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490 lines
No EOL
19 KiB
Markdown
490 lines
No EOL
19 KiB
Markdown
## PGPainless API with pgpainless-core
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The `pgpainless-core` module contains the bulk of the actual OpenPGP implementation.
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This is a quickstart guide. For more in-depth exploration of the API, checkout [](indepth.md).
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:::{note}
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This chapter is work in progress.
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:::
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### Setup
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PGPainless' releases are published to and can be fetched from Maven Central.
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To get started, you first need to include `pgpainless-core` in your projects build script:
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```
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// If you use Gradle
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...
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dependencies {
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...
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implementation "org.pgpainless:pgpainless-core:XYZ"
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...
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}
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// If you use Maven
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...
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<dependencies>
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...
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<dependency>
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<groupId>org.pgpainless</groupId>
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<artifactId>pgpainless-core</artifactId>
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<version>XYZ</version>
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</dependency>
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...
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</dependencies>
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```
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This will automatically pull in PGPainless' dependencies, such as Bouncy Castle.
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:::{important}
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Replace `XYZ` with the current version, in this case {{ env.config.version }}!
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:::
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The entry point to the API is the `PGPainless` class.
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For many common use-cases, examples can be found in the
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{{ '[examples package](https://{}/main/pgpainless-core/src/test/java/org/pgpainless/example)'.format(repo_pgpainless_src) }}.
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There is a very good chance that you can find code examples there that fit your needs.
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### Read and Write Keys
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Reading keys from ASCII armored strings or from binary files is easy:
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```java
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String key = "-----BEGIN PGP PRIVATE KEY BLOCK-----\n"...;
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PGPSecretKeyRing secretKey = PGPainless.readKeyRing()
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.secretKeyRing(key);
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```
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Similarly, keys or certificates can quickly be exported:
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```java
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// ASCII armored key
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PGPSecretKeyRing secretKey = ...;
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String armored = PGPainless.asciiArmor(secretKey);
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// binary (unarmored) key
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byte[] binary = secretKey.getEncoded();
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```
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### Generate a Key
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PGPainless comes with a method to quickly generate modern OpenPGP keys.
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There are some predefined key archetypes, but it is possible to fully customize the key generation to fit your needs.
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```java
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// EdDSA primary key with EdDSA signing- and XDH encryption subkeys
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PGPSecretKeyRing secretKeys = PGPainless.generateKeyRing()
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.modernKeyRing("Romeo <romeo@montague.lit>", "thisIsAPassword");
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// RSA key without additional subkeys
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PGPSecretKeyRing secretKeys = PGPainless.generateKeyRing()
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.simpleRsaKeyRing("Juliet <juliet@montague.lit>", RsaLength._4096);
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```
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As you can see, it is possible to generate all kinds of different keys.
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### Extract a Certificate
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If you have a secret key, you might want to extract a public key certificate from it:
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```java
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PGPSecretKeyRing secretKey = ...;
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PGPPublicKeyRing certificate = PGPainless.extractCertificate(secretKey);
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```
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### Apply / Remove ASCII Armor
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ASCII armor is a layer of radix64 encoding that can be used to wrap binary OpenPGP data in order to make it save to
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transport via text-based channels (e.g. email bodies).
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The way in which ASCII armor can be applied depends on the type of data that you want to protect.
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The easies way to ASCII armor an OpenPGP key or certificate is by using PGPainless' `asciiArmor()` method:
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```java
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PGPPublicKey certificate = ...;
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String asciiArmored = PGPainless.asciiArmor(certificate);
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```
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If you want to ASCII armor ciphertext, you can enable ASCII armoring during encrypting/signing by requesting
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PGPainless to armor the result:
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```java
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ProducerOptions producerOptions = ...; // prepare as usual (see next section)
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producerOptions.setAsciiArmor(true); // enable armoring
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EncryptionStream encryptionStream = PGPainless.encryptAndOrSign()
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.onOutputStream(out)
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.withOptions(producerOptions);
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...
