Given n number of sorted files, the task is to find the minimum computations done to reach the Optimal Merge Pattern.
When two or more sorted files are to be merged altogether to form a single file, the minimum computations are done to reach this file are known as Optimal Merge Pattern.
If more than 2 files need to be merged then it can be done in pairs. For example, if need to merge 4 files A, B, C, D. First Merge A with B to get X1, merge X1 with C to get X2, merge X2 with D to get X3 as the output file.
If we have two files of sizes m and n, the total computation time will be m+n. Here, we use the greedy strategy by merging the two smallest size files among all the files present.
Examples:
Given 3 files with sizes 2, 3, 4 units. Find an optimal way to combine these files
Input: n = 3, size = {2, 3, 4}
Output: 14
Explanation: There are different ways to combine these files:
Method 1: Optimal method
Method 2:
Method 3:
Input: n = 6, size = {2, 3, 4, 5, 6, 7}
Output: 68
Explanation: Optimal way to combine these files
Input: n = 5, size = {5,10,20,30,30}
Output: 205Input: n = 5, size = {8,8,8,8,8}
Output: 96
Observations:
From the above results, we may conclude that for finding the minimum cost of computation we need to have our array always sorted, i.e., add the minimum possible computation cost and remove the files from the array. We can achieve this optimally using a min-heap(priority-queue) data structure.
Approach:
Node represents a file with a given size also given nodes are greater than 2
- Add all the nodes in a priority queue (Min Heap).{pq.poll = file size}
- Initialize count = 0 // variable to store file computations.
- Repeat while (size of priority Queue is greater than 1)
- int weight = pq.poll(); pq.pop;//pq denotes priority queue, remove 1st smallest and pop(remove) it out
- weight+=pq.poll() && pq.pop(); // add the second element and then pop(remove) it out
- count +=weight;
- pq.add(weight) // add this combined cost to priority queue;
- count is the final answer
Below is the implementation of the above approach:
// C++ program to implement // Optimal File Merge Pattern #include <bits/stdc++.h> using namespace std;
// Function to find minimum computation int minComputation( int size, int files[])
{ // Create a min heap
priority_queue< int , vector< int >, greater< int > > pq;
for ( int i = 0; i < size; i++) {
// Add sizes to priorityQueue
pq.push(files[i]);
}
// Variable to count total Computation
int count = 0;
while (pq.size() > 1) {
// pop two smallest size element
// from the min heap
int first_smallest = pq.top();
pq.pop();
int second_smallest = pq.top();
pq.pop();
int temp = first_smallest + second_smallest;
// Add the current computations
// with the previous one's
count += temp;
// Add new combined file size
// to priority queue or min heap
pq.push(temp);
}
return count;
} // Driver code int main()
{ // No of files
int n = 6;
// 6 files with their sizes
int files[] = { 2, 3, 4, 5, 6, 7 };
// Total no of computations
// do be done final answer
cout << "Minimum Computations = "
<< minComputation(n, files);
return 0;
} // This code is contributed by jaigoyal1328 |
// Java program to implement // Optimal File Merge Pattern import java.util.PriorityQueue;
import java.util.Scanner;
public class OptimalMergePatterns {
// Function to find minimum computation
static int minComputation( int size, int files[])
{
// create a min heap
PriorityQueue<Integer> pq = new PriorityQueue<>();
for ( int i = 0 ; i < size; i++) {
// add sizes to priorityQueue
pq.add(files[i]);
}
// variable to count total computations
int count = 0 ;
while (pq.size() > 1 ) {
// pop two smallest size element
// from the min heap
int temp = pq.poll() + pq.poll();
// add the current computations
// with the previous one's
count += temp;
// add new combined file size
// to priority queue or min heap
pq.add(temp);
}
return count;
}
public static void main(String[] args)
{
// no of files
int size = 6 ;
// 6 files with their sizes
int files[] = new int [] { 2 , 3 , 4 , 5 , 6 , 7 };
// total no of computations
// do be done final answer
System.out.println( "Minimum Computations = "
+ minComputation(size, files));
}
} |
# Python Program to implement # Optimal File Merge Pattern class Heap():
# Building own implementation of Min Heap
def __init__( self ):
self .h = []
def parent( self , index):
# Returns parent index for given index
if index > 0 :
return (index - 1 ) / / 2
def lchild( self , index):
# Returns left child index for given index
return ( 2 * index) + 1
def rchild( self , index):
# Returns right child index for given index
return ( 2 * index) + 2
def addItem( self , item):
# Function to add an item to heap
self .h.append(item)
if len ( self .h) = = 1 :
# If heap has only one item no need to heapify
return
index = len ( self .h) - 1
parent = self .parent(index)
# Moves the item up if it is smaller than the parent
while index > 0 and item < self .h[parent]:
self .h[index], self .h[parent] = self .h[parent], self .h[parent]
index = parent
parent = self .parent(index)
def deleteItem( self ):
# Function to add an item to heap
length = len ( self .h)
self .h[ 0 ], self .h[length - 1 ] = self .h[length - 1 ], self .h[ 0 ]
deleted = self .h.pop()
# Since root will be violating heap property
# Call moveDownHeapify() to restore heap property
self .moveDownHeapify( 0 )
return deleted
def moveDownHeapify( self , index):
