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457 lines
18 KiB
Markdown
457 lines
18 KiB
Markdown
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---
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comments: true
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---
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# 8.3 Top-k problem
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!!! question
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Given an unordered array `nums` of length $n$, return the largest $k$ elements in the array.
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For this problem, we will first introduce two straightforward solutions, then explain a more efficient heap-based method.
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## 8.3.1 Method 1: Iterative selection
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We can perform $k$ rounds of iterations as shown in the Figure 8-6 , extracting the $1^{st}$, $2^{nd}$, $\dots$, $k^{th}$ largest elements in each round, with a time complexity of $O(nk)$.
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This method is only suitable when $k \ll n$, as the time complexity approaches $O(n^2)$ when $k$ is close to $n$, which is very time-consuming.
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![Iteratively finding the largest k elements](top_k.assets/top_k_traversal.png){ class="animation-figure" }
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<p align="center"> Figure 8-6 Iteratively finding the largest k elements </p>
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!!! tip
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When $k = n$, we can obtain a complete ordered sequence, which is equivalent to the "selection sort" algorithm.
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## 8.3.2 Method 2: Sorting
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As shown in the Figure 8-7 , we can first sort the array `nums` and then return the last $k$ elements, with a time complexity of $O(n \log n)$.
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Clearly, this method "overachieves" the task, as we only need to find the largest $k$ elements, without the need to sort the other elements.
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![Sorting to find the largest k elements](top_k.assets/top_k_sorting.png){ class="animation-figure" }
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<p align="center"> Figure 8-7 Sorting to find the largest k elements </p>
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## 8.3.3 Method 3: Heap
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We can solve the Top-k problem more efficiently based on heaps, as shown in the following process.
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1. Initialize a min heap, where the top element is the smallest.
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2. First, insert the first $k$ elements of the array into the heap.
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3. Starting from the $k + 1^{th}$ element, if the current element is greater than the top element of the heap, remove the top element of the heap and insert the current element into the heap.
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4. After completing the traversal, the heap contains the largest $k$ elements.
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=== "<1>"
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![Find the largest k elements based on heap](top_k.assets/top_k_heap_step1.png){ class="animation-figure" }
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=== "<2>"
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![top_k_heap_step2](top_k.assets/top_k_heap_step2.png){ class="animation-figure" }
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=== "<3>"
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![top_k_heap_step3](top_k.assets/top_k_heap_step3.png){ class="animation-figure" }
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=== "<4>"
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![top_k_heap_step4](top_k.assets/top_k_heap_step4.png){ class="animation-figure" }
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=== "<5>"
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![top_k_heap_step5](top_k.assets/top_k_heap_step5.png){ class="animation-figure" }
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=== "<6>"
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![top_k_heap_step6](top_k.assets/top_k_heap_step6.png){ class="animation-figure" }
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=== "<7>"
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![top_k_heap_step7](top_k.assets/top_k_heap_step7.png){ class="animation-figure" }
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=== "<8>"
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![top_k_heap_step8](top_k.assets/top_k_heap_step8.png){ class="animation-figure" }
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=== "<9>"
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![top_k_heap_step9](top_k.assets/top_k_heap_step9.png){ class="animation-figure" }
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<p align="center"> Figure 8-8 Find the largest k elements based on heap </p>
