# Refactoring a recursive function into iterative in a coin-change type of problem

In a `coin-change` type of problem, I'm trying to refactor the recursive function into iterative. Given a set of `coin_types`, the function `coinr` finds the minimum number of coins to pay a given amount, `sum`, recursively.

``````# Any coin_type could be used more than once or it may not be used at all

sub coinr (\$sum, @coin_types) { # As this is for learning basic programming
my \$result = \$sum;          # No memoization (dynamic programming) is used
if \$sum == @coin_types.any { return 1 }
else { for @coin_types.grep(* <= \$sum) -> \$coin_type {
my \$current = 1 + coinr(\$sum - \$coin_type, @coin_types);
\$result = \$current if \$current < \$result; } }
\$result;
}

say &coinr(@*ARGS[0], split(' ', @*ARGS[1]));

# calling with
# 8 "1 4 5" gives 2 (4+4)
# 14 "1 3 5" gives 4 (1+3+5+5), etc.
``````

This function was originally written in Python and I converted it to Raku. Here is my take on the iterative version, which is very incomplete:

``````# Iterative

sub coini (\$sum, @coin_types) {
my \$result = 1;
for @coin_types -> \$coin_type {
for 1 ... \$sum -> \$i {
if \$sum-\$coin_type == @coin_types.any { \$result += 1 } #?
else { # ???
}
}
}
}
``````

Can somebody help me on this?

There are a number of different ways to implement this iteratively (There's More Than One Way To Do It, as we like to say!) Here's one approach:

``````sub coini(\$sum is copy, @coin-types) {
gather while \$sum > 0 { take \$sum -= @coin-types.grep(* ≤ \$sum).max } .elems
}
``````

This decreases the (now mutable) `\$sum` by the largest coin possible, and keeps track of the current `\$sum` in a list. Then, since we only want the number of coins, it returns the length of that list.

• This is a good example of the gather/take construct and shows how to use an argument inside the function by the `is copy` trait. – Lars Malmsteen Jul 8 at 10:50