The next greater element of some element x
in an array is the first greater element that is to the right of x
in the same array.
You are given two distinct 0-indexed integer arrays nums1
and nums2
, where nums1
is a subset of nums2
.
For each 0 <= i < nums1.length
, find the index j
such that nums1[i] == nums2[j]
and determine the next greater element of nums2[j]
in nums2
. If there is no next greater element, then the answer for this query is -1
.
Return an array ans
of length nums1.length
such that ans[i]
is the next greater element as described above.
Example 1:
Input: nums1 = [4,1,2], nums2 = [1,3,4,2] Output: [-1,3,-1] Explanation: The next greater element for each value of nums1 is as follows: - 4 is underlined in nums2 = [1,3,4,2]. There is no next greater element, so the answer is -1. - 1 is underlined in nums2 = [1,3,4,2]. The next greater element is 3. - 2 is underlined in nums2 = [1,3,4,2]. There is no next greater element, so the answer is -1.
Example 2:
Input: nums1 = [2,4], nums2 = [1,2,3,4] Output: [3,-1] Explanation: The next greater element for each value of nums1 is as follows: - 2 is underlined in nums2 = [1,2,3,4]. The next greater element is 3. - 4 is underlined in nums2 = [1,2,3,4]. There is no next greater element, so the answer is -1.
Constraints:
1 <= nums1.length <= nums2.length <= 1000
0 <= nums1[i], nums2[i] <= 104
- All integers in
nums1
andnums2
are unique. - All the integers of
nums1
also appear innums2
.
Follow up: Could you find an
O(nums1.length + nums2.length)
solution?
class Solution:
def nextGreaterElement(self, nums1: List[int], nums2: List[int]) -> List[int]:
m = {}
stk = []
for v in nums2:
while stk and stk[-1] < v:
m[stk.pop()] = v
stk.append(v)
return [m.get(v, -1) for v in nums1]
class Solution:
def nextGreaterElement(self, nums1: List[int], nums2: List[int]) -> List[int]:
m = {}
stk = []
for v in nums2[::-1]:
while stk and stk[-1] <= v:
stk.pop()
if stk:
m[v] = stk[-1]
stk.append(v)
return [m.get(x, -1) for x in nums1]
class Solution {
public int[] nextGreaterElement(int[] nums1, int[] nums2) {
Deque<Integer> stk = new ArrayDeque<>();
Map<Integer, Integer> m = new HashMap<>();
for (int v : nums2) {
while (!stk.isEmpty() && stk.peek() < v) {
m.put(stk.pop(), v);
}
stk.push(v);
}
int n = nums1.length;
int[] ans = new int[n];
for (int i = 0; i < n; ++i) {
ans[i] = m.getOrDefault(nums1[i], -1);
}
return ans;
}
}
class Solution {
public int[] nextGreaterElement(int[] nums1, int[] nums2) {
Deque<Integer> stk = new ArrayDeque<>();
Map<Integer, Integer> m = new HashMap<>();
for (int i = nums2.length - 1; i >= 0; --i) {
while (!stk.isEmpty() && stk.peek() <= nums2[i]) {
stk.pop();
}
if (!stk.isEmpty()) {
m.put(nums2[i], stk.peek());
}
stk.push(nums2[i]);
}
int n = nums1.length;
int[] ans = new int[n];
for (int i = 0; i < n; ++i) {
ans[i] = m.getOrDefault(nums1[i], -1);
}
return ans;
}
}
/**
* @param {number[]} nums1
* @param {number[]} nums2
* @return {number[]}
*/
var nextGreaterElement = function (nums1, nums2) {
let stk = [];
let m = {};
for (let v of nums2) {
while (stk && stk[stk.length - 1] < v) {
m[stk.pop()] = v;
}
stk.push(v);
}
return nums1.map(e => m[e] || -1);
};
/**
* @param {number[]} nums1
* @param {number[]} nums2
* @return {number[]}
*/
var nextGreaterElement = function (nums1, nums2) {
let stk = [];
let m = {};
for (let v of nums2.reverse()) {
while (stk && stk[stk.length - 1] <= v) {
stk.pop();
}
if (stk) {
m[v] = stk[stk.length - 1];
}
stk.push(v);
}
return nums1.map(e => m[e] || -1);
};
class Solution {
public:
vector<int> nextGreaterElement(vector<int>& nums1, vector<int>& nums2) {
stack<int> stk;
unordered_map<int, int> m;
for (int& v : nums2) {
while (!stk.empty() && stk.top() < v) {
m[stk.top()] = v;
stk.pop();
}
stk.push(v);
}
vector<int> ans;
for (int& v : nums1) ans.push_back(m.count(v) ? m[v] : -1);
return ans;
}
};
class Solution {
public:
vector<int> nextGreaterElement(vector<int>& nums1, vector<int>& nums2) {
stack<int> stk;
unordered_map<int, int> m;
for (int i = nums2.size() - 1; ~i; --i)
{
while (!stk.empty() && stk.top() <= nums2[i]) stk.pop();
if (!stk.empty()) m[nums2[i]] = stk.top();
stk.push(nums2[i]);
}
vector<int> ans;
for (int& v : nums1) ans.push_back(m.count(v) ? m[v] : -1);
return ans;
}
};
func nextGreaterElement(nums1 []int, nums2 []int) []int {
stk := []int{}
m := map[int]int{}
for _, v := range nums2 {
for len(stk) > 0 && stk[len(stk)-1] < v {
m[stk[len(stk)-1]] = v
stk = stk[:len(stk)-1]
}
stk = append(stk, v)
}
var ans []int
for _, v := range nums1 {
val, ok := m[v]
if !ok {
val = -1
}
ans = append(ans, val)
}
return ans
}
func nextGreaterElement(nums1 []int, nums2 []int) []int {
stk := []int{}
m := map[int]int{}
for i := len(nums2) - 1; i >= 0; i-- {
for len(stk) > 0 && stk[len(stk)-1] <= nums2[i] {
stk = stk[:len(stk)-1]
}
if len(stk) > 0 {
m[nums2[i]] = stk[len(stk)-1]
}
stk = append(stk, nums2[i])
}
var ans []int
for _, v := range nums1 {
val, ok := m[v]
if !ok {
val = -1
}
ans = append(ans, val)
}
return ans
}
function nextGreaterElement(nums1: number[], nums2: number[]): number[] {
const map = new Map<number, number>();
const stack: number[] = [Infinity];
for (const num of nums2) {
while (num > stack[stack.length - 1]) {
map.set(stack.pop(), num);
}
stack.push(num);
}
return nums1.map(num => map.get(num) || -1);
}
use std::collections::HashMap;
impl Solution {
pub fn next_greater_element(nums1: Vec<i32>, nums2: Vec<i32>) -> Vec<i32> {
let mut map = HashMap::new();
let mut stack = Vec::new();
for num in nums2 {
while num > *stack.last().unwrap_or(&i32::MAX) {
map.insert(stack.pop().unwrap(), num);
}
stack.push(num);
}
nums1
.iter()
.map(|n| *map.get(n).unwrap_or(&-1))
.collect::<Vec<i32>>()
}
}
impl Solution {
pub fn next_greater_element(nums1: Vec<i32>, nums2: Vec<i32>) -> Vec<i32> {
nums1.iter().map(|target| {
let mut res = -1;
for num in nums2.iter().rev() {
if num == target {
break;
}
if num > target {
res = *num;
}
}
res
}).collect::<Vec<i32>>()
}
}