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Example code is as follows:
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=== "Python"
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```python title="top_k.py"
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def top_k_heap(nums: list[int], k: int) -> list[int]:
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"""基于堆查找数组中最大的 k 个元素"""
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# 初始化小顶堆
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heap = []
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# 将数组的前 k 个元素入堆
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for i in range(k):
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heapq.heappush(heap, nums[i])
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# 从第 k+1 个元素开始,保持堆的长度为 k
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for i in range(k, len(nums)):
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# 若当前元素大于堆顶元素,则将堆顶元素出堆、当前元素入堆
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if nums[i] > heap[0]:
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heapq.heappop(heap)
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heapq.heappush(heap, nums[i])
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return heap
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```
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=== "C++"
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```cpp title="top_k.cpp"
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/* 基于堆查找数组中最大的 k 个元素 */
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priority_queue<int, vector<int>, greater<int>> topKHeap(vector<int> &nums, int k) {
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// 初始化小顶堆
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priority_queue<int, vector<int>, greater<int>> heap;
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// 将数组的前 k 个元素入堆
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for (int i = 0; i < k; i++) {
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heap.push(nums[i]);
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}
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// 从第 k+1 个元素开始,保持堆的长度为 k
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for (int i = k; i < nums.size(); i++) {
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// 若当前元素大于堆顶元素,则将堆顶元素出堆、当前元素入堆
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if (nums[i] > heap.top()) {
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heap.pop();
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heap.push(nums[i]);
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}
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}
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return heap;
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}
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```
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=== "Java"
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```java title="top_k.java"
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/* 基于堆查找数组中最大的 k 个元素 */
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Queue<Integer> topKHeap(int[] nums, int k) {
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// 初始化小顶堆
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Queue<Integer> heap = new PriorityQueue<Integer>();
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// 将数组的前 k 个元素入堆
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for (int i = 0; i < k; i++) {
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heap.offer(nums[i]);
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}
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// 从第 k+1 个元素开始,保持堆的长度为 k
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for (int i = k; i < nums.length; i++) {
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// 若当前元素大于堆顶元素,则将堆顶元素出堆、当前元素入堆
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if (nums[i] > heap.peek()) {
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heap.poll();
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heap.offer(nums[i]);
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}
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}
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return heap;
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}
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```
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=== "C#"
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```csharp title="top_k.cs"
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/* 基于堆查找数组中最大的 k 个元素 */
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PriorityQueue<int, int> TopKHeap(int[] nums, int k) {
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// 初始化小顶堆
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PriorityQueue<int, int> heap = new();
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// 将数组的前 k 个元素入堆
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for (int i = 0; i < k; i++) {
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heap.Enqueue(nums[i], nums[i]);
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}
