CommonHMAC in Swift

You can do it in Swift. Just make sure you add #import <CommonCrypto/CommonHMAC.h> to the bridging Objective-C bridging header.

Update: For Swift 4 see a much better solution using the Swift Package Manager here: https://github.com/jernejstrasner/SwiftCrypto

enum CryptoAlgorithm {
    case MD5, SHA1, SHA224, SHA256, SHA384, SHA512

    var HMACAlgorithm: CCHmacAlgorithm {
        var result: Int = 0
        switch self {
        case .MD5:      result = kCCHmacAlgMD5
        case .SHA1:     result = kCCHmacAlgSHA1
        case .SHA224:   result = kCCHmacAlgSHA224
        case .SHA256:   result = kCCHmacAlgSHA256
        case .SHA384:   result = kCCHmacAlgSHA384
        case .SHA512:   result = kCCHmacAlgSHA512
        }
        return CCHmacAlgorithm(result)
    }

    var digestLength: Int {
        var result: Int32 = 0
        switch self {
        case .MD5:      result = CC_MD5_DIGEST_LENGTH
        case .SHA1:     result = CC_SHA1_DIGEST_LENGTH
        case .SHA224:   result = CC_SHA224_DIGEST_LENGTH
        case .SHA256:   result = CC_SHA256_DIGEST_LENGTH
        case .SHA384:   result = CC_SHA384_DIGEST_LENGTH
        case .SHA512:   result = CC_SHA512_DIGEST_LENGTH
        }
        return Int(result)
    }
}

extension String {

    func hmac(algorithm: CryptoAlgorithm, key: String) -> String {
        let str = self.cStringUsingEncoding(NSUTF8StringEncoding)
        let strLen = Int(self.lengthOfBytesUsingEncoding(NSUTF8StringEncoding))
        let digestLen = algorithm.digestLength
        let result = UnsafeMutablePointer<CUnsignedChar>.alloc(digestLen)
        let keyStr = key.cStringUsingEncoding(NSUTF8StringEncoding)
        let keyLen = Int(key.lengthOfBytesUsingEncoding(NSUTF8StringEncoding))

        CCHmac(algorithm.HMACAlgorithm, keyStr!, keyLen, str!, strLen, result)

        let digest = stringFromResult(result, length: digestLen)

        result.dealloc(digestLen)

        return digest
    }

    private func stringFromResult(result: UnsafeMutablePointer<CUnsignedChar>, length: Int) -> String {
        var hash = NSMutableString()
        for i in 0..<length {
            hash.appendFormat("%02x", result[i])
        }
        return String(hash)
    }

}

Try this for Swift 3.1 :

enum CryptoAlgorithm {
    case MD5, SHA1, SHA224, SHA256, SHA384, SHA512

    var HMACAlgorithm: CCHmacAlgorithm {
        var result: Int = 0
        switch self {
        case .MD5:      result = kCCHmacAlgMD5
        case .SHA1:     result = kCCHmacAlgSHA1
        case .SHA224:   result = kCCHmacAlgSHA224
        case .SHA256:   result = kCCHmacAlgSHA256
        case .SHA384:   result = kCCHmacAlgSHA384
        case .SHA512:   result = kCCHmacAlgSHA512
        }
        return CCHmacAlgorithm(result)
    }

    var digestLength: Int {
        var result: Int32 = 0
        switch self {
        case .MD5:      result = CC_MD5_DIGEST_LENGTH
        case .SHA1:     result = CC_SHA1_DIGEST_LENGTH
        case .SHA224:   result = CC_SHA224_DIGEST_LENGTH
        case .SHA256:   result = CC_SHA256_DIGEST_LENGTH
        case .SHA384:   result = CC_SHA384_DIGEST_LENGTH
        case .SHA512:   result = CC_SHA512_DIGEST_LENGTH
        }
        return Int(result)
    }
}

extension String {

    func hmac(algorithm: CryptoAlgorithm, key: String) -> String {
        let str = self.cString(using: String.Encoding.utf8)
        let strLen = Int(self.lengthOfBytes(using: String.Encoding.utf8))
        let digestLen = algorithm.digestLength
        let result = UnsafeMutablePointer<CUnsignedChar>.allocate(capacity: digestLen)
        let keyStr = key.cString(using: String.Encoding.utf8)
        let keyLen = Int(key.lengthOfBytes(using: String.Encoding.utf8))

