PGPainless is an easy-to-use OpenPGP library for Java and Android applications
PGPainless aims to make using OpenPGP in Java projects as simple as possible. It does so by introducing an intuitive Builder structure, which allows easy setup of encryption/decryption operations, as well as straight forward key generation.
PGPainless is based around the Bouncy Castle java library and can be used on Android down to API level 10. It can be configured to either use the Java Cryptographic Engine (JCE), or Bouncy Castles lightweight reimplementation.
While signature verification in Bouncy Castle is limited to signature correctness, PGPainless goes much further. It also checks if signing subkeys are properly bound to their primary key, if keys are expired or revoked, as well as if keys are allowed to create signatures in the first place.
These rigorous checks make PGPainless stand out from other Java-based OpenPGP libraries and are the reason why PGPainless currently scores first place on Sequoia-PGPs Interoperability Test-Suite.
At FlowCrypt we are using PGPainless in our Kotlin code bases on Android and on server side. The ergonomics of legacy PGP tooling on Java is not very good, and PGPainless improves it greatly. We were so happy with our initial tests and with Paul - the maintainer, that we decided to sponsor further development of this library.
-Tom @ FlowCrypt.com
Finally, testing irrefutably confirmed that the library removes many associated difficulties with PGP use in its provision of an approachable and uncomplicated API. In this regard, Paul Schaub deserves the utmost praise.
-Mario @ Cure53.de
The very easiest way to start using OpenPGP on Java/Kotlin based systems is to use an implementation of sop-java.
sop-java
defines a very stripped down API and is super easy to get started with.
Luckily PGPainless provides an implementation for the sop-java
interface definitions in the form of pgpainless-sop.
If you need more flexibility, directly using pgpainless-core
is the way to go.
Most of PGPainless' features can be accessed directly from the PGPainless
class.
If you want to get started, this class is your friend :)
For further details you should check out the javadoc!
Reading keys from ASCII armored strings or from binary files is easy:
String key = "-----BEGIN PGP PRIVATE KEY BLOCK-----\n"...
PGPSecretKeyRing secretKey = PGPainless.readKeyRing()
.secretKeyRing(key);
Similarly, keys can quickly be exported::
PGPSecretKeyRing secretKey = ...;
String armored = PGPainless.asciiArmor(secretKey);
ByteArrayOutputStream binary = new ByteArrayOutputStream();
secretKey.encode(binary);
Extract a public key certificate from a secret key:
PGPSecretKeyRing secretKey = ...;
PGPPublicKeyRing certificate = PGPainless.extractCertificate(secretKey);
PGPainless comes with a simple to use KeyRingBuilder
class that helps you to quickly generate modern OpenPGP keys.
There are some predefined key archetypes, but it is possible to fully customize key generation to your needs.
// RSA key without additional subkeys
PGPSecretKeyRing secretKeys = PGPainless.generateKeyRing()
.simpleRsaKeyRing("Juliet <[email protected]>", RsaLength._4096);
// EdDSA primary key with EdDSA signing- and XDH encryption subkeys
PGPSecretKeyRing secretKeys = PGPainless.generateKeyRing()
.modernKeyRing("Romeo <[email protected]>", "I defy you, stars!");
// Customized key
PGPSecretKeyRing keyRing = PGPainless.buildKeyRing()
.setPrimaryKey(KeySpec.getBuilder(
RSA.withLength(RsaLength._8192),
KeyFlag.SIGN_DATA, KeyFlag.CERTIFY_OTHER))
.addSubkey(
KeySpec.getBuilder(ECDSA.fromCurve(EllipticCurve._P256), KeyFlag.SIGN_DATA)
.overrideCompressionAlgorithms(CompressionAlgorithm.ZLIB)
).addSubkey(
KeySpec.getBuilder(
ECDH.fromCurve(EllipticCurve._P256),
KeyFlag.ENCRYPT_COMMS, KeyFlag.ENCRYPT_STORAGE)
).addUserId("Juliet <[email protected]>")
.addUserId("xmpp:[email protected]")
.setPassphrase(Passphrase.fromPassword("romeo_oh_Romeo<3"))
.build();
PGPainless makes it easy and painless to encrypt and/or sign data. Passed in keys are automatically evaluated, so that you don't accidentally encrypt to revoked or expired keys. PGPainless will furthermore detect which algorithms are supported by recipient keys and will negotiate algorithms accordingly. Still it allows you to manually specify which algorithms to use of course.
