Swift cross-platform RSA wrapper library for RSA encryption and signing. Works on supported Apple platforms (using Security framework). Linux (using OpenSSL) is working but is still somewhat of a work in progress.
- CryptorRSA: Utility functions for RSA encryption and signing. Pure Swift
- Swift Open Source
swift-4.0.0-RELEASE
toolchain (Minimum REQUIRED for latest release) - Swift Open Source
swift-5.2-RELEASE
toolchain (Recommended) - Swift toolchain included in Xcode Version 10.0 (10A255) or higher.
- macOS 11.5.0 (Big Sur) or higher
- Xcode Version 12.0 (9A325) or higher using the included toolchain (Minimum REQUIRED for latest release).
- Xcode Version 13.4.1 (13F100) or higher using the included toolchain (Recommended).
- iOS 14.5 or higher
- Xcode Version 9.0 (9A325) or higher using the included toolchain (Minimum REQUIRED for latest release).
- Xcode Version 13.4.1 (13F100) or higher using the included toolchain (Recommended).
- Ubuntu 16.04 (or 16.10 but only tested on 16.04) and 18.04.
- One of the Swift Open Source toolchain listed above.
- OpenSSL is provided by the distribution. Note: 1.0.x, 1.1.x and later releases of OpenSSL are supported.
- The appropriate libssl-dev package is required to be installed when building.
To build CryptorRSA from the command line:
% cd <path-to-clone>
% swift build
To run the supplied unit tests for CryptorRSA from the command line:
% cd <path-to-clone>
% swift build
% swift test
To include BlueRSA into a Swift Package Manager package, add it to the dependencies
attribute defined in your Package.swift
file. You can select the version using the majorVersion
and minor
parameters. For example:
dependencies: [
.package(url: "https://github.com/Kitura/BlueRSA", majorVersion: <majorVersion>, minor: <minor>)
]
To include BlueRSA in a project using Carthage, add a line to your Cartfile
with the GitHub organization and project names and version. For example:
github "Kitura/BlueRSA" ~> <majorVersion>.<minor>
The first you need to do is import the CryptorRSA framework. This is done by the following:
import CryptorRSA
BlueRSA supports the following major data types:
-
Key Handling
CryptorRSA.PublicKey
- Represents an RSA Public Key.CryptorRSA.PrivateKey
- Represents an RSA Private Key.
-
Data Handling
CryptorRSA.EncryptedData
- Represents encrypted data.CryptorRSA.PlaintextData
- Represents plaintext or decrypted data.CryptorRSA.SignedData
- Represents signed data.
BlueRSA provides seven (7) functions each for creating public and private keys from data. They are as follows (where createXXXX is either createPublicKey
or createPrivateKey
depending on what you're trying to create):
CryptorRSA.createXXXX(with data: Data) throws
- This creates either a private or public key containing the data provided. It is assumed that the data being provided is in the proper format.CryptorRSA.createXXXX(withBase64 base64String: String) throws
- This creates either a private or public key using theBase64 encoded String
provided.CryptorRSA.createXXXX(withPEM pemString: String) throws
- This creates either a private or public key using thePEM encoded String
provided.CryptorRSA.createXXXX(withPEMNamed pemName: String, onPath path: String) throws
- This creates either a private or public key using thePEM encoded file
pointed at by thepemName
and located on the path specified bypath
provided.CryptorRSA.createXXXX(withDERNamed derName: String, onPath path: String) throws
- This creates either a private or public key using theDER encoded file
pointed at by thederName
and located on the path specified bypath
provided.CryptorRSA.createXXXX(withPEMNamed pemName: String, in bundle: Bundle = Bundle.main) throws
- This creates either a private or public key using thePEM encoded file
pointed at by thepemName
and located in theBundle
specified bybundle
provided. By default this API will look in themain
bundle. Note: Apple Platforms OnlyCryptorRSA.createXXXX(withDERNamed derName: String, in bundle: Bundle = Bundle.main) throws
- This creates either a private or public key using theDER encoded file
pointed at by thederName
and located in theBundle
specified bybundle
provided. By default this API will look in themain
bundle. Note: Apple Platforms Only
Additionally, there are three APIs for creating a public key by extracting the key from a PEM formatted certificate: They are:
CryptorRSA.createPublicKey(extractingFrom data: Data) throws
- This creates either a public key by extracting from thePEM encoded certificate
pointed at by thedata
.CryptorRSA.createPublicKey(extractingFrom certName: String, onPath path: String) throws
- This creates a public key by extracting from thePEM encoded certificate
pointed at by thecertName
and located on the path specified bypath
provided.CryptorRSA.createPublicKey(extractingFrom certName: String, in bundle: Bundle = Bundle.main) throws
- This creates a public key using thePEM encoded certificate
pointed at by thederName
and located in theBundle
specified bybundle
provided. By default this API will look in themain
bundle. Note: Apple Platforms Only
Example
The following example illustrates creating a public key given PEM encoded file located on a certain path. *Note: Exception handling omitted for brevity.
import Foundation
import CryptorRSA
...
let keyName = ...
let keyPath = ...
let publicKey = try CryptorRSA.createPublicKey(withPEMNamed: keyName, onPath: keyPath)
...
