zoukankan      html  css  js  c++  java
  • [Swift]LeetCode347. 前K个高频元素 | Top K Frequent Elements

    ★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★
    ➤微信公众号:山青咏芝(shanqingyongzhi)
    ➤博客园地址:山青咏芝(https://www.cnblogs.com/strengthen/
    ➤GitHub地址:https://github.com/strengthen/LeetCode
    ➤原文地址: https://www.cnblogs.com/strengthen/p/10740914.html 
    ➤如果链接不是山青咏芝的博客园地址,则可能是爬取作者的文章。
    ➤原文已修改更新!强烈建议点击原文地址阅读!支持作者!支持原创!
    ★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★★

    Given a non-empty array of integers, return the k most frequent elements.

    Example 1:

    Input: nums = [1,1,1,2,2,3], k = 2
    Output: [1,2]
    

    Example 2:

    Input: nums = [1], k = 1
    Output: [1]

    Note:

    • You may assume k is always valid, 1 ≤ k ≤ number of unique elements.
    • Your algorithm's time complexity must be better than O(n log n), where n is the array's size.

    给定一个非空的整数数组,返回其中出现频率前 高的元素。

    示例 1:

    输入: nums = [1,1,1,2,2,3], k = 2
    输出: [1,2]
    

    示例 2:

    输入: nums = [1], k = 1
    输出: [1]

    说明:

    • 你可以假设给定的 总是合理的,且 1 ≤ k ≤ 数组中不相同的元素的个数。
    • 你的算法的时间复杂度必须优于 O(n log n) , 是数组的大小。

    推荐1(助力理解优先队列):