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```
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If you have an already encrypted / signed binary message and want to add ASCII armoring retrospectively, you need
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to make use of BouncyCastle's `ArmoredOutputStream` as follows:
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```java
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InputStream binaryOpenPgpIn = ...; // e.g. new ByteArrayInputStream(binaryMessage);
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OutputStream output = ...; // e.g. new ByteArrayOutputStream();
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ArmoredOutputStream armorOut = ArmoredOutputStreamFactory.get(output);
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Streams.pipeAll(binaryOpenPgpIn, armorOut);
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armorOut.close(); // important!
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```
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The output stream will now contain the ASCII armored representation of the binary data.
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If the data you want to wrap in ASCII armor is non-OpenPGP data (e.g. the String "Hello World!"),
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you need to use the following code:
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```java
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InputStream inputStream = ...;
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OutputStream output = ...;
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EncryptionStream armorStream = PGPainless.encryptAndOrSign()
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.onOutputStream(output)
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.withOptions(ProducerOptions.noEncryptionNoSigning()
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.setAsciiArmor(true));
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Streams.pipeAll(inputStream, armorStream);
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armorStream.close();
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```
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To remove ASCII armor, you can make use of BouncyCastle's `ArmoredInputStream` as follows:
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```java
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InputStream input = ...; // e.g. new ByteArrayInputStream(armoredString.getBytes(StandardCharsets.UTF8));
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OutputStream output = ...;
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ArmoredInputStream armorIn = new ArmoredInputStream(input);
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Streams.pipeAll(armorIn, output);
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armorIn.close();
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```
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The output stream will now contain the binary OpenPGP data.
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### Encrypt and/or Sign a Message
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Encrypting and signing messages is done using the same API in PGPainless.
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The type of action depends on the configuration of the `ProducerOptions` class, which in term accepts
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`SigningOptions` and `EncryptionOptions` objects:
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```java
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// Encrypt only
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ProducerOptions options = ProducerOptions.encrypt(encryptionOptions);
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// Sign only
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ProducerOptions options = ProducerOptions.sign(signingOptions);
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// Sign and encrypt
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ProducerOptions options = ProducerOptions.signAndEncrypt(signingOptions, encryptionOptions);
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```
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The `ProducerOptions` object can then be passed into the `encryptAndOrSign()` API:
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```java
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InputStream plaintext = ...; // The data that shall be encrypted and/or signed
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OutputStream ciphertext = ...; // Destination for the ciphertext
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EncryptionStream encryptionStream = PGPainless.encryptAndOrSign()
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.onOutputStream(ciphertext)
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.withOptions(options); // pass in the options object
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Streams.pipeAll(plaintext, encryptionStream); // pipe the data through
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encryptionStream.close(); // important! Close the stream to finish encryption/signing
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EncryptionResult result = encryptionStream.getResult(); // metadata
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```
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The `ciphertext` output stream now contains the encrypted and/or signed data.
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Now lets take a look at the configuration of the `SigningOptions` object and how to instruct PGPainless to add a simple
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signature to the message:
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```java
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PGPSecretKeyRing signingKey = ...; // Key used for signing
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SecretKeyRingProtector protector = ...; // Protector to unlock the signing key
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SigningOptions signOptions = SigningOptions.get()
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.addSignature(protector, signingKey);
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```
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This will add an inline signature to the message.
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It is possible to add multiple signatures from different keys by repeating the `addSignature()` method call.
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If instead of an inline signature, you want to create a detached signature instead (e.g. because you do not want
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to alter the data you are signing), you can add the signature as follows:
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```java
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signOptions.addDetachedSignature(protector, signingKey);
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```
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Passing in the `SigningOptions` object like this will result in the signature not being added to the message itself.
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Instead, the signature can later be acquired from the `EncryptionResult` object via `EncryptionResult.getDetachedSignatures()`.
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That way, it can be distributed independent of the message.
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The `EncryptionOptions` object can be configured in a similar way:
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```java
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PGPPublicKey certificate = ...;
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EncryptionOptions encOptions = EncryptionOptions.get()
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.addRecipient(certificate);
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```
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Once again, it is possible to add multiple recipients by repeating the `addRecipient()` method call.
