What are all the combinations of three digits? Let's write a few out manually.

```
000, 001, 002 ... 009, 010, 011 ... 099, 100, 101 ... 998, 999
```

We ended up simply *counting*! We enumerated all the numbers between 0 and 999. For an arbitrary number of digits this generalises straightforwardly: the upper limit is `10^n`

(exclusive), where `n`

is the number of digits.

Numbers are designed this way on purpose. It would be jolly strange if there was a possible combination of three digits which wasn't a valid number, or if there was a number below 1000 which couldn't be expressed by combining three digits!

This suggests a simple plan to me, which just involves arithmetic and doesn't require a deep understanding of Haskell*:

- Generate a list of numbers between 0 and
`10^n`

- Turn each number into a list of digits.

Step 2 is the fun part. To extract the digits (in base 10) of a three-digit number, you do this:

- Take the quotient and remainder of your number with respect to 100. The quotient is the first digit of the number.
- Take the remainder from step 1 and take its quotient and remainder with respect to 10. The quotient is the second digit.
- The remainder from step 2 was the third digit. This is the same as taking the quotient with respect to 1.

For an *n*-digit number, we take the quotient `n`

times, starting with `10^(n-1)`

and ending with `1`

. Each time, we use the remainder from the last step as the input to the next step. This suggests that our function to turn a number into a list of digits should be implemented as a fold: we'll thread the remainder through the operation and build a list as we go. (I'll leave it to you to figure out how this algorithm changes if you're not in base 10!)

Now let's implement that idea. We want calculate a specified number of digits, zero-padding when necessary, of a given number. What should the type of `digits`

be?

```
digits :: Int -> Int -> [Int]
```

Hmm, it takes in a number of digits and an integer, and produces a list of integers representing the digits of the input integer. The list will contain single-digit integers, each one of which will be one digit of the input number.

```
digits numberOfDigits theNumber = reverse $ fst $ foldr step ([], theNumber) powersOfTen
where step exponent (digits, remainder) =
let (digit, newRemainder) = remainder `divMod` exponent
in (digit : digits, newRemainder)
powersOfTen = [10^n | n <- [0..(numberOfDigits-1)]]
```

What's striking to me is that this code looks quite similar to my English description of the arithmetic we wanted to perform. We generate a powers-of-ten table by exponentiating numbers from 0 upwards. Then we fold that table back up; at each step we put the quotient on the list of digits and send the remainder to the next step. We have to `reverse`

the output list at the end because of the right-to-left way it got built.

By the way, the pattern of generating a list, transforming it, and then folding it back up is an idiomatic thing to do in Haskell. It's even got its own high-falutin' mathsy name, *hylomorphism*. GHC knows about this pattern too and can compile it into a tight loop, optimising away the very existence of the list you're working with.

Let's test it!

```
ghci> digits 3 123
[1, 2, 3]
ghci> digits 5 10101
[1, 0, 1, 0, 1]
ghci> digits 6 99
[0, 0, 0, 0, 9, 9]
```

It works like a charm! (Well, it misbehaves when `numberOfDigits`

is too small for `theNumber`

, but never mind about that.) Now we just have to generate a counting list of numbers on which to use `digits`

.

```
combinationsOfDigits :: Int -> [[Int]]
combinationsOfDigits numberOfDigits = map (digits numberOfDigits) [0..(10^numberOfDigits)-1]
```

... and we've finished!

```
ghci> combinationsOfDigits 2
[[0,0],[0,1],[0,2],[0,3],[0,4],[0,5],[0,6],[0,7],[0,8],[0,9],[1,0],[1,1] ... [9,7],[9,8],[9,9]]
```

_{* For a version which does require a deep understanding of Haskell, see my other answer.}

`n-1`

choices, generate those for`n`

choices. You'll want to output a list, not a fixed-length tuple.`replicateM n [1..100]`

does the job. It's a non-trivial exercise to realize why, though -- so leave that for when you are more familiar with Haskell.`sequence $ replicate 3 [0..9]`

will generate the cross product as a list, not a tuple but easy to generalize`000`

,`001`

,`002`

...`009`

,`010`

,`011`

...`999`

... Am I missing something, or isn't this the mathematical concept known ascounting?4more comments