给定一个整数数组 nums 和一个整数目标值 target,请你在该数组中找出 和为目标值 target 的那 两个 整数,并返回它们的数组下标。
你可以假设每种输入只会对应一个答案。但是,数组中同一个元素在答案里不能重复出现。
你可以按任意顺序返回答案。
示例 1:
输入:nums = [2,7,11,15], target = 9 输出:[0,1] 解释:因为 nums[0] + nums[1] == 9 ,返回 [0, 1] 。
示例 2:
输入:nums = [3,2,4], target = 6 输出:[1,2]
示例 3:
输入:nums = [3,3], target = 6 输出:[0,1]
提示:
2 <= nums.length <= 104-109 <= nums[i] <= 109-109 <= target <= 109- 只会存在一个有效答案
进阶:你可以想出一个时间复杂度小于 O(n2) 的算法吗?
方法一:哈希表
我们可以用哈希表
遍历数组 nums,当发现 target - nums[i] 在哈希表中,说明找到了目标值,返回 target - nums[i] 的下标以及
时间复杂度 nums 的长度。
class Solution:
def twoSum(self, nums: List[int], target: int) -> List[int]:
m = {}
for i, x in enumerate(nums):
y = target - x
if y in m:
return [m[y], i]
m[x] = iclass Solution {
public int[] twoSum(int[] nums, int target) {
Map<Integer, Integer> m = new HashMap<>();
for (int i = 0;; ++i) {
int x = nums[i];
int y = target - x;
if (m.containsKey(y)) {
return new int[] {m.get(y), i};
}
m.put(x, i);
}
}
}class Solution {
public:
vector<int> twoSum(vector<int>& nums, int target) {
unordered_map<int, int> m;
for (int i = 0; ; ++i) {
int x = nums[i];
int y = target - x;
if (m.count(y)) {
return {m[y], i};
}
m[x] = i;
}
}
};func twoSum(nums []int, target int) []int {
m := map[int]int{}
for i := 0; ; i++ {
x := nums[i]
y := target - x
if j, ok := m[y]; ok {
return []int{j, i}
}
m[x] = i
}
}/**
* @param {number[]} nums
* @param {number} target
* @return {number[]}
*/
var twoSum = function (nums, target) {
const m = new Map();
for (let i = 0; ; ++i) {
const x = nums[i];
const y = target - x;
if (m.has(y)) {
return [m.get(y), i];
}
m.set(x, i);
}
};public class Solution {
public int[] TwoSum(int[] nums, int target) {
var m = new Dictionary<int, int>();
for (int i = 0, j; ; ++i) {
int x = nums[i];
int y = target - x;
if (m.TryGetValue(y, out j)) {
return new [] {j, i};
}
if (!m.ContainsKey(x)) {
m.Add(x, i);
}
}
}
}class Solution {
func twoSum(_ nums: [Int], _ target: Int) -> [Int] {
var m = [Int: Int]()
var i = 0
while true {
let x = nums[i]
let y = target - nums[i]
if let j = m[target - nums[i]] {
return [j, i]
}
m[nums[i]] = i
i += 1
}
}
}use std::collections::HashMap;
impl Solution {
pub fn two_sum(nums: Vec<i32>, target: i32) -> Vec<i32> {
let mut map = HashMap::new();
for (i, item) in nums.iter().enumerate() {
if map.contains_key(item) {
return vec![i as i32, map[item]];
} else {
let x = target - nums[i];
map.insert(x, i as i32);
}
}
unreachable!()
}
}import std/enumerate
proc twoSum(nums: seq[int], target: int): seq[int] =
var
bal: int
tdx: int
for idx, val in enumerate(nums):
bal = target - val
if bal in nums:
tdx = nums.find(bal)
if idx != tdx:
return @[idx, tdx]class Solution {
/**
* @param Integer[] $nums
* @param Integer $target
* @return Integer[]
*/
function twoSum($nums, $target) {
$len = count($nums);
for ($i = 0; $i < $len; $i++) {
for ($j = 1 + $i; $j < $len; $j++) {
if ($nums[$i] + $nums[$j] == $target) {
return [$i, $j];
}
}
}
}
}