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Implementation of Dynamic Array in Python

What is a dynamic array?

A dynamic array is similar to an array, but with the difference that its size can be dynamically modified at runtime. Don’t need to specify how much large an array beforehand. The elements of an array occupy a contiguous block of memory, and once created, its size cannot be changed. A dynamic array can, once the array is filled, allocate a bigger chunk of memory, copy the contents from the original array to this new space, and continue to fill the available slots.

We’ll be using a built in library called ctypes of python . Check out the documentation for more info, but its basically going to be used here as a raw array from the ctypes module.

A quick note on public vs private methods, we can use an underscore _ before the method name to keep it non-public. 

For example:

Python




class M(object):
 
    def public(self):
        print 'Use Tab to see me !'
 
    def _private(self):
        print "You won't be able to Tab to see me !"


Python




m = M()
m.public()


Output:

Use Tab to see me!

Python




m._private()


Output:

You won't be able to see me!

Dynamic Array Logic Implementation:

The key is to provide means to grows an array A that stores the elements of a list. We can’t actually grow the array, its capacity is fixed. If an element is appended to a list at a time, when the underlying array is full, we need to perform following steps.

  1. Allocate a new array B with larger capacity (A commonly used rule for the new array is to have twice the capacity of the existing array )
  2. Set B[i]=A[i], for i=0 to n-1 where n denotes the current no of items.
  3. Set A=B that is, we hence forth use B as the array of supporting list.
  4. Insert new element in the new array.

Dynamic Array Code Implementation: 

Python3




import ctypes
 
 
class DynamicArray(object):
    '''
    DYNAMIC ARRAY CLASS (Similar to Python List)
    '''
 
    def __init__(self):
        self.n = 0  # Count actual elements (Default is 0)
        self.capacity = 1  # Default Capacity
        self.A = self.make_array(self.capacity)
 
    def __len__(self):
        """
        Return number of elements stored in array
        """
        return self.n
 
    def __getitem__(self, k):
        """
        Return element at index k
        """
        if not 0 <= k < self.n:
            # Check it k index is in bounds of array
            return IndexError('K is out of bounds !')
 
        return self.A[k]  # Retrieve from the array at index k
 
    def append(self, ele):
        """
        Add element to end of the array
        """
        if self.n == self.capacity:
            # Double capacity if not enough room
            self._resize(2 * self.capacity)
 
        self.A[self.n] = ele  # Set self.n index to element
        self.n += 1
 
    def insertAt(self, item, index):
        """
        This function inserts the item at any specified index.
        """
 
        if index < 0 or index > self.n:
            print("please enter appropriate index..")
            return
 
        if self.n == self.capacity:
            self._resize(2*self.capacity)
 
        for i in range(self.n-1, index-1, -1):
            self.A[i+1] = self.A[i]
 
        self.A[index] = item
        self.n += 1
 
    def delete(self):
        """
        This function deletes item from the end of array
        """
 
        if self.n == 0:
            print("Array is empty deletion not Possible")
            return
 
        self.A[self.n-1] = 0
        self.n -= 1
 
    def removeAt(self, index):
        """
        This function deletes item from a specified index..
        """
 
        if self.n == 0:
            print("Array is empty deletion not Possible")
            return
 
        if index < 0 or index >= self.n:
            return IndexError("Index out of bound....deletion not possible")
 
        if index == self.n-1:
            self.A[index] = 0
            self.n -= 1
            return
 
        for i in range(index, self.n-1):
            self.A[i] = self.A[i+1]
 
        self.A[self.n-1] = 0
        self.n -= 1
 
    def _resize(self, new_cap):
        """
        Resize internal array to capacity new_cap
        """
 
        B = self.make_array(new_cap)  # New bigger array
 
        for k in range(self.n):  # Reference all existing values
            B[k] = self.A[k]
 
        self.A = # Call A the new bigger array
        self.capacity = new_cap  # Reset the capacity
 
    def make_array(self, new_cap):
        """
        Returns a new array with new_cap capacity
        """
        return (new_cap * ctypes.py_object)()
 
# Instantiate
 
 
arr = DynamicArray()
 
# append the new elements
 
arr.append(1)
 
arr.append(2)
 
arr.append(3)
 
# length of the given append in array
 
print(len(arr))
 
# access the given append in array
 
print(arr[1])
 
print(arr[2])
 
# remove the given the array
 
arr.removeAt(2)
 
# length of the array
 
print(len(arr))
 
# index of the array
 
print(arr[1])
 
    #This code Contribute by Raja.Ramakrishna


Output:

3
2
3
2
2

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