        CCHmac(algorithm.HMACAlgorithm, keyStr!, keyLen, str!, strLen, result)

        let digest = stringFromResult(result: result, length: digestLen)

        result.deallocate(capacity: digestLen)

        return digest
    }

    private func stringFromResult(result: UnsafeMutablePointer<CUnsignedChar>, length: Int) -> String {
        let hash = NSMutableString()
        for i in 0..<length {
            hash.appendFormat("%02x", result[i])
        }
        return String(hash)
    }

}

Don't forget add #import <CommonCrypto/CommonHMAC.h> to Header.h

I wanted to keep things minimal. Avoid the added complexity of creating a generic class that could handle all the different digest types and instead just have a small method I could drop into a class if needed. I also prefer to avoid adding extensions to core classes.

Add the following include to your -Bridging-Header.h file:

#import <CommonCrypto/CommonHMAC.h>

Then in the class that needs to call CCHmac() add a private method:

private func hmac(string: NSString, key: NSData) -> NSData {
  let keyBytes = UnsafePointer<CUnsignedChar>(key.bytes)
  let data = string.cStringUsingEncoding(NSUTF8StringEncoding)
  let dataLen = Int(string.lengthOfBytesUsingEncoding(NSUTF8StringEncoding))
  let digestLen = Int(CC_SHA1_DIGEST_LENGTH)
  let result = UnsafeMutablePointer<CUnsignedChar>.alloc(digestLen)
  CCHmac(CCHmacAlgorithm(kCCHmacAlgSHA1), keyBytes, key.length, data, dataLen, result);
  return NSData(bytes: result, length: digestLen)
}

If I need a different CCHmacAlgorithm I would just replace the two constants in that method with the appropriate ones. In my case I needed kCCHmacAlgSHA256 and CC_SHA256_DIGEST_LENGTH.

Thanks to Jernej Strasner and others for the other answers, I just wanted something simpler for my case.

Swift can figure out how to map to the Obj-C frameworks but not so much for direct C functions. Apple has provided some bindings for stuff like GCD and AudioToolbox, but not everything. It seems CommonCrypto does not have proper bindings yet.

For this case, I would recommend writing your own basic wrappers in Obj-C, then use these wrapper classes in Swift.

For example you could create an HMAC class in Obj-C:

// This enum is in HMAC.h
typedef NS_ENUM(NSInteger, HMACAlgorithm)
{
    SHA1,
    MD5,
    SHA256,
    SHA384,
    SHA512,
    SHA224
};

// Class methods here
+ (NSData *)calculateWithAlgorithm:(HMACAlgorithm)algorithm forKey:(const void *)key andData:(const void *)data
{
    NSInteger digestLength = [self digestLengthForAlgorithm:algorithm];
    unsigned char hmac[digestLength];

    CCHmac(algorithm, &key, strlen(key), &data, strlen(data), &hmac);

    NSData *hmacBytes = [NSData dataWithBytes:hmac length:sizeof(hmac)];
    return hmacBytes;
}

+ (NSInteger)digestLengthForAlgorithm:(HMACAlgorithm)algorithm
{
    switch (algorithm)
    {
        case MD5: return CC_MD5_DIGEST_LENGTH;
        case SHA1: return CC_SHA1_DIGEST_LENGTH;
        case SHA224: return CC_SHA224_DIGEST_LENGTH;
        case SHA256: return CC_SHA256_DIGEST_LENGTH;
        case SHA384: return CC_SHA384_DIGEST_LENGTH;
        case SHA512: return CC_SHA512_DIGEST_LENGTH;
        default: return 0;
    }
}

Then in Swift:

class SwiftHMAC
{
    // Swift will automatically pull the enum from Obj-C

    func calculate(algorithm:HMACAlgorithm, key:Byte[], data:Byte[]) -> Byte[]
    {
        let computedHMAC = HMAC.calculateWithAlgorithm(algorithm, forKey: key, andData: data)

        var rawBytes = Byte[](count: computedHMAC.length, repeatedValue: 0)
        computedHMAC.getBytes(&rawBytes)

        return rawBytes
    }
}

Just remember to add #import "HMAC.h" to your Swift bridging header as well as #import "<##Your-Project-Name##>-Swift.h" to the Obj-C implementation (.m) file.