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You can also encrypt a message to a password like this:
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```java
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encOptions.addPassphrase(Passphrase.fromPassword("sw0rdf1sh"));
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```
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Both methods can be used in combination to create a message which can be decrypted with either a recipients secret key
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or the passphrase.
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### Decrypt and/or Verify a Message
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Decryption and verification of a message is both done using the same API.
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Whether a message was actually signed / encrypted can be determined after the message has been processed by checking
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the `MessageMetadata` object which can be obtained from the `DecryptionStream`.
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To configure the decryption / verification process, the `ConsumerOptions` object is used:
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```java
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PGPPublicKeyRing verificationCert = ...; // optional, signers certificate for signature verification
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PGPSecretKeyRing decryptionKey = ...; // optional, decryption key
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ConsumerOptions options = ConsumerOptions.get()
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.addVerificationCert(verificationCert) // add a verification cert for signature verification
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.addDecryptionKey(decryptionKey); // add a secret key for message decryption
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```
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Both verification certificates and decryption keys are optional.
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If you know the message is signed, but not encrypted you can omit providing a decryption key.
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Same goes for if you know that the message is encrypted, but not signed.
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In this case you can omit the verification certificate.
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On the other hand, providing these parameters does not hurt.
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PGPainless will ignore unused keys / certificates, so if you provide a decryption key and the message is not encrypted,
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nothing bad will happen.
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It is possible to provide multiple verification certs and decryption keys. PGPainless will pick suitable ones on the fly.
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If the message is signed with key `0xAAAA` and you provide certificates `0xAAAA` and `0xBBBB`, it will verify
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with cert `0xAAAA` and ignore `0xBBBB`.
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To do the actual decryption / verification of the message, do the following:
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```java
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InputStream ciphertext = ...; // encrypted and/or signed message
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OutputStream plaintext = ...; // destination for the plaintext
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ConsumerOptions options = ...; // see above
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DecryptionStream consumerStream = PGPainless.decryptAndOrVerify()
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.onInputStream(ciphertext)
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.withOptions(options);
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Streams.pipeAll(consumerStream, plaintext);
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consumerStream.close(); // important!
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// The result will contain metadata of the message
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MessageMetadata result = consumerStream.getMetadata();
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```
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After the message has been processed, you can consult the `MessageMetadata` object to determine the nature of the message:
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```java
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boolean wasEncrypted = result.isEncrypted();
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SubkeyIdentifier decryptionKey = result.getDecryptionKey();
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List<SignatureVerification> validSignatures = result.getVerifiedSignatures();
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boolean wasSignedByCert = result.isVerifiedSignedBy(certificate);
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// For files:
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String fileName = result.getFileName();
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Date modificationData = result.getModificationDate();
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```
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### Verify a Signature
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In some cases, detached signatures are distributed alongside the message.
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This is the case for example with Debians `Release` and `Release.gpg` files.
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Here, `Release` is the plaintext message, which is unaltered by the signing process while `Release.gpg` contains
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the detached OpenPGP signature.
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To verify a detached signature, you need to call the PGPainless API like this:
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```java
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InputStream plaintext = ...; // e.g. new FileInputStream(releaseFile);
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InputStream detachedSignature = ...; // e.g. new FileInputStream(releaseGpgFile);
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PGPPublicKeyRing certificate = ...; // e.g. debians public signing key
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ConsumerOptions options = ConsumerOptions.get()
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.addVerificationCert(certificate) // provide certificate for verification
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.addVerificationOfDetachedSignatures(detachedSignature) // provide detached signature
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DecryptionStream verificationStream = PGPainless.decryptAndOrVerify()
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.onInputStream(plaintext)
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.withOptions(options);
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Streams.drain(verificationStream); // push all the data through the stream
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verificationStream.close(); // finish verification
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MessageMetadata result = verificationStream.getMetadata(); // get metadata of signed message
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assertTrue(result.isVerifiedSignedBy(certificate)); // check if message was in fact signed
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```
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### Legacy Compatibility
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Out of the box, PGPainless is configured to use secure defaults and perform checks for recommended
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security features. This means that for example messages generated using older OpenPGP
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implementations which do not follow those best practices might fail to decrypt/verify.
