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I've been working on a project to verify digital signature of provided XML documents.
The document schema is as provided below.
<?xml version="1.0" encoding="UTF-8"?>
<XMLReport>
<INNER_CONTENT>----content----</INNER_CONTENT>
<Signature>
<SIGNALGO>SHA512</SIGNALGO>
<KeyInfo>3082010A0282010100D8F165280...........</KeyInfo>
<SignatureValue>{data}</SignatureValue>
<HASH>{data}</HASH>
</Signature>
</XMLReport>
So far, I've tried to decrypt the SignatureValue in the provided document using the public key constructed from the KeyInfo field. I'm using the BouncyCastle library to do the above, but it's been throwing me the below exception.
Org.BouncyCastle.Crypto.InvalidCipherTextException: 'block incorrect'
The error occurs at the below code:
var decryptedBytes = decryptEngine.ProcessBlock(Encoding.GetEncoding(1256).GetBytes(segment), 0, segment.Length);
Am I approaching this the wrong way? Some help to solve this issue is much appreciated.
Edit:
public static string RsaDecryptWithPublic(string encryptedData, string publicKey) {
var decryptedResult = string.Empty;
try {
Int32 EncryptedLength = 256;
int len = encryptedData.Length;
var length = len / EncryptedLength;
var decryptEngine = new Pkcs1Encoding(new RsaEngine());
using(var txtreader = new StringReader(publicKey)) {
var keyParameter = (AsymmetricKeyParameter) new PemReader(txtreader).ReadObject();
decryptEngine.Init(false, keyParameter);
}
var sb = new StringBuilder();
string resultData = "";
for (var i = 0; i < length; i++) {
string segment = encryptedData.Substring(i * EncryptedLength, EncryptedLength);
try {
var decryptedBytes = decryptEngine.ProcessBlock(Encoding.GetEncoding(1256).GetBytes(segment), 0, segment.Length);
resultData = Encoding.GetEncoding(1256).GetString(decryptedBytes);
} catch (Exception GenEx) {
string error = GenEx.Message;
}
sb.Append(resultData);
}
decryptedResult = sb.ToString();
} catch (Exception ex) {
}
return decryptedResult;
}
I've seen plenty of encryption/decryption tutorials and examples on the net in C# that use the System.Security.Cryptography.RSACryptoServiceProvider, but what I'm hoping to be able to do is:
Create an RSA public/private keypair
Transmit the public key (or for proof of concept, just move it in a string variable)
Create a new RSA crypto provider and encrypt a string with the public key
Transmit the encrypted string (or data) back to the original crypto provider and decrypt the string
Could anyone point me to a useful resource for this?
well there are really enough examples for this, but anyway, here you go
using System;
using System.Security.Cryptography;
namespace RsaCryptoExample
{
static class Program
{
static void Main()
{
//lets take a new CSP with a new 2048 bit rsa key pair
var csp = new RSACryptoServiceProvider(2048);
//how to get the private key
var privKey = csp.ExportParameters(true);
//and the public key ...
var pubKey = csp.ExportParameters(false);
//converting the public key into a string representation
string pubKeyString;
{
//we need some buffer
var sw = new System.IO.StringWriter();
//we need a serializer
var xs = new System.Xml.Serialization.XmlSerializer(typeof(RSAParameters));
//serialize the key into the stream
xs.Serialize(sw, pubKey);
//get the string from the stream
pubKeyString = sw.ToString();
}
//converting it back
{
//get a stream from the string
var sr = new System.IO.StringReader(pubKeyString);
//we need a deserializer
var xs = new System.Xml.Serialization.XmlSerializer(typeof(RSAParameters));
//get the object back from the stream
pubKey = (RSAParameters)xs.Deserialize(sr);
}
//conversion for the private key is no black magic either ... omitted
//we have a public key ... let's get a new csp and load that key
csp = new RSACryptoServiceProvider();
csp.ImportParameters(pubKey);
//we need some data to encrypt
var plainTextData = "foobar";
//for encryption, always handle bytes...
var bytesPlainTextData = System.Text.Encoding.Unicode.GetBytes(plainTextData);
//apply pkcs#1.5 padding and encrypt our data
var bytesCypherText = csp.Encrypt(bytesPlainTextData, false);
//we might want a string representation of our cypher text... base64 will do
var cypherText = Convert.ToBase64String(bytesCypherText);
/*
* some transmission / storage / retrieval
*
* and we want to decrypt our cypherText
*/
//first, get our bytes back from the base64 string ...
bytesCypherText = Convert.FromBase64String(cypherText);
//we want to decrypt, therefore we need a csp and load our private key
csp = new RSACryptoServiceProvider();
csp.ImportParameters(privKey);
//decrypt and strip pkcs#1.5 padding
bytesPlainTextData = csp.Decrypt(bytesCypherText, false);
//get our original plainText back...
