If you are not interested in the details of Mongolian but just want a quick answer about using and converting Unicode values in Swift, then skip down to the first part of the accepted answer.
Background
I want to render Unicode text for traditional Mongolian to be used in iOS apps. The better and long term solution is to use an AAT smart font that would render this complex script. (Such fonts do exist but their license does not allow modification and non-personal use.) However, since I have never made a font, let alone all of the rendering logic for an AAT font, I just plan to do the rendering myself in Swift for now. Maybe at some later date I can learn to make a smart font.
Externally I will use Unicode text, but internally (for display in a UITextView) I will convert the Unicode to individual glyphs that are stored in a dumb font (coded with Unicode PUA values). So my rendering engine needs to convert Mongolian Unicode values (range: U+1820 to U+1842) to glyph values stored in the PUA (range: U+E360 to U+E5CF). Anyway, this is my plan since it is what I did in Java in the past, but maybe I need to change my whole way of thinking.
Example
The following image shows su written twice in Mongolian using two different forms for the letter u (in red). (Mongolian is written vertically with letters being connected like cursive letters in English.)
In Unicode these two strings would be expressed as
var suForm1: String = "\u{1830}\u{1826}"
var suForm2: String = "\u{1830}\u{1826}\u{180B}"
The Free Variation Selector (U+180B) in suForm2 is recognized (correctly) by Swift String to be a unit with the u (U+1826) that precedes it. It is considered by Swift to be a single character, an extended grapheme cluster. However, for the purposes of doing the rendering myself, I need to differentiate u (U+1826) and FVS1 (U+180B) as two distinct UTF-16 code points.
For internal display purposes, I would convert the above Unicode strings to the following rendered glyph strings:
suForm1 = "\u{E46F}\u{E3BA}"
suForm2 = "\u{E46F}\u{E3BB}"
Question
I have been playing around with Swift String and Character. There are a lot of convenient things about them, but since in my particular case I deal exclusively with UTF-16 code units, I wonder if I should be using the old NSString rather than Swift's String. I realize that I can use String.utf16 to get UTF-16 code points, but the conversion back to String isn't very nice.
Would it be better to stick with String and Character or should I use NSString and unichar?
What I have read
Strings and Characters documentation
Strings in Swift
NSString and Unicode
Updates to this question have been hidden in order to clean the page up. See the edit history.
Updated for Swift 3
String and Character
For almost everyone in the future who visits this question, String and Character will be the answer for you.
Set Unicode values directly in code:
var str: String = "I want to visit 北京, Москва, मुंबई, القاهرة, and 서울시. 😊"
var character: Character = "🌍"
Use hexadecimal to set values
var str: String = "\u{61}\u{5927}\u{1F34E}\u{3C0}" // a大🍎π
var character: Character = "\u{65}\u{301}" // é = "e" + accent mark
Note that the Swift Character can be composed of multiple Unicode code points, but appears to be a single character. This is called an Extended Grapheme Cluster.
See this question also.
Convert to Unicode values:
str.utf8
str.utf16
str.unicodeScalars // UTF-32
String(character).utf8
String(character).utf16
String(character).unicodeScalars
Convert from Unicode hex values:
let hexValue: UInt32 = 0x1F34E
// convert hex value to UnicodeScalar
guard let scalarValue = UnicodeScalar(hexValue) else {
// early exit if hex does not form a valid unicode value
return
}
// convert UnicodeScalar to String
let myString = String(scalarValue) // 🍎
Or alternatively:
let hexValue: UInt32 = 0x1F34E
if let scalarValue = UnicodeScalar(hexValue) {
let myString = String(scalarValue)
}
A few more examples
let value0: UInt8 = 0x61
let value1: UInt16 = 0x5927
let value2: UInt32 = 0x1F34E
let string0 = String(UnicodeScalar(value0)) // a
let string1 = String(UnicodeScalar(value1)) // 大
let string2 = String(UnicodeScalar(value2)) // 🍎
// convert hex array to String
let myHexArray = [0x43, 0x61, 0x74, 0x203C, 0x1F431] // an Int array
var myString = ""
for hexValue in myHexArray {
myString.append(UnicodeScalar(hexValue))
}
print(myString) // Cat‼🐱
Note that for UTF-8 and UTF-16 the conversion is not always this easy. (See UTF-8, UTF-16, and UTF-32 questions.)
