# Idiomatic way to create n-ary cartesian product (combinations of several sets of parameters)

To create all possible combinations of two sets of parameters and perform an action on them, you can do:

``````setOf(foo, bar, baz).forEach { a ->
setOf(0, 1).forEach { b ->
/* use a and b */
}
}
``````

However, if you have (potentially many) more parameters, this quickly turns into a pyramid of doom:

``````setOf(foo, bar, baz).forEach { a ->
setOf(0, 1).forEach { b ->
setOf(true, false, null).forEach { c ->
setOf("Hello,", "World!").forEach { d ->
/* use a, b, c and d */
}
}
}
}
``````

You could write this similarly with `for` loops, or differently like so:

``````val dAction = { d: String -> /* use a, b, c and d */ }
val cAction = { c: Boolean? -> setOf("Hello,", "World!").forEach(dAction) }
val bAction = { b: Int -> setOf(true, false, null).forEach(cAction) }
val aAction = { a: Any? -> setOf(0, 1).forEach(bAction) }
setOf(foo, bar, baz).forEach(aAction)
``````

But I don't think that's any better, because there are some readability issues here: d, c, b and a's actions are written in reverse. Their type specifications cannot be inferred, so they must be specified. It's reversed sequentially compared to the pyramid of doom. The order of the sets providing the possible values should not matter, but it does: you just want to create any combinations from a bunch of sets, however, in this code every line depends on the previous.

It would be very nice to have an idiomatic way of doing something like Python's or Haskell's comprehensions, in which you (almost like the mathematical notation) can do something like:

``````{ /* use a, b, c and d */
for a in setOf(foo, bar, baz),
for b in setOf(0, 1),
for c in setOf(true, false, null),
for d in setOf("Hello,", "World!")
}
``````

Which is very easy to read: there is no excessive indentation, the action you're interested in goes first, the data sources are very clearly defined, etc.

Side note: similar problems occur with `flatMap`-`flatMap`-...-`flatMap`-`map`.

Any ideas about how to neatly create n-ary cartesian products in Kotlin?

I would recommend using `Arrow-kt`'s Applicative on `List`. See the example:

``````val ints = listOf(1, 2, 3, 4)
val strings = listOf("a", "b", "c")
val booleans = listOf(true, false)

val combined = ListK.applicative()
.tupled(ints.k(), strings.k(), doubles.k())
.fix()

// or use the shortcut `arrow.instances.list.applicative.tupled`
// val combined = tupled(ints, strings, booleans)

combined.forEach { (a, b, c) -> println("a=\$a, b=\$b, c=\$c") }
``````

Which produces the Cartesian product

a=1, b=a, c=true

a=1, b=b, c=true

a=1, b=c, c=true

a=2, b=a, c=true

a=2, b=b, c=true

a=2, b=c, c=true

a=3, b=a, c=true

a=3, b=b, c=true

a=3, b=c, c=true

a=4, b=a, c=true

a=4, b=b, c=true

a=4, b=c, c=true

a=1, b=a, c=false

a=1, b=b, c=false

a=1, b=c, c=false

a=2, b=a, c=false

a=2, b=b, c=false

a=2, b=c, c=false

a=3, b=a, c=false

a=3, b=b, c=false

a=3, b=c, c=false

a=4, b=a, c=false

a=4, b=b, c=false

a=4, b=c, c=false

• Nice to see that Arrow has this feature. You'd expect that from a functional programming lib. I prefer not to add an additional dependency just to be able to do this. This answer is great for users of Arrow, or looking for a reason to use Arrow. I'll await a different answer that might shed light on the problem with either some nifty Kotlin construct, or just a plain: no, it can't be done without ugly code. ;) – Erik Dec 13 '18 at 7:32

I've created a solution myself, so I don't have to add a dependency as suggested by Omar's answer.

