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With Swift 3 leaning towards Data instead of [UInt8], I'm trying to ferret out what the most efficient/idiomatic way to encode/decode swifts various number types (UInt8, Double, Float, Int64, etc) as Data objects.

There's this answer for using [UInt8], but it seems to be using various pointer APIs that I can't find on Data.

I'd like to basically some custom extensions that look something like:

let input = 42.13 // implicit Double
let bytes = input.data
let roundtrip = bytes.to(Double) // --> 42.13

The part that really eludes me, I've looked through a bunch of the docs, is how I can get some sort of pointer thing (OpaquePointer or BufferPointer or UnsafePointer?) from any basic struct (which all of the numbers are). In C, I would just slap an ampersand in front of it, and there ya go.

173

Note: The answer (originally written for Swift 3) has been updated for Swift 4.2/Xcode 10 now, that made some simplifications possible. Some of my previous suggestions invoked undefined behaviour, this has been fixed. I have also added remarks about byte order and alignment.

How to create Data from a value

As of Swift 4.2, data can be created from a value simply with

let value = 42.13
let data = withUnsafeBytes(of: value) { Data($0) }

print(data as NSData) // <713d0ad7 a3104540>

Explanation:

  • withUnsafeBytes(of: value) invokes the closure with a buffer pointer covering the raw bytes of the value.
  • A raw buffer pointer is a sequence of bytes, therefore Data($0) can be used to create the data.

Before Swift 4.2, it was necessary to create a mutable copy first:

let value = 42.13
var mutableValue = value
let data = withUnsafeBytes(of: &mutableValue) { Data.init($0) }

How to retrieve a value from Data

NSData had a bytes property to get access to the underlying storage. struct Data has a generic withUnsafeBytes(_:) method instead, which can be used like this:

let data = Data(bytes: [0x71, 0x3d, 0x0a, 0xd7, 0xa3, 0x10, 0x45, 0x40])
let value = data.withUnsafeBytes { (ptr: UnsafePointer<Double>) -> Double in
    return ptr.pointee
}
print(value) // 42.13

If the ContentType can be inferred from the context then it need not be specified in the closure, so this can be simplified to

let data = Data(bytes: [0x71, 0x3d, 0x0a, 0xd7, 0xa3, 0x10, 0x45, 0x40])
let value: Double = data.withUnsafeBytes { $0.pointee }
print(value) // 42.13

Generic solution #1

The above conversions can now easily be implemented as generic methods of struct Data:

extension Data {

    init<T>(from value: T) {
        self = Swift.withUnsafeBytes(of: value) { Data($0) }
    }

    func to<T>(type: T.Type) -> T {
        return self.withUnsafeBytes { $0.pointee }
    }
}

Example:

let value = 42.13 // implicit Double
let data = Data(from: value)
print(data as NSData) // <713d0ad7 a3104540>

let roundtrip = data.to(type: Double.self)
print(roundtrip) // 42.13

Similarly, you can convert arrays to Data and back:

extension Data {

    init<T>(fromArray values: [T]) {
        self = values.withUnsafeBytes { Data($0) }
    }

    func toArray<T>(type: T.Type) -> [T] {
        return self.withUnsafeBytes {
            [T](UnsafeBufferPointer(start: $0, count: self.count/MemoryLayout<T>.stride))
        }
    }
}

Example:

let value: [Int16] = [1, Int16.max, Int16.min]
let data = Data(fromArray: value)
print(data as NSData) // <0100ff7f 0080>

let roundtrip = data.toArray(type: Int16.self)
print(roundtrip) // [1, 32767, -32768]

Generic solution #2

The above approach has one disadvantage: As in How to convert a double into a byte array in swift?, it actually works only with "simple" types like integers and floating point types. "Complex" types like Array and String have (hidden) pointers to the underlying storage and cannot be passed around by just copying the struct itself. It also would not work with reference types which are just pointers to the real object storage.

