I'm trying out some examples from the Swift book, namely the matrix example they have which introduces subscript options. This is the code I have:

struct Matrix<T> {
    let rows: Int, columns: Int
    var grid: T[]

    var description: String {
        return "\(grid)"

    init(rows: Int, columns: Int, initialValue: T) {
        self.rows = rows
        self.columns = columns
        grid = Array(count: rows * columns, repeatedValue: initialValue)

    func indexIsValidForRow(row: Int, column: Int) -> Bool {
        return row >= 0 && row < rows && column >= 0 && column < columns

    subscript(row: Int, column: Int) -> T {
        get {
            assert(indexIsValidForRow(row, column: column), "Index out of range")
            return grid[(row * columns) + column]
        set {
            assert(indexIsValidForRow(row, column: column), "Index out of range")
            grid[(row * columns) + column] = newValue

This is mostly copied from the book. A major difference is in this line here:

struct Matrix<T>

As far as I can tell, this says to the compiler that my Matrix class can hold values of type T, specified by the code using this class. Now, I'd like to make sure that the type T can be compared, so I can write this:

struct Matrix<T: Equatable>

This might be useful in case I want to compare 2 matrices, which would mean comparing their values. I also want to provide the ability to sum two matrices, so I should also add to this line a protocol requiring that the type 'T' given by the user of the matrix can be added:

struct Matrix<T: Equatable, "Summable">

Likewise, I'd also like to say:

struct Matrix<T: Equatable, "Summable", "Multipliable">

Question 1: What protocol name can I use? How can I achieve this?

On a related note, to add addition abilities using the '+' operator, I should declare a function like this (this applies also to multiplication):

@infix func + (m1: Matrix<T>, m2: Matrix<T>) -> Matrix<T> {
    // perform addition here and return a new matrix
    return result

However, this code is not accepted by Xcode. More specifically, this ) -> Matrix<T> { produces the error: Use of undeclared type 'T'. What I mean by that <T> is that the result will be a matrix that has the same type of the two input matrices, but I'm probably messing the syntax completely.

Question 2: How can I provide type information to the result of the addition?

  • I updated my answer. My failure to define the + operator failed because I tested it in the REPL, where it doesn't work. It does work when used in a file, which apparently defines a 'global environment' Cheers! – GoZoner Jun 4 '14 at 21:39

Here's for your second question (but you really should ask two separate questions):

@infix func + <T> (m1: Matrix<T>, m2: Matrix<T>) -> Matrix<T> { ... }

For your first question: before solving it, here's the syntax to define multiple constraints for type parameter:

struct Matrix<T where T: Equatable, T: Summable, T: Multipliable> {...}

or, as GoZoner writes in the comments:

struct Matrix<T: protocol<Equatable, Summable, Multipliable>> {...}

But we're not going to need it. First, define a new protocol and list the operations that you need. You can even make it extend Equatable:

protocol SummableMultipliable: Equatable {
    func +(lhs: Self, rhs: Self) -> Self
    func *(lhs: Self, rhs: Self) -> Self

Then, provide extensions for the types that you want to conform. Here, for Int and Double, the extensions are even empty, as the implementation of the needed ops is built-in:

extension Int: SummableMultipliable {}
extension Double: SummableMultipliable {}

Then, declare your type constraint on the type parameter:

struct Matrix<T: SummableMultipliable> { ... }

Finally, you can write stuff like this:

let intMat = Matrix<Int>(rows: 3, columns: 3, initialValue: 0)
let doubleMat = Matrix<Double>(rows: 3, columns: 3, initialValue: 0)
let i: Int = intMat[0,0]
let d: Double = doubleMat[0,0]

The last thing you'll need is to insert the type constraint in the definition of your operator:

@infix func + <T: SummableMultipliable> (m1: Matrix<T>, m2: Matrix<T>) -> Matrix<T> { ... }
  • Awesome! I know, you're completely right, but it was a spur of the moment thing: it was when I was writing the question that I noticed the 2nd problem... – Alex Jun 4 '14 at 20:47
  • I think it is workable as <T: Equatable, Summable, Multipliable> – GoZoner Jun 4 '14 at 20:50
  • @GoZoner No: in your example, Summable and Multipliable are interpreted as the name of two more type parameters with no contraints. – Jean-Philippe Pellet Jun 4 '14 at 20:50
  • @Alex I updated my answer with a solution to your first question as well. – Jean-Philippe Pellet Jun 4 '14 at 20:56
  • Awesome! That works perfectly. So in a protocol declaration you can refer to the type of the object as Self: that's what you are doing here, correct? func +(lhs: Self, rhs: Self) -> Self – Alex Jun 4 '14 at 20:59

For Question 1 start by defining a protocol

protocol Summable { func ignore () }

It has a throw away method. Then add it as an extension to the things that you want to be summable.

extension Int: Summable { func ignore () {} }

[Note: I tried the above w/o a throw away method but got a failure; I suspect Swift needed something, anything in the protocol.]

Now a test

 35> protocol Summable { func ignore () }
 36> extension Int: Summable { func ignore () {} }
 37> func testing<T: Summable> (x: T) -> T { return x }
 38> testing(1)
$R16: (Int) = 1
 39> testing(1.2)
<REPL>:39:1: error: cannot convert the expression's type '$T1' to type 'Summable'

For Question 2, [edit] Use the following

@infix func +<T: Summable> (m1: Matrix<T>, m2: Matrix<T>) -> Matrix<T> { ... }

[Note: I tried the above in the REPL, which didn't work. But it works in a file (probably defines a 'global environment' which the REPL doesn't)]

  • 1
    That is a good idea. I was expecting to have a protocol already defined for me by the standard library, like with Equatable, but oh well... Also, is it not possible to define a protocol with no methods (essentially, an empty protocol), or even a protocol that includes the addition operator? I'll be trying this in a few minutes. – Alex Jun 4 '14 at 20:45

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