NSString and unichar
It is also possible to work with NSString and unichar in Swift, but you should realize that unless you are familiar with Objective C and good at converting the syntax to Swift, it will be difficult to find good documentation.
Also, unichar is a UInt16 array and as mentioned above the conversion from UInt16 to Unicode scalar values is not always easy (i.e., converting surrogate pairs for things like emoji and other characters in the upper code planes).
Custom string structure
For the reasons mentioned in the question, I ended up not using any of the above methods. Instead I wrote my own string structure, which was basically an array of UInt32 to hold Unicode scalar values.
Again, this is not the solution for most people. First consider using extensions if you only need to extend the functionality of String or Character a little.
But if you really need to work exclusively with Unicode scalar values, you could write a custom struct.
The advantages are:
Don't need to constantly switch between Types (String, Character, UnicodeScalar, UInt32, etc.) when doing string manipulation.
After Unicode manipulation is finished, the final conversion to String is easy.
Easy to add more methods when they are needed
Simplifies converting code from Java or other languages
Disadavantages are:
makes code less portable and less readable for other Swift developers
not as well tested and optimized as the native Swift types
it is yet another file that has to be included in a project every time you need it
You can make your own, but here is mine for reference. The hardest part was making it Hashable.
// This struct is an array of UInt32 to hold Unicode scalar values
// Version 3.4.0 (Swift 3 update)
struct ScalarString: Sequence, Hashable, CustomStringConvertible {
fileprivate var scalarArray: [UInt32] = []
init() {
// does anything need to go here?
}
init(_ character: UInt32) {
self.scalarArray.append(character)
}
init(_ charArray: [UInt32]) {
for c in charArray {
self.scalarArray.append(c)
}
}
init(_ string: String) {
for s in string.unicodeScalars {
self.scalarArray.append(s.value)
}
}
// Generator in order to conform to SequenceType protocol
// (to allow users to iterate as in `for myScalarValue in myScalarString` { ... })
func makeIterator() -> AnyIterator<UInt32> {
return AnyIterator(scalarArray.makeIterator())
}
// append
mutating func append(_ scalar: UInt32) {
self.scalarArray.append(scalar)
}
mutating func append(_ scalarString: ScalarString) {
for scalar in scalarString {
self.scalarArray.append(scalar)
}
}
mutating func append(_ string: String) {
for s in string.unicodeScalars {
self.scalarArray.append(s.value)
}
}
// charAt
func charAt(_ index: Int) -> UInt32 {
return self.scalarArray[index]
}
// clear
mutating func clear() {
self.scalarArray.removeAll(keepingCapacity: true)
}
// contains
func contains(_ character: UInt32) -> Bool {
for scalar in self.scalarArray {
if scalar == character {
return true
}
}
return false
}
// description (to implement Printable protocol)
var description: String {
return self.toString()
}
// endsWith
func endsWith() -> UInt32? {
return self.scalarArray.last
}
// indexOf
// returns first index of scalar string match
func indexOf(_ string: ScalarString) -> Int? {
if scalarArray.count < string.length {
return nil
}
for i in 0...(scalarArray.count - string.length) {
for j in 0..<string.length {
if string.charAt(j) != scalarArray[i + j] {
break // substring mismatch
}
if j == string.length - 1 {
return i
}
}
}
return nil
}
// insert
mutating func insert(_ scalar: UInt32, atIndex index: Int) {
self.scalarArray.insert(scalar, at: index)
}
mutating func insert(_ string: ScalarString, atIndex index: Int) {
var newIndex = index
for scalar in string {
self.scalarArray.insert(scalar, at: newIndex)
newIndex += 1
}
}
mutating func insert(_ string: String, atIndex index: Int) {
var newIndex = index
for scalar in string.unicodeScalars {
self.scalarArray.insert(scalar.value, at: newIndex)
newIndex += 1
}
}
// isEmpty
var isEmpty: Bool {
return self.scalarArray.count == 0
}
// hashValue (to implement Hashable protocol)
var hashValue: Int {
// DJB Hash Function
return self.scalarArray.reduce(5381) {
($0 << 5) &+ $0 &+ Int($1)
}
}
// length
var length: Int {
return self.scalarArray.count
}
// remove character
mutating func removeCharAt(_ index: Int) {
