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546 lines
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21 KiB
Markdown
546 lines
No EOL
21 KiB
Markdown
## SOP API with pgpainless-sop
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The Stateless OpenPGP Protocol (SOP) defines a simplistic interface for the most important OpenPGP operations.
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It allows you to encrypt, decrypt, sign and verify messages, generate keys and add/remove ASCII armor from data.
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However, it does not yet provide tools for key management.
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Furthermore, the implementation is deciding for you, which (secure) algorithms to use, and it doesn't let you
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change those.
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If you want to read more about the background of the SOP protocol, there is a [whole chapter](../sop) dedicated to it.
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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-sop` 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-sop: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-sop</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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:::{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 `SOP` interface, for which `pgpainless-sop` provides a concrete implementation
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`SOPImpl`.
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```java
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// Instantiate the API
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SOP sop = new SOPImpl();
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```
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Now you are ready to go!
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### Generate a Key
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To generate a new OpenPGP key, the method `SOP.generateKey()` is your friend:
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```java
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// generate key
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byte[] keyBytes = sop.generateKey()
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.userId("John Doe <john.doe@pgpainless.org>")
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.withKeyPassword("f00b4r")
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.generate()
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.getBytes();
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```
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The call `userId(String userId)` can be called multiple times to add multiple user-ids to the key, but it MUST
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be called at least once.
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The argument given in the first invocation will become the keys primary user-id.
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Optionally, the key can be protected with a password by calling `withKeyPassword(String password)`.
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If this method is not called, the key will be unprotected.
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The `generate()` method call generates the key and returns a `Ready` object.
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This in turn can be used to write the result to a stream via `writeTo(OutputStream out)`, or to get the result
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as bytes via `getBytes()`.
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In both cases, the resulting output will be the UTF8 encoded, ASCII armored OpenPGP secret key.
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To disable ASCII armoring, call `noArmor()` before calling `generate()`.
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Revision `05` of the Stateless OpenPGP Protocol specification introduced the concept of profiles for
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certain operations.
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The key generation feature is the first operation to make use of profiles to specify different key algorithms.
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To set a profile, simply call `profile(String profileName)` and pass in one of the available profile identifiers.
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To explore, which profiles are available, refer to the dedicated [section](#explore-profiles).
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The default profile used by `pgpainless-sop` is called `draft-koch-eddsa-for-openpgp-00`.
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If this profile is used, the resulting OpenPGP secret key will consist of a certification-capable 256-bits
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ed25519 EdDSA primary key, a 256-bits ed25519 EdDSA subkey used for signing, as well as a 256-bits X25519
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ECDH subkey for encryption.
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Another profile defined by `pgpainless-sop` is `rfc4880`, which changes the key generation behaviour such that
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the resulting key is a single 4096-bit RSA key capable of certifying, signing and encrypting.
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The whole key does not have an expiration date set.
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### Extract a Certificate
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Now that you generated your secret key, you probably want to share the public key with your contacts.
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To extract the OpenPGP public key (which we will call *certificate* from now on) from the secret key,
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use the `SOP.extractCert()` method call:
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```java
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// extract certificate
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byte[] certificateBytes = sop.extractCert()
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.key(keyBytes)
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.getBytes();
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```
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The `key(_)` method either takes a byte array (like in the example), or an `InputStream`.
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In both cases it returns another `Ready` object from which the certificate can be accessed, either via
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`writeTo(OutputStream out)` or `getBytes()`.
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By default, the resulting certificate will be ASCII armored, regardless of whether the input key was armored or not.
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To disable ASCII armoring, call `noArmor()` before calling `key(_)`.
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In our example, `certificateBytes` can now safely be shared with anyone.
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### Change Key Password
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OpenPGP keys can (but don't need to) be password protected.
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The `changeKeyPassword()` API can be used to add, change or remove password protection from OpenPGP keys.
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While the input to this operation can be keys with different per-subkey passwords, the output will use at most one password.
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Via `oldKeyPassphrase()`, multiple decryption passphrase candidates can be provided.
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These are tried one after another to unlock protected subkeys.
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In order to successfully change the passphrase of an OpenPGP key, all of its subkeys needs to be successfully decrypted.
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If one or more subkeys cannot be decrypted, the operation fails with a `KeyIsProtected` exception.
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The result is either fully encrypted for a single passphrase (passed via `newKeyPassphrase()`),
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or unprotected if the new key passphrase is omitted.
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```java
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byte[] keyBefore = ...
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byte[] keyAfter = sop.changeKeyPassword()
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// Provide old passphrases - all subkeys need to be decryptable,
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// otherwise KeyIsProtected exception will be thrown
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.oldKeyPassphrase("4d4m5m1th")
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.oldKeyPassphrase("d4v1dR1c4rd0")
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// Provide the new passphrase - if omitted, key will be unprotected
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.newKeyPassphrase("fr1edr1ch3n93l5")
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.keys(keyBefore)
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.getBytes();
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```
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### Generate Revocation Certificates
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You might want to generate a revocation certificate for your OpenPGP key.
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This certificate can be published to a key server to let your contacts known that your key is no longer
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trustworthy.
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The `revokeKey()` API can be used to generate a "hard-revocation", which retroactively invalidates all
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signatures previously issued by the key.
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If the input secret key is an OpenPGP v6 key, the result will be a minimal revocation certificate,
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consisting of only the bare primary public key and a revocation signature. For v4 keys, the result
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will consist of the whole public certificate plus a revocation signature.