plainTextData = System.Text.Encoding.Unicode.GetString(bytesPlainTextData);
}
}
}
as a side note: the calls to Encrypt() and Decrypt() have a bool parameter that switches between OAEP and PKCS#1.5 padding ... you might want to choose OAEP if it's available in your situation
public static string Encryption(string strText)
{
var publicKey = "<RSAKeyValue><Modulus>21wEnTU+mcD2w0Lfo1Gv4rtcSWsQJQTNa6gio05AOkV/Er9w3Y13Ddo5wGtjJ19402S71HUeN0vbKILLJdRSES5MHSdJPSVrOqdrll/vLXxDxWs/U0UT1c8u6k/Ogx9hTtZxYwoeYqdhDblof3E75d9n2F0Zvf6iTb4cI7j6fMs=</Modulus><Exponent>AQAB</Exponent></RSAKeyValue>";
var testData = Encoding.UTF8.GetBytes(strText);
using (var rsa = new RSACryptoServiceProvider(1024))
{
try
{
// client encrypting data with public key issued by server
rsa.FromXmlString(publicKey.ToString());
var encryptedData = rsa.Encrypt(testData, true);
var base64Encrypted = Convert.ToBase64String(encryptedData);
return base64Encrypted;
}
finally
{
rsa.PersistKeyInCsp = false;
}
}
}
public static string Decryption(string strText)
{
var privateKey = "<RSAKeyValue><Modulus>21wEnTU+mcD2w0Lfo1Gv4rtcSWsQJQTNa6gio05AOkV/Er9w3Y13Ddo5wGtjJ19402S71HUeN0vbKILLJdRSES5MHSdJPSVrOqdrll/vLXxDxWs/U0UT1c8u6k/Ogx9hTtZxYwoeYqdhDblof3E75d9n2F0Zvf6iTb4cI7j6fMs=</Modulus><Exponent>AQAB</Exponent><P>/aULPE6jd5IkwtWXmReyMUhmI/nfwfkQSyl7tsg2PKdpcxk4mpPZUdEQhHQLvE84w2DhTyYkPHCtq/mMKE3MHw==</P><Q>3WV46X9Arg2l9cxb67KVlNVXyCqc/w+LWt/tbhLJvV2xCF/0rWKPsBJ9MC6cquaqNPxWWEav8RAVbmmGrJt51Q==</Q><DP>8TuZFgBMpBoQcGUoS2goB4st6aVq1FcG0hVgHhUI0GMAfYFNPmbDV3cY2IBt8Oj/uYJYhyhlaj5YTqmGTYbATQ==</DP><DQ>FIoVbZQgrAUYIHWVEYi/187zFd7eMct/Yi7kGBImJStMATrluDAspGkStCWe4zwDDmdam1XzfKnBUzz3AYxrAQ==</DQ><InverseQ>QPU3Tmt8nznSgYZ+5jUo9E0SfjiTu435ihANiHqqjasaUNvOHKumqzuBZ8NRtkUhS6dsOEb8A2ODvy7KswUxyA==</InverseQ><D>cgoRoAUpSVfHMdYXW9nA3dfX75dIamZnwPtFHq80ttagbIe4ToYYCcyUz5NElhiNQSESgS5uCgNWqWXt5PnPu4XmCXx6utco1UVH8HGLahzbAnSy6Cj3iUIQ7Gj+9gQ7PkC434HTtHazmxVgIR5l56ZjoQ8yGNCPZnsdYEmhJWk=</D></RSAKeyValue>";
var testData = Encoding.UTF8.GetBytes(strText);
using (var rsa = new RSACryptoServiceProvider(1024))
{
try
{
var base64Encrypted = strText;
// server decrypting data with private key
rsa.FromXmlString(privateKey);
var resultBytes = Convert.FromBase64String(base64Encrypted);
var decryptedBytes = rsa.Decrypt(resultBytes, true);
var decryptedData = Encoding.UTF8.GetString(decryptedBytes);
return decryptedData.ToString();
}
finally
{
rsa.PersistKeyInCsp = false;
}
}
}
Honestly, I have difficulty implementing it because there's barely any tutorials I've searched that displays writing the keys into the files. The accepted answer was "fine". But for me I had to improve it so that both keys gets saved into two separate files. I've written a helper class so y'all just gotta copy and paste it. Hope this helps lol.
using Microsoft.Win32;
using System;
using System.IO;
using System.Security.Cryptography;
namespace RsaCryptoExample
{
class RSAFileHelper
{
readonly string pubKeyPath = "public.key";//change as needed
readonly string priKeyPath = "private.key";//change as needed
public void MakeKey()
{
//lets take a new CSP with a new 2048 bit rsa key pair
RSACryptoServiceProvider csp = new RSACryptoServiceProvider(2048);
//how to get the private key
RSAParameters privKey = csp.ExportParameters(true);
//and the public key ...
RSAParameters pubKey = csp.ExportParameters(false);
//converting the public key into a string representation
string pubKeyString;
{
//we need some buffer
var sw = new StringWriter();
//we need a serializer
var xs = new System.Xml.Serialization.XmlSerializer(typeof(RSAParameters));
//serialize the key into the stream
xs.Serialize(sw, pubKey);
//get the string from the stream
pubKeyString = sw.ToString();
File.WriteAllText(pubKeyPath, pubKeyString);
}
string privKeyString;
{
//we need some buffer
var sw = new StringWriter();
//we need a serializer
var xs = new System.Xml.Serialization.XmlSerializer(typeof(RSAParameters));
//serialize the key into the stream
xs.Serialize(sw, privKey);
//get the string from the stream
privKeyString = sw.ToString();
File.WriteAllText(priKeyPath, privKeyString);
}
}
public void EncryptFile(string filePath)
{
//converting the public key into a string representation
string pubKeyString;
{
using (StreamReader reader = new StreamReader(pubKeyPath)){pubKeyString = reader.ReadToEnd();}
}
//get a stream from the string
var sr = new StringReader(pubKeyString);
//we need a deserializer
var xs = new System.Xml.Serialization.XmlSerializer(typeof(RSAParameters));
//get the object back from the stream
RSACryptoServiceProvider csp = new RSACryptoServiceProvider();
csp.ImportParameters((RSAParameters)xs.Deserialize(sr));
byte[] bytesPlainTextData = File.ReadAllBytes(filePath);
//apply pkcs#1.5 padding and encrypt our data
var bytesCipherText = csp.Encrypt(bytesPlainTextData, false);
//we might want a string representation of our cypher text... base64 will do
string encryptedText = Convert.ToBase64String(bytesCipherText);
File.WriteAllText(filePath,encryptedText);
}
public void DecryptFile(string filePath)
{
//we want to decrypt, therefore we need a csp and load our private key
RSACryptoServiceProvider csp = new RSACryptoServiceProvider();
string privKeyString;
{
privKeyString = File.ReadAllText(priKeyPath);
//get a stream from the string
var sr = new StringReader(privKeyString);
//we need a deserializer
var xs = new System.Xml.Serialization.XmlSerializer(typeof(RSAParameters));
//get the object back from the stream
RSAParameters privKey = (RSAParameters)xs.Deserialize(sr);
csp.ImportParameters(privKey);
}
string encryptedText;
using (StreamReader reader = new StreamReader(filePath)) { encryptedText = reader.ReadToEnd(); }
byte[] bytesCipherText = Convert.FromBase64String(encryptedText);
//decrypt and strip pkcs#1.5 padding
byte[] bytesPlainTextData = csp.Decrypt(bytesCipherText, false);
//get our original plainText back...
File.WriteAllBytes(filePath, bytesPlainTextData);
}
}
}
I'll share my very simple code for sample purpose. Hope it will help someone like me searching for quick code reference.
My goal was to receive rsa signature from backend, then validate against input string using public key and store locally for future periodic verifications.
