Program for Worst Fit algorithm in Memory Management
Last Updated :
13 Sep, 2023
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Prerequisite : Partition allocation methods
Worst Fit allocates a process to the partition which is largest sufficient among the freely available partitions available in the main memory. If a large process comes at a later stage, then memory will not have space to accommodate it.
Example:
Input : blockSize[] = {100, 500, 200, 300, 600};
processSize[] = {212, 417, 112, 426};
Output:
Process No. Process Size Block no.
1 212 5
2 417 2
3 112 5
4 426 Not Allocated
Implementation: 1- Input memory blocks and processes with sizes. 2- Initialize all memory blocks as free. 3- Start by picking each process and find the maximum block size that can be assigned to current process i.e., find max(bockSize[1], blockSize[2],.....blockSize[n]) > processSize[current], if found then assign it to the current process. 5- If not then leave that process and keep checking the further processes.
Below is implementation of above steps.
// C++ implementation of worst - Fit algorithm
#include<bits/stdc++.h>
using namespace std;
// Function to allocate memory to blocks as per worst fit
// algorithm
void worstFit(int blockSize[], int m, int processSize[],
int n)
{
// Stores block id of the block allocated to a
// process
int allocation[n];
// Initially no block is assigned to any process
memset(allocation, -1, sizeof(allocation));
// pick each process and find suitable blocks
// according to its size ad assign to it
for (int i=0; i<n; i++)
{
// Find the best fit block for current process
int wstIdx = -1;
for (int j=0; j<m; j++)
{
if (blockSize[j] >= processSize[i])
{
if (wstIdx == -1)
wstIdx = j;
else if (blockSize[wstIdx] < blockSize[j])
wstIdx = j;
}
}
// If we could find a block for current process
if (wstIdx != -1)
{
// allocate block j to p[i] process
allocation[i] = wstIdx;
// Reduce available memory in this block.
blockSize[wstIdx] -= processSize[i];
}
}
cout << "\nProcess No.\tProcess Size\tBlock no.\n";
for (int i = 0; i < n; i++)
{
cout << " " << i+1 << "\t\t" << processSize[i] << "\t\t";
if (allocation[i] != -1)
cout << allocation[i] + 1;
else
cout << "Not Allocated";
cout << endl;
}
}
// Driver code
int main()
{
int blockSize[] = {100, 500, 200, 300, 600};
int processSize[] = {212, 417, 112, 426};
int m = sizeof(blockSize)/sizeof(blockSize[0]);
int n = sizeof(processSize)/sizeof(processSize[0]);
worstFit(blockSize, m, processSize, n);
return 0 ;
}
// Java implementation of worst - Fit algorithm
public class GFG
{
// Method to allocate memory to blocks as per worst fit
// algorithm
static void worstFit(int blockSize[], int m, int processSize[],
int n)
{
// Stores block id of the block allocated to a
// process
int allocation[] = new int[n];
// Initially no block is assigned to any process
for (int i = 0; i < allocation.length; i++)
allocation[i] = -1;
// pick each process and find suitable blocks
// according to its size ad assign to it
for (int i=0; i<n; i++)
{
// Find the best fit block for current process
int wstIdx = -1;
for (int j=0; j<m; j++)
{
if (blockSize[j] >= processSize[i])
{
if (wstIdx == -1)
wstIdx = j;
else if (blockSize[wstIdx] < blockSize[j])
wstIdx = j;
}
}
// If we could find a block for current process
if (wstIdx != -1)
{
// allocate block j to p[i] process
allocation[i] = wstIdx;
// Reduce available memory in this block.
blockSize[wstIdx] -= processSize[i];
}
}
System.out.println("\nProcess No.\tProcess Size\tBlock no.");
for (int i = 0; i < n; i++)
{
System.out.print(" " + (i+1) + "\t\t" + processSize[i] + "\t\t");
if (allocation[i] != -1)
System.out.print(allocation[i] + 1);
else
System.out.print("Not Allocated");
System.out.println();
}
}
// Driver Method
public static void main(String[] args)
{
int blockSize[] = {100, 500, 200, 300, 600};
int processSize[] = {212, 417, 112, 426};
int m = blockSize.length;
int n = processSize.length;
worstFit(blockSize, m, processSize, n);
}
}
# Python3 implementation of worst - Fit algorithm
# Function to allocate memory to blocks as
# per worst fit algorithm
def worstFit(blockSize, m, processSize, n):
# Stores block id of the block
# allocated to a process
# Initially no block is assigned
# to any process
allocation = [-1] * n
# pick each process and find suitable blocks
# according to its size ad assign to it
for i in range(n):
# Find the best fit block for
# current process
wstIdx = -1
for j in range(m):
if blockSize[j] >= processSize[i]:
if wstIdx == -1:
wstIdx = j
elif blockSize[wstIdx] < blockSize[j]:
wstIdx = j
# If we could find a block for
# current process
if wstIdx != -1:
# allocate block j to p[i] process
allocation[i] = wstIdx
# Reduce available memory in this block.
blockSize[wstIdx] -= processSize[i]
print("Process No. Process Size Block no.")