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// 从第 k+1 个元素开始,保持堆的长度为 k
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for (int i = k; i < nums.Length; i++) {
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// 若当前元素大于堆顶元素,则将堆顶元素出堆、当前元素入堆
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if (nums[i] > heap.Peek()) {
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heap.Dequeue();
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heap.Enqueue(nums[i], nums[i]);
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}
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}
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return heap;
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}
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```
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=== "Go"
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```go title="top_k.go"
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/* 基于堆查找数组中最大的 k 个元素 */
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func topKHeap(nums []int, k int) *minHeap {
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// 初始化小顶堆
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h := &minHeap{}
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heap.Init(h)
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// 将数组的前 k 个元素入堆
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for i := 0; i < k; i++ {
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heap.Push(h, nums[i])
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}
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// 从第 k+1 个元素开始,保持堆的长度为 k
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for i := k; i < len(nums); i++ {
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// 若当前元素大于堆顶元素,则将堆顶元素出堆、当前元素入堆
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if nums[i] > h.Top().(int) {
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heap.Pop(h)
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heap.Push(h, nums[i])
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}
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}
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return h
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}
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```
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=== "Swift"
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```swift title="top_k.swift"
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/* 基于堆查找数组中最大的 k 个元素 */
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func topKHeap(nums: [Int], k: Int) -> [Int] {
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// 初始化一个小顶堆,并将前 k 个元素建堆
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var heap = Heap(nums.prefix(k))
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// 从第 k+1 个元素开始,保持堆的长度为 k
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for i in nums.indices.dropFirst(k) {
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// 若当前元素大于堆顶元素,则将堆顶元素出堆、当前元素入堆
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if nums[i] > heap.min()! {
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_ = heap.removeMin()
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heap.insert(nums[i])
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}
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}
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return heap.unordered
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}
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```
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=== "JS"
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```javascript title="top_k.js"
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/* 元素入堆 */
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function pushMinHeap(maxHeap, val) {
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// 元素取反
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maxHeap.push(-val);
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}
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/* 元素出堆 */
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function popMinHeap(maxHeap) {
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// 元素取反
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return -maxHeap.pop();
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}
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/* 访问堆顶元素 */
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function peekMinHeap(maxHeap) {
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// 元素取反
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return -maxHeap.peek();
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}
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/* 取出堆中元素 */
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function getMinHeap(maxHeap) {
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// 元素取反
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return maxHeap.getMaxHeap().map((num) => -num);
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}
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/* 基于堆查找数组中最大的 k 个元素 */
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function topKHeap(nums, k) {