self.scalarArray.remove(at: index)
}
func removingAllInstancesOfChar(_ character: UInt32) -> ScalarString {
var returnString = ScalarString()
for scalar in self.scalarArray {
if scalar != character {
returnString.append(scalar)
}
}
return returnString
}
func removeRange(_ range: CountableRange<Int>) -> ScalarString? {
if range.lowerBound < 0 || range.upperBound > scalarArray.count {
return nil
}
var returnString = ScalarString()
for i in 0..<scalarArray.count {
if i < range.lowerBound || i >= range.upperBound {
returnString.append(scalarArray[i])
}
}
return returnString
}
// replace
func replace(_ character: UInt32, withChar replacementChar: UInt32) -> ScalarString {
var returnString = ScalarString()
for scalar in self.scalarArray {
if scalar == character {
returnString.append(replacementChar)
} else {
returnString.append(scalar)
}
}
return returnString
}
func replace(_ character: UInt32, withString replacementString: String) -> ScalarString {
var returnString = ScalarString()
for scalar in self.scalarArray {
if scalar == character {
returnString.append(replacementString)
} else {
returnString.append(scalar)
}
}
return returnString
}
func replaceRange(_ range: CountableRange<Int>, withString replacementString: ScalarString) -> ScalarString {
var returnString = ScalarString()
for i in 0..<scalarArray.count {
if i < range.lowerBound || i >= range.upperBound {
returnString.append(scalarArray[i])
} else if i == range.lowerBound {
returnString.append(replacementString)
}
}
return returnString
}
// set (an alternative to myScalarString = "some string")
mutating func set(_ string: String) {
self.scalarArray.removeAll(keepingCapacity: false)
for s in string.unicodeScalars {
self.scalarArray.append(s.value)
}
}
// split
func split(atChar splitChar: UInt32) -> [ScalarString] {
var partsArray: [ScalarString] = []
if self.scalarArray.count == 0 {
return partsArray
}
var part: ScalarString = ScalarString()
for scalar in self.scalarArray {
if scalar == splitChar {
partsArray.append(part)
part = ScalarString()
} else {
part.append(scalar)
}
}
partsArray.append(part)
return partsArray
}
// startsWith
func startsWith() -> UInt32? {
return self.scalarArray.first
}
// substring
func substring(_ startIndex: Int) -> ScalarString {
// from startIndex to end of string
var subArray: ScalarString = ScalarString()
for i in startIndex..<self.length {
subArray.append(self.scalarArray[i])
}
return subArray
}
func substring(_ startIndex: Int, _ endIndex: Int) -> ScalarString {
// (startIndex is inclusive, endIndex is exclusive)
var subArray: ScalarString = ScalarString()
for i in startIndex..<endIndex {
subArray.append(self.scalarArray[i])
}
return subArray
}
// toString
func toString() -> String {
var string: String = ""
for scalar in self.scalarArray {
if let validScalor = UnicodeScalar(scalar) {
string.append(Character(validScalor))
}
}
return string
}
// trim
// removes leading and trailing whitespace (space, tab, newline)
func trim() -> ScalarString {
//var returnString = ScalarString()
let space: UInt32 = 0x00000020
let tab: UInt32 = 0x00000009
let newline: UInt32 = 0x0000000A
var startIndex = self.scalarArray.count
var endIndex = 0
// leading whitespace
for i in 0..<self.scalarArray.count {
if self.scalarArray[i] != space &&
self.scalarArray[i] != tab &&
self.scalarArray[i] != newline {
startIndex = i
break
}
}
// trailing whitespace
for i in stride(from: (self.scalarArray.count - 1), through: 0, by: -1) {
if self.scalarArray[i] != space &&
self.scalarArray[i] != tab &&
self.scalarArray[i] != newline {
endIndex = i + 1
break
}
}
if endIndex <= startIndex {
return ScalarString()
}
return self.substring(startIndex, endIndex)
}
// values
func values() -> [UInt32] {
return self.scalarArray
}
}
func ==(left: ScalarString, right: ScalarString) -> Bool {
return left.scalarArray == right.scalarArray
}
func +(left: ScalarString, right: ScalarString) -> ScalarString {
var returnString = ScalarString()
for scalar in left.values() {
returnString.append(scalar)
}
for scalar in right.values() {
returnString.append(scalar)
}
return returnString
}
//Swift 3.0
// This struct is an array of UInt32 to hold Unicode scalar values
struct ScalarString: Sequence, Hashable, CustomStringConvertible {
private var scalarArray: [UInt32] = []
init() {
// does anything need to go here?