      1 public struct Heap<T> {
      2     public var nodes = [T]()
      3     private var orderCriteria: (T, T) -> Bool
      4     
      5     public init(sort: @escaping (T, T) -> Bool) {
      6         orderCriteria = sort
      7     }
      8     
      9     public init(array: [T], sort: @escaping (T, T) -> Bool) {
     10         self.orderCriteria = sort
     11         configureHeap(from: array)
     12     }
     13     
     14     public var isEmpty: Bool {
     15         return nodes.isEmpty
     16     }
     17     
     18     public var count: Int {
     19         return nodes.count
     20     }
     21     
     22     public mutating func configureHeap(from array: [T]) {
     23         nodes = array
     24         for i in stride(from: nodes.count / 2 - 1, through: 0, by: -1) {
     25             shiftDown(i)
     26         }
     27     }
     28     
     29     public mutating func reset() {
     30         for i in stride(from: nodes.count / 2 - 1, through: 0, by: -1) {
     31             shiftDown(i)
     32         }
     33     }
     34     
     35     @inline(__always) internal func parentIndex(ofIndex index: Int) -> Int {
     36         return (index - 1) / 2
     37     }
     38     
     39     @inline(__always) internal func leftChildIndex(ofIndex index: Int) -> Int {
     40         return index * 2 + 1
     41     }
     42     
     43     @inline(__always) internal func rightChildIndex(ofIndex index: Int) -> Int {
     44         return index * 2 + 2
     45     }
     46     
     47     public func peek() -> T? {
     48         return nodes.first
     49     }
     50     
     51     internal mutating func shiftUp(_ index: Int) {
     52         var childIndex = index
     53         let child = nodes[childIndex]
     54         var parentIndex = self.parentIndex(ofIndex: index)
     55         while childIndex > 0 && orderCriteria(child, nodes[parentIndex]) {
     56             nodes[childIndex] = nodes[parentIndex]
     57             childIndex = parentIndex
     58             parentIndex = self.parentIndex(ofIndex: childIndex)
     59         }
     60         nodes[childIndex] = child
     61     }
     62     
     63     internal mutating func shiftDown(from index: Int, until endIndex: Int) {
     64         let leftChildIndex = self.leftChildIndex(ofIndex: index)
     65         let rightChildIndex = self.rightChildIndex(ofIndex: index)
     66         
     67         var first = index
     68         if leftChildIndex < endIndex && orderCriteria(nodes[leftChildIndex], nodes[first]) {
     69             first = leftChildIndex
     70         }
     71         if rightChildIndex < endIndex && orderCriteria(nodes[rightChildIndex], nodes[first]) {
     72             first = rightChildIndex
     73         }
     74         if first == index {
     75             return
     76         }
     77         nodes.swapAt(index, first)
     78         shiftDown(from: first, until: endIndex)
     79     }
     80     
     81     internal mutating func shiftDown(_ index: Int) {
     82         shiftDown(from: index, until: nodes.count)
     83     }
     84     
     85     public mutating func insert(_ value: T) {
     86         nodes.append(value)
     87         shiftUp(nodes.count - 1)
     88     }
     89     
     90     public mutating func insert<S: Sequence>(_ sequence:S) where S.Iterator.Element == T {
     91         for value in sequence {
     92             insert(value)
     93         }
     94     }
     95     
     96     public mutating func replace(index i: Int, value: T) {
     97         guard i < nodes.count else {
     98             return
     99         }
    100         remove(at: i)
    101         insert(value)
    102     }
    103     
    104     @discardableResult
    105     public mutating func remove() -> T? {
    106         guard !nodes.isEmpty else {
    107             return nil
    108         }
    109         if nodes.count == 1 {
    110             return nodes.removeLast()
    111         } else {
    112             let value = nodes[0]
    113             nodes[0] = nodes.removeLast()
    114             shiftDown(0)
    115             return value
    116         }
    117     }
    118     
    119     @discardableResult
    120     public mutating func remove(at index: Int) -> T? {
    121         guard index < nodes.count else { return nil}
    122         let size = nodes.count - 1
    123         if index != size {
    124             nodes.swapAt(index, size)
    125             shiftDown(from: index,  until: size)
    126             shiftUp(index)
    127         }
    128         return nodes.removeLast()
    129     }
    130     
    131     public mutating func sort() -> [T] {
    132         for i in stride(from: self.nodes.count - 1, to: 0, by: -1) {
    133             nodes.swapAt(0, i)
    134             shiftDown(from: 0, until: i)
    135         }
    136         return nodes
    137     }
    138 
    139 }
    140 
    141 
    142 class Solution {
    143     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
    144         var heap = Heap<(Int, Int)>.init { (f, s) -> Bool in
    145             return f.1 < s.1
    146         }
    147         var dict = [Int: Int]()
    148         for i in nums {
    149             dict[i] = (dict[i] ?? 0) + 1
    150         }
    151         
    152         for i in dict {
    153             heap.insert(i)
    154             if heap.count > k {
    155                 heap.remove()
    156             }
    157         }
    158         var array = [Int]()
    159         while heap.count > 0 {
    160             array.append(heap.peek()!.0)
    161             heap.remove()
    162         }
    163         return array.reversed()
    164     }
    165 }

     推荐2(助力理解优先队列):

