## Overview

Given your array `a`

and the index of your current position `i`

, repeat the following until you reach the last element.

Consider all candidate "jump-to elements" in `a[i+1]`

to `a[a[i] + i]`

. For each such element at index `e`

, calculate `v`

= `a[e]`

+ `e`

. If one of the elements is the last element, jump to the last element. Otherwise, jump to the element with the maximal `v`

.

More simply put, of the elements within reach, look for the one that will get you furthest on the *next* jump. We know this selection, `x`

, is the right one because compared to every other element `y`

you can jump to, the elements reachable from `y`

are a subset of the elements reachable from `x`

(except for elements from a backward jump, which are obviously bad choices).

This algorithm runs in O(n) because each element need be considered only once (elements that would be considered a second time can be skipped).

## Example

Consider the array of values `a`

, indicies, `i`

, and sums of index and value `v`

.

```
i -> 0 1 2 3 4 5 6 7 8 9 10 11 12
a -> [4, 11, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1]
v -> 4 12 3 4 5 6 7 8 9 10 11 12 13
```

Start at index 0 and consider the next 4 elements. Find the one with maximal `v`

. That element is at index 1, so jump to 1. Now consider the next 11 elements. The goal is within reach, so jump to the goal.

## Demo

See here or here with code.