This has to do with how the String
type works in Swift, and how the contains(_:)
method works.
The ‘👩👩👧👦 ‘ is what’s known as an emoji sequence, which is rendered as one visible character in a string. The sequence is made up of Character
objects, and at the same time it is made up of UnicodeScalar
objects.
If you check the character count of the string, you’ll see that it is made up of four characters, while if you check the unicode scalar count, it will show you a different result:
print("👩👩👧👦".characters.count) // 4
print("👩👩👧👦".unicodeScalars.count) // 7
Now, if you parse through the characters and print them, you’ll see what seems like normal characters, but in fact the three first characters contain both an emoji as well as a zero-width joiner in their UnicodeScalarView
:
for char in "👩👩👧👦".characters {
print(char)
let scalars = String(char).unicodeScalars.map({ String($0.value, radix: 16) })
print(scalars)
}
// 👩
// ["1f469", "200d"]
// 👩
// ["1f469", "200d"]
// 👧
// ["1f467", "200d"]
// 👦
// ["1f466"]
As you can see, only the last character does not contain a zero-width joiner, so when using the contains(_:)
method, it works as you’d expect. Since you aren’t comparing against emoji containing zero-width joiners, the method won’t find a match for any but the last character.
To expand on this, if you create a String
which is composed of an emoji character ending with a zero-width joiner, and pass it to the contains(_:)
method, it will also evaluate to false
. This has to do with contains(_:)
being the exact same as range(of:) != nil
, which tries to find an exact match to the given argument. Since characters ending with a zero-width joiner form an incomplete sequence, the method tries to find a match for the argument while combining characters ending with a zero-width joiners into a complete sequence. This means that the method won’t ever find a match if:
- the argument ends with a zero-width joiner, and
- the string to parse doesn’t contain an incomplete sequence (i.e. ending with a zero-width joiner and not followed by a compatible character).
To demonstrate:
let s = "\u{1f469}\u{200d}\u{1f469}\u{200d}\u{1f467}\u{200d}\u{1f466}" // 👩👩👧👦
s.range(of: "\u{1f469}\u{200d}") != nil // false
s.range(of: "\u{1f469}\u{200d}\u{1f469}") != nil // false
However, since the comparison only looks ahead, you can find several other complete sequences within the string by working backwards:
s.range(of: "\u{1f466}") != nil // true
s.range(of: "\u{1f467}\u{200d}\u{1f466}") != nil // true
s.range(of: "\u{1f469}\u{200d}\u{1f467}\u{200d}\u{1f466}") != nil // true
// Same as the above:
s.contains("\u{1f469}\u{200d}\u{1f467}\u{200d}\u{1f466}") // true
The easiest solution would be to provide a specific compare option to the range(of:options:range:locale:)
method. The option String.CompareOptions.literal
performs the comparison on an exact character-by-character equivalence. As a side note, what’s meant by character here is not the Swift Character
, but the UTF-16 representation of both the instance and comparison string – however, since String
doesn’t allow malformed UTF-16, this is essentially equivalent to comparing the Unicode scalar representation.
Here I’ve overloaded the Foundation
method, so if you need the original one, rename this one or something:
extension String {
func contains(_ string: String) -> Bool {
return self.range(of: string, options: String.CompareOptions.literal) != nil
}
}
Now the method works as it “should” with each character, even with incomplete sequences:
s.contains("👩") // true
s.contains("👩\u{200d}") // true
s.contains("\u{200d}") // true