      1 class Solution {
      2     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
      3         
      4         let numCount = self.countNums(nums)
      5         
      6         var heap = MinHeap<NumberCount>([])
      7         
      8         for n in numCount{
      9             heap.add(n)
     10             if heap.count > k{
     11                 heap.poll()
     12             }
     13         }
     14         
     15         var result = [Int]()
     16         
     17         while heap.peek() != nil{
     18             let currentN = heap.poll()
     19             result.append(currentN.n)
     20         }
     21         
     22         result.reverse()
     23         
     24         return result
     25     }
     26     
     27     func countNums(_ nums:[Int]) -> [NumberCount]{
     28         
     29         var dict = [Int:Int]()
     30         for n in nums{
     31             var count = dict[n] ?? 0
     32             count += 1
     33             dict[n] = count
     34         }
     35         
     36         var result = [NumberCount]()
     37         
     38         for(k,v) in dict{
     39             let newN = NumberCount(k, v)
     40             result.append(newN)
     41         }
     42         
     43         return result
     44     }
     45 }
     46 
     47 class MinHeap<T:Comparable>{
     48     
     49     var data:[T]
     50     
     51     init(_ data:[T]){
     52         self.data = data
     53     }
     54     
     55     func parent(_ index:Int) -> T{
     56         return self.data[self.parentIndex(index)]
     57     }
     58     
     59     func leftChild(_ index:Int) -> T{
     60         return self.data[self.leftChildIndex(index)]
     61     }
     62     
     63     func rightChild(_ index:Int) -> T{
     64         return self.data[self.rightChildIndex(index)]
     65     }
     66     
     67     func parentIndex(_ index:Int) -> Int{
     68         return (index - 1) / 2
     69     }
     70     
     71     func leftChildIndex(_ index:Int) -> Int{
     72         return index * 2 + 1
     73     }
     74     
     75     func rightChildIndex(_ index:Int) -> Int{
     76         return index * 2 + 2
     77     }
     78     
     79     func hasParent(_ index:Int) -> Bool{
     80         return self.parentIndex(index) >= 0
     81     }
     82     
     83     func hasLeftChild(_ index:Int) -> Bool{
     84         return self.leftChildIndex(index) < self.count
     85     }
     86     
     87     func hasRightChild(_ index:Int) -> Bool{
     88         return self.rightChildIndex(index) < self.count
     89     }
     90     
     91     func add(_ item:T){
     92         self.data.append(item)
     93         if self.data.count > 1{
     94             self.heapifyUp()
     95         }
     96     }
     97     
     98     func poll() -> T{
     99         let first = self.data[0]
    100         self.data[0] = self.data[self.count - 1]
    101         self.data.removeLast()
    102         self.heapifyDown()
    103         return first
    104     }
    105     
    106     func peek() -> T?{
    107         if self.count == 0{
    108             return nil
    109         }
    110         return self.data[0]
    111     }
    112     
    113     func heapifyUp(){
    114         var currentIndex = self.count - 1
    115         while hasParent(currentIndex) && parent(currentIndex) > self.data[currentIndex]{
    116             self.data.swapAt(currentIndex, parentIndex(currentIndex))
    117             currentIndex = parentIndex(currentIndex)
    118         }
    119     }
    120     
    121     func heapifyDown(){
    122         var currentIndex = 0
    123         while hasLeftChild(currentIndex){
    124             var smallerIndex = leftChildIndex(currentIndex)
    125             if hasRightChild(currentIndex) && rightChild(currentIndex) < leftChild(currentIndex){
    126                 smallerIndex = rightChildIndex(currentIndex)
    127             }
    128             if self.data[currentIndex] > self.data[smallerIndex]{
    129                 self.data.swapAt(currentIndex, smallerIndex)
    130                 currentIndex = smallerIndex
    131             }else{
    132                 break
    133             }
    134         }
    135     }
    136     
    137     var count:Int{
    138         return self.data.count
    139     }
    140 }
    141 
    142 class NumberCount : Comparable{
    143     
    144     let n:Int
    145     var count:Int = 0
    146     
    147     init(_ n:Int, _ count:Int){
    148         self.n = n
    149         self.count = count
    150     }
    151     
    152     static func < (lhs:NumberCount, rhs:NumberCount) -> Bool{
    153         return lhs.count < rhs.count
    154     }
    155     
    156     static func == (lhs:NumberCount, rhs:NumberCount) -> Bool{
    157         return lhs.count == rhs.count
    158     }
    159 }

    推荐3(助力理解优先队列):

