index that jump most steps in next jump.
if(cur != last){
jumps++;
}else{
break;
}
}
return -1;

}
};
``````
-
Thank you for your inputs. I have updated my code to handle case where solution does not exist. –  AlienOnEarth Apr 25 '14 at 21:52

Summary of your algorithm:

1. Take the first item and look how far you can get with this
(incrementing `i` until `arr[j]+j < i`)
2. Go to the next item that you can reach from the first one and that takes you at least to `i`th item.
3. Repeat this until you reach the last entry.

First:
Yes it runs in `O(n)` since the algorithm pushes both `i` an `j` only one time from `1` to `n` in worst case.

Second
I have not seen a proof that `O(n²)` is the optimal time-complexity.

Thrid
You can visualise the `arr` like this
so this is exactly what your algorithm does. You can use this to proof by induction that your algorithm is correct. But as @Leo mentioned, there has to be a solution.

Fix for no-solution-case
make sure that `j < i` holds

EDIT Sorry, I screwed up the image a little bit but I think it is clear what I meant.

-
Cool visualization :) –  Niklas B. Apr 25 '14 at 22:28
The visualization makes it look like the algorithm here is not O(n), and makes it look like O(N^2). Imagine input {9,8,7,6,5,4,3,2,1,0}. –  Mooing Duck Feb 6 at 0:14
The algorithm in the question contains two not nested loops that run in linear time. I realy don't see where the quadratic complexity should come from. The visualization does not show the complexity. –  AbcAeffchen Feb 6 at 0:47