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```java
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byte[] keys = ...
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byte[] revoked = sop.revokeKey()
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// primary key password(s) if the key(s) are protected
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.withKeyPassword("5w0rdf1sh")
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// one or more secret keys
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.keys(keys)
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.getBytes();
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```
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### Apply / Remove ASCII Armor
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Perhaps you want to print your secret key onto a piece of paper for backup purposes,
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but you accidentally called `noArmor()` when generating the key.
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To add ASCII armor to some binary OpenPGP data, the `armor()` API can be used:
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```java
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// wrap data in ASCII armor
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byte[] armoredData = sop.armor()
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.data(binaryData)
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.getBytes();
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```
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The `data(_)` method can either be called by providing a byte array, or an `InputStream`.
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To remove ASCII armor from armored data, simply use the `dearmor()` API:
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```java
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// remove ASCII armor
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byte[] binaryData = sop.unarmor()
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.data(armoredData)
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.getBytes();
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```
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Once again, the `data(_)` method can be called either with a byte array or an `InputStream` as argument.
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If the input data is not validly armored OpenPGP data, the `data(_)` method call will throw a `BadData` exception.
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### Encrypt a Message
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Now lets get to the juicy part and finally encrypt a message!
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In this example, we will assume that Alice is the sender that wants to send a message to Bob.
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Beforehand, Alice acquired Bobs certificate, e.g. by fetching it from a key server.
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To encrypt a message, you can make use of the `encrypt()` API:
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```java
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// encrypt and sign a message
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byte[] aliceKey = ...; // Alice' secret key
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byte[] aliceCert = ...; // Alice' certificate (e.g. via extractCert())
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byte[] bobCert = ...; // Bobs certificate
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byte[] plaintext = "Hello, World!\n".getBytes(); // plaintext
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byte[] ciphertext = sop.encrypt()
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// encrypt for each recipient
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.withCert(bobCert)
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.withCert(aliceCert)
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// Optionally: Sign the message
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.signWith(aliceKey)
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.withKeyPassword("sw0rdf1sh") // if signing key is protected
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// provide the plaintext
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.plaintext(plaintext)
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.getBytes();
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```
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Here you encrypt the message for each recipient (Alice probably wants to be able to decrypt the message too!)
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by calling `withCert(_)` with the recipients certificate as argument. It does not matter, if the certificate
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is ASCII armored or not, and the method can either be called with a byte array or an `InputStream` as argument.
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The API not only supports asymmetric encryption via OpenPGP certificates, but it can also encrypt messages
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symmetrically using one or more passwords. Both mechanisms can even be used together in the same message!
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To (additionally or exclusively) encrypt the message for a password, simply call `withPassword(String password)`
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before the `plaintext(_)` method call.
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It is recommended (but not required) to sign encrypted messages.
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In order to sign the message before encryption is applied, call `signWith(_)` with the signing key as argument.
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This method call can be repeated multiple times to sign the message with multiple signing keys.
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If any keys used for signing are password protected, you need to provide the signing key password via
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`withKeyPassword(_)`.
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It does not matter in which order signing keys and key passwords are provided, the implementation will figure out
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matches on its own. If different key passwords are used, the `withKeyPassword(_)` method can be called multiple times.
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You can modify the behaviour of the encrypt operation by switching between different profiles via the
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`profile(String profileName)` method.
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At the time of writing, the only available profile for this operation is `rfc4880` which applies encryption
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as defined in [rfc4880](https://datatracker.ietf.org/doc/html/rfc4880).
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To explore, which profiles are available, refer to the dedicated [section](#explore-profiles).
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By default, the encrypted message will be ASCII armored. To disable ASCII armor, call `noArmor()` before the
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`plaintext(_)` method call.
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Lastly, you need to provide the plaintext by calling `plaintext(_)` with either a byte array or an `InputStream`
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as argument.
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The ciphertext can then be accessed from the resulting `Ready` object as usual.
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### Decrypt a Message
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Now let's switch perspective and help Bob decrypt the message from Alice.
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Decrypting encrypted messages is done in a similar fashion using the `decrypt()` API:
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```java
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// decrypt a message and verify its signature(s)
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byte[] aliceCert = ...; // Alice' certificate
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byte[] bobKey = ...; // Bobs secret key
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byte[] bobCert = ...; // Bobs certificate
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byte[] ciphertext = ...; // the encrypted message
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ReadyWithResult<DecryptionResult> readyWithResult = sop.decrypt()
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.withKey(bobKey)
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.verifyWithCert(aliceCert)
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.withKeyPassword("password123") // if decryption key is protected
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.ciphertext(ciphertext);
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```
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The `ReadyWithResult<DecryptionResult>` can now be processed in two different ways, depending on whether you want the
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plaintext as bytes or simply write it out to an `OutputStream`.
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To get the plaintext bytes directly, you shall proceed as follows:
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```java
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ByteArrayAndResult<DecryptionResult> bytesAndResult = readyWithResult.toByteArrayAndResult();
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DecryptionResult result = bytesAndResult.getResult();
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byte[] plaintext = bytesAndResult.getBytes();
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```
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If you instead want to write the plaintext out to an `OutputStream`, the following code can be used:
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```java
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OutputStream out = ...;
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DecryptionResult result = readyWithResult.writeTo(out);
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```
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Note, that in both cases you acquire a `DecryptionResult` object. This contains information about the message,
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such as which signatures could