      1 class Solution {
      2     struct MyTuple: Comparable {
      3         var first, second: Int
      4         static func < (lhs: MyTuple, rhs: MyTuple) -> Bool {
      5             return lhs.second < rhs.second
      6         }
      7     }
      8     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
      9         var dict: [Int: Int] = [:]
     10         for num in nums {
     11             if let val = dict[num] {
     12                 dict[num] = val + 1
     13             }
     14             else {
     15                 dict[num] = 1
     16             }
     17         }
     18 
     19         var heap: Heap<MyTuple> = Heap(isMaxHeap: false)
     20         for (key, value) in dict {
     21             if heap.count < k {
     22                 heap.insert(MyTuple(first: key, second: value))
     23             }
     24             else {
     25                 if value > heap.top()!.second {
     26                     heap.replace(MyTuple(first: key, second: value))
     27                 }
     28             }
     29         }
     30 
     31         var result: [Int] = []
     32         while !heap.isEmpty() {
     33             result.append(heap.delete()!.first)
     34         }
     35 
     36         return result.reversed()
     37     }
     38 }
     39 
     40 struct Heap<T: Comparable> {
     41     fileprivate var nums: [T?] = [Optional.none]
     42     fileprivate var isMaxHeap: Bool = true
     43     public var count: Int {
     44         return nums.count - 1
     45     }
     46     
     47     public init(_ arr: [T] = [], isMaxHeap: Bool = true) {
     48         self.isMaxHeap = isMaxHeap
     49         self.nums.append(contentsOf: arr)
     50         for i in stride(from: count/2, to: 0, by: -1) {
     51             isMaxHeap ? heapifyDown(i, &nums, >) : heapifyDown(i, &nums, <)
     52         }
     53     }
     54     
     55     // 是否为空
     56     public func isEmpty() -> Bool {
     57         return count == 0
     58     }
     59     
     60     // 插入元素
     61     public mutating func insert(_ num: T) {
     62         nums.append(num)
     63         heapify(count, &nums) { a, b in
     64             return self.isMaxHeap ? a > b : a < b
     65         }
     66     }
     67     
     68     // 删除堆顶元素
     69     public mutating func delete() -> T? {
     70         guard !isEmpty() else {
     71             return nil
     72         }
     73         //将堆顶元素与最后一个元素交换
     74         nums.swapAt(1, count)
     75         let res = nums.removeLast()
     76         heapifyDown(1, &nums) { a, b in
     77             return self.isMaxHeap ? a > b : a < b
     78         }
     79         return res
     80     }
     81     
     82     // 堆顶元素
     83     public func top() -> T? {
     84         guard !isEmpty() else {
     85             return nil
     86         }
     87         return nums[1]
     88     }
     89     
     90     // 替换堆顶元素
     91     public mutating func replace(_ num: T) {
     92         nums[1] = num
     93         isMaxHeap ? heapifyDown(1, &nums, >) : heapifyDown(1, &nums, <)
     94     }
     95     
     96     // 堆化(自下向上)
     97     private func heapify(_ location: Int, _ nums: inout [T?],  _ compare: (T, T) -> Bool) {
     98         var loc = location
     99         while loc/2 > 0 && compare(nums[loc]!, nums[loc/2]!) {
    100             nums.swapAt(loc, loc/2)
    101             loc /= 2
    102         }
    103     }
    104     
    105     // 堆化(自上而下)
    106     fileprivate func heapifyDown(_ location: Int, _ nums: inout [T?], _ compare: (T, T) -> Bool) {
    107         var loc = location
    108         while loc * 2 <= count {
    109             var swapLoc = loc
    110             if compare(nums[loc * 2]!, nums[loc]!) {
    111                 swapLoc = loc * 2
    112             }
    113             if loc * 2 + 1 <= count && compare(nums[loc * 2 + 1]!, nums[swapLoc]!) {
    114                 swapLoc = loc * 2 + 1
    115             }
    116             if loc == swapLoc {
    117                 break
    118             }
    119             nums.swapAt(loc, swapLoc)
    120             loc = swapLoc
    121         }
    122     }
    123 }

     92ms

     1 class Solution {
     2     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
     3         if nums == [] { return [] }
     4         var map = [Int : Int]()
     5         
     6         // O(n)
     7         for i in 0...nums.count-1 {
     8             if let m = map[nums[i]] {
     9                 // O(1)?
    10                 map.updateValue(m + 1, forKey: nums[i])
    11             }
    12             else{
    13                 map[nums[i]] = 1
    14             }
    15         }
    16         
    17         // sortedBy is O(n log n)
    18         var mapVal = map.sorted(by: { $0.value > $1.value })
    19         var res = [Int]()
    20         
    21         // O(k)
    22         for i in 0...k-1 {
    23             res.append(mapVal[i].key)
    24         }
    25         
    26         return res
    27     }
    28 }