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It is however possible to circumvent certain security checks to allow processing of such messages.
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:::{note}
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It is not recommended to disable security checks, as that might enable certain attacks on the OpenPGP protocol.
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:::
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#### Missing / broken MDC (modification detection code)
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RFC4880 has two different types of encrypted data packets. The *Symmetrically Encrypted Data* packet (SED) and the *Symmetrically Encrypted Integrity-Protected Data* packet.
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The latter has an added MDC packet which prevents modifications to the ciphertext.
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While implementations are highly encouraged to only use the latter package type, some older implementations still generate
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encrypted data packets which are not integrity protected.
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To allow PGPainless to decrypt such messages, you need to set a flag in the `ConsumerOptions` object:
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```java
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ConsumerOptions options = ConsumerOptions.get()
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.setIgnoreMDCErrors(true) // <-
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.setDecryptionKey(secretKey)
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...
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DecryptionStream decryptionStream = PGPainless.decryptAndOrVerify()
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.onInputStream(ciphertextIn)
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.withOptions(options);
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...
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```
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:::{note}
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It is highly advised to only set this flag if you know what you are doing.
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It might also be a good idea to try decrypting a message without the flag set first and only re-try
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decryption with the flag set in case of a `MessageNotIntegrityProtectedException` (don't forget to rewind the ciphertextInputStream).
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:::
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#### Weak keys and broken algorithms
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Some users might cling on to older keys using weak algorithms / small key sizes.
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PGPainless refuses to encrypt to weak certificates and sign with weak keys.
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By default, PGPainless follows the recommendations for acceptable key sizes of [the German BSI in 2021](https://www.bsi.bund.de/SharedDocs/Downloads/EN/BSI/Publications/TechGuidelines/TG02102/BSI-TR-02102-1.pdf).
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It can however be configured to accept older key material / algorithms too.
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Minimal key lengths can be configured by changing PGPainless' policy:
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```java
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Map<PublicKeyAlgorithm, Integer> algorithms = new HashMap<>();
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// put all acceptable algorithms and their minimal key length
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algorithms.put(PublicKeyAlgorithm.RSA_GENERAL, 1024);
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algorithms.put(PublicKeyAlgorithm.ECDSA, 100);
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...
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Policy.PublicKeyAlgorithmPolicy pkPolicy =
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new Policy.PublicKeyAlgorithmPolicy(algorithms);
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// set the custom algorithm policy
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PGPainless.getPolicy().setPublicKeyAlgorithmPolicy();
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```
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Since OpenPGP uses a hybrid encryption scheme of asymmetric and symmetric encryption algorithms,
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it also comes with a policy for symmetric encryption algorithms.
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This list can be modified to allow for weaker algorithms like follows:
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```java
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// default fallback algorithm for message encryption
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SymmetricKeyAlgorithm fallbackAlgorithm = SymmetricKeyAlgorithm.AES_256;
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// acceptable algorithms
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List<SymmetricKeyAlgorithm> algorithms = new ArrayList<>();
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algorithms.add(SymmetricKeyAlgorithm.AES_256);
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algorithms.add(SymmetricKeyAlgorithm.AES_192);
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algorithms.add(SymmetricKeyAlgorithm.AES_128);
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algorithms.add(SymmetricKeyAlgorithm.TWOFISH);
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algorithms.add(SymmetricKeyAlgorithm.BLOWFISH);
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...
