Java
Java
RSA Encrypt Hash using SHA256 hash function and SHA1 mask function
See more RSA Examples
How can this Javascript be duplicated using Chilkat?
function a(e, t) {
var r = s.pki.publicKeyFromPem(e)
, n = r.encrypt(t, "RSA-OAEP", {
md: s.md.sha256.create(),
mgf1: {
md: s.md.sha1.create()
}
});
return s.util.encode64(n)
}
Note: The OAEP padding uses random bytes in the padding, and therefore each time encryption happens, even using the same data and key, the result will be different -- but still valid. One should not expect to get the same output.
Chilkat Java Downloads
import com.chilkatsoft.*;
public class ChilkatExample {
static {
try {
System.loadLibrary("chilkat");
} catch (UnsatisfiedLinkError e) {
System.err.println("Native code library failed to load.\n" + e);
System.exit(1);
}
}
public static void main(String argv[])
{
boolean success = false;
// This example requires the Chilkat API to have been previously unlocked.
// See Global Unlock Sample for sample code.
CkPublicKey pubkey = new CkPublicKey();
CkStringBuilder sbPem = new CkStringBuilder();
boolean bCrlf = true;
sbPem.AppendLine("-----BEGIN PUBLIC KEY-----",bCrlf);
sbPem.AppendLine("MIIBIjANBgkqhkiG9w0BAQEFAAOCAQ8AMIIBCgKCAQEA33TqqLR3eeUmDtHS89qF",bCrlf);
sbPem.AppendLine("3p4MP7Wfqt2Zjj3lZjLjjCGDvwr9cJNlNDiuKboODgUiT4ZdPWbOiMAfDcDzlOxA",bCrlf);
sbPem.AppendLine("04DDnEFGAf+kDQiNSe2ZtqC7bnIc8+KSG/qOGQIVaay4Ucr6ovDkykO5Hxn7OU7s",bCrlf);
sbPem.AppendLine("Jp9TP9H0JH8zMQA6YzijYH9LsupTerrY3U6zyihVEDXXOv08vBHk50BMFJbE9iwF",bCrlf);
sbPem.AppendLine("wnxCsU5+UZUZYw87Uu0n4LPFS9BT8tUIvAfnRXIEWCha3KbFWmdZQZlyrFw0buUE",bCrlf);
sbPem.AppendLine("f0YN3/Q0auBkdbDR/ES2PbgKTJdkjc/rEeM0TxvOUf7HuUNOhrtAVEN1D5uuxE1W",bCrlf);
sbPem.AppendLine("SwIDAQAB",bCrlf);
sbPem.AppendLine("-----END PUBLIC KEY-----",bCrlf);
// Load the public key object from the PEM.
success = pubkey.LoadFromString(sbPem.getAsString());
if (success == false) {
System.out.println(pubkey.lastErrorText());
return;
}
String originalData = "This is the original data to be SHA-256 hashed and RSA encrypted.";
// First we SHA-256 hash the original data to get the hash in base64 format:
CkCrypt2 crypt = new CkCrypt2();
crypt.put_HashAlgorithm("SHA-256");
crypt.put_EncodingMode("base64");
String hashBase64 = crypt.hashStringENC(originalData);
// Setup RSA to use OAEP padding with SHA-1 for the mask function.
CkRsa rsa = new CkRsa();
rsa.put_PkcsPadding(false);
rsa.put_OaepHash("SHA256");
rsa.UsePublicKey(pubkey);
rsa.put_EncodingMode("base64");
// We can provide a binary encoding mode, such as "base64", "hex", "base64url", etc.
// for the Charset property. The Charset property was previously limited to character encodings, such as
// "utf-8", "iso-8859-1", etc. If a binary encoding is used, then the string passed in is decoded to the binary
// bytes as indicated. (If an actual charset, such as "utf-8" is used, then the input string is converted to the
// byte representation of the charset, and then encrypted.)
// Given that a hash is composed of non-text binary bytes, we'll set the Charset property equal to "base64"
// (because we have the base64 hash from above).
rsa.put_Charset("base64");
// Note: The OAEP padding uses random bytes in the padding, and therefore each time encryption happens,
// even using the same data and key, the result will be different -- but still valid. One should not expect
// to get the same output.
boolean bUsePrivateKey = false;
String encryptedStr = rsa.encryptStringENC(hashBase64,bUsePrivateKey);
if (rsa.get_LastMethodSuccess() == false) {
System.out.println(rsa.lastErrorText());
return;
}
System.out.println("Base64 RSA encrypted output: " + encryptedStr);
}
}