EncryptionStream encryptionStream = PGPainless.encryptAndOrSign()
.onOutputStream(outputStream)
.withOptions(
ProducerOptions.signAndEncrypt(
new EncryptionOptions()
.addRecipient(aliceKey)
.addRecipient(bobsKey)
// optionally encrypt to a passphrase
.addPassphrase(Passphrase.fromPassword("password123"))
// optionally override symmetric encryption algorithm
.overrideEncryptionAlgorithm(SymmetricKeyAlgorithm.AES_192),
new SigningOptions()
// Sign in-line (using one-pass-signature packet)
.addInlineSignature(secretKeyDecryptor, aliceSecKey, signatureType)
// Sign using a detached signature
.addDetachedSignature(secretKeyDecryptor, aliceSecKey, signatureType)
// optionally override hash algorithm
.overrideHashAlgorithm(HashAlgorithm.SHA256)
).setAsciiArmor(true) // Ascii armor or not
);
Streams.pipeAll(plaintextInputStream, encryptionStream);
encryptionStream.close();
// Information about the encryption (algorithms, detached signatures etc.)
EncryptionResult result = encryptionStream.getResult();
Decrypting data and verifying signatures is being done similarly.
PGPainless will not only verify correctness of signatures, but also if the signing key was allowed to create the signature.
A key might not be allowed to create signatures if, for example, it expired or was revoked, or was not properly bound to the key ring.
Furthermore, PGPainless will reject signatures made using weak algorithms like SHA-1.
This behaviour can be modified though using the Policy
class.
DecryptionStream decryptionStream = PGPainless.decryptAndOrVerify()
.onInputStream(encryptedInputStream)
.withOptions(new ConsumerOptions()
.addDecryptionKey(bobSecKeys, secretKeyProtector)
.addVerificationCert(alicePubKeys)
);
Streams.pipeAll(decryptionStream, outputStream);
decryptionStream.close();
// Result contains information like signature status etc.
MessageMetadata metadata = decryptionStream.getMetadata();
After the DecryptionStream
was closed, you can get metadata about the processed data by retrieving the MessageMetadata
.
Again, this object will contain information about how the message was encrypted, who signed it and so on.
Many more examples can be found in the examples package!!!
PGPainless is available on maven central. In order to include it in your project, just add the maven central repository and add PGPainless as a dependency.
repositories {
mavenCentral()
}
dependencies {
implementation 'org.pgpainless:pgpainless-core:1.6.6'
}
Do you need a custom feature? Are you unsure of what's the best way to integrate PGPainless into your product? We offer paid professional services. Don't hesitate to send an inquiry to [email protected].
Join the projects IRC channel #pgpainless on OFTC if you have any questions!
PGPainless is developed in - and accepts contributions from - the following places:
We are using SemVer (MAJOR.MINOR.PATCH) versioning, although MINOR releases could contain breaking changes from time to time.
If you want to contribute a bug fix, please check the release/X.Y
branches first to see, what the oldest release is
which contains the bug you are fixing. That way we can update older revisions of the library easily.
Please follow the code of conduct if you want to be part of the project.
Development on PGPainless is generously sponsored by FlowCrypt.com. Thank you very very very much!
Parts of PGPainless development (project page) will be funded by NGI Assure through NLNet.
NGI Assure is made possible with financial support from the European Commission's Next Generation Internet programme, under the aegis of DG Communications Networks, Content and Technology.
Thanks to YourKit for providing a free license of the YourKit Java Profiler to support PGPainless Development!
Big thank you also to those who decided to support the work by donating!
Notably @msfjarvis
You make my day!