class Heap:
"""
A generic Heap class, can be used as min or max by passing the key function
accordingly.
"""
def __init__(self, key=None):
self.arr = list()
self.pos_map = {}
self.size = 0
self.key = key or (lambda x: x)
def _parent(self, i):
"""Returns parent index of given index if exists else None"""
return int((i - 1) / 2) if i > 0 else None
def _left(self, i):
"""Returns left-child-index of given index if exists else None"""
left = int(2 * i + 1)
return left if 0 < left < self.size else None
def _right(self, i):
"""Returns right-child-index of given index if exists else None"""
right = int(2 * i + 2)
return right if 0 < right < self.size else None
def _swap(self, i, j):
"""Performs changes required for swapping two elements in the heap"""
self.pos_map[self.arr[i][0]], self.pos_map[self.arr[j][0]] = (
self.pos_map[self.arr[j][0]],
self.pos_map[self.arr[i][0]],
)
self.arr[i], self.arr[j] = self.arr[j], self.arr[i]
def _cmp(self, i, j):
"""Compares the two items using default comparison"""
return self.arr[i][1] < self.arr[j][1]
def _get_valid_parent(self, i):
"""
Returns index of valid parent as per desired ordering among given index and
both it's children
"""
left = self._left(i)
right = self._right(i)
valid_parent = i
if left is not None and not self._cmp(left, valid_parent):
valid_parent = left
if right is not None and not self._cmp(right, valid_parent):
valid_parent = right
return valid_parent
def _heapify_up(self, index):
"""Fixes the heap in upward direction of given index"""
parent = self._parent(index)
while parent is not None and not self._cmp(index, parent):
self._swap(index, parent)
index, parent = parent, self._parent(parent)
def _heapify_down(self, index):
"""Fixes the heap in downward direction of given index"""
valid_parent = self._get_valid_parent(index)
while valid_parent != index:
self._swap(index, valid_parent)
index, valid_parent = valid_parent, self._get_valid_parent(valid_parent)
def update_item(self, item, item_value):
"""Updates given item value in heap if present"""
if item not in self.pos_map:
return
index = self.pos_map[item]
self.arr[index] = [item, self.key(item_value)]
self._heapify_up(index)
self._heapify_down(index)
def delete_item(self, item):
"""Deletes given item from heap if present"""
if item not in self.pos_map:
return
index = self.pos_map[item]
del self.pos_map[item]
self.arr[index] = self.arr[self.size - 1]
self.pos_map[self.arr[self.size - 1][0]] = index
self.size -= 1
if self.size > index:
self._heapify_up(index)
self._heapify_down(index)
def insert_item(self, item, item_value):
"""Inserts given item with given value in heap"""
arr_len = len(self.arr)
if arr_len == self.size:
self.arr.append([item, self.key(item_value)])
else:
self.arr[self.size] = [item, self.key(item_value)]
self.pos_map[item] = self.size
self.size += 1
self._heapify_up(self.size - 1)
def get_top(self):
"""Returns top item tuple (Calculated value, item) from heap if present"""
return self.arr[0] if self.size else None
def extract_top(self):
"""
Return top item tuple (Calculated value, item) from heap and removes it as well
if present
"""
top_item_tuple = self.get_top()
if top_item_tuple:
self.delete_item(top_item_tuple[0])
return top_item_tuple
def test_heap() -> None:
"""
>>> h = Heap() # Max-heap
>>> h.insert_item(5, 34)
>>> h.insert_item(6, 31)
>>> h.insert_item(7, 37)
>>> h.get_top()
[7, 37]
>>> h.extract_top()
[7, 37]
>>> h.extract_top()
[5, 34]
>>> h.extract_top()
[6, 31]
>>> h = Heap(key=lambda x: -x) # Min heap
>>> h.insert_item(5, 34)
>>> h.insert_item(6, 31)
>>> h.insert_item(7, 37)
>>> h.get_top()
[6, -31]
>>> h.extract_top()
[6, -31]
>>> h.extract_top()
[5, -34]
>>> h.extract_top()
[7, -37]
>>> h.insert_item(8, 45)
>>> h.insert_item(9, 40)
>>> h.insert_item(10, 50)
>>> h.get_top()
[9, -40]
>>> h.update_item(10, 30)
>>> h.get_top()
[10, -30]
>>> h.delete_item(10)
>>> h.get_top()
[9, -40]
"""
pass
if __name__ == "__main__":
import doctest
doctest.testmod()