#18 Medium Array Two Pointers Sorting

4Sum — LeetCode 18

Find all unique quadruplets in an array that sum to a given target. Master the reduce-by-two-pointers pattern — the same intuition behind 3Sum, extended one level deeper.

Time O(n³)

Space O(1)

Difficulty Medium

Pattern Two Pointers

Companies Google · Amazon · Adobe

⚡ Complexity

O(n³)

Time

O(1)

Space

Acceptance rate37.8%

🏷 Key concepts

Two Pointers Sorting Deduplication K-Sum Pattern Array Overflow Guard

🔗 Related problems

#1 Two Sum

#15 3Sum

#16 3Sum Closest

#454 4Sum II

#259 3Sum Smaller

💡 Interview tip

Mention the K-Sum generalisation upfront — show you see the recursive pattern, not just the specific case.

Always cast to long before summing — overflow is a real trap and interviewers watch for it.

📋

Problem statement

Given an array nums of n integers and an integer target, return all unique quadruplets [nums[a], nums[b], nums[c], nums[d]] such that:

• 0 <= a, b, c, d < n
• a, b, c, d are distinct indices
• nums[a] + nums[b] + nums[c] + nums[d] == target

You may return the answer in any order. The result must not contain duplicate quadruplets.

🧪

Examples

Example 1

Input nums = [1,0,-1,0,-2,2],  target = 0

Output [[-2,-1,1,2],[-2,0,0,2],[-1,0,0,1]]

Explanation: After sorting → [-2,-1,0,0,1,2]. Three unique quadruplets sum to 0: -2+(-1)+1+2 = 0  |  -2+0+0+2 = 0  |  -1+0+0+1 = 0

Example 2

Input nums = [2,2,2,2,2],  target = 8

Output [[2,2,2,2]]

Explanation: Only one unique quadruplet exists even though the value 2 appears five times. Duplicate-skip logic collapses all repeats into a single result.

👁

Pointer movement

Sorted array: [-2, -1, 0, 0, 1, 2]  target = 0

■ i — outer fix ■ j — inner fix ■ L — left ptr ■ R — right ptr

Step 1 — i=0(-2), j=1(-1), L=2(0), R=5(2) → sum=-1 < 0 → move L right

i

-2

[0]

j

-1

[1]

L

0

[2]

0

[3]

1

[4]

R

2

[5]

-2 + (-1) + 0 + 2 = -1 < target(0) → L++

Step 2 — L=4(1), R=5(2) → sum=0 ✓ FOUND [-2,-1,1,2]

i

-2

[0]

j

-1

[1]

0

[2]

0

[3]

L

1

[4]

R

2

[5]

-2 + (-1) + 1 + 2 = 0 ✓ → Record [-2,-1,1,2]

Step 3 — j=2(0), L=3(0), R=5(2) → sum=0 ✓ FOUND [-2,0,0,2]

i

-2

[0]

-1

[1]

j

0

[2]

L

0

[3]

1

[4]

R

2

[5]

-2 + 0 + 0 + 2 = 0 ✓ → Record [-2,0,0,2]

Step 4 — i=1(-1), j=2(0), L=3(0), R=4(1) → sum=0 ✓ FOUND [-1,0,0,1]

-2

[0]

i

-1

[1]

j

0

[2]

L

0

[3]

R

1

[4]

2

[5]

-1 + 0 + 0 + 1 = 0 ✓ → Record [-1,0,0,1] · Done!

🧠

Intuition & approach

💡

Core insight: Reduce 4Sum → 3Sum → 2Sum. Fix two outer pointers with nested loops, then use a two-pointer sweep on the remaining subarray. Sorting enables both the two-pointer technique and O(1) duplicate skipping.

1

Sort the array

Call Arrays.sort(nums). This enables two-pointer convergence (sorted order guarantees that moving L right increases the sum, moving R left decreases it) and makes duplicate detection trivial — equals-previous means skip.

2

Fix i — first outer loop

Iterate i from 0 to n-4. If i > 0 and nums[i] == nums[i-1], skip — we've already explored all quadruplets starting with this value. This prevents duplicate quadruplets at the first position.