Here is main part used for signature verification:
...
var signature = Get(url); // base64_encoded signature received from server
var inputtext= "inputtext"; // this is main text signature was created for
bool result = VerifySignature(inputtext, signature);
...
private bool VerifySignature(string input, string signature)
{
var result = false;
using (var cps=new RSACryptoServiceProvider())
{
// converting input and signature to Bytes Arrays to pass to VerifyData rsa method to verify inputtext was signed using privatekey corresponding to public key we have below
byte[] inputtextBytes = Encoding.UTF8.GetBytes(input);
byte[] signatureBytes = Convert.FromBase64String(signature);
cps.FromXmlString("<RSAKeyValue><Modulus>....</Modulus><Exponent>....</Exponent></RSAKeyValue>"); // xml formatted publickey
result = cps.VerifyData(inputtextBytes , new SHA1CryptoServiceProvider(), signatureBytes );
}
return result;
}
for big data
public class RsaService : System.IDisposable
{
public delegate int TransformBlockCall(System.ReadOnlySpan<byte> data, System.Span<byte> destination);
private readonly RSA _encoder;
private readonly RSAEncryptionPadding _padding;
private readonly TransformBlockCall _encryptBlockCall;
private readonly TransformBlockCall _decryptBlockCall;
private int _encrypt_InputBlockSize;
private int _encrypt_OutputBlockSize;
private int _decrypt_InputBlockSize;
private int _decrypt_OutputBlockSize;
public RsaService(RSA encoder) {
if(encoder == null)
throw new System.ArgumentNullException(nameof(encoder));
_encoder = encoder;
_padding = RSAEncryptionPadding.Pkcs1;
_encryptBlockCall = new TransformBlockCall(EncryptBlock);
_decryptBlockCall = new TransformBlockCall(DecryptBlock);
OnEndSetParameters();
}
private void OnEndSetParameters() {
_encrypt_InputBlockSize = GetSizeOutputEncryptOfKeySize(_encoder.KeySize);
_encrypt_OutputBlockSize = _encoder.KeySize / 8;
_decrypt_InputBlockSize = _encrypt_OutputBlockSize;
_decrypt_OutputBlockSize = _encrypt_OutputBlockSize;
}
public void ImportParameters(RSAParameters parameters) {
_encoder.ImportParameters(parameters);
OnEndSetParameters();
}
public byte[] Encrypt(byte[] data) {
if(data == null) throw new System.ArgumentNullException(nameof(data));
if(data.Length == 0) return data;
int outputLength = GetEncryptOutputMaxByteCount(data.Length);
byte[] outputData = new byte[outputLength];
Encrypt(data, outputData);
return outputData;
}
public byte[] Decrypt(byte[] data) {
if(data == null) throw new System.ArgumentNullException(nameof(data));
if(data.Length == 0) return data;
int maxOutputLength = GetDecryptOutputMaxByteCount(data.Length);
byte[] outputData = new byte[maxOutputLength];
int actual_OutputLength = Decrypt(data, outputData);
if(maxOutputLength > actual_OutputLength)
System.Array.Resize(ref outputData, actual_OutputLength);
return outputData;
}
public int Encrypt(System.ReadOnlySpan<byte> data, System.Span<byte> destination) {
#if DEBUG
int inputBlockSize = _encrypt_InputBlockSize;
int outputBlockSize = _encoder.KeySize / 8;
int blockCount = (data.Length / inputBlockSize);
if(data.Length % inputBlockSize != 0)
blockCount++;
System.Diagnostics.Debug.Assert((blockCount * outputBlockSize) <= destination.Length);
#endif
if(data.Length > _encrypt_InputBlockSize)
return TransformFinal(_encryptBlockCall, data, destination, _encrypt_InputBlockSize);
else
return _encryptBlockCall(data, destination);
}
public int Decrypt(System.ReadOnlySpan<byte> data, System.Span<byte> destination) {
if(data.Length > _decrypt_InputBlockSize)
return TransformFinal(_decryptBlockCall, data, destination, _decrypt_InputBlockSize);
else
return _decryptBlockCall(data, destination);
}
private int EncryptBlock(System.ReadOnlySpan<byte> data, System.Span<byte> destination) => _encoder.Encrypt(data, destination, _padding);
private int DecryptBlock(System.ReadOnlySpan<byte> data, System.Span<byte> destination) => _encoder.Decrypt(data, destination, _padding);
public int GetEncryptOutputMaxByteCount(int inputCount) => GetBlockCount(inputCount, _encrypt_InputBlockSize) * _encrypt_OutputBlockSize;
public int GetDecryptOutputMaxByteCount(int inputCount) => GetBlockCount(inputCount, _decrypt_InputBlockSize) * _decrypt_OutputBlockSize;
public void Dispose() {
_encoder.Dispose();
System.GC.SuppressFinalize(this);
}
#region Methods_Helper
public static RsaService Create(RSAParameters parameters) => new RsaService(RSA.Create(parameters));
public static RsaService Create() => new RsaService(RSA.Create());
// [keySize] ÷ 8 - [11 bytes for padding] = Result
// Exsimple: [2048 key size] ÷ 8 - [11 bytes for padding] = 245
public static int GetSizeOutputEncryptOfKeySize(int keySize) => (keySize / 8) - 11;
private static int GetBlockCount(int dataLength,int inputBlockSize) {
int blockCount = (dataLength / inputBlockSize);
if(dataLength % inputBlockSize != 0)
blockCount++;
return blockCount;
}
public static int TransformFinal(TransformBlockCall transformBlockCall, System.ReadOnlySpan<byte> data, System.Span<byte> destination, int inputBlockSize) {
int blockCount = GetBlockCount(data.Length, inputBlockSize);
int data_writtenCount = 0;
int destination_writtenCount = 0;
while(blockCount-- > 0) {
if(blockCount == 0) {
inputBlockSize = data.Length - data_writtenCount;
if(inputBlockSize == 0) break;
}
destination_writtenCount += transformBlockCall(data: data.Slice(data_writtenCount, inputBlockSize)
, destination: destination.Slice(destination_writtenCount));
data_writtenCount += inputBlockSize;
}
return destination_writtenCount;
}
public static (RSAParameters keyPublic, RSAParameters keyPrivate) GenerateKeyPair(int keySize = 2048) {
RSAParameters keyPriv;
RSAParameters keyPub;
using(var rsa = RSA.Create(keySize)) {
keyPriv = rsa.ExportParameters(true);
keyPub = rsa.ExportParameters(false);
}
return (keyPub, keyPriv);
}
#endregion Methods_Helper
}
public static class Program
{
static void Main() {
var (keyPublic, keyPrivate) = RsaService.GenerateKeyPair();
var encryptor = RsaService.Create(keyPublic);
var decryptor = RsaService.Create(keyPrivate);
string originalText = "";
for(int i = 0; i < 1000; i++) {
originalText += "ABC123456789";
}
byte[] inputData = Encoding.UTF8.GetBytes(originalText); // data random for test
System.Console.WriteLine("inputData.Length: {0}", inputData.Length);
var encryptedData = encryptor.Encrypt(inputData);
System.Console.WriteLine("encryptedData.Length: {0}", encryptedData.Length);
byte[] decryptedData = decryptor.Decrypt(encryptedData);
string decryptedText = Encoding.UTF8.GetString(decryptedData);
System.Console.WriteLine("status: {0}", decryptedText == originalText);
}
}
I have written the following code in swift to try and replicate something I have working in C#. I know I have gone wrong but I'm not exactly sure where.