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// 初始化小顶堆
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// 请注意:我们将堆中所有元素取反,从而用大顶堆来模拟小顶堆
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const maxHeap = new MaxHeap([]);
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// 将数组的前 k 个元素入堆
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for (let i = 0; i < k; i++) {
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pushMinHeap(maxHeap, nums[i]);
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}
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// 从第 k+1 个元素开始,保持堆的长度为 k
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for (let i = k; i < nums.length; i++) {
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// 若当前元素大于堆顶元素,则将堆顶元素出堆、当前元素入堆
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if (nums[i] > peekMinHeap(maxHeap)) {
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popMinHeap(maxHeap);
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pushMinHeap(maxHeap, nums[i]);
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}
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}
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// 返回堆中元素
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return getMinHeap(maxHeap);
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}
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```
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=== "TS"
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```typescript title="top_k.ts"
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/* 元素入堆 */
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function pushMinHeap(maxHeap: MaxHeap, val: number): void {
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// 元素取反
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maxHeap.push(-val);
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}
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/* 元素出堆 */
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function popMinHeap(maxHeap: MaxHeap): number {
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// 元素取反
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return -maxHeap.pop();
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}
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/* 访问堆顶元素 */
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function peekMinHeap(maxHeap: MaxHeap): number {
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// 元素取反
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return -maxHeap.peek();
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}
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/* 取出堆中元素 */
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function getMinHeap(maxHeap: MaxHeap): number[] {
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// 元素取反
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return maxHeap.getMaxHeap().map((num: number) => -num);
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}
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/* 基于堆查找数组中最大的 k 个元素 */
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function topKHeap(nums: number[], k: number): number[] {
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// 初始化小顶堆
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// 请注意:我们将堆中所有元素取反,从而用大顶堆来模拟小顶堆
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const maxHeap = new MaxHeap([]);
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// 将数组的前 k 个元素入堆
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for (let i = 0; i < k; i++) {
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pushMinHeap(maxHeap, nums[i]);
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}
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// 从第 k+1 个元素开始,保持堆的长度为 k
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for (let i = k; i < nums.length; i++) {
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// 若当前元素大于堆顶元素,则将堆顶元素出堆、当前元素入堆
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if (nums[i] > peekMinHeap(maxHeap)) {
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popMinHeap(maxHeap);
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pushMinHeap(maxHeap, nums[i]);
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}
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}
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// 返回堆中元素
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return getMinHeap(maxHeap);
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}
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```
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=== "Dart"
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```dart title="top_k.dart"
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/* 基于堆查找数组中最大的 k 个元素 */
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MinHeap topKHeap(List<int> nums, int k) {
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// 初始化小顶堆,将数组的前 k 个元素入堆
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MinHeap heap = MinHeap(nums.sublist(0, k));
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// 从第 k+1 个元素开始,保持堆的长度为 k
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for (int i = k; i < nums.length; i++) {