Below is a corrected version to what @jernej-strasner posted

enum HMACAlgorithm {
    case MD5, SHA1, SHA224, SHA256, SHA384, SHA512

    func toCCEnum() -> CCHmacAlgorithm {
        var result: Int = 0
        switch self {
        case .MD5:
            result = kCCHmacAlgMD5
        case .SHA1:
            result = kCCHmacAlgSHA1
        case .SHA224:
            result = kCCHmacAlgSHA224
        case .SHA256:
            result = kCCHmacAlgSHA256
        case .SHA384:
            result = kCCHmacAlgSHA384
        case .SHA512:
            result = kCCHmacAlgSHA512
        }
        return CCHmacAlgorithm(result)
    }

    func digestLength() -> Int {
        var result: CInt = 0
        switch self {
        case .MD5:
            result = CC_MD5_DIGEST_LENGTH
        case .SHA1:
            result = CC_SHA1_DIGEST_LENGTH
        case .SHA224:
            result = CC_SHA224_DIGEST_LENGTH
        case .SHA256:
            result = CC_SHA256_DIGEST_LENGTH
        case .SHA384:
            result = CC_SHA384_DIGEST_LENGTH
        case .SHA512:
            result = CC_SHA512_DIGEST_LENGTH
        }
        return Int(result)
    }
}

extension String {

    func digest(algorithm: HMACAlgorithm, key: String) -> String! {
        let str = self.cStringUsingEncoding(NSUTF8StringEncoding)
        let strLen = UInt(self.lengthOfBytesUsingEncoding(NSUTF8StringEncoding))
        let digestLen = algorithm.digestLength()
        let result = UnsafeMutablePointer<CUnsignedChar>.alloc(digestLen)
        let keyStr = key.cStringUsingEncoding(NSUTF8StringEncoding)
        let keyLen = UInt(key.lengthOfBytesUsingEncoding(NSUTF8StringEncoding))

        CCHmac(algorithm.toCCEnum(), keyStr!, keyLen, str!, strLen, result)

        var hash = NSMutableString()
        for i in 0..<digestLen {
            hash.appendFormat("%02x", result[i])
        }

        result.destroy()

        return String(hash)
    }

}

For OS X (but not for iOS as of this writing, when 9.3.1 is current), you can use a SecTransform to compute an HMAC SHA-1 in Swift with no bridging header and no Objective-C. Here's an example using the input from the first HMAC-SHA-1 test case in RFC 2202:

import Foundation
import Security

var error: Unmanaged<CFError>?
let transform = SecDigestTransformCreate(kSecDigestHMACSHA1, 0, &error)
let input = "Hi There"
let inputData = input.dataUsingEncoding(NSUTF8StringEncoding)!
let key = [UInt8](count: 20, repeatedValue: 0x0b)
let keyData = key.withUnsafeBufferPointer { buffer in NSData(bytes: buffer.baseAddress, length: buffer.count) }
SecTransformSetAttribute(transform, kSecTransformInputAttributeName, inputData, &error)
SecTransformSetAttribute(transform, kSecDigestHMACKeyAttribute, keyData, &error)
let outputData = SecTransformExecute(transform, &error) as! NSData

This is the full source of "How to import CommonCrypto in Swift project without Obj-c briging header", modified for Swift 3.0. The actual code work is of "Mihael Isaev".

//
//  HMAC.swift
//
//  Created by Mihael Isaev on 21.04.15.
//  Copyright (c) 2014 Mihael Isaev inc. All rights reserved.
//
// ***********************************************************
//
// How to import CommonCrypto in Swift project without Obj-c briging header
//
// To work around this create a directory called CommonCrypto in the root of the project using Finder.
// In this directory create a file name module.map and copy the following into the file.
// You will need to alter the paths to ensure they point to the headers on your system.
//
// module CommonCrypto [system] {
//     header "/Applications/Xcode.app/Contents/Developer/Platforms/iPhoneOS.platform/Developer/SDKs/iPhoneOS.sdk/usr/include/CommonCrypto/CommonCrypto.h"
//     export *
// }
// To make this module visible to Xcode, go to Build Settings, Swift Compiler – Search Paths
// and set Import Paths to point to the directory that contains the CommonCrypto directory.
//
// You should now be able to use import CommonCrypto in your Swift code.
//
// You have to set the Import Paths in every project that uses your framework so that Xcode can find it.
//
// ***********************************************************
//
// Modification for Swift 3.0 by Sanjay Sampat on 04.Jan.2017
//
// ***********************************************************

import Foundation
import CommonCrypto

extension String {
    var md5: String {
    return HMAC.hash(inp: self, algo: HMACAlgo.MD5)
}

