Question
PYTHON ORDERED HASHTABLE I'm having touble with the following assignment and implementation of an array-backed ordered hashtable in python. Ordered Hashtable Overview For this assignment
PYTHON ORDERED HASHTABLE
I'm having touble with the following assignment and implementation of an array-backed ordered hashtable in python.
Ordered Hashtable
Overview
For this assignment you will update and complete the implementation of the hashtable data structure presented in class, which exposes an API mirroring that of the built-in Python dict. When iterating over its contents (supported by the __iter__, keys, values, and items methods), your updated implementation will also reflect the order in which key/value pairs were originally inserted into the hashtable. This will require that you implement the two-tiered list system described during lecture.
The operations you will implement are listed alongside their descriptions below (h refers to a hashtable):
Operation | Description |
---|---|
h[k] = v | If h does not contain key k, a new kv mapping is added, else the value for key k is updated to v. |
h[k] | If h contains key k, the corresponding value is returned, else a KeyError is raised. |
del h[k] | If h contains key k, it is removed along with its value, else a KeyError is raised. Note that if k is re-inserted at some later point it is considered a new key (for ordering purposes). |
k in h | Returns True if key k is in h. |
len(h) | Returns the number of keys in h. |
iter(h) | Returns an iterator over all the keys in h, in the order they were added. |
h.keys() | (Same as above) |
h.values() | Returns an iterator over all the values in h, in the order they were added. |
h.items() | Returns an iterator over all the key/value pairs (as tuples) in h, in the order they were added. |
Your hashtable will be provided with the initial number of buckets on creation (i.e., in __init__); your implementation must heed this value, as there may be performance ramifications if it does not.
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class OrderedHashtable: class Node: """This class is used to create nodes in the singly linked "chains" in each hashtable bucket.""" def __init__(self, index, next=None): # don't rename the following attributes! self.index = index self.next = next def __init__(self, n_buckets=1000): # the following two variables should be used to implement the "two-tiered" # ordered hashtable described in class -- don't rename them! self.indices = [None] * n_buckets self.entries = [] self.count = 0 def __getitem__(self, key): # YOUR CODE HERE raise NotImplementedError() def __setitem__(self, key, val): # YOUR CODE HERE raise NotImplementedError() def __delitem__(self, key): # YOUR CODE HERE raise NotImplementedError() def __contains__(self, key): try: _ = self[key] return True except: return False def __len__(self): return self.count def __iter__(self): # YOUR CODE HERE raise NotImplementedError() def keys(self): return iter(self) def values(self): # YOUR CODE HERE raise NotImplementedError() def items(self): # YOUR CODE HERE raise NotImplementedError() def __str__(self): return '{ ' + ', '.join(str(k) + ': ' + str(v) for k, v in self.items()) + ' }' def __repr__(self): return str(self)
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# (3 tests) Short tests from unittest import TestCase import random tc = TestCase() ht = OrderedHashtable(2) for k, v in (('batman', 'bruce wayne'), ('superman', 'clark kent'), ('spiderman', 'peter parker')): ht[k] = v tc.assertEqual(len(ht), 3) tc.assertEqual(ht['superman'], 'clark kent') tc.assertTrue('spiderman' in ht) tc.assertFalse('iron man' in ht) with tc.assertRaises(KeyError): ht['iron man']
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# (3 points) Basic tests (insertion, fetch, count, chain-lengths) from unittest import TestCase import random tc = TestCase() class MyInt(int): def __hash__(self): """MyInts hash to themselves already current Python default, but just to ensure consistency.""" return self def ll_len(l): """Returns the length of a linked list with head `l` (assuming no sentinel)""" c = 0 while l: c += 1 l = l.next return c ht = OrderedHashtable(10) for i in range(25): ht[MyInt(i)] = i*2 tc.assertEqual(len(ht), 25) for i in range(5): tc.assertEqual(ll_len(ht.indices[i]), 3) for i in range(5, 10): tc.assertEqual(ll_len(ht.indices[i]), 2) for i in range(25): tc.assertTrue(MyInt(i) in ht) tc.assertEqual(ht[MyInt(i)], i*2)
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# (3 points) Update testing from unittest import TestCase import random tc = TestCase() ht = OrderedHashtable(100) d = {} for i in range(100): k, v = str(i), str(i*2) d[k] = v ht[k] = v for j in range(0, 100, 2): k, v = str(i), str(i*3) d[k] = v ht[k] = v for j in range(0, 100, 4): k, v = str(i), str(i*4) d[k] = v ht[k] = v for i in range(100): tc.assertTrue(k in ht) tc.assertEqual(d[k], ht[k])
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# (3 points) Deletion testing from unittest import TestCase import random tc = TestCase() ht = OrderedHashtable(100) d = {} for i in range(100): k, v = str(i), str(random.randrange(10000000, 99999999)) d[k] = v ht[k] = v for _ in range(50): k = str(random.randrange(100)) if k in d: del d[k] del ht[k] tc.assertEqual(len(ht), len(d)) for k,v in ht.items(): tc.assertEqual(d[k], v)
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# (4 points) Iteration order testing from unittest import TestCase import random tc = TestCase() ht = OrderedHashtable(1000) l = [str(i) for i in range(0, 1000)] random.shuffle(l) for x in l: ht[x] = x for _ in range(50): idx_to_del = random.randrange(len(l)) val_to_del = l[idx_to_del] del ht[val_to_del] del l[idx_to_del] if random.randrange(2) == 0: l.append(val_to_del) ht[val_to_del] = val_to_del for x, y in zip(l, ht): tc.assertEqual(x, y)
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# (4 points) Stress testing from unittest import TestCase from time import time import random tc = TestCase() ht = OrderedHashtable(100000) d = {} start = time() for _ in range(100000): k, v = str(random.randrange(100000)), str(random.randrange(10000000, 99999999)) d[k] = v ht[k] = v for k,v in d.items(): tc.assertTrue(k in ht) tc.assertEqual(d[k], ht[k]) end = time() print(end-start) tc.assertLess(end-start, 1.5, 'Your implementation ran too slow!')
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