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// 若当前元素大于堆顶元素,则将堆顶元素出堆、当前元素入堆
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if (nums[i] > heap.peek()) {
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heap.pop();
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heap.push(nums[i]);
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}
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}
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return heap;
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}
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```
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=== "Rust"
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```rust title="top_k.rs"
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/* 基于堆查找数组中最大的 k 个元素 */
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fn top_k_heap(nums: Vec<i32>, k: usize) -> BinaryHeap<Reverse<i32>> {
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// BinaryHeap 是大顶堆,使用 Reverse 将元素取反,从而实现小顶堆
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let mut heap = BinaryHeap::<Reverse<i32>>::new();
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// 将数组的前 k 个元素入堆
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for &num in nums.iter().take(k) {
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heap.push(Reverse(num));
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}
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// 从第 k+1 个元素开始,保持堆的长度为 k
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for &num in nums.iter().skip(k) {
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// 若当前元素大于堆顶元素,则将堆顶元素出堆、当前元素入堆
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if num > heap.peek().unwrap().0 {
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heap.pop();
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heap.push(Reverse(num));
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}
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}
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heap
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}
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```
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=== "C"
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```c title="top_k.c"
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/* 元素入堆 */
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void pushMinHeap(MaxHeap *maxHeap, int val) {
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// 元素取反
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push(maxHeap, -val);
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}
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/* 元素出堆 */
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int popMinHeap(MaxHeap *maxHeap) {
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// 元素取反
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return -pop(maxHeap);
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}
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/* 访问堆顶元素 */
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int peekMinHeap(MaxHeap *maxHeap) {
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// 元素取反
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return -peek(maxHeap);
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}
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/* 取出堆中元素 */
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int *getMinHeap(MaxHeap *maxHeap) {
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// 将堆中所有元素取反并存入 res 数组
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int *res = (int *)malloc(maxHeap->size * sizeof(int));
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for (int i = 0; i < maxHeap->size; i++) {
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res[i] = -maxHeap->data[i];
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}
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return res;
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}
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/* 取出堆中元素 */
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int *getMinHeap(MaxHeap *maxHeap) {
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// 将堆中所有元素取反并存入 res 数组
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int *res = (int *)malloc(maxHeap->size * sizeof(int));
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for (int i = 0; i < maxHeap->size; i++) {
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res[i] = -maxHeap->data[i];
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}
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return res;
|
||
|
}
|
||
|
|
||
|
// 基于堆查找数组中最大的 k 个元素的函数
|
||
|
int *topKHeap(int *nums, int sizeNums, int k) {
|
||
|
// 初始化小顶堆
|
||
|
// 请注意:我们将堆中所有元素取反,从而用大顶堆来模拟小顶堆
|
||
|
int *empty = (int *)malloc(0);
|
||
|
MaxHeap *maxHeap = newMaxHeap(empty, 0);
|
||
|
// 将数组的前 k 个元素入堆
|
||
|
for (int i = 0; i < k; i++) {
|
||
|
pushMinHeap(maxHeap, nums[i]);
|
||
|
}
|
||
|
// 从第 k+1 个元素开始,保持堆的长度为 k
|
||
|
for (int i = k; i < sizeNums; i++) {
|
||
|
// 若当前元素大于堆顶元素,则将堆顶元素出堆、当前元素入堆
|
||
|
if (nums[i] > peekMinHeap(maxHeap)) {
|
||
|
popMinHeap(maxHeap);
|
||
|
pushMinHeap(maxHeap, nums[i]);
|
||
|
}
|
||
|