var sha1: String {
    return HMAC.hash(inp: self, algo: HMACAlgo.SHA1)
}

var sha224: String {
    return HMAC.hash(inp: self, algo: HMACAlgo.SHA224)
}

var sha256: String {
    return HMAC.hash(inp: self, algo: HMACAlgo.SHA256)
}

var sha384: String {
    return HMAC.hash(inp: self, algo: HMACAlgo.SHA384)
}

var sha512: String {
    return HMAC.hash(inp: self, algo: HMACAlgo.SHA512)
}

func aesEncrypt(key:String, iv:String, options:Int = kCCOptionPKCS7Padding) -> String? {
    if let keyData = key.data(using: String.Encoding.utf8),
        let data = self.data(using: String.Encoding.utf8),
        let cryptData    = NSMutableData(length: Int((data.count)) + kCCBlockSizeAES128) {


            let keyLength              = size_t(kCCKeySizeAES128)
            let operation: CCOperation = UInt32(kCCEncrypt)
            let algoritm:  CCAlgorithm = UInt32(kCCAlgorithmAES128)
            let options:   CCOptions   = UInt32(options)



        var numBytesEncrypted :size_t = 0

        let base64cryptStringOut = keyData.withUnsafeBytes {(keyBytes: UnsafePointer<CChar>)->String? in
            return data.withUnsafeBytes {(dataBytes: UnsafePointer<CChar>)->String? in

                let cryptStatus = CCCrypt(operation,
                                          algoritm,
                                          options,
                                          keyBytes, keyLength,
                                          iv,
                                          dataBytes, data.count,
                                          cryptData.mutableBytes, cryptData.length,
                                          &numBytesEncrypted)

                if UInt32(cryptStatus) == UInt32(kCCSuccess) {
                    cryptData.length = Int(numBytesEncrypted)
                    let base64cryptString = cryptData.base64EncodedString(options: .lineLength64Characters)
                    return base64cryptString


                }
                else {
                    return nil
                }
            }
        }
        return base64cryptStringOut
    }
    return nil
}

func aesDecrypt(key:String, iv:String, options:Int = kCCOptionPKCS7Padding) -> String? {
    if let keyData = key.data(using: String.Encoding.utf8),
        let data = NSData(base64Encoded: self, options: .ignoreUnknownCharacters),
        let cryptData    = NSMutableData(length: Int((data.length)) + kCCBlockSizeAES128) {

            let keyLength              = size_t(kCCKeySizeAES128)
            let operation: CCOperation = UInt32(kCCDecrypt)
            let algoritm:  CCAlgorithm = UInt32(kCCAlgorithmAES128)
            let options:   CCOptions   = UInt32(options)

            var numBytesEncrypted :size_t = 0

        let unencryptedMessageOut = keyData.withUnsafeBytes {(keyBytes: UnsafePointer<CChar>)->String? in
            let cryptStatus = CCCrypt(operation,
                algoritm,
                options,
                keyBytes, keyLength,
                iv,
                data.bytes, data.length,
                cryptData.mutableBytes, cryptData.length,
                &numBytesEncrypted)

            if UInt32(cryptStatus) == UInt32(kCCSuccess) {
                cryptData.length = Int(numBytesEncrypted)
                let unencryptedMessage = String(data: cryptData as Data, encoding:String.Encoding.utf8)
                return unencryptedMessage
            }
            else {
                return nil
            }
        }
        return unencryptedMessageOut
    }
    return nil
}
}

public struct HMAC {

static func hash(inp: String, algo: HMACAlgo) -> String {
    if let stringData = inp.data(using: String.Encoding.utf8, allowLossyConversion: false) {
        return hexStringFromData(input: digest(input: stringData as NSData, algo: algo))
    }
    return ""
}

private static func digest(input : NSData, algo: HMACAlgo) -> NSData {
    let digestLength = algo.digestLength()
    var hash = [UInt8](repeating: 0, count: digestLength)
    switch algo {
    case .MD5:
        CC_MD5(input.bytes, UInt32(input.length), &hash)
        break
    case .SHA1:
        CC_SHA1(input.bytes, UInt32(input.length), &hash)
        break
    case .SHA224:
        CC_SHA224(input.bytes, UInt32(input.length), &hash)
        break
    case .SHA256:
        CC_SHA256(input.bytes, UInt32(input.length), &hash)
        break
    case .SHA384:
        CC_SHA384(input.bytes, UInt32(input.length), &hash)
        break
    case .SHA512:
        CC_SHA512(input.bytes, UInt32(input.length), &hash)
        break
    }
    return NSData(bytes: hash, length: digestLength)
}