The code is meant to encrypt a string and return an encrypted string. The encrypted string should remain the same every time. Unfortunately the webservice that this app connects to is a bit old and I have no control to change it.
Thank you for any assistance!
Swift code:
enum HMACAlgorithm {
case MD5, SHA1, SHA224, SHA256, SHA384, SHA512
func toCCHmacAlgorithm() -> 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)
}
}
class ViewController: UIViewController {
//Encypt Outlet
#IBOutlet weak var stringToEn: UITextField!
#IBOutlet weak var outputEn: UITextField!
override func viewDidLoad() {
super.viewDidLoad()
// Do any additional setup after loading the view, typically from a nib.
}
override func didReceiveMemoryWarning() {
super.didReceiveMemoryWarning()
// Dispose of any resources that can be recreated.
}
#IBAction func encyptPressed(_ sender: Any) {
let input = stringToEn.text
let hmacResult: String = input!.hmac(algorithm: HMACAlgorithm.SHA1, key: "GVDev789")
outputEn.text = hmacResult
}
}
extension String{
func hmac(algorithm: HMACAlgorithm, key: String) -> String {
let cKey = key.cString(using: String.Encoding.utf8)
let cData = self.cString(using: String.Encoding.utf8)
var result = [CUnsignedChar](repeating: 0, count: Int(algorithm.digestLength()))
CCHmac(algorithm.toCCHmacAlgorithm(), cKey!, 1000, cData!, 1000, &result)
// cchmac Int(strlen(cKey!)) Int(strlen(cData!))
let hmacData:NSData = NSData(bytes: result, length: (Int(algorithm.digestLength())))
let hmacBase64 = hmacData.base64EncodedString(options: NSData.Base64EncodingOptions.lineLength76Characters)
return String(hmacBase64)
}
}
What is working in C#
public static string getEncryptedText(string input)
{
return EncryptText(input);
}
private static string EncryptText(string strText)
{
PasswordDeriveBytes pdbPassword = default(PasswordDeriveBytes);
PasswordDeriveBytes pdbIV = default(PasswordDeriveBytes);
DESCryptoServiceProvider DES = new DESCryptoServiceProvider();
byte[] salt = {
(byte)Strings.Asc("G"),
(byte)Strings.Asc("V"),
(byte)Strings.Asc("D"),
(byte)Strings.Asc("e"),
(byte)Strings.Asc("v"),
(byte)Strings.Asc("7"),
(byte)Strings.Asc("8"),
(byte)Strings.Asc("9")
};
System.IO.MemoryStream ms = new System.IO.MemoryStream();
CryptoStream cs = default(CryptoStream);
string plainText = strText;
byte[] plainBytes = null;
plainBytes = System.Text.Encoding.UTF8.GetBytes(plainText);
pdbPassword = new PasswordDeriveBytes("Password", salt);
pdbPassword.HashName = "SHA1";
pdbPassword.IterationCount = 1000;
DES.Key = pdbPassword.GetBytes(8);
pdbIV = new PasswordDeriveBytes("PbeIv", salt);
pdbIV.HashName = "SHA1";
pdbIV.IterationCount = 1000;
DES.IV = pdbIV.GetBytes(8);
cs = new CryptoStream(ms, DES.CreateEncryptor(), CryptoStreamMode.Write);
cs.Write(plainBytes, 0, plainBytes.Length);
cs.FlushFinalBlock();
return Convert.ToBase64String(ms.ToArray());
}
}
I have been trying to put together an in-memory public-key encryption infrastructure using OpenPGP via Bouncy Castle. One of our vendors uses OpenPGP public key encryption to encrypt all their feeds, and requires us to do the same, so I'm stuck with the technology and the implementation. So now I'm coding an OpenPGP encryption/ decryption toolkit for automating these feeds.
The examples at bouncycastle.org inexplicably default to writing encrypted data to and collecting keys from a file system; this is not what I want to do, so I've been trying to get everything stream-based.
I have gotten to the point where I can actually get my code to compile and run, but my encrypted payload is empty. I think I'm missing something silly, but after several days of trying this and that, I have lost the ability to objectively examine this.
My utility class contains these methods:
public static PgpPublicKey ImportPublicKey(
this Stream publicIn)
{
var pubRings =
new PgpPublicKeyRingBundle(PgpUtilities.GetDecoderStream(publicIn)).GetKeyRings().OfType<PgpPublicKeyRing>();
var pubKeys = pubRings.SelectMany(x => x.GetPublicKeys().OfType<PgpPublicKey>());
var pubKey = pubKeys.FirstOrDefault();
return pubKey;
}
public static Stream Streamify(this string theString, Encoding encoding = null)
{
encoding = encoding ?? Encoding.UTF8;
var stream = new MemoryStream(encoding.GetBytes(theString));
return stream;
}
public static string Stringify(this Stream theStream,
Encoding encoding = null)
{
encoding = encoding ?? Encoding.UTF8;
using (var reader = new StreamReader(theStream, encoding))
{
return reader.ReadToEnd();
}
}
public static byte[] ReadFully(this Stream stream)
{
if (!stream.CanRead) throw new ArgumentException("This is not a readable stream.");
var buffer = new byte[32768];
using (var ms = new MemoryStream())
{
while (true)
{
var read = stream.Read(buffer, 0, buffer.Length);
if (read <= 0)
return ms.ToArray();
ms.Write(buffer, 0, read);
}
}
}
public static void PgpEncrypt(
this Stream toEncrypt,
Stream outStream,
PgpPublicKey encryptionKey,
bool armor = true,
bool verify = true,
CompressionAlgorithmTag compressionAlgorithm = CompressionAlgorithmTag.Zip)
{
if (armor) outStream = new ArmoredOutputStream(outStream);
var compressor = new PgpCompressedDataGenerator(CompressionAlgorithmTag.Zip);
outStream = compressor.Open(outStream);
var data = toEncrypt.ReadFully();
var encryptor = new PgpEncryptedDataGenerator(SymmetricKeyAlgorithmTag.Cast5, verify, new SecureRandom());
encryptor.AddMethod(encryptionKey);
outStream = encryptor.Open(outStream, data.Length);
outStream.Write(data, 0, data.Length);
}
My test method looks like this:
private static void EncryptMessage()
{
var pubKey = #"<public key text>";
var clearText = "This is an encrypted message. There are many like it but this one is cryptic.";
using (var stream = pubKey.Streamify())
{
var key = stream.ImportPublicKey();
using (var clearStream = clearText.Streamify())
using (var cryptoStream = new MemoryStream())
{
clearStream.PgpEncrypt(cryptoStream,key);
cryptoStream.Position = 0;
Console.WriteLine(cryptoStream.Stringify());
Console.WriteLine("Press any key to continue.");
}
}
Console.ReadKey();
}
The result I get looks like this:
-----BEGIN PGP MESSAGE-----
Version: BCPG C# v1.7.4114.6378
Press any key to continue.