}
|
||
|
int *res = getMinHeap(maxHeap);
|
||
|
// 释放内存
|
||
|
delMaxHeap(maxHeap);
|
||
|
return res;
|
||
|
}
|
||
|
```
|
||
|
|
||
|
=== "Kotlin"
|
||
|
|
||
|
```kotlin title="top_k.kt"
|
||
|
/* 基于堆查找数组中最大的 k 个元素 */
|
||
|
fun topKHeap(nums: IntArray, k: Int): Queue<Int> {
|
||
|
// 初始化小顶堆
|
||
|
val heap = PriorityQueue<Int>()
|
||
|
// 将数组的前 k 个元素入堆
|
||
|
for (i in 0..<k) {
|
||
|
heap.offer(nums[i])
|
||
|
}
|
||
|
// 从第 k+1 个元素开始,保持堆的长度为 k
|
||
|
for (i in k..<nums.size) {
|
||
|
// 若当前元素大于堆顶元素,则将堆顶元素出堆、当前元素入堆
|
||
|
if (nums[i] > heap.peek()) {
|
||
|
heap.poll()
|
||
|
heap.offer(nums[i])
|
||
|
}
|
||
|
}
|
||
|
return heap
|
||
|
}
|
||
|
```
|
||
|
|
||
|
=== "Ruby"
|
||
|
|
||
|
```ruby title="top_k.rb"
|
||
|
[class]{}-[func]{top_k_heap}
|
||
|
```
|
||
|
|
||
|
=== "Zig"
|
||
|
|
||
|
```zig title="top_k.zig"
|
||
|
[class]{}-[func]{topKHeap}
|
||
|
```
|
||
|
|
||
|
??? pythontutor "Code Visualization"
|
||
|
|
||
|
<div style="height: 549px; width: 100%;"><iframe class="pythontutor-iframe" src="https://pythontutor.com/iframe-embed.html#code=import%20heapq%0A%0Adef%20top_k_heap%28nums%3A%20list%5Bint%5D,%20k%3A%20int%29%20-%3E%20list%5Bint%5D%3A%0A%20%20%20%20%22%22%22%E5%9F%BA%E4%BA%8E%E5%A0%86%E6%9F%A5%E6%89%BE%E6%95%B0%E7%BB%84%E4%B8%AD%E6%9C%80%E5%A4%A7%E7%9A%84%20k%20%E4%B8%AA%E5%85%83%E7%B4%A0%22%22%22%0A%20%20%20%20%23%20%E5%88%9D%E5%A7%8B%E5%8C%96%E5%B0%8F%E9%A1%B6%E5%A0%86%0A%20%20%20%20heap%20%3D%20%5B%5D%0A%20%20%20%20%23%20%E5%B0%86%E6%95%B0%E7%BB%84%E7%9A%84%E5%89%8D%20k%20%E4%B8%AA%E5%85%83%E7%B4%A0%E5%85%A5%E5%A0%86%0A%20%20%20%20for%20i%20in%20range%28k%29%3A%0A%20%20%20%20%20%20%20%20heapq.heappush%28heap,%20nums%5Bi%5D%29%0A%20%20%20%20%23%20%E4%BB%8E%E7%AC%AC%20k%2B1%20%E4%B8%AA%E5%85%83%E7%B4%A0%E5%BC%80%E5%A7%8B%EF%BC%8C%E4%BF%9D%E6%8C%81%E5%A0%86%E7%9A%84%E9%95%BF%E5%BA%A6%E4%B8%BA%20k%0A%20%20%20%20for%20i%20in%20range%28k,%20len%28nums%29%29%3A%0A%20%20%20%20%20%20%20%20%23%20%E8%8B%A5%E5%BD%93%E5%89%8D%E5%85%83%E7%B4%A0%E5%A4%A7%E4%BA%8E%E5%A0%86%E9%A1%B6%E5%85%83%E7%B4%A0%EF%BC%8C%E5%88%99%E5%B0%86%E5%A0%86%E9%A1%B6%E5%85%83%E7%B4%A0%E5%87%BA%E5%A0%86%E3%80%81%E5%BD%93%E5%89%8D%E5%85%83%E7%B4%A0%E5%85%A5%E5%A0%86%0A%20%20%20%20%20%20%20%20if%20nums%5Bi%5D%20%3E%20heap%5B0%5D%3A%0A%20%20%20%20%20%20%20%20%20%20%20%20heapq.heappop%28heap%29%0A%20%20%20%20%20%20%20%20%20%20%20%20heapq.heappush%28heap,%20nums%5Bi%5D%29%0A%20%20%20%20return%20heap%0A%0A%22%22%22Driver%20Code%22%22%22%0Aif%20__name__%20%3D%3D%20%22__main__%22%3A%0A%20%20%20%20nums%20%3D%20%5B1,%207,%206,%203,%202%5D%0A%20%20%20%20k%20%3D%203%0A%0A%20%20%20%20res%20%3D%20top_k_heap%28nums,%20k%29&codeDivHeight=472&codeDivWidth=350&cumulative=false&curInstr=6&heapPrimitives=nevernest&origin=opt-frontend.js&py=311&rawInputLstJSON=%5B%5D&textReferences=false"> </iframe></div>
|
||
|
<div style="margin-top: 5px;"><a href="https://pythontutor.com/iframe-embed.html#code=import%20heapq%0A%0Adef%20top_k_heap%28nums%3A%20list%5Bint%5D,%20k%3A%20int%29%20-%3E%20list%5Bint%5D%3A%0A%20%20%20%20%22%22%22%E5%9F%BA%E4%BA%8E%E5%A0%86%E6%9F%A5%E6%89%BE%E6%95%B0%E7%BB%84%E4%B8%AD%E6%9C%80%E5%A4%A7%E7%9A%84%20k%20%E4%B8%AA%E5%85%83%E7%B4%A0%22%22%22%0A%20%20%20%20%23%20%E5%88%9D%E5%A7%8B%E5%8C%96%E5%B0%8F%E9%A1%B6%E5%A0%86%0A%20%20%20%20heap%20%3D%20%5B%5D%0A%20%20%20%20%23%20%E5%B0%86%E6%95%B0%E7%BB%84%E7%9A%84%E5%89%8D%20k%20%E4%B8%AA%E5%85%83%E7%B4%A0%E5%85%A5%E5%A0%86%0A%20%20%20%20for%20i%20in%20range%28k%29%3A%0A%20%20%20%20%20%20%20%20heapq.heappush%28heap,%20nums%5Bi%5D%29%0A%20%20%20%20%23%20%E4%BB%8E%E7%AC%AC%20k%2B1%20%E4%B8%AA%E5%85%83%E7%B4%A0%E5%BC%80%E5%A7%8B%EF%BC%8C%E4%BF%9D%E6%8C%81%E5%A0%86%E7%9A%84%E9%95%BF%E5%BA%A6%E4%B8%BA%20k%0A%20%20%20%20for%20i%20in%20range%28k,%20len%28nums%29%29%3A%0A%20%20%20%20%20%20%20%20%23%20%E8%8B%A5%E5%BD%93%E5%89%8D%E5%85%83%E7%B4%A0%E5%A4%A7%E4%BA%8E%E5%A0%86%E9%A1%B6%E5%85%83%E7%B4%A0%EF%BC%8C%E5%88%99%E5%B0%86%E5%A0%86%E9%A1%B6%E5%85%83%E7%B4%A0%E5%87%BA%E5%A0%86%E3%80%81%E5%BD%93%E5%89%8D%E5%85%83%E7%B4%A0%E5%85%A5%E5%A0%86%0A%20%20%20%20%20%20%20%20if%20nums%5Bi%5D%20%3E%20heap%5B0%5D%3A%0A%20%20%20%20%20%20%20%20%20%20%20%20heapq.heappop%28heap%29%0A%20%20%20%20%20%20%20%20%20%20%20%20heapq.heappush%28heap,%20nums%5Bi%5D%29%0A%20%20%20%20return%20heap%0A%0A%22%22%22Driver%20Code%22%22%22%0Aif%20__name__%20%3D%3D%20%22__main__%22%3A%0A%20%20%20%20nums%20%3D%20%5B1,%207,%206,%203,%202%5D%0A%20%20%20%20k%20%3D%203%0A%0A%20%20%20%20res%20%3D%20top_k_heap%28nums,%20k%29&codeDivHeight=800&codeDivWidth=600&cumulative=false&curInstr=6&heapPrimitives=nevernest&origin=opt-frontend.js&py=311&rawInputLstJSON=%5B%5D&textReferences=false" target="_blank" rel="noopener noreferrer">Full Screen ></a></div>
|
||
|
|
||
|
A total of $n$ rounds of heap insertions and deletions are performed, with the maximum heap size being $k$, hence the time complexity is $O(n \log k)$. This method is very efficient; when $k$ is small, the time complexity tends towards $O(n)$; when $k$ is large, the time complexity will not exceed $O(n \log n)$.
|
||
|
|
||
|
Additionally, this method is suitable for scenarios with dynamic data streams. By continuously adding data, we can maintain the elements within the heap, thereby achieving dynamic updates of the largest $k$ elements.
|