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Policy.SymmetricKeyAlgorithmPolicy skPolicy =
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new SymmtricKeyAlgorithmPolicy(fallbackAlgorithm, algorithms);
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// set the custom algorithm policy
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// algorithm policy applicable when decrypting messages created by legacy senders:
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PGPainless.getPolicy()
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.setSymmetricKeyDecryptionAlgorithmPolicy(skPolicy);
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// algorithm policy applicable when generating messages for legacy recipients:
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PGPainless.getPolicy()
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.setSymmetricKeyEncryptionAlgorithmPolicy(skPolicy);
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```
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Hash algorithms are used in OpenPGP to create signatures.
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Since signature verification is an integral part of the OpenPGP protocol, PGPainless comes
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with multiple policies for acceptable hash algorithms, depending on the use-case.
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Revocation signatures are critical, so you might want to handle revocation signatures differently from normal signatures.
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By default, PGPainless uses a smart hash algorithm policy for both use-cases, which takes into consideration
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not only the hash algorithm itself, but also the creation date of the signature.
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That way, signatures using SHA-1 are acceptable if they were created before February 2013, but are rejected if their
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creation date is after that point in time.
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A custom hash algorithm policy can be set like this:
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```java
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HashAlgorithm fallbackAlgorithm = HashAlgorithm.SHA512;
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Map<HashAlgorithm, Date> algorithms = new HashMap<>();
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// Accept MD5 on signatures made before 1997-02-01
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algorithms.put(HashAlgorithm.MD5,
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DateUtil.parseUTCDate("1997-02-01 00:00:00 UTC"));
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// Accept SHA-1, regardless of signature creation time
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algorithms.put(HashAlgorithm.SHA1, null);
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...
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Policy.HashAlgorithmPolicy hPolicy =
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new Policy.HashAlgorithmPolicy(fallbackAlgorithm, algorithms);
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// set policy for revocation signatures
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PGPainless.getPolicy()
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.setRevocationSignatureHashAlgorithmPolicy(hPolicy);
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// set policy for normal signatures (certifications and document signatures)
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PGPainless.getPolicy()
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.setSignatureHashAlgorithmPolicy(hPolicy);
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```
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Lastly, PGPainless comes with a policy on acceptable compression algorithms, which currently accepts any
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compression algorithm.
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A custom compression algorithm policy can be set in a similar way:
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```java
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CompressionAlgorithm fallback = CompressionAlgorithm.ZIP;
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List<CompressionAlgorithm> algorithms = new ArrayList<>();
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algorithms.add(CompressionAlgorith.ZIP);
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algorithms.add(CompressionAlgorithm.BZIP2);
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...
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Policy.CompressionAlgorithmPolicy cPolicy =
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new Policy.CompressionAlgorithmPolicy(fallback, algorithms);
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PGPainless.getPolicy()
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.setCompressionAlgorithmPolicy(cPolicy);
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```
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To prevent a class of attacks described in the [paper](https://www.kopenpgp.com/#paper)
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"Victory by KO: Attacking OpenPGP Using Key Overwriting",
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PGPainless offers the option to validate private key material each time before using it,
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to make sure that an attacker didn't tamper with the corresponding public key parameters.
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These checks are disabled by default, but they can be enabled as follows:
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```java
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PGPainless.getPolicy()
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.setEnableKeyParameterValidation(true);
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```
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:::{note}
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Validation checks against KOpenPGP attacks are disabled by default, since they are very costly
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and only make sense in certain scenarios.
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Please read and understand the paper to decide, if enabling the checks makes sense for your use-case.
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:::
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### Known Notations
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In OpenPGP, signatures can contain [notation subpackets](https://www.rfc-editor.org/rfc/rfc4880#section-5.2.3.16).
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A notation can give meaning to a signature, or add additional contextual information.
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Signature subpackets can be marked as critical, meaning an implementation that does not know about
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a certain subpacket MUST reject the signature.
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The same is true for critical notations.
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For that reason, PGPainless comes with a `NotationRegistry` class which can be used to register known notations,
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such that a signature containing a critical notation of a certain value is not rejected.
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To register a known notation, you can do the following:
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```java
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NotationRegistry registry = PGPainless.getPolicy()
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.getNotationRegistry();
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registry.addKnownNotation("sample@example.com");
|
|
``` |