}
init(_ character: UInt32) {
self.scalarArray.append(character)
}
init(_ charArray: [UInt32]) {
for c in charArray {
self.scalarArray.append(c)
}
}
init(_ string: String) {
for s in string.unicodeScalars {
self.scalarArray.append(s.value)
}
}
// Generator in order to conform to SequenceType protocol
// (to allow users to iterate as in `for myScalarValue in myScalarString` { ... })
//func generate() -> AnyIterator<UInt32> {
func makeIterator() -> AnyIterator<UInt32> {
let nextIndex = 0
return AnyIterator {
if (nextIndex > self.scalarArray.count-1) {
return nil
}
return self.scalarArray[nextIndex + 1]
}
}
// append
mutating func append(scalar: UInt32) {
self.scalarArray.append(scalar)
}
mutating func append(scalarString: ScalarString) {
for scalar in scalarString {
self.scalarArray.append(scalar)
}
}
mutating func append(string: String) {
for s in string.unicodeScalars {
self.scalarArray.append(s.value)
}
}
// charAt
func charAt(index: Int) -> UInt32 {
return self.scalarArray[index]
}
// clear
mutating func clear() {
self.scalarArray.removeAll(keepingCapacity: true)
}
// contains
func contains(character: UInt32) -> Bool {
for scalar in self.scalarArray {
if scalar == character {
return true
}
}
return false
}
// description (to implement Printable protocol)
var description: String {
var string: String = ""
for scalar in scalarArray {
string.append(String(describing: UnicodeScalar(scalar))) //.append(UnicodeScalar(scalar)!)
}
return string
}
// endsWith
func endsWith() -> UInt32? {
return self.scalarArray.last
}
// insert
mutating func insert(scalar: UInt32, atIndex index: Int) {
self.scalarArray.insert(scalar, at: index)
}
// isEmpty
var isEmpty: Bool {
get {
return self.scalarArray.count == 0
}
}
// hashValue (to implement Hashable protocol)
var hashValue: Int {
get {
// DJB Hash Function
var hash = 5381
for i in 0 ..< scalarArray.count {
hash = ((hash << 5) &+ hash) &+ Int(self.scalarArray[i])
}
/*
for i in 0..< self.scalarArray.count {
hash = ((hash << 5) &+ hash) &+ Int(self.scalarArray[i])
}
*/
return hash
}
}
// length
var length: Int {
get {
return self.scalarArray.count
}
}
// remove character
mutating func removeCharAt(index: Int) {
self.scalarArray.remove(at: index)
}
func removingAllInstancesOfChar(character: UInt32) -> ScalarString {
var returnString = ScalarString()
for scalar in self.scalarArray {
if scalar != character {
returnString.append(scalar: scalar) //.append(scalar)
}
}
return returnString
}
// replace
func replace(character: UInt32, withChar replacementChar: UInt32) -> ScalarString {
var returnString = ScalarString()
for scalar in self.scalarArray {
if scalar == character {
returnString.append(scalar: replacementChar) //.append(replacementChar)
} else {
returnString.append(scalar: scalar) //.append(scalar)
}
}
return returnString
}
// func replace(character: UInt32, withString replacementString: String) -> ScalarString {
func replace(character: UInt32, withString replacementString: ScalarString) -> ScalarString {
var returnString = ScalarString()
for scalar in self.scalarArray {
if scalar == character {
returnString.append(scalarString: replacementString) //.append(replacementString)
} else {
returnString.append(scalar: scalar) //.append(scalar)
}
}
return returnString
}
// set (an alternative to myScalarString = "some string")
mutating func set(string: String) {
self.scalarArray.removeAll(keepingCapacity: false)
for s in string.unicodeScalars {
self.scalarArray.append(s.value)
}
}
// split
func split(atChar splitChar: UInt32) -> [ScalarString] {
var partsArray: [ScalarString] = []
var part: ScalarString = ScalarString()
for scalar in self.scalarArray {
if scalar == splitChar {
partsArray.append(part)
part = ScalarString()
} else {
part.append(scalar: scalar) //.append(scalar)
}
}
partsArray.append(part)
return partsArray
}
// startsWith
func startsWith() -> UInt32? {
return self.scalarArray.first
}
// substring
func substring(startIndex: Int) -> ScalarString {
// from startIndex to end of string
var subArray: ScalarString = ScalarString()
for i in startIndex ..< self.length {
subArray.append(scalar: self.scalarArray[i]) //.append(self.scalarArray[i])
}
return subArray
}
func substring(startIndex: Int, _ endIndex: Int) -> ScalarString {
// (startIndex is inclusive, endIndex is exclusive)
var subArray: ScalarString = ScalarString()
for i in startIndex ..< endIndex {
subArray.append(scalar: self.scalarArray[i]) //.append(self.scalarArray[i])
}
return subArray
}
// toString
func toString() -> String {
let string: String = ""
for scalar in self.scalarArray {
string.appending(String(describing:UnicodeScalar(scalar))) //.append(UnicodeScalar(scalar)!)