Can someone tell me what I am doing wrong?
OK, I managed to get this working. There were several problems with this implementation. One problem was that certain things had to be done in order. Here is what seems to need to happen:
The raw data needs to be put into a PgpLiteralData object
The literal data needs to be encrypted.
The encrypted data needs to be compressed.
The compressed data (optionally) needs to be armored.
The underlying streams need to be closed in order of usage.
There should be a more elegant way to do this, but the streams used by the BouncyCastle library are all frustratingly one-way, and at several points, I needed to convert the stream to a byte array to get another part to work. I include the code I used and independently verified; if someone has a verifyably better way of doing this, I would be quite interested.
public static class OpenPgpUtility
{
public static void ExportKeyPair(
Stream secretOut,
Stream publicOut,
AsymmetricKeyParameter publicKey,
AsymmetricKeyParameter privateKey,
string identity,
char[] passPhrase,
bool armor)
{
if (armor)
{
secretOut = new ArmoredOutputStream(secretOut);
}
var secretKey = new PgpSecretKey(
PgpSignature.DefaultCertification,
PublicKeyAlgorithmTag.RsaGeneral,
publicKey,
privateKey,
DateTime.UtcNow,
identity,
SymmetricKeyAlgorithmTag.Cast5,
passPhrase,
null,
null,
new SecureRandom()
);
secretKey.Encode(secretOut);
if (armor)
{
secretOut.Close();
publicOut = new ArmoredOutputStream(publicOut);
}
var key = secretKey.PublicKey;
key.Encode(publicOut);
if (armor)
{
publicOut.Close();
}
}
public static PgpPublicKey ImportPublicKey(
this Stream publicIn)
{
var pubRings =
new PgpPublicKeyRingBundle(PgpUtilities.GetDecoderStream(publicIn)).GetKeyRings().OfType<PgpPublicKeyRing>();
var pubKeys = pubRings.SelectMany(x => x.GetPublicKeys().OfType<PgpPublicKey>());
var pubKey = pubKeys.FirstOrDefault();
return pubKey;
}
public static PgpSecretKey ImportSecretKey(
this Stream secretIn)
{
var secRings =
new PgpSecretKeyRingBundle(PgpUtilities.GetDecoderStream(secretIn)).GetKeyRings().OfType<PgpSecretKeyRing>();
var secKeys = secRings.SelectMany(x => x.GetSecretKeys().OfType<PgpSecretKey>());
var secKey = secKeys.FirstOrDefault();
return secKey;
}
public static Stream Streamify(this string theString, Encoding encoding = null)
{
encoding = encoding ?? Encoding.UTF8;
var stream = new MemoryStream(encoding.GetBytes(theString));
return stream;
}
public static string Stringify(this Stream theStream,
Encoding encoding = null)
{
encoding = encoding ?? Encoding.UTF8;
using (var reader = new StreamReader(theStream, encoding))
{
return reader.ReadToEnd();
}
}
public static byte[] ReadFully(this Stream stream, int position = 0)
{
if (!stream.CanRead) throw new ArgumentException("This is not a readable stream.");
if (stream.CanSeek) stream.Position = 0;
var buffer = new byte[32768];
using (var ms = new MemoryStream())
{
while (true)
{
var read = stream.Read(buffer, 0, buffer.Length);
if (read <= 0)
return ms.ToArray();
ms.Write(buffer, 0, read);
}
}
}
public static void PgpEncrypt(
this Stream toEncrypt,
Stream outStream,
PgpPublicKey encryptionKey,
bool armor = true,
bool verify = false,
CompressionAlgorithmTag compressionAlgorithm = CompressionAlgorithmTag.Zip)
{
var encryptor = new PgpEncryptedDataGenerator(SymmetricKeyAlgorithmTag.Cast5, verify, new SecureRandom());
var literalizer = new PgpLiteralDataGenerator();
var compressor = new PgpCompressedDataGenerator(compressionAlgorithm);
encryptor.AddMethod(encryptionKey);
//it would be nice if these streams were read/write, and supported seeking. Since they are not,
//we need to shunt the data to a read/write stream so that we can control the flow of data as
//we go.
using (var stream = new MemoryStream()) // this is the read/write stream
using (var armoredStream = armor ? new ArmoredOutputStream(stream) : stream as Stream)
using (var compressedStream = compressor.Open(armoredStream))
{
//data is encrypted first, then compressed, but because of the one-way nature of these streams,
//other "interim" streams are required. The raw data is encapsulated in a "Literal" PGP object.
var rawData = toEncrypt.ReadFully();
var buffer = new byte[1024];
using (var literalOut = new MemoryStream())
using (var literalStream = literalizer.Open(literalOut, 'b', "STREAM", DateTime.UtcNow, buffer))
{
literalStream.Write(rawData, 0, rawData.Length);
literalStream.Close();
var literalData = literalOut.ReadFully();
//The literal data object is then encrypted, which flows into the compressing stream and
//(optionally) into the ASCII armoring stream.
using (var encryptedStream = encryptor.Open(compressedStream, literalData.Length))
{
encryptedStream.Write(literalData, 0, literalData.Length);
encryptedStream.Close();
compressedStream.Close();
armoredStream.Close();
//the stream processes are now complete, and our read/write stream is now populated with
//encrypted data. Convert the stream to a byte array and write to the out stream.
stream.Position = 0;
var data = stream.ReadFully();
outStream.Write(data, 0, data.Length);
}
}
}
}
}
My test method looked like this:
private static void EncryptMessage()
{
var pubKey = #"<public key text here>";
var clearText = #"<message text here>";
using (var stream = pubKey.Streamify())
{
var key = stream.ImportPublicKey();
using (var clearStream = clearText.Streamify())
using (var cryptoStream = new MemoryStream())
{
clearStream.PgpEncrypt(cryptoStream, key);
cryptoStream.Position = 0;
var cryptoString = cryptoStream.Stringify();
Console.WriteLine(cryptoString);
Console.WriteLine("Press any key to continue.");
}
}
Console.ReadKey();
}
Since someone asked, my decryption algorithm looked like this:
public static Stream PgpDecrypt(
this Stream encryptedData,
string armoredPrivateKey,
string privateKeyPassword,
Encoding armorEncoding = null)
{
armorEncoding = armorEncoding ?? Encoding.UTF8;
var stream = PgpUtilities.GetDecoderStream(encryptedData);
var layeredStreams = new List<Stream> { stream }; //this is to clean up/ dispose of any layered streams.