    96ms

     1 class Solution {
     2     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
     3 
     4         var countDict = [Int: Int]()
     5         
     6         for n in nums {
     7             countDict[n, default: 0] += 1
     8         }
     9         
    10         var sorted = countDict.sorted { $0.value > $1.value }
    11         
    12         return sorted[0..<k].map { $0.key }
    13     }
    14 }

    100ms

     1 class Solution {
     2     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
     3         guard nums.count > 1 else { return nums }
     4         
     5         var hashMap: [Int: Int] = [:]
     6         
     7         for i in nums {
     8             hashMap[i, default: 0] +=  1 
     9         }
    10         
    11         let sortedPairs = hashMap.sorted{ $0.value > $1.value}
    12         
    13         let sortedKeys = sortedPairs.map{ $0.key }
    14      
    15         return Array(sortedKeys.prefix(k))
    16     }
    17 }

    104ms

     1 class Solution {
     2     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
     3         
     4         var res = [Int]()
     5         var map = [Int:Int]()
     6         if k > nums.count { return res }
     7         
     8         for num in nums {
     9             map[num] = map[num] == nil ? 1 : map[num]! + 1
    10         }
    11         
    12         let sortedArray = map.sorted{ $0.value > $1.value }
    13         var count = 0
    14         for (key, value) in sortedArray {
    15         if(count >= k) { break }
    16             res.append(key)
    17             count += 1 
    18         }
    19         return res
    20     }
    21 }

    108ms

    1 class Solution {
    2     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
    3         let counter: [Int: Int] = nums.reduce(into: [Int: Int]()) { $0[$1, default: 0] += 1}
    4         let sortedKeys = counter.keys.sorted { counter[$0]! >= counter[$1]!}
    5         return [Int](sortedKeys[0..<k])
    6     }
    7 }

    112ms

     1 class Solution {
     2     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
     3         var countMap: [Int: Int] = [:]
     4         for num in nums {
     5             countMap[num, default: 0] += 1
     6         }
     7         
     8         var sortedList: [[Int]] = Array(repeating: [], count: nums.count + 1)
     9         for (key, value) in countMap {
    10             sortedList[value].append(key) 
    11         }
    12         
    13         var result: [Int] = []
    14         var i = nums.count
    15         while i > 0 && result.count < k {
    16             result.append(contentsOf: sortedList[i])
    17             
    18             i -= 1
    19         }
    20         return result
    21     }
    22 }

    120ms

     1 class Solution {
     2     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
     3     var dict = [Int:Int]()
     4     nums.forEach {
     5         dict[$0] = (dict[$0] == nil ? 0 : dict[$0]! ) + 1
     6     }
     7  
     8     return dict.sorted(by:  { $0.value > $1.value } )[0..<k].map({$0.key})
     9 }
    10 }

    124ms

     1 class Solution {
     2     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
     3         var countMap:[Int:Int] = [:]
     4         for num in nums {
     5             countMap[num] = countMap[num] == nil ? 1 : countMap[num]! + 1
     6         }
     7         var vals = Array(countMap.keys)
     8         vals.sort {
     9             return countMap[$0]! > countMap[$1]!
    10         }
    11         return Array(vals[0..<k])
    12     }
    13 }

    148ms

     1 class Solution {
     2     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
     3         //  input: [1, 1, 1, 2, 2, 3, 3, 3, 4, 4, 4,]
     4         //  buckets: [[], [], [2], [1, 4, 3], [], [], [], [], [], [], [], []]
     5         // list of numbers whose frequency is at buckets[i]
     6         var buckets = Array(repeating: [Int](), count: nums.count + 1)
     7         
     8         // key: number      value: number of times it appears in the array
     9         var freqMap = [Int: Int]()
    10         
    11         for num in nums {
    12             if let times = freqMap[num] {
    13                 freqMap[num] = 1 + times
    14             } else {
    15                 freqMap[num] = 1
    16             }
    17         }
    18 
    19         for key in freqMap.keys {
    20             let frequency = freqMap[key]!
    21             buckets[frequency].append(key)
    22         }
    23         
    24         print(buckets)
    25 
    26         // we go backwards because the end contains the highest frequencies
    27         var result = [Int]()
    28         for i in stride(from: buckets.count - 1, to: 0, by: -1) {
    29             if !buckets[i].isEmpty && result.count < k {
    30                 result.append(contentsOf: buckets[i])
    31             }
    32         }
    33         return result
    34     }
    35 }

