给定一个二进制最小堆和一个值 x,打印所有值小于给定值 x 的二进制堆节点。
Examples : Consider the below min heap as
common input two both below examples.
2
/ \
3 15
/ \ / \
5 4 45 80
/ \ / \
6 150 77 120
Input : x = 15
Output : 2 3 5 6 4
Input : x = 80
Output : 2 3 5 6 4 77 15 45
这个想法是对给定的二进制堆进行预序遍历。在进行前序遍历时,如果节点的值大于给定的值 x,我们将返回到之前的递归调用。因为最小堆中的所有子节点都大于父节点。否则,我们打印当前节点并为其子节点重复。
C++
// A C++ program to print all values
// smaller than a given value in Binary
// Heap
#include
using namespace std;
// A class for Min Heap
class MinHeap {
// pointer to array of elements in heap
int* harr;
// maximum possible size of min heap
int capacity;
int heap_size; // Current no. of elements.
public:
// Constructor
MinHeap(int capacity);
// to heapify a subtree with root at
// given index
void MinHeapify(int);
int parent(int i) { return (i - 1) / 2; }
int left(int i) { return (2 * i + 1); }
int right(int i) { return (2 * i + 2); }
// Inserts a new key 'k'
void insertKey(int k);
// Function to print all nodes smaller than k
void printSmallerThan(int k, int pos);
};
// Function to print all elements smaller than k
void MinHeap::printSmallerThan(int x, int pos = 0)
{
/* Make sure item exists */
if (pos >= heap_size)
return;
if (harr[pos] >= x) {
/* Skip this node and its descendants,
as they are all >= x . */
return;
}
cout << harr[pos] << " ";
printSmallerThan(x, left(pos));
printSmallerThan(x, right(pos));
}
// Constructor: Builds a heap from a given
// array a[] of given size
MinHeap::MinHeap(int cap)
{
heap_size = 0;
capacity = cap;
harr = new int[cap];
}
// Inserts a new key 'k'
void MinHeap::insertKey(int k)
{
if (heap_size == capacity) {
cout << "\nOverflow: Could not insertKey\n";
return;
}
// First insert the new key at the end
heap_size++;
int i = heap_size - 1;
harr[i] = k;
// Fix the min heap property if it is violated
while (i != 0 && harr[parent(i)] > harr[i]) {
swap(harr[i], harr[parent(i)]);
i = parent(i);
}
}
// A recursive method to heapify a subtree with
// root at given index. This method assumes that
// the subtrees are already heapified
void MinHeap::MinHeapify(int i)
{
int l = left(i);
int r = right(i);
int smallest = i;
if (l < heap_size && harr[l] < harr[i])
smallest = l;
if (r < heap_size && harr[r] < harr[smallest])
smallest = r;
if (smallest != i) {
swap(harr[i], harr[smallest]);
MinHeapify(smallest);
}
}
// Driver program to test above functions
int main()
{
MinHeap h(50);
h.insertKey(3);
h.insertKey(2);
h.insertKey(15);
h.insertKey(5);
h.insertKey(4);
h.insertKey(45);
h.insertKey(80);
h.insertKey(6);
h.insertKey(150);
h.insertKey(77);
h.insertKey(120);
// Print all nodes smaller than 100.
int x = 100;
h.printSmallerThan(x);
return 0;
} Java
// A Java program to print all values
// smaller than a given value in Binary
// Heap
// A class for Min Heap
class MinHeap {
// array of elements in heap
int[] harr;
// maximum possible size of min heap
int capacity;
int heap_size; // Current no. of elements.
int parent(int i) { return (i - 1) / 2; }
int left(int i) { return (2 * i + 1); }
int right(int i) { return (2 * i + 2); }
// Function to print all elements smaller than k
void printSmallerThan(int x, int pos)
{
/* Make sure item exists */
if (pos >= heap_size)
return;
if (harr[pos] >= x) {
/* Skip this node and its descendants,
as they are all >= x . */
return;
}
System.out.print(harr[pos] + " ");
printSmallerThan(x, left(pos));
printSmallerThan(x, right(pos));
}
// Constructor: Builds a heap of given size
public MinHeap(int cap)
{
heap_size = 0;
capacity = cap;
harr = new int[cap];
}
// Inserts a new key 'k'
void insertKey(int k)
{
if (heap_size == capacity) {
System.out.println("Overflow: Could not insertKey");
return;
}
// First insert the new key at the end
heap_size++;
int i = heap_size - 1;
harr[i] = k;
// Fix the min heap property if it is violated
while (i != 0 && harr[parent(i)] > harr[i]) {
swap(i, parent(i));
i = parent(i);
}
}
// A utility function to swap two elements
void swap(int x, int y)
{
int temp = harr[x];
harr[x] = harr[y];
harr[y] = temp;
}
// Driver code
public static void main(String[] args)
{
MinHeap h = new MinHeap(15);
h.insertKey(3);
h.insertKey(2);
h.insertKey(15);
h.insertKey(5);
h.insertKey(4);
h.insertKey(45);
h.insertKey(80);
h.insertKey(6);
h.insertKey(150);
h.insertKey(77);
h.insertKey(120);
// Print all nodes smaller than 100.
int x = 100;
h.printSmallerThan(x, 0);
}
};
// This code is contributed by shubham96301C#
// A C# program to print all values
// smaller than a given value in
// Binary Heap
using System;
// A class for Min Heap
public class MinHeap
{
// array of elements in heap
int[] harr;
// maximum possible size of min heap
int capacity;
// Current no. of elements
int heap_size;
int parent(int i) { return (i - 1) / 2; }
int left(int i) { return (2 * i + 1); }
int right(int i) { return (2 * i + 2); }
// Function to print
// all elements smaller than k
void printSmallerThan(int x, int pos)
{
/* Make sure item exists */
if (pos >= heap_size)
return;
if (harr[pos] >= x)
{
/* Skip this node and its descendants,
as they are all >= x . */
return;
}
Console.Write(harr[pos] + " ");
printSmallerThan(x, left(pos));
printSmallerThan(x, right(pos));
}
// Constructor: Builds a heap of given size
public MinHeap(int cap)
{
heap_size = 0;
capacity = cap;
harr = new int[cap];
}
// Inserts a new key 'k'
void insertKey(int k)
{
if (heap_size == capacity)
{
Console.WriteLine("Overflow: Could not insertKey");
return;
}
// First insert the new key at the end
heap_size++;
int i = heap_size - 1;
harr[i] = k;
// Fix the min heap property
// if it is violated
while (i != 0 &&
harr[parent(i)] > harr[i])
{
swap(i, parent(i));
i = parent(i);
}
}
// A utility function to swap two elements
void swap(int x, int y)
{
int temp = harr[x];
harr[x] = harr[y];
harr[y] = temp;
}
// Driver code
public static void Main(String[] args)
{
MinHeap h = new MinHeap(15);
h.insertKey(3);
h.insertKey(2);
h.insertKey(15);
h.insertKey(5);
h.insertKey(4);
h.insertKey(45);
h.insertKey(80);
h.insertKey(6);
h.insertKey(150);
h.insertKey(77);
h.insertKey(120);
// Print all nodes smaller than 100.
int x = 100;
h.printSmallerThan(x, 0);
}
}
// This code is contributed by PrinciRaj1992输出:
2 3 5 6 4 77 15 45 80
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