var dataObjectFactory = new PgpObjectFactory(stream);
var dataObject = dataObjectFactory.NextPgpObject();
Dictionary<long, PgpSecretKey> secretKeys;
using (var privateKeyStream = armoredPrivateKey.Streamify(armorEncoding))
{
var secRings =
new PgpSecretKeyRingBundle(PgpUtilities.GetDecoderStream(privateKeyStream)).GetKeyRings()
.OfType<PgpSecretKeyRing>();
var pgpSecretKeyRings = secRings as PgpSecretKeyRing[] ?? secRings.ToArray();
if (!pgpSecretKeyRings.Any()) throw new ArgumentException("No secret keys found.");
secretKeys = pgpSecretKeyRings.SelectMany(x => x.GetSecretKeys().OfType<PgpSecretKey>())
.ToDictionary(key => key.KeyId, value => value);
}
while (!(dataObject is PgpLiteralData) && dataObject != null)
{
try
{
var compressedData = dataObject as PgpCompressedData;
var listedData = dataObject as PgpEncryptedDataList;
//strip away the compression stream
if (compressedData != null)
{
stream = compressedData.GetDataStream();
layeredStreams.Add(stream);
dataObjectFactory = new PgpObjectFactory(stream);
}
//strip the PgpEncryptedDataList
if (listedData != null)
{
var encryptedDataList = listedData.GetEncryptedDataObjects()
.OfType<PgpPublicKeyEncryptedData>().First();
var decryptionKey = secretKeys[encryptedDataList.KeyId]
.ExtractPrivateKey(privateKeyPassword.ToCharArray());
stream = encryptedDataList.GetDataStream(decryptionKey);
layeredStreams.Add(stream);
dataObjectFactory = new PgpObjectFactory(stream);
}
dataObject = dataObjectFactory.NextPgpObject();
}
catch (Exception ex)
{
//Log exception here.
throw new PgpException("Failed to strip encapsulating streams.", ex);
}
}
foreach (var layeredStream in layeredStreams)
{
layeredStream.Close();
layeredStream.Dispose();
}
if (dataObject == null) return null;
var literalData = (PgpLiteralData)dataObject;
var ms = new MemoryStream();
using (var clearData = literalData.GetInputStream())
{
Streams.PipeAll(clearData, ms);
}
ms.Position = 0;
return ms;
}
I've seen plenty of encryption/decryption tutorials and examples on the net in C# that use the System.Security.Cryptography.RSACryptoServiceProvider, but what I'm hoping to be able to do is:
Create an RSA public/private keypair
Transmit the public key (or for proof of concept, just move it in a string variable)
Create a new RSA crypto provider and encrypt a string with the public key
Transmit the encrypted string (or data) back to the original crypto provider and decrypt the string
Could anyone point me to a useful resource for this?
well there are really enough examples for this, but anyway, here you go
using System;
using System.Security.Cryptography;
namespace RsaCryptoExample
{
static class Program
{
static void Main()
{
//lets take a new CSP with a new 2048 bit rsa key pair
var csp = new RSACryptoServiceProvider(2048);
//how to get the private key
var privKey = csp.ExportParameters(true);
//and the public key ...
var pubKey = csp.ExportParameters(false);
//converting the public key into a string representation
string pubKeyString;
{
//we need some buffer
var sw = new System.IO.StringWriter();
//we need a serializer
var xs = new System.Xml.Serialization.XmlSerializer(typeof(RSAParameters));
//serialize the key into the stream
xs.Serialize(sw, pubKey);
//get the string from the stream
pubKeyString = sw.ToString();
}
//converting it back
{
//get a stream from the string
var sr = new System.IO.StringReader(pubKeyString);
//we need a deserializer
var xs = new System.Xml.Serialization.XmlSerializer(typeof(RSAParameters));
//get the object back from the stream
pubKey = (RSAParameters)xs.Deserialize(sr);
}
//conversion for the private key is no black magic either ... omitted
//we have a public key ... let's get a new csp and load that key
csp = new RSACryptoServiceProvider();
csp.ImportParameters(pubKey);
//we need some data to encrypt
var plainTextData = "foobar";
//for encryption, always handle bytes...
var bytesPlainTextData = System.Text.Encoding.Unicode.GetBytes(plainTextData);
//apply pkcs#1.5 padding and encrypt our data
var bytesCypherText = csp.Encrypt(bytesPlainTextData, false);
//we might want a string representation of our cypher text... base64 will do
var cypherText = Convert.ToBase64String(bytesCypherText);
/*
* some transmission / storage / retrieval
*
* and we want to decrypt our cypherText
*/
//first, get our bytes back from the base64 string ...
bytesCypherText = Convert.FromBase64String(cypherText);
//we want to decrypt, therefore we need a csp and load our private key
csp = new RSACryptoServiceProvider();
csp.ImportParameters(privKey);
//decrypt and strip pkcs#1.5 padding
bytesPlainTextData = csp.Decrypt(bytesCypherText, false);
//get our original plainText back...
