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89 lines
3.2 KiB
Python
89 lines
3.2 KiB
Python
"""
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A shopkeeper has bags of wheat that each have different weights and different profits.
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eg.
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no_of_items : 5
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profit [15, 14,10,45,30]
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weight [2,5,1,3,4]
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max_weight that can be carried : 7
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Constraints:
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max_weight > 0
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profit[i] >= 0
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weight[i] >= 0
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Calculate:
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The maximum profit that the shopkeeper can make given maxmum weight that can
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be carried.
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This problem is implemented here with MEMOIZATION method using the concept of Dynamic Programming
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"""
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"""
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for more information visit https://en.wikipedia.org/wiki/Memoization
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"""
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def knapsack(values:list, weights:list, num_of_items:int, max_weight:int, dp:list) -> int:
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"""
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Function description is as follows-
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:param weights: Take a list of weights
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:param values: Take a list of profits corresponding to the weights
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:param number_of_items: number of items available to pick from
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:param max_weight: Maximum weight that could be carried
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:param dp: it is a list of list, i.e, a table whose (i,j) cell represents the maximum profit earned
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for i items and j as the maximum weight allowed, it is an essential part for implementing this problems
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using memoization dynamic programming
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:return: Maximum expected gain
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Testcase 1:
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>>> values = [1, 2, 4, 5]
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>>> wt = [5, 4, 8, 6]
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>>> n = len(values)
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>>> w = 5
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>>> dp = [[-1 for x in range(w+1)] for y in range(n+1)]
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>>> knapsack(values,wt,n,w,dp)
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2
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Testcase 2:
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>>> values = [3 ,4 , 5]
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>>> wt = [10, 9 , 8]
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>>> n = len(values)
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>>> w = 25
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>>> dp = [[-1 for x in range(w+1)] for y in range(n+1)]
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>>> knapsack(values,wt,n,w,dp)
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9
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Testcase 3:
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>>> values = [15, 14,10,45,30]
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>>> wt = [2,5,1,3,4]
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>>> n = len(values)
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>>> w = 7
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>>> dp = [[-1 for x in range(w+1)] for y in range(n+1)]
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>>> knapsack(values,wt,n,w,dp)
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75
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"""
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if max_weight == 0 or num_of_items == 0: #no profit gain if any of these two become zero
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dp[num_of_items][max_weight] = 0
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return 0
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elif dp[num_of_items][max_weight] != -1: #if this case is previously encountered => maximum gain for this case is already
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#in dp table
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return dp[num_of_items][max_weight]
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elif weights[num_of_items-1] <= max_weight: #if the item can be included in the bag
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# ans1 stores the maximum profit if the item at index num_of_items -1 is included in the bag
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ans1 = values[num_of_items - 1] + knapsack(values, weights, num_of_items-1, max_weight-weights[num_of_items-1], dp)
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# ans2 stores the maximum profit if the item at index num_of_items -1 is not included in the bag
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ans2 = knapsack(values, weights, num_of_items-1, max_weight, dp)
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# the final answer is the maximum profit gained from any of ans1 or ans2
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dp[num_of_items][max_weight] = max(ans1, ans2)
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return dp[num_of_items][max_weight]
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# if the item's weight exceeds the max_weight of the bag => it cannot be included in the bag
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else:
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dp[num_of_items][max_weight] = knapsack(values, weights, num_of_items-1, max_weight, dp)
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return dp[num_of_items][max_weight]
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if __name__ == '__main__':
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import doctest
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doctest.testmod(name='knapsack', verbose=True) |