for i in range(n):
print(i + 1, " ",
processSize[i], end = " ")
if allocation[i] != -1:
print(allocation[i] + 1)
else:
print("Not Allocated")
# Driver code
if __name__ == '__main__':
blockSize = [100, 500, 200, 300, 600]
processSize = [212, 417, 112, 426]
m = len(blockSize)
n = len(processSize)
worstFit(blockSize, m, processSize, n)
# This code is contributed by PranchalK
// C# implementation of worst - Fit algorithm
using System;
class GFG
{
// Method to allocate memory to blocks
// as per worst fit algorithm
static void worstFit(int []blockSize, int m,
int []processSize, int n)
{
// Stores block id of the block allocated to a
// process
int []allocation = new int[n];
// Initially no block is assigned to any process
for (int i = 0; i < allocation.Length; i++)
allocation[i] = -1;
// pick each process and find suitable blocks
// according to its size ad assign to it
for (int i = 0; i < n; i++)
{
// Find the best fit block for current process
int wstIdx = -1;
for (int j = 0; j < m; j++)
{
if (blockSize[j] >= processSize[i])
{
if (wstIdx == -1)
wstIdx = j;
else if (blockSize[wstIdx] < blockSize[j])
wstIdx = j;
}
}
// If we could find a block for current process
if (wstIdx != -1)
{
// allocate block j to p[i] process
allocation[i] = wstIdx;
// Reduce available memory in this block.
blockSize[wstIdx] -= processSize[i];
}
}
Console.WriteLine("\nProcess No.\tProcess Size\tBlock no.");
for (int i = 0; i < n; i++)
{
Console.Write(" " + (i+1) + "\t\t\t" + processSize[i] + "\t\t\t");
if (allocation[i] != -1)
Console.Write(allocation[i] + 1);
else
Console.Write("Not Allocated");
Console.WriteLine();
}
}
// Driver code
public static void Main(String[] args)
{
int []blockSize = {100, 500, 200, 300, 600};
int []processSize = {212, 417, 112, 426};
int m = blockSize.Length;
int n = processSize.Length;
worstFit(blockSize, m, processSize, n);
}
}
// This code has been contributed by 29AjayKumar
<script>
// Javascript implementation of
// worst - Fit algorithm
// Method to allocate memory to
// blocks as per worst fit
// algorithm
function worstFit(blockSize, m,
processSize, n)
{
// Stores block id of the block allocated
// to a process
let allocation = new Array(n);
// Initially no block is assigned
// to any process
for(let i = 0; i < allocation.length; i++)
allocation[i] = -1;
// Pick each process and find suitable blocks
// according to its size ad assign to it
for(let i = 0; i < n; i++)
{
// Find the best fit block
// for current process
let wstIdx = -1;
for(let j = 0; j < m; j++)
{
if (blockSize[j] >= processSize[i])
{
if (wstIdx == -1)
wstIdx = j;
else if (blockSize[wstIdx] <
blockSize[j])
wstIdx = j;
}
}
// If we could find a block for
// current process
if (wstIdx != -1)
{
// Allocate block j to p[i] process
allocation[i] = wstIdx;
// Reduce available memory in this block.
blockSize[wstIdx] -= processSize[i];
}
}
document.write("<br>Process No.  " +
" Process Size  " +
" Block no.<br>");
for(let i = 0; i < n; i++)
{
document.write(" " + (i + 1) +
"     " +
"    " +
processSize[i] +
"      ");
if (allocation[i] != -1)
document.write(allocation[i] + 1);
else
document.write("Not Allocated");
document.write("<br>");
}
}
// Driver code
let blockSize = [ 100, 500, 200, 300, 600 ];
let processSize = [ 212, 417, 112, 426 ];
let m = blockSize.length;
let n = processSize.length;
worstFit(blockSize, m, processSize, n);
// This code is contributed by rag2127
</script>
Output
Process No. Process Size Block no. 1 212 5 2 417 2 3 112 5 4 426 Not Allocated
Time Complexity: O(N*M) where N is processSize length and M is blockSize length.
Auxiliary Space: O(N)