plainTextData = System.Text.Encoding.Unicode.GetString(bytesPlainTextData);
}
}
}
as a side note: the calls to Encrypt() and Decrypt() have a bool parameter that switches between OAEP and PKCS#1.5 padding ... you might want to choose OAEP if it's available in your situation
public static string Encryption(string strText)
{
var publicKey = "<RSAKeyValue><Modulus>21wEnTU+mcD2w0Lfo1Gv4rtcSWsQJQTNa6gio05AOkV/Er9w3Y13Ddo5wGtjJ19402S71HUeN0vbKILLJdRSES5MHSdJPSVrOqdrll/vLXxDxWs/U0UT1c8u6k/Ogx9hTtZxYwoeYqdhDblof3E75d9n2F0Zvf6iTb4cI7j6fMs=</Modulus><Exponent>AQAB</Exponent></RSAKeyValue>";
var testData = Encoding.UTF8.GetBytes(strText);
using (var rsa = new RSACryptoServiceProvider(1024))
{
try
{
// client encrypting data with public key issued by server
rsa.FromXmlString(publicKey.ToString());
var encryptedData = rsa.Encrypt(testData, true);
var base64Encrypted = Convert.ToBase64String(encryptedData);
return base64Encrypted;
}
finally
{
rsa.PersistKeyInCsp = false;
}
}
}
public static string Decryption(string strText)
{
var privateKey = "<RSAKeyValue><Modulus>21wEnTU+mcD2w0Lfo1Gv4rtcSWsQJQTNa6gio05AOkV/Er9w3Y13Ddo5wGtjJ19402S71HUeN0vbKILLJdRSES5MHSdJPSVrOqdrll/vLXxDxWs/U0UT1c8u6k/Ogx9hTtZxYwoeYqdhDblof3E75d9n2F0Zvf6iTb4cI7j6fMs=</Modulus><Exponent>AQAB</Exponent><P>/aULPE6jd5IkwtWXmReyMUhmI/nfwfkQSyl7tsg2PKdpcxk4mpPZUdEQhHQLvE84w2DhTyYkPHCtq/mMKE3MHw==</P><Q>3WV46X9Arg2l9cxb67KVlNVXyCqc/w+LWt/tbhLJvV2xCF/0rWKPsBJ9MC6cquaqNPxWWEav8RAVbmmGrJt51Q==</Q><DP>8TuZFgBMpBoQcGUoS2goB4st6aVq1FcG0hVgHhUI0GMAfYFNPmbDV3cY2IBt8Oj/uYJYhyhlaj5YTqmGTYbATQ==</DP><DQ>FIoVbZQgrAUYIHWVEYi/187zFd7eMct/Yi7kGBImJStMATrluDAspGkStCWe4zwDDmdam1XzfKnBUzz3AYxrAQ==</DQ><InverseQ>QPU3Tmt8nznSgYZ+5jUo9E0SfjiTu435ihANiHqqjasaUNvOHKumqzuBZ8NRtkUhS6dsOEb8A2ODvy7KswUxyA==</InverseQ><D>cgoRoAUpSVfHMdYXW9nA3dfX75dIamZnwPtFHq80ttagbIe4ToYYCcyUz5NElhiNQSESgS5uCgNWqWXt5PnPu4XmCXx6utco1UVH8HGLahzbAnSy6Cj3iUIQ7Gj+9gQ7PkC434HTtHazmxVgIR5l56ZjoQ8yGNCPZnsdYEmhJWk=</D></RSAKeyValue>";
var testData = Encoding.UTF8.GetBytes(strText);
using (var rsa = new RSACryptoServiceProvider(1024))
{
try
{
var base64Encrypted = strText;
// server decrypting data with private key
rsa.FromXmlString(privateKey);
var resultBytes = Convert.FromBase64String(base64Encrypted);
var decryptedBytes = rsa.Decrypt(resultBytes, true);
var decryptedData = Encoding.UTF8.GetString(decryptedBytes);
return decryptedData.ToString();
}
finally
{
rsa.PersistKeyInCsp = false;
}
}
}
Honestly, I have difficulty implementing it because there's barely any tutorials I've searched that displays writing the keys into the files. The accepted answer was "fine". But for me I had to improve it so that both keys gets saved into two separate files. I've written a helper class so y'all just gotta copy and paste it. Hope this helps lol.
using Microsoft.Win32;
using System;
using System.IO;
using System.Security.Cryptography;
namespace RsaCryptoExample
{
class RSAFileHelper
{
readonly string pubKeyPath = "public.key";//change as needed
readonly string priKeyPath = "private.key";//change as needed
public void MakeKey()
{
//lets take a new CSP with a new 2048 bit rsa key pair
RSACryptoServiceProvider csp = new RSACryptoServiceProvider(2048);
//how to get the private key
RSAParameters privKey = csp.ExportParameters(true);
//and the public key ...
RSAParameters pubKey = csp.ExportParameters(false);
//converting the public key into a string representation
string pubKeyString;
{
//we need some buffer
var sw = new StringWriter();
//we need a serializer
var xs = new System.Xml.Serialization.XmlSerializer(typeof(RSAParameters));
//serialize the key into the stream
xs.Serialize(sw, pubKey);
//get the string from the stream
pubKeyString = sw.ToString();
File.WriteAllText(pubKeyPath, pubKeyString);
}
string privKeyString;
{
//we need some buffer
var sw = new StringWriter();
//we need a serializer
var xs = new System.Xml.Serialization.XmlSerializer(typeof(RSAParameters));
//serialize the key into the stream
xs.Serialize(sw, privKey);
//get the string from the stream
privKeyString = sw.ToString();
File.WriteAllText(priKeyPath, privKeyString);
}
}
public void EncryptFile(string filePath)
{
//converting the public key into a string representation
string pubKeyString;
{
using (StreamReader reader = new StreamReader(pubKeyPath)){pubKeyString = reader.ReadToEnd();}
}
//get a stream from the string
var sr = new StringReader(pubKeyString);
//we need a deserializer
var xs = new System.Xml.Serialization.XmlSerializer(typeof(RSAParameters));
//get the object back from the stream
RSACryptoServiceProvider csp = new RSACryptoServiceProvider();
csp.ImportParameters((RSAParameters)xs.Deserialize(sr));
byte[] bytesPlainTextData = File.ReadAllBytes(filePath);
//apply pkcs#1.5 padding and encrypt our data
var bytesCipherText = csp.Encrypt(bytesPlainTextData, false);
//we might want a string representation of our cypher text... base64 will do
string encryptedText = Convert.ToBase64String(bytesCipherText);
File.WriteAllText(filePath,encryptedText);
}
public void DecryptFile(string filePath)
{
//we want to decrypt, therefore we need a csp and load our private key
RSACryptoServiceProvider csp = new RSACryptoServiceProvider();
string privKeyString;
{
privKeyString = File.ReadAllText(priKeyPath);
//get a stream from the string
var sr = new StringReader(privKeyString);
//we need a deserializer
var xs = new System.Xml.Serialization.XmlSerializer(typeof(RSAParameters));
//get the object back from the stream
RSAParameters privKey = (RSAParameters)xs.Deserialize(sr);
csp.ImportParameters(privKey);
}
string encryptedText;
using (StreamReader reader = new StreamReader(filePath)) { encryptedText = reader.ReadToEnd(); }
byte[] bytesCipherText = Convert.FromBase64String(encryptedText);
//decrypt and strip pkcs#1.5 padding
byte[] bytesPlainTextData = csp.Decrypt(bytesCipherText, false);
//get our original plainText back...
File.WriteAllBytes(filePath, bytesPlainTextData);
}
}
}
I'll share my very simple code for sample purpose. Hope it will help someone like me searching for quick code reference.
My goal was to receive rsa signature from backend, then validate against input string using public key and store locally for future periodic verifications.