}
return string
}
// values
func values() -> [UInt32] {
return self.scalarArray
}
}
func ==(left: ScalarString, right: ScalarString) -> Bool {
if left.length != right.length {
return false
}
for i in 0 ..< left.length {
if left.charAt(index: i) != right.charAt(index: i) {
return false
}
}
return true
}
func +(left: ScalarString, right: ScalarString) -> ScalarString {
var returnString = ScalarString()
for scalar in left.values() {
returnString.append(scalar: scalar) //.append(scalar)
}
for scalar in right.values() {
returnString.append(scalar: scalar) //.append(scalar)
}
return returnString
}
Related
I want to add NumPy like functionality to a Swift array where you can use the + or - operators to add/subtract a Double to every element of a numeric Array and return a new Array with the new elements as [Double]. Here is how I have implemented it in 2 extensions for Int and Floating point types:
extension Array where Element: BinaryInteger {
static func + (array: Self, num: Double) -> [Double]
{
return array.map{Double($0) + num}
}
static func - (array: Self, num: Double) -> [Double]
{
return array.map{Double($0) - num}
}
}
extension Array where Element: BinaryFloatingPoint {
static func + (array: Self, num: Double) -> [Double]
{
return array.map{Double($0) + num}
}
static func - (array: Self, num: Double) -> [Double]
{
return array.map{Double($0) - num}
}
}
As you can see there is a lot of duplicate code here. Is there a better way to implement this?
I tried this but it doesn't work:
extension Array where Element: Numeric {
static func + (array: Self, num: Double) -> [Double]
{
return array.map{Double($0) + num}
}
static func - (array: Self, num: Double) -> [Double]
{
return array.map{Double($0) - num}
}
}
The compiler complains at line Double($0) since Double doesn't have initializer for Numeric.
Why use Double at all? You're just introducing potential precision issues for integer types that have perfect precision over integers
extension Array where Element: Numeric {
static func + (array: Self, num: Element) -> [Element] {
return array.map { $0 + num }
}
static func - (array: Self, num: Element) -> [Element] {
return array.map { $0 - num }
}
}
print([1, 2, 3] + 10) // => [11, 12, 13]
I decided to check type of Element and force typecast instead:
extension Array where Element: Numeric {
static func + (array: Self, num: Decimal) -> [Decimal]
{
if let first = array.first {
switch first {
case is Int:
return array.map{Decimal($0 as! Int) + num}
case is Double:
return array.map{Decimal($0 as! Double) + num}
case is Decimal:
return array.map{$0 as! Decimal + num}
default:
break
}
}
return []
}
static func - (array: Self, num: Decimal) -> [Decimal]
{
if let first = array.first {
switch first {
case is Int:
return array.map{Decimal($0 as! Int) - num}
case is Double:
return array.map{Decimal($0 as! Double) - num}
case is Decimal:
return array.map{$0 as! Decimal - num}
default:
break
}
}
return []
}
static func / (array: Self, num: Decimal) -> [Decimal]
{
if let first = array.first {
switch first {
case is Int:
return array.map{Decimal($0 as! Int) / num}
case is Double:
return array.map{Decimal($0 as! Double) / num}
case is Decimal:
return array.map{$0 as! Decimal / num}
default:
break
}
}
return []
}
}
I need to convert IP address (e.g. "127.0.0.1") to integer value and vice-versa for my logger. I've found some samples for ObjC:
How to convert an IP address from NSString to unsigned int in Objective-C?
iOS convert IP Address to integer and backwards
How to do it in Swift and what the best way?
