# Coin changing algorithm

Suppose I have a set of coins having denominations a1, a2, ... ak.

One of them is known to be equal to 1.

I want to make change for all integers 1 to n using the minimum number of coins.

Any ideas for the algorithm.

eg. 1, 3, 4 coin denominations
n = 11
optimal selection is 3, 0, 2 in the order of coin denominations.

n = 12
optimal selection is 2, 2, 1.

Note: not homework just a modification of this problem

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I often do my very best to help homework cheaters. I'm cheered at the thought of them sailing through school, failing their job interviews and then remaining unemployed. Less competition in my job market. – Carl Smotricz Dec 31 '09 at 19:48
@Carl: The problem with that is that some of them make it through the interview, write "code", and then we get stuck trying to fix or maintain it. I'd rather them fail at the school level instead. – Ken White Dec 31 '09 at 19:58
Helping some guy solve one homework problem is not suddenly going to make them an A+ student. In some cases it might help that student "see the light" and grow into a bright young developer. Someone that repeats the behavior however (not trying to solve problems on their own) is more likely to just be someone that never grows because they aren't challenging themselves. They'll crash and burn miserably at some point, most likely exam day. At least where I went to school, exams were such a large fraction of our grades that homework was effectively irrelevant (in one course exams were 100%). – jason Dec 31 '09 at 20:13

This is a classic dynamic programming problem (note first that the greedy algorithm does not always work here!).

Assume the coins are ordered so that a_1 > a_2 > ... > a_k = 1. We define a new problem. We say that the (i, j) problem is to find the minimum number of coins making change for j using coins a_i > a_(i + 1) > ... > a_k. The problem we wish to solve is (1, j) for any j with 1 <= j <= n. Say that C(i, j) is the answer to the (i, j) problem.

Now, consider an instance (i, j). We have to decide whether or not we are using one of the a_i coins. If we are not, we are just solving a (i + 1, j) problem and the answer is C(i + 1, j). If we are, we complete the solution by making change for j - a_i. To do this using as few coins as possible, we want to solve the (i, j - a_i) problem. We arrange things so that these two problems are already solved for us and then:

C(i, j) = C(i + 1, j)                         if a_i > j
= min(C(i + 1, j), 1 + C(i, j - a_i)) if a_i <= j

Now figure out what the initial cases are and how to translate this to the language of your choice and you should be good to go.

If you want to try you hands at another interesting problem that requires dynamic programming, look at Project Euler Problem 67.

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Why wont the greedy approach always work, I don't understand? – hhafez Dec 31 '09 at 19:51
@hhafez: Consider making change for 30 given coins of denomination {1, 10, 20, 25}. The greedy algorithm produces {25, 1, 1, 1, 1, 1} but the optimal solution is {20, 10}. I think the term for coin-sets for which the greedy algorithm does work is a "friendly coin set." It is an interesting problem to determine whether or not a coin set is friendly. I could have the term wrong but the problem is interesting either way. – jason Dec 31 '09 at 19:52
Excellent thanks for that explanation – hhafez Dec 31 '09 at 19:57
Why was this down voted? – jason Oct 22 '11 at 2:21

Here's a sample implementation of a dynamic programming algorithm in Python. It is simpler than the algorithm that Jason describes, because it only calculates 1 row of the 2D table he describes.

Please note that using this code to cheat on homework will make Zombie Dijkstra cry.

import sys
def get_best_coins(coins, target):
costs = [0]
coins_used = [None]
for i in range(1,target + 1):
if i % 1000 == 0:
print '...',
bestCost = sys.maxint
bestCoin = -1
for coin in coins:
if coin <= i:
cost = 1 + costs[i - coin]
if cost < bestCost:
bestCost = cost
bestCoin = coin
costs.append(bestCost)
coins_used.append(bestCoin)
ret = []
while target > 0:
ret.append(coins_used[target])
target -= coins_used[target]
return ret

coins = [1,10,25]
target = 100033
print get_best_coins(coins, target)
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