Here is main part used for signature verification:
...
var signature = Get(url); // base64_encoded signature received from server
var inputtext= "inputtext"; // this is main text signature was created for
bool result = VerifySignature(inputtext, signature);
...
private bool VerifySignature(string input, string signature)
{
var result = false;
using (var cps=new RSACryptoServiceProvider())
{
// converting input and signature to Bytes Arrays to pass to VerifyData rsa method to verify inputtext was signed using privatekey corresponding to public key we have below
byte[] inputtextBytes = Encoding.UTF8.GetBytes(input);
byte[] signatureBytes = Convert.FromBase64String(signature);
cps.FromXmlString("<RSAKeyValue><Modulus>....</Modulus><Exponent>....</Exponent></RSAKeyValue>"); // xml formatted publickey
result = cps.VerifyData(inputtextBytes , new SHA1CryptoServiceProvider(), signatureBytes );
}
return result;
}
for big data
public class RsaService : System.IDisposable
{
public delegate int TransformBlockCall(System.ReadOnlySpan<byte> data, System.Span<byte> destination);
private readonly RSA _encoder;
private readonly RSAEncryptionPadding _padding;
private readonly TransformBlockCall _encryptBlockCall;
private readonly TransformBlockCall _decryptBlockCall;
private int _encrypt_InputBlockSize;
private int _encrypt_OutputBlockSize;
private int _decrypt_InputBlockSize;
private int _decrypt_OutputBlockSize;
public RsaService(RSA encoder) {
if(encoder == null)
throw new System.ArgumentNullException(nameof(encoder));
_encoder = encoder;
_padding = RSAEncryptionPadding.Pkcs1;
_encryptBlockCall = new TransformBlockCall(EncryptBlock);
_decryptBlockCall = new TransformBlockCall(DecryptBlock);
OnEndSetParameters();
}
private void OnEndSetParameters() {
_encrypt_InputBlockSize = GetSizeOutputEncryptOfKeySize(_encoder.KeySize);
_encrypt_OutputBlockSize = _encoder.KeySize / 8;
_decrypt_InputBlockSize = _encrypt_OutputBlockSize;
_decrypt_OutputBlockSize = _encrypt_OutputBlockSize;
}
public void ImportParameters(RSAParameters parameters) {
_encoder.ImportParameters(parameters);
OnEndSetParameters();
}
public byte[] Encrypt(byte[] data) {
if(data == null) throw new System.ArgumentNullException(nameof(data));
if(data.Length == 0) return data;
int outputLength = GetEncryptOutputMaxByteCount(data.Length);
byte[] outputData = new byte[outputLength];
Encrypt(data, outputData);
return outputData;
}
public byte[] Decrypt(byte[] data) {
if(data == null) throw new System.ArgumentNullException(nameof(data));
if(data.Length == 0) return data;
int maxOutputLength = GetDecryptOutputMaxByteCount(data.Length);
byte[] outputData = new byte[maxOutputLength];
int actual_OutputLength = Decrypt(data, outputData);
if(maxOutputLength > actual_OutputLength)
System.Array.Resize(ref outputData, actual_OutputLength);
return outputData;
}
public int Encrypt(System.ReadOnlySpan<byte> data, System.Span<byte> destination) {
#if DEBUG
int inputBlockSize = _encrypt_InputBlockSize;
int outputBlockSize = _encoder.KeySize / 8;
int blockCount = (data.Length / inputBlockSize);
if(data.Length % inputBlockSize != 0)
blockCount++;
System.Diagnostics.Debug.Assert((blockCount * outputBlockSize) <= destination.Length);
#endif
if(data.Length > _encrypt_InputBlockSize)
return TransformFinal(_encryptBlockCall, data, destination, _encrypt_InputBlockSize);
else
return _encryptBlockCall(data, destination);
}
public int Decrypt(System.ReadOnlySpan<byte> data, System.Span<byte> destination) {
if(data.Length > _decrypt_InputBlockSize)
return TransformFinal(_decryptBlockCall, data, destination, _decrypt_InputBlockSize);
else
return _decryptBlockCall(data, destination);
}
private int EncryptBlock(System.ReadOnlySpan<byte> data, System.Span<byte> destination) => _encoder.Encrypt(data, destination, _padding);
private int DecryptBlock(System.ReadOnlySpan<byte> data, System.Span<byte> destination) => _encoder.Decrypt(data, destination, _padding);
public int GetEncryptOutputMaxByteCount(int inputCount) => GetBlockCount(inputCount, _encrypt_InputBlockSize) * _encrypt_OutputBlockSize;
public int GetDecryptOutputMaxByteCount(int inputCount) => GetBlockCount(inputCount, _decrypt_InputBlockSize) * _decrypt_OutputBlockSize;
public void Dispose() {
_encoder.Dispose();
System.GC.SuppressFinalize(this);
}
#region Methods_Helper
public static RsaService Create(RSAParameters parameters) => new RsaService(RSA.Create(parameters));
public static RsaService Create() => new RsaService(RSA.Create());
// [keySize] ÷ 8 - [11 bytes for padding] = Result
// Exsimple: [2048 key size] ÷ 8 - [11 bytes for padding] = 245
public static int GetSizeOutputEncryptOfKeySize(int keySize) => (keySize / 8) - 11;
private static int GetBlockCount(int dataLength,int inputBlockSize) {
int blockCount = (dataLength / inputBlockSize);
if(dataLength % inputBlockSize != 0)
blockCount++;
return blockCount;
}
public static int TransformFinal(TransformBlockCall transformBlockCall, System.ReadOnlySpan<byte> data, System.Span<byte> destination, int inputBlockSize) {
int blockCount = GetBlockCount(data.Length, inputBlockSize);
int data_writtenCount = 0;
int destination_writtenCount = 0;
while(blockCount-- > 0) {
if(blockCount == 0) {
inputBlockSize = data.Length - data_writtenCount;
if(inputBlockSize == 0) break;
}
destination_writtenCount += transformBlockCall(data: data.Slice(data_writtenCount, inputBlockSize)
, destination: destination.Slice(destination_writtenCount));
data_writtenCount += inputBlockSize;
}
return destination_writtenCount;
}
public static (RSAParameters keyPublic, RSAParameters keyPrivate) GenerateKeyPair(int keySize = 2048) {
RSAParameters keyPriv;
RSAParameters keyPub;
using(var rsa = RSA.Create(keySize)) {
keyPriv = rsa.ExportParameters(true);
keyPub = rsa.ExportParameters(false);
}
return (keyPub, keyPriv);
}
#endregion Methods_Helper
}
public static class Program
{
static void Main() {
var (keyPublic, keyPrivate) = RsaService.GenerateKeyPair();
var encryptor = RsaService.Create(keyPublic);
var decryptor = RsaService.Create(keyPrivate);
string originalText = "";
for(int i = 0; i < 1000; i++) {
originalText += "ABC123456789";
}
byte[] inputData = Encoding.UTF8.GetBytes(originalText); // data random for test
System.Console.WriteLine("inputData.Length: {0}", inputData.Length);
var encryptedData = encryptor.Encrypt(inputData);
System.Console.WriteLine("encryptedData.Length: {0}", encryptedData.Length);
byte[] decryptedData = decryptor.Decrypt(encryptedData);
string decryptedText = Encoding.UTF8.GetString(decryptedData);
System.Console.WriteLine("status: {0}", decryptedText == originalText);
}
}