This is how I would approach the conversion. It might look a bit over engineering but all properties are useful in other contexts as well:
extension Numeric {
var data: Data {
var bytes = self
return Data(bytes: &bytes, count: MemoryLayout<Self>.size)
}
}
extension Data {
func numeric<T: Numeric>() -> T { withUnsafeBytes { $0.load(as: T.self) } }
}
extension LosslessStringConvertible {
var string: String { .init(self) }
}
The following implementations rely on Network Technology:
import Network
extension StringProtocol {
var ipV4Address: IPv4Address? { .init(string) }
}
extension Data {
var ipV4Address: IPv4Address? { .init(self) }
}
extension IPv4Address {
var uint32: UInt32 { rawValue.numeric() }
}
extension UInt32 {
var ipV4Address: IPv4Address? { data.ipV4Address }
}
Usage:
if let ipV4Address = "10.0.0.1".ipV4Address { // 10.0.0.1
let uint32 = ipV4Address.uint32 // 16777226
let loadedIPv4Address = uint32.ipV4Address! // 10.0.0.1
}
There two possible approaches to do it in Swift:
Using old school inet_aton and inet_ntoa
func ipv4_StringToInt(_ value: String) -> UInt32? {
var addr = in_addr()
return inet_aton(value.cString(using: .ascii), &addr) != 0
? UInt32(addr.s_addr)
: nil
}
func ipv4_IntToString(_ value: UInt32) -> String {
let addr = in_addr(s_addr: value)
return String(cString:inet_ntoa(addr))
}
Using IPv4Address from Network
func ipv4_StringToInt(_ value: String) -> UInt32? {
IPv4Address(value)?.rawValue.withUnsafeBytes {
$0.load(as: UInt32.self)
}
}
func ipv4_IntToString(_ value: UInt32) -> String {
let data = withUnsafeBytes(of: value) { Data($0) }
return IPv4Address(data)!.debugDescription
}
How to use:
if let addr = ipv4_StringToInt("127.0.0.1") { // addr = 0x100007F
let ip = ipv4_IntToString(addr)
print(ip) // Outputs: 127.0.0.1
}
Is there a way to search through a UITableView and ignore certain characters like commas or dots?
I.e. I would like to search for "St George" but my data set contains "St. George" so the result is always zero.
EDITED Q:
func filteredArray(searchText: NSString) {
if searchText == "" {
array_search = array_all
} else {
showTableViewResults()
array_search.removeAll()
for i in 0 ..< array_all.count {
let object:MyObject = array_all[i]
let languageSearchString = object.myObjectName
let searchStr:String = languageSearchString!
