org/study_deck_02/dsa/greedy/0045-jump-game-ii.org

#+PROPERTY: STUDY_DECK_02
* TODO 0045. Jump Game II :medium:
:PROPERTIES:
:NEETCODE: [[file:../../roadmap.org::*0045. Jump Game II][0045. Jump Game II]]
:END:

You are given a *0-indexed* array of integers ~nums~ of length ~n~. You are initially positioned at index 0.

Each element ~nums[i]~ represents the maximum length of a forward jump from index ~i~. In other words, if you are at index ~i~, you can jump to any index ~(i + j)~ where:

 - ~0 <= j <= nums[i]~ and

 - ~i + j < n~

Return /the minimum number of jumps to reach index /~n - 1~. The test cases are generated such that you can reach index ~n - 1~.

*Example 1:*


#+begin_src
Input: nums = [2,3,1,1,4]
Output: 2
Explanation: The minimum number of jumps to reach the last index is 2. Jump 1 step from index 0 to 1, then 3 steps to the last index.
#+end_src


*Example 2:*


#+begin_src
Input: nums = [2,3,0,1,4]
Output: 2
#+end_src


*Constraints:*

 - ~1 <= nums.length <= 10^{4}~

 - ~0 <= nums[i] <= 1000~

 - It's guaranteed that you can reach ~nums[n - 1]~.

** TODO Approach
Write your approach here.

** TODO Python
#+begin_src python
class Solution:
    def jump(self, nums: List[int]) -> int:
#+end_src

** TODO C++
#+begin_src cpp
class Solution {
public:
    int jump(vector<int>& nums) {
        
    }
};
#+end_src
refactor: move DSA notes to org/study_deck_02/ 2026-06-01 16:12:21 +08:00			`#+PROPERTY: STUDY_DECK_02`
fix: move #+PROPERTY: STUDY_DECK_02 to top of file 2026-06-01 17:12:10 +08:00			`* TODO 0045. Jump Game II :medium:`
Add solution notes scaffold and sub-heading format 2026-06-01 02:33:30 +08:00			`:PROPERTIES:`
feat: populate note files with problem descriptions and code stubs 2026-06-01 17:22:07 +08:00			`:NEETCODE: [[file:../../roadmap.org::*0045. Jump Game II][0045. Jump Game II]]`
Add solution notes scaffold and sub-heading format 2026-06-01 02:33:30 +08:00			`:END:`

feat: populate note files with problem descriptions and code stubs 2026-06-01 17:22:07 +08:00			`You are given a 0-indexed array of integers ~nums~ of length ~n~. You are initially positioned at index 0.`

			`Each element ~nums[i]~ represents the maximum length of a forward jump from index ~i~. In other words, if you are at index ~i~, you can jump to any index ~(i + j)~ where:`

			`- ~0 <= j <= nums[i]~ and`

			`- ~i + j < n~`

			`Return /the minimum number of jumps to reach index /~n - 1~. The test cases are generated such that you can reach index ~n - 1~.`

			`Example 1:`


			`#+begin_src`
			`Input: nums = [2,3,1,1,4]`
			`Output: 2`
			`Explanation: The minimum number of jumps to reach the last index is 2. Jump 1 step from index 0 to 1, then 3 steps to the last index.`
			`#+end_src`


			`Example 2:`


			`#+begin_src`
			`Input: nums = [2,3,0,1,4]`
			`Output: 2`
			`#+end_src`


			`Constraints:`

			`- ~1 <= nums.length <= 10^{4}~`

			`- ~0 <= nums[i] <= 1000~`

			`- It's guaranteed that you can reach ~nums[n - 1]~.`

Add TODO checkboxes to Python/C++ sub-headings 2026-06-01 02:39:53 +08:00			`** TODO Approach`
			`Write your approach here.`

			`** TODO Python`
			`#+begin_src python`
feat: populate note files with problem descriptions and code stubs 2026-06-01 17:22:07 +08:00			`class Solution:`
			`def jump(self, nums: List[int]) -> int:`
Add TODO checkboxes to Python/C++ sub-headings 2026-06-01 02:39:53 +08:00			`#+end_src`

			`** TODO C++`
Add solution notes scaffold and sub-heading format 2026-06-01 02:33:30 +08:00			`#+begin_src cpp`
feat: populate note files with problem descriptions and code stubs 2026-06-01 17:22:07 +08:00			`class Solution {`
			`public:`
			`int jump(vector<int>& nums) {`

			`}`
			`};`
Add solution notes scaffold and sub-heading format 2026-06-01 02:33:30 +08:00			`#+end_src`