# Understanding change-making algorithm

I was looking for a good solution to the Change-making problem and I found this code(Python):

``````target = 200
coins = [1,2,5,10,20,50,100,200]
ways = [1]+[0]*target
for coin in coins:
for i in range(coin,target+1):
ways[i]+=ways[i-coin]
print(ways[target])
``````

I have no problems understanding what the code literally does,but I can't understand WHY it works. Anyone can help?

-

To get all possible sets that elements are equal to 'a' or 'b' or 'c' (our coins) that sum up to 'X' you can:

• Take all such sets that sum up to X-a and add an extra 'a' to each one.
• Take all such sets that sum up to X-b and add an extra 'b' to each one.
• Take all such sets that sum up to X-c and add an extra 'c' to each one.

So number of ways you can get X is sum of numbers of ways you can get X-a and X-b and X-c.

``````ways[i]+=ways[i-coin]
``````

Rest is simple recurrence.

Extra hint: at the start you can get set with sum zero in exactly one way (empty set)

``````ways = [1]+[0]*target
``````
-

This is a classical example of dynamic programming. It uses caching to avoid the pitfall of counting things like 3+2 = 5 twice (because of another possible solution: 2+3). A recursive algorithm falls into that pitfall. Let's focus on simple example, where `target = 5` and `coins = [1,2,3]`. The piece of code you posted counts:

1. 3+2
2. 3+1+1
3. 2+2+1
4. 1+2+1+1
5. 1+1+1+1+1

when the recursive version counts:

1. 3+2
2. 2+3
3. 3+1+1
4. 1+3+1
5. 1+1+3
6. 2+1+2
7. 1+1+2
8. 2+2+1
9. 2+1+1+1
10. 1+2+1+1
11. 1+1+2+1
12. 1+1+1+2
13. 1+1+1+1+1

Recursive code:

``````coinsOptions = [1, 2, 3]
def numberOfWays(target):
if (target < 0):
return 0
elif(target == 0):
return 1
else:
return sum([numberOfWays(target - coin) for coin in coinsOptions])
print numberOfWays(5)
``````

Dynamic programming:

``````target = 5
coins = [1,2,3]
ways = [1]+[0]*target
for coin in coins:
for i in range(coin, target+1):
ways[i]+=ways[i-coin]
print ways[target]
``````

Edit I edited your post to have it, but remember about it in future.

-

The main idea behind the code is the following: "On each step there are `ways` ways to make change of `i` amount of money given coins `[1,...coin]`".

So on the first iteration you have only a coin with denomination of `1`. I believe it is evident to see that there is only one way to give a change having only these coins for any target. On this step `ways` array will look like `[1,...1]` (only one way for all targets from `0` to `target`).

On the next step we add a coin with denomination of `2` to the previous set of coins. Now we can calculate how many change combinations there are for each target from `0` to `target`. Obviously, the number of combination will increase only for targets >= `2` (or new coin added, in general case). So for a target equals `2` the number of combinations will be `ways[2](old)` + `ways[0](new)`. Generally, every time when `i` equals a new coin introduced we need to add `1` to previous number of combinations, where a new combination will consist only from one coin.

For `target` > `2`, the answer will consist of sum of "all combinations of `target` amount having all coins less than `coin`" and "all combinations of `coin` amount having all coins less than `coin` itself".

Here I described two basic steps, but I hope it is easy to generalise it.

Let me show you a computational tree for `target = 4` and `coins=[1,2]`:

ways[4] given coins=[1,2] =

ways[4] given coins=[1] + ways[2] given coins=[1,2] =

1 + ways[2] given coins=[1] + ways[0] given coins=[1,2] =

1 + 1 + 1 = 3

So there are three ways to give a change: `[1,1,1,1], [1,1,2], [2,2]`.

The code given above is completely equivalent to the recursive solution. If you understand the recursive solution, I bet you understand the solution given above.

-