if searchStr.lowercased().contains(searchText.lowercased) {
array_search.append(object)
}
}
}
tableView.reloadData()
recordsFoundLabel.text = "records found: \(array_search.count)"
}
You can filter all characters thats not a letter out of your String before performing your search. The same applies to the table view data source elements. Also as mentioned by rmaddy you should implement a case insensitive search:
edit/update Swift 5.2 or later
extension StringProtocol {
func caseInsensitiveContains<S: StringProtocol>(_ string: S) -> Bool { range(of: string, options: .caseInsensitive) != nil }
}
extension StringProtocol where Self: RangeReplaceableCollection {
var letters: Self { filter(\.isLetter) }
}
Testing:
let search = "st george"
let tableViewSource = ["Apple", "Orange", "Banana", "St. George"]
let filtered = tableViewSource.filter {
$0.letters.caseInsensitiveContains(search.letters)
}
print(filtered) // ["St. George"]
If you would like to literally just remove punctuation from your String (note that would keep the spaces in your String), you can do as follow:
extension StringProtocol where Self: RangeReplaceableCollection {
mutating func removePunctuation() { removeAll(where: \.isPunctuation) }
}
extension Bool {
var negated: Bool { !self }
}
extension StringProtocol where Self: RangeReplaceableCollection {
var removingPunctuation: Self { filter(\.isPunctuation.negated) }
}
Testing:
let filtered = tableViewSource.filter {
$0.removingPunctuation.caseInsensitiveContains(search.removingPunctuation)
}
print(filtered) // ["St. George"]
If you would like to implement the same logic as Xcode autocomplete you would need to do a search for each character and change the startIndex of the string searched:
extension StringProtocol where Self: RangeReplaceableCollection {
func containsCharactersInSequence<S: StringProtocol>(_ string: S, options: String.CompareOptions = []) -> (result: Bool, ranges: [Range<Index>]) {
var found = 0
var startIndex = self.startIndex
var index = string.startIndex
var ranges: [Range<Index>] = []
while index < string.endIndex,
let range = self[startIndex...].range(of: string[index...index], options: options) {
ranges.append(range)
startIndex = range.upperBound
string.formIndex(after: &index)
found += 1
}
return (found == string.count, ranges)
}
}
Playground Testing:
let search = "stgre"
let tableViewSource = ["Apple", "Orange", "Banana", "St. George"]
let filtered = tableViewSource.filter {
$0.containsCharactersInSequence(search, options: .caseInsensitive).result
}
print(filtered) // ["St. George"]
I think you should simply implement a function that for any given string, will return te same string without any point, (or whatever you want to erase); such as :
func erase(characters: [String], fromText text: String) -> String {
var result = String()
for character in text.characters {
if !characters.contains(character) {
result += String(character)
}
}
return result
}
(I cant test it from where i am but you get the idea right ?)
Hope it helps
extension Array where Element: _ArrayType, Element.Generator.Element: Any {
func transpose() -> [Element] {
if self.isEmpty { return [Element]() }
let count = self[0].count
var out = [Element](repeating: Element(), count: count)
for outer in self {
for (index, inner) in outer.enumerated() {
out[index].append(inner)
}
}
return out
}
}
I am getting this error in Swift 3.0 after converting it from Swift 2.2. The elements of the array are also array. So how to define it in Swift 3.0?
extension Array where Element : Collection, Element.Index == Int, Element.IndexDistance == Int {
func transpose() -> [[Element.Iterator.Element]] {
typealias InnerElement = Element.Iterator.Element
if self.isEmpty { return [] }
let count = self[0].count
var out = [[InnerElement]](repeating: [InnerElement](), count: count)
for outer in self {
for (index, inner) in outer.enumerated() {
out[index].append(inner)
}
}
return out
}
}
I need capital letters from a string. With NSString it was sth like:
for (var i = 0; i<str.length; i++) {
let c = str.characterAtIndex(i)
if c >= 'A' && c < 'Z' {
//..
}
}
In Swift it starts like:
for (var i = 0; i<countElements(str); i++) {
//..
}
But I do not know i.e. how to pick i-th character, I am checking this
Here's a slightly more idiomatic version in swift
func capitalLetters(s: String) -> [Character] {
return filter(s) { ("A"..."Z").contains($0) }
}
capitalLetters("fOo BAr") // ["O", "B", "A"]
or even:
func capitalLetters(s: String) -> [Character] {
func isCapital(c: Character) -> Bool {
return ("A"..."Z").contains(c)
}
return filter(s, isCapital)
}
capitalLetters("fOo BAr")
or also, you could make the syntax nicer by providing an extension
extension String {
func capitalLetters() -> [Character] {
func isCapital(c: Character) -> Bool {
return ("A"..."Z").contains(c)
}
return filter(self, isCapital)
}
}
"fOo BAr".capitalLetters()
For example this work fine in Swift :
var st = "Hello World"
for ch in st {
if ch >= "A" && ch <= "Z"{
println(ch)
}
}
And print
H
W
Or you could this instead :
var range = "A"..."Z"
for ch in st {
if range.contains(String(ch)) {
println(ch)
}
}
Or the solution of #Gabrielle updated to Swift 2.0:
func capitalLetters(s: String) -> [Character] {
return s.characters.filter { ("A"..."Z").contains($0) }
}
capitalLetters("fOo BAr") // ["O", "B", "A"]