<Do something with the key...>
BlueRSA provides functions for the creation of each of the three (3) data handling types:
Plaintext Data Handling and Signing
There are two class level functions for creating a PlaintextData
object. These are:
CryptorRSA.createPlaintext(with data: Data) -> PlaintextData
- This function creates aPlaintextData
containing the specifieddata
.CryptorRSA.createPlaintext(with string: String, using encoding: String.Encoding) throws -> PlaintextData
- This function creates aPlaintextData
object using thestring
encoded with the specifiedencoding
as the data.
Once the PlaintextData
object is created, there are two instance functions that can be used to manipulate the contained data. These are:
encrypted(with key: PublicKey, algorithm: Data.Algorithm) throws -> EncryptedData?
- This function allows you to encrypt containing data using the publickey
andalgorithm
specified. This function returns an optionalEncryptedData
object containing the encryped data.signed(with key: PrivateKey, algorithm: Data.Algorithm) throws -> SignedData?
- This function allows you to sign the contained data using the privatekey
andalgorithm
specified. This function returns an optionalSignedData
object containing the signature of the signed data.
Example
- Encryption: Note: Exception handling omitted for brevity.
import Foundation
import CryptorRSA
...
let keyName = ...
let keyPath = ...
let myData: Data = <... Data to be encrypted ...>
let publicKey = try CryptorRSA.createPublicKey(withPEMNamed: keyName, onPath: keyPath)
let myPlaintext = CryptorRSA.createPlaintext(with: myData)
let encryptedData = try myPlaintext.encrypted(with: publicKey, algorithm: .sha1)
...
< Do something with the encrypted data...>
- Signing: Note: Exception handling omitted for brevity.
import Foundation
import CryptorRSA
...
let keyName = ...
let keyPath = ...
let myData: Data = <... Data to be signed ...>
let privateKey = try CryptorRSA.createPrivateKey(withPEMNamed: keyName, onPath: keyPath)
let myPlaintext = CryptorRSA.createPlaintext(with: myData)
let signedData = try myPlaintext.signed(with: privateKey, algorithm: .sha1)
...
< Do something with the signed data...>
Encrypted Data Handling
There are two class level functions for creating a EncryptedData
object. These are:
CryptorRSA.createEncrypted(with data: Data) -> EncryptedData
- This function creates aEncryptedData
containing the specified encrypteddata
.CryptorRSA.createEncrypted(with base64String: String) throws -> EncryptedData
- This function creates aEncrpytedData
using the Base64 representation of already encrypted data.
Once the EncryptedData
object is created, there is an instance function that can be used to decrypt the enclosed data:
decrypted(with key: PrivateKey, algorithm: Data.Algorithm) throws -> DecryptedData?
- This function allows you to decrypt containing data using the publickey
andalgorithm
specified. This function returns an optionalDecryptedData
object containing the encryped data.
BlueRSA currently supports OAEP
padding, which is the recommended padding algorithm.
Example
- Decryption: Note: Exception handling omitted for brevity.
import Foundation
import CryptorRSA
...
let keyName = ...
let keyPath = ...
let publicKey = try CryptorRSA.createPublicKey(withPEMNamed: keyName, onPath: keyPath)
let pkeyName = ...
let pkeyPath = ...
let privateKey = try CryptorRSA.createPrivateKey(withPEMNamed: pkeyName, onPath: pkeyPath)
let myData: Data = <... Data to be encrypted ...>
let myPlaintext = CryptorRSA.createPlaintext(with: myData)
let encryptedData = try myPlaintext.encrypted(with: publicKey, algorithm: .sha1)
let decryptedData = try encryptedData.decrypted(with: privateKey, algorithm: .sha1)
...
< Do something with the decrypted data...>
There is a single class level function that can be used to create a SignedData
object. It is:
CryptorRSA.createSigned(with data: Data) -> SignedData
- This function creates aSignedData
containing the specified signeddata
.
Once created or obtained PlaintextData
and SignedData
, there is an instance function which can be used to verify the signature contained therein:
-
verify(with key: PublicKey, signature: SignedData, algorithm: Data.Algorithm) throws -> Bool
- This function is used to verify, using the publickey
andalgorithm
, thesignature
. Returns true if the signature is valid, false otherwise. -
Verifying: Note: Exception handling omitted for brevity.
import Foundation
import CryptorRSA
...
let keyName = ...
let keyPath = ...
let publicKey = try CryptorRSA.createPublicKey(withPEMNamed: keyName, onPath: keyPath)
let pkeyName = ...
let pkeyPath = ...
let privateKey = try CryptorRSA.createPrivateKey(withPEMNamed: pkeyName, onPath: pkeyPath)
let myData: Data = <... Data to be signed ...>
let myPlaintext = CryptorRSA.createPlaintext(with: myData)
let signedData = try myPlaintext.signed(with: privateKey, algorithm: .sha1)
if try myPlaintext.verify(with: publicKey, signature: signedData, algorithm: .sha1) {
print("Signature verified")
} else {
print("Signature Verification Failed")
}
All three of the data handling types have two common utility instance functions. These are:
digest(using algorithm: Data.Algorithm) throws -> Data
- This function returns aData
object containing a digest constructed using the specifiedalgorithm
.string(using encoding: String.Encoding) throws -> String
- This functions returns aString
representation of the data using the specifiedencoding
.
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This library is licensed under Apache 2.0. Full license text is available in LICENSE.