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competitive-programming/2023_11_16/longest-increasing-subsequence
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Luca Lombardo de0b29db31 longest increasing subsequence DP solution 6 months ago
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src longest increasing subsequence DP solution 6 months ago
Cargo.toml longest increasing subsequence DP solution 6 months ago
README.md longest increasing subsequence DP solution 6 months ago

README.md

Longest Increasing Subsequence

Let's have a look at how this algorithm for finding the longest increasing subsequence works:

impl Solution {
    pub fn length_of_lis(nums: Vec<i32>) -> i32 {
        let mut ans: Vec<i32> = Vec::new();
        ans.push(nums[0]);

        for &num in nums[1..].iter() {
            if num > *ans.last().unwrap() {
                ans.push(num);
            } else {
                let mut low = 0;
                let mut high = ans.len() - 1;
                while low < high {
                    let mid = low + (high - low) / 2;
                    if ans[mid] < num {
                        low = mid + 1;
                    } else {
                        high = mid;
                    }
                }
                ans[low] = num;
            }
        }
        ans.len() as i32
    }
}

  • It initializes an empty vector ans and pushes the first element of the input vector into it.

  • It then iterates over the rest of the input vector. For each number:

    • If the number is greater than the last number in ans, it pushes the number into ans.
    • If the number is not greater, it performs a binary search in ans to find the first number that is not less than the current number and replaces it with the current number. This is done using a while loop that adjusts the low and high indices until low is no longer less than high. The loop invariant is that ans[low] is the first number in ans that is not less than the current number. The loop terminates when low and high are equal, and low is the index of the first number in ans that is not less than the current number. The current number is then inserted into ans at index low, replacing the existing number which is larger.

  • Finally, it returns the length of ans as the length of the longest increasing subsequence.

This algorithm works because ans always contains the smallest tail elements for all increasing subsequences of the same length. When a new number comes in, if it is larger than all tail elements, it extends the longest increasing subsequence. If it is not, it can potentially become a tail element of an increasing subsequence of a certain length, replacing the existing larger one.

Complexity Analysis

  • Time complexity : O(n \log n). Binary search takes \log n time and it is called $n$ times.
  • Space complexity : O(n). The size of ans can grow up to n.