    156ms

     1 class Solution {
     2     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
     3         var temp = (Dictionary(nums.map { ($0, 1) }, uniquingKeysWith: +)).sorted { (a, b) -> Bool in
     4             return a.value>b.value
     5             }.compactMap { (a) -> Int? in
     6                 return a.key
     7         }
     8         return Array(temp[0..<k])
     9     }
    10 }

    160ms

     1 class Solution {
     2     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
     3         
     4         // Map for value -> # occurences
     5         var dict = [Int: Int]()
     6         for value in nums {
     7             dict[value] = (dict[value] ?? 0) + 1
     8         }
     9         
    10         print(dict)
    11         
    12         // Index maps to frequency the value appears in array
    13         var buckets = [[Int]](repeating: [], count: nums.count + 1)
    14         for (key, value) in dict {
    15             buckets[value].append(key)
    16         }
    17         
    18         print(buckets)
    19         
    20         var kMostFrequent = [Int]()
    21         var currMost = 0
    22         
    23         for subArr in buckets.reversed() where currMost < k {
    24             for value in subArr where currMost < k {
    25                 kMostFrequent.append(value)
    26                 currMost += 1
    27             }
    28         }
    29         
    30         return kMostFrequent
    31     }
    32 }

    164ms

     1 class Solution {
     2     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
     3         if k < 0 || k > nums.count { return [] }
     4         var dict = [Int: Int]()
     5         nums.forEach {
     6             dict[$0] = (dict[$0] ?? 0) + 1
     7         }
     8         
     9         var pairs = dict.map { $0 }
    10         quickSelect(&pairs, 0, pairs.count - 1, k)
    11         return Array(pairs.prefix(k).map { $0.key })
    12     }
    13     
    14     func quickSelect(_ pairs: inout [(key: Int, value: Int)], _ start: Int, _ end: Int, _ k: Int) {
    15         
    16         if start == end {
    17             return 
    18         }
    19         
    20         let pivot = pairs[end]
    21         var left = start
    22         for i in start..<end {
    23             if pairs[i].value >= pivot.value {
    24                 pairs.swapAt(left, i)
    25                 left += 1
    26             }
    27         }
    28         pairs.swapAt(left, end)
    29         
    30         if left + 1 == k {
    31             return 
    32         } else if left + 1 > k {
    33             quickSelect(&pairs, start, end - 1, k)
    34         } else {
    35             quickSelect(&pairs, left + 1, end, k)
    36         }
    37     }
    38 }

    172ms

     1 class Solution {
     2     func topKFrequent(_ nums: [Int], _ k: Int) -> [Int] {
     3         guard k >= 1 && k <= nums.count else {
     4             return []
     5         }
     6         var numCounts = [Int: Int]()
     7         for num in nums {
     8             if let numCount = numCounts[num] {
     9                 numCounts[num] = numCount + 1
    10             } else {
    11                 numCounts[num] = 1
    12             }
    13         }
    14         let numInfos = numCounts.sorted {
    15             $0.1 >= $1.1
    16         }
    17         return Array(numInfos[0 ..< k]).map {
    18             $0.0
    19         }
    20     }
    21 }
  • 相关阅读:
    类型"ImportMeta"上不存在属性"env"(Property 'env' does not exist on type 'ImportMeta')
    微信小程序开发常见问题
    js构建沙箱环境sandbox
    js 判断两个对象是否相同
    js判断类型方法
    初学knockoutjs记录4——Computed observables依赖监控(1 Using computed observables使用计算监控属性)
    初学knockoutjs记录3——Observables监控属性(2 Observable Arrays 监控数组)
    初学knockoutjs记录2——Observables监控属性(1 创建带有监控属性的view model)
    初学knockoutjs记录1——入门介绍及下载安装
    C、C++、JAVA编译器是如何处理未经初始化的变量的。
  • 原文地址:https://www.cnblogs.com/strengthen/p/10740914.html
Copyright © 2011-2022 走看看