private static func hexStringFromData(input: NSData) -> String {
    var bytes = [UInt8](repeating: 0, count: input.length)
    input.getBytes(&bytes, length: input.length)

    var hexString = ""
    for byte in bytes {
        hexString += String(format:"%02x", UInt8(byte))
    }

    return hexString
}

}

enum HMACAlgo {
case MD5, SHA1, SHA224, SHA256, SHA384, SHA512

func digestLength() -> Int {
    var result: CInt = 0
    switch self {
    case .MD5:
        result = CC_MD5_DIGEST_LENGTH
    case .SHA1:
        result = CC_SHA1_DIGEST_LENGTH
    case .SHA224:
        result = CC_SHA224_DIGEST_LENGTH
    case .SHA256:
        result = CC_SHA256_DIGEST_LENGTH
    case .SHA384:
        result = CC_SHA384_DIGEST_LENGTH
    case .SHA512:
        result = CC_SHA512_DIGEST_LENGTH
    }
    return Int(result)
}
}

The following is example of usage.

    // TEST for Encryption and Decryption through HMAC Swift 3.0
    let iv = "iv-salt-Sanjay--" // fixed 16 chars.
    let cryptoKeyString = "01234567890123456789012345678901"
    let originalString = "My Name is Sanjay Sampat, Password is IL0ve2view2Kill@4#"
    print("Original String: \(originalString)")
    if let encodedString = originalString.aesEncrypt(key: cryptoKeyString, iv: iv){
        print("String Encoded: \(encodedString)")
        if let decryptedString = encodedString.aesDecrypt(key: cryptoKeyString, iv: iv)
        {
            print("String Decoded: \(decryptedString)")
        }
        else{
            print("Decoding failed")
        }
    }
    else{
        print("Encoding failed")
    }


    // Example To create sha1 from string
    let testString = "This is string to test sha1 hash string."
    let sha1Digest = testString.sha1
    print("sha1-hash-string: \(sha1Digest)")

I hope this could be a ready reference for some user like me. :)

Thank You Jernej Strasner for your great answer. Here I just updating his answer for Swift 3.1:

enum CryptoAlgorithm {
case MD5, SHA1, SHA224, SHA256, SHA384, SHA512

 var HMACAlgorithm: CCHmacAlgorithm {
    var result: Int = 0
    switch self {
    case .MD5:      result = kCCHmacAlgMD5
    case .SHA1:     result = kCCHmacAlgSHA1
    case .SHA224:   result = kCCHmacAlgSHA224
    case .SHA256:   result = kCCHmacAlgSHA256
    case .SHA384:   result = kCCHmacAlgSHA384
    case .SHA512:   result = kCCHmacAlgSHA512
    }
    return CCHmacAlgorithm(result)
 }

 var digestLength: Int {
    var result: Int32 = 0
    switch self {
    case .MD5:      result = CC_MD5_DIGEST_LENGTH
    case .SHA1:     result = CC_SHA1_DIGEST_LENGTH
    case .SHA224:   result = CC_SHA224_DIGEST_LENGTH
    case .SHA256:   result = CC_SHA256_DIGEST_LENGTH
    case .SHA384:   result = CC_SHA384_DIGEST_LENGTH
    case .SHA512:   result = CC_SHA512_DIGEST_LENGTH
    }
    return Int(result)
 }
}

extension String {

func hmac(algorithm: CryptoAlgorithm, key: String) -> String {
    let str = self.cString(using: String.Encoding.utf8)
    let strLen = Int(self.lengthOfBytes(using: String.Encoding.utf8))
    let digestLen = algorithm.digestLength
    let result = UnsafeMutablePointer<CUnsignedChar>.allocate(capacity: digestLen)
    let keyStr = key.cString(using: String.Encoding.utf8)
    let keyLen = Int(key.lengthOfBytes(using: String.Encoding.utf8))

    CCHmac(algorithm.HMACAlgorithm, keyStr!, keyLen, str!, strLen, result)

    let digest = stringFromResult(result: result, length: digestLen)

    result.deallocate(capacity: digestLen)

    return digest
}

private func stringFromResult(result: UnsafeMutablePointer<CUnsignedChar>, length: Int) -> String {
    let hash = NSMutableString()
    for i in 0..<length {
        hash.appendFormat("%02x", result[i])
    }
    return String(hash)
}

And also to use it:

func sha256(StringToSign : String, secretKey : String) -> String{

    let hex = StringToSign.hmac(algorithm: .SHA256, key: secretKey)
    let hexData = hex.data(using: String.Encoding.utf8)
    let finalString = hexData?.base64EncodedString(options: [.lineLength64Characters])

    return finalString!