# Function to make the items follow Heap property
# Compares the value with the children and moves item down
lc, rc = self .lchild(index), self .rchild(index)
length, smallest = len ( self .h), index
if lc < length and self .h[lc] < = self .h[smallest]:
smallest = lc
if rc < length and self .h[rc] < = self .h[smallest]:
smallest = rc
if smallest ! = index:
# Swaps the parent node with the smaller child
self .h[smallest], self .h[index] = self .h[index], self .h[smallest]
# Recursive call to compare next subtree
self .moveDownHeapify(smallest)
def increaseItem( self , index, value):
# Increase the value of 'index' to 'value'
if value < = self .h[index]:
return
self .h[index] = value
self .moveDownHeapify(index)
class OptimalMergePattern():
def __init__( self , n, items):
self .n = n
self .items = items
self .heap = Heap()
def optimalMerge( self ):
# Corner cases if list has no more than 1 item
if self .n < = 0 :
return 0
if self .n = = 1 :
return self .items[ 0 ]
# Insert items into min heap
for _ in self .items:
self .heap.addItem(_)
count = 0
while len ( self .heap.h) ! = 1 :
tmp = self .heap.deleteItem()
count + = (tmp + self .heap.h[ 0 ])
self .heap.increaseItem( 0 , tmp + self .heap.h[ 0 ])
return count
# Driver Code if __name__ = = '__main__' :
OMP = OptimalMergePattern( 6 , [ 2 , 3 , 4 , 5 , 6 , 7 ])
ans = OMP.optimalMerge()
print (ans)
# This code is contributed by Rajat Gupta |
using System;
using System.Collections.Generic;
public class OptimalMergePatterns
{ // Function to find minimum computation
static int MinComputation( int size, int [] files)
{
// create a list to store file sizes
List< int > fileList = new List< int >(files);
// variable to count total computations
int count = 0;
while (fileList.Count > 1) {
// sort the file sizes in ascending order
fileList.Sort();
// get the two smallest file sizes
int file1 = fileList[0];
int file2 = fileList[1];
// calculate the combined file size
int combinedFileSize = file1 + file2;
// add the current computations
// with the previous one's
count += combinedFileSize;
// remove the two smallest file sizes
fileList.RemoveAt(0);
fileList.RemoveAt(0);
// add new combined file size
// to the list of file sizes
fileList.Add(combinedFileSize);
}
return count;
}
public static void Main( string [] args)
{
// no of files
int size = 6;
// 6 files with their sizes
int [] files = new int [] { 2, 3, 4, 5, 6, 7 };
// total no of computations
// do be done final answer
Console.WriteLine( "Minimum Computations = "
+ MinComputation(size, files));
}
} // This code is contributed by phasing17. |
// JavaScript program to implement // Optimal File Merge Pattern class Heap { // Building own implementation of Min Heap
constructor() {
this .h = [];
}
parent(index) {
// Returns parent index for given index
if (index > 0) {
return Math.floor((index - 1) / 2);
}
}
lchild(index) {
// Returns left child index for given index
return 2 * index + 1;
}
rchild(index) {
// Returns right child index for given index
return 2 * index + 2;
}
addItem(item) {
// Function to add an item to heap
this .h.push(item);
if ( this .h.length === 1) {
// If heap has only one item no need to heapify
return ;
}
let index = this .h.length - 1;
let parent = this .parent(index);
// Moves the item up if it is smaller than the parent
while (index > 0 && item < this .h[parent]) {
[ this .h[index], this .h[parent]] = [ this .h[parent], this .h[index]];
index = parent;
parent = this .parent(index);
}
}
deleteItem() {
// Function to add an item to heap
const length = this .h.length;
[ this .h[0], this .h[length - 1]] = [ this .h[length - 1], this .h[0]];
const deleted = this .h.pop();
// Since root will be violating heap property
// Call moveDownHeapify() to restore heap property
this .moveDownHeapify(0);
return deleted;
}
moveDownHeapify(index) {
// Function to make the items follow Heap property
// Compares the value with the children and moves item down
const lc = this .lchild(index);
const rc = this .rchild(index);
const length = this .h.length;
let smallest = index;
if (lc < length && this .h[lc] <= this .h[smallest]) {
smallest = lc;
}
if (rc < length && this .h[rc] <= this .h[smallest]) {
smallest = rc;
}
if (smallest !== index) {
// Swaps the parent node with the smaller child
[ this .h[smallest], this .h[index]] = [ this .h[index], this .h[smallest]];
// Recursive call to compare next subtree
this .moveDownHeapify(smallest);
}
}
increaseItem(index, value) {
// Increase the value of 'index' to 'value'
if (value <= this .h[index]) {
return ;
}
this .h[index] = value;
this .moveDownHeapify(index);
}
} class OptimalMergePattern { constructor(n, items) {
this .n = n;
this .items = items;
this .heap = new Heap();
}
optimalMerge() {
// Corner cases if list has no more than 1 item
if ( this .n <= 0) {
return 0;
}
if ( this .n === 1) {
return this .items[0];
}
// Insert items into min heap
for (const item of this .items) {
this .heap.addItem(item);
}
let count = 0;
while ( this .heap.h.length !== 1) {
const tmp = this .heap.deleteItem();
count += tmp + this .heap.h[0];
this .heap.increaseItem(0, tmp + this .heap.h[0])
}
return count
}
} // Driver Code let OMP = new OptimalMergePattern(6, [2, 3, 4, 5, 6, 7])
let ans = OMP.optimalMerge() console.log( "Minimum Computations =" , ans)
// This code is contributed by phasing17 |
Minimum Computations = 68
Time Complexity: O(nlogn)
Auxiliary Space: O(n)