3

Fix j — second outer loop

Iterate j from i+1 to n-3. Skip duplicates with: if j > i+1 and nums[j] == nums[j-1]. Note the guard is j > i+1 not j > 0 — we only skip when it's not the very first j in this i iteration.

4

Two-pointer sweep: L and R

Set L = j+1, R = n-1. While L < R:
· sum == target → record, skip inner duplicates on both sides, advance both pointers.
· sum < target → L++ (need bigger value).
· sum > target → R-- (need smaller value).

5

Guard against integer overflow

With constraints up to 10⁹, four values can sum to 4×10⁹ — well beyond int range (~2.1×10⁹). Cast at least one operand to long before any addition: (long)nums[i] + nums[j] + nums[L] + nums[R].

⚠

Common mistake: Using j > 0 instead of j > i+1 for the j-duplicate skip. This incorrectly skips the very first j value after i, causing missed results.

💻

Java solution — optimal two-pointer

Java

import java.util.*;

class Solution {
    public List<List<Integer>> fourSum(int[] nums, int target) {
        Arrays.sort(nums);                            // O(n log n)
        List<List<Integer>> result = new ArrayList<>();
        int n = nums.length;

        for (int i = 0; i < n - 3; i++) {
            // Skip duplicate values for i
            if (i > 0 && nums[i] == nums[i - 1]) continue;

            for (int j = i + 1; j < n - 2; j++) {
                // Skip duplicate values for j (guard: j > i+1, not j > 0)
                if (j > i + 1 && nums[j] == nums[j - 1]) continue;

                int left = j + 1, right = n - 1;

                while (left < right) {
                    // Cast to long — prevents integer overflow
                    long sum = (long) nums[i] + nums[j] + nums[left] + nums[right];

                    if (sum == target) {
                        result.add(Arrays.asList(nums[i], nums[j], nums[left], nums[right]));

                        // Skip duplicates for left pointer
                        while (left < right && nums[left] == nums[left + 1]) left++;
                        // Skip duplicates for right pointer
                        while (left < right && nums[right] == nums[right - 1]) right--;

                        left++;    // Move both inward after recording
                        right--;

                    } else if (sum < target) {
                        left++;    // Sum too small → grow it
                    } else {
                        right--;   // Sum too large → shrink it
                    }
                }
            }
        }
        return result;
    }
}

♾

Bonus — generalised K-Sum (recursive)

The two-pointer pattern extends cleanly to any K. Fix k-2 pointers recursively, then apply two-pointer at depth 2. This single function handles 2Sum, 3Sum, 4Sum — and beyond.

Java

class Solution {
    public List<List<Integer>> fourSum(int[] nums, int target) {
        Arrays.sort(nums);
        return kSum(nums, (long) target, 0, 4);
    }

    private List<List<Integer>> kSum(int[] nums, long target, int start, int k) {
        List<List<Integer>> res = new ArrayList<>();
        if (start == nums.length || k < 2) return res;

        if (k == 2) {           // Base case: classic two-pointer
            int l = start, r = nums.length - 1;
            while (l < r) {
                long sum = nums[l] + nums[r];
                if      (sum == target) { res.add(new ArrayList<>(Arrays.asList(nums[l++], nums[r--])); }
                else if (sum <  target) l++;
                else                    r--;
                while (l < r && l > start     && nums[l] == nums[l-1]) l++;
                while (l < r && r < nums.length-1 && nums[r] == nums[r+1]) r--;
            }
            return res;
        }

        for (int i = start; i < nums.length - k + 1; i++) {
            if (i > start && nums[i] == nums[i - 1]) continue;
            for (List<Integer> subset : kSum(nums, target - nums[i], i + 1, k - 1)) {
                subset.0.add(0, nums[i]);    // prepend current element
                res.add(subset);
            }
        }
        return res;
    }
}

📊

Approach comparison

Approach	Time	Space	Notes
Sort + Two Pointers ✓	O(n³)	O(1)	Optimal. What LeetCode expects. Handles duplicates cleanly.
Fix 2 + HashMap	O(n³)	O(n)	Same time. Extra space. Dedup via Set of Lists is slower.
Recursive K-Sum	O(n³)	O(n)	Elegant. Generalises to any K. Slightly more call-stack overhead.
4 Nested Loops	O(n⁴)	O(1)	TLE beyond n≈50. Only useful for tiny inputs.