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.