So solve that problem, one can

  • Define a protocol which defines the methods for converting to Data and back:

    protocol DataConvertible {
        init?(data: Data)
        var data: Data { get }
    }
    
  • Implement the conversions as default methods in a protocol extension:

    extension DataConvertible {
    
        init?(data: Data) {
            guard data.count == MemoryLayout<Self>.size else { return nil }
            self = data.withUnsafeBytes { $0.pointee }
        }
    
        var data: Data {
            return withUnsafeBytes(of: self) { Data($0) }
        }
    }
    

    I have chosen a failable initializer here which checks that the number of bytes provided matches the size of the type.

  • And finally declare conformance to all types which can safely be converted to Data and back:

    extension Int : DataConvertible { }
    extension Float : DataConvertible { }
    extension Double : DataConvertible { }
    // add more types here ...
    

This makes the conversion even more elegant:

let value = 42.13
let data = value.data
print(data as NSData) // <713d0ad7 a3104540>

if let roundtrip = Double(data: data) {
    print(roundtrip) // 42.13
}

The advantage of the second approach is that you cannot inadvertently do unsafe conversions. The disadvantage is that you have to list all "safe" types explicitly.

You could also implement the protocol for other types which require a non-trivial conversion, such as:

extension String: DataConvertible {
    init?(data: Data) {
        self.init(data: data, encoding: .utf8)
    }
    var data: Data {
        // Note: a conversion to UTF-8 cannot fail.
        return self.data(using: .utf8)!
    }
}

or implement the conversion methods in your own types to do whatever is necessary so serialize and deserialize a value.

Further remarks

Byte order

No byte order conversion is done in the above methods, the data is always in the host byte order. For a platform independent representation (e.g. “big endian” aka “network” byte order), use the corresponding integer properties resp. initializers. For example:

let value = 1000
let data = value.bigEndian.data
print(data as NSData) // <00000000 000003e8>

if let roundtrip = Int(data: data) {
    print(Int(bigEndian: roundtrip)) // 1000
}

Of course this conversion can also be done generally, in the generic conversion method.

Alignment

The above methods to extract a value from Data all assume that the data is properly aligned for the value type. If that is not guaranteed, subdata(in:) can be used to create a copy with aligned underlying storage.

  • 2
    Great explanations. Wish I could give two up-votes. – Travis Griggs Jun 26 '16 at 0:27
  • 1
    @TravisGriggs: Copying an int or float will most probably not be relevant, but you can do similar things in Swift. If you have an ptr: UnsafeMutablePointer<UInt8> then you can assign to the referenced memory via something like UnsafeMutablePointer<T>(ptr + offset).pointee = value which closely corresponds to your Swift code. There is one potential problem: Some processors allow only aligned memory access, e.g. you cannot store an Int at a odd memory location. I don't know if that applies to the currently used Intel and ARM processors. – Martin R Jun 26 '16 at 12:32
  • 1
    @TravisGriggs: (cont'd) ... Also this requires that a sufficiently large Data object has already been created, and in Swift you can only create and initialize the Data object, so you might have an additional copy of zero bytes during the initialization. – If you need more details then I would suggest that you post a new question. – Martin R Jun 26 '16 at 12:35
  • 2
    @HansBrende: I am afraid that is currently not possible. It would require an extension Array: DataConvertible where Element: DataConvertible. That is not possible in Swift 3, but planned for Swift 4 (as far as I know). Compare "Conditional conformances" in github.com/apple/swift/blob/master/docs/… – Martin R Nov 11 '16 at 19:36
  • 2
    B r i l l i a n t ! – vadian Jan 11 '17 at 7:57
3

You can get an unsafe pointer to mutable objects by using withUnsafePointer:

withUnsafePointer(&input) { /* $0 is your pointer */ }

I don't know of a way to get one for immutable objects, because the inout operator only works on mutable objects.

This is demonstrated in the answer that you've linked to.

2

In my case, Martin R's answer helped but the result was inverted. So I did a small change in his code:

extension UInt16 : DataConvertible {

    init?(data: Data) {
        guard data.count == MemoryLayout<UInt16>.size else { 
          return nil 
        }
    self = data.withUnsafeBytes { $0.pointee }
    }

    var data: Data {
         var value = CFSwapInt16HostToBig(self)//Acho que o padrao do IOS 'e LittleEndian, pois os bytes estavao ao contrario
         return Data(buffer: UnsafeBufferPointer(start: &value, count: 1))
    }
}

The problem is related with LittleEndian and BigEndian.

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