}

after swift 1.2 replace the lines in func digest

let strLen = UInt(self.lengthOfBytesUsingEncoding(NSUTF8StringEncoding))
let keyLen = UInt(key.lengthOfBytesUsingEncoding(NSUTF8StringEncoding))

by

let strLen = self.lengthOfBytesUsingEncoding(NSUTF8StringEncoding)
let keyLen = key.lengthOfBytesUsingEncoding(NSUTF8StringEncoding)

Swift 4 version demo on Github repo

You can do it in Swift. Just make sure you add #import to the bridging Objective-C bridging header.

You can see it in GitHub ZYCrypto

code

import Foundation

extension String {
    func hmac(by algorithm: Algorithm, key: [UInt8]) -> [UInt8] {
        var result = [UInt8](repeating: 0, count: algorithm.digestLength())
        CCHmac(algorithm.algorithm(), key, key.count, self.bytes, self.bytes.count, &result)
        return result
    }

    func hashHex(by algorithm: Algorithm) -> String {
        return algorithm.hash(string: self).hexString
    }

     func hash(by algorithm: Algorithm) -> [UInt8] {
        return algorithm.hash(string: self)
     }
}


enum Algorithm {
    case MD5, SHA1, SHA224, SHA256, SHA384, SHA512

    func algorithm() -> CCHmacAlgorithm {
        var result: Int = 0
        switch self {
        case .MD5:
            result = kCCHmacAlgMD5
        case .SHA1:
            result = kCCHmacAlgSHA1
        case .SHA224:
            result = kCCHmacAlgSHA224
        case .SHA256:
            result = kCCHmacAlgSHA256
        case .SHA384:
            result = kCCHmacAlgSHA384
        case .SHA512:
            result = kCCHmacAlgSHA512
        }
        return CCHmacAlgorithm(result)
    }

    func digestLength() -> Int {
        var result: CInt = 0
        switch self {
        case .MD5:
            result = CC_MD5_DIGEST_LENGTH
        case .SHA1:
            result = CC_SHA1_DIGEST_LENGTH
        case .SHA224:
            result = CC_SHA224_DIGEST_LENGTH
        case .SHA256:
            result = CC_SHA256_DIGEST_LENGTH
        case .SHA384:
            result = CC_SHA384_DIGEST_LENGTH
        case .SHA512:
            result = CC_SHA512_DIGEST_LENGTH
        }
        return Int(result)
    }

    func hash(string: String) -> String {
        var hash = [UInt8](repeating: 0, count: self.digestLength())
        switch self {
        case .MD5:
            CC_MD5(string.bytes, CC_LONG(string.bytes.count), &hash)
        case .SHA1:
            CC_SHA1(string.bytes, CC_LONG(string.bytes.count), &hash)
        case .SHA224:
            CC_SHA224(string.bytes, CC_LONG(string.bytes.count), &hash)
        case .SHA256:
            CC_SHA256(string.bytes, CC_LONG(string.bytes.count), &hash)
        case .SHA384:
            CC_SHA384(string.bytes, CC_LONG(string.bytes.count), &hash)
        case .SHA512:
            CC_SHA512(string.bytes, CC_LONG(string.bytes.count), &hash)
        }
        return hash.hexString
    }
}

extension Array where Element == UInt8 {
    var hexString: String {
        return self.reduce(""){$0 + String(format: "%02x", $1)}
    }

    var base64String: String {
        return self.data.base64EncodedString(options: Data.Base64EncodingOptions.lineLength76Characters)
    }

    var data: Data {
        return Data(self)
    }
}

extension String {
    var bytes: [UInt8] {
        return [UInt8](self.utf8)
    }
}

extension Data {
    var bytes: [UInt8] {
        return [UInt8](self)
    }
}

How to Use

let tData = "test string".hmac(by: .SHA256, key: "key string".bytes)
let oDada = "other test string".hamc(by: .SHA256, key: tData)
let signature = oData.hexSting.lowercased()

let sha256Hash = "test string".hashHex(by: .SHA256)
let md5Hash = "test string".hash(by: .MD5).base64String