I created a function that takes any number of sets of any size:

``````fun cartesianProduct(vararg sets: Set<*>): Set<List<*>> =
when (sets.size) {
0, 1 -> emptySet()
else -> sets.fold(listOf(listOf<Any?>())) { acc, set ->
acc.flatMap { list -> set.map { element -> list + element } }
}.toSet()
}
``````

Example:

``````val a = setOf(1, 2)
val b = setOf(3, 4)
val c = setOf(5)
val d = setOf(6, 7, 8)

val abcd: Set<List<*>> = cartesianProduct(a, b, c, d)

println(abcd)
``````

Output:

``````[[1, 3, 5, 6], [1, 3, 5, 7], [1, 3, 5, 8], [1, 4, 5, 6], [1, 4, 5, 7], [1, 4, 5, 8], [2, 3, 5, 6], [2, 3, 5, 7], [2, 3, 5, 8], [2, 4, 5, 6], [2, 4, 5, 7], [2, 4, 5, 8]]
``````

The function `cartesianProduct` returns a set of lists. There's a number of problems with these lists:

• Any type information is lost, because the returned set contains lists that contain the union of types of the input sets. The returned type of these lists' elements is `Any?`. The function returns a `Set<List<*>>`, i.e. `Set<List<Any?>>`.
• The lists could be of any size, while you want them to be of the specified size (the number of input sets, 4 in the example above).

However, using reflection, we can solve these problems. The action we want to take with every list can be written as a function (e.g. a constructor of some class, which is also just a function):

``````data class Parameters(val number: Int, val maybe: Boolean?) {
override fun toString() = "number = \$number, maybe = \$maybe"
}

val e: Set<Int> = setOf(1, 2)
val f: Set<Boolean?> = setOf(true, false, null)

val parametersList: List<Parameters> = cartesianProduct(e, f).map { ::Parameters.call(*it.toTypedArray()) }

println(parametersList.joinToString("\n"))
``````

Output:

``````number = 1, maybe = true
number = 1, maybe = false
number = 1, maybe = null
number = 2, maybe = true
number = 2, maybe = false
number = 2, maybe = null
``````

The signature of the transform (`::Parameters` in the example) specifies the contract for the lists' contents.

Because `map { ::Parameters.call(*it.toTypedArray()) }` is not very nice, I've created a second extension function that does it for me:

``````fun <T> Set<List<*>>.map(transform: KFunction<T>) = map { transform.call(*it.toTypedArray()) }
``````

With that, the code becomes quite idiomatic:

``````val parametersList: List<Parameters> = cartesianProduct(e, f).map(::Parameters)
``````

The code is available from this GitHub Gist, where I will update it if I ever improve it. There are also tests: the cartesian product of no input or a single input return the empty set, as is mathematically expected. I'm neither saying that this is an optimal solution, nor that it is mathematically sound (not every mathematical property is explicitly implemented and tested), but it works for the question's purpose.

• With this answer there is still the issue of type variance, because the star projections don't know or care about the types in the sets that are passed to this functions. This can later result in issues when using the types, because they now have type `Any?` and have to be downcasted. – Erik Dec 13 '18 at 15:22
• ^ I was just about to mention this, you lose not only type inference, but also can make mistakes like `cartesianProduct(setOf(1, 2), setOf("a", "b")).forEach { (a, b, c) -> println("a=\$a, b=\$b, c=\$c") }` an it will compile fine but crash at runtime – Omar Mainegra Dec 13 '18 at 15:49
• Also the returned value is a `List` not a product type like `TupleN` or an heterogeneous list which can bring other issues (i.e. mistakely sort the list) – Omar Mainegra Dec 13 '18 at 15:55
• Ah, I hadn't thought about sorting yet. In my specific use case the order doesn't matter, so it wasn't an issue. Although, on my Gist there is one test that asserts equality, which fails for a different order. This doesn't guarantee the order isn't touched, though. But my implementation should have a stable order. I'm still looking into a way to improve this implementation with knowledge about types and the number of elements. If you have ideas, feel free to contribute to my answer or elsewhere. – Erik Dec 13 '18 at 16:32
• You're right. Looking at Arrow's source, they have data class definitions for tuples from two through twenty-two elements. Any larger amount of arguments is unlikely and probably is too computationally heavy. I'll leave my answer for reference as a naive implementation in which type information is erased, which still can be useful for whomever doesn't want Arrow as an extra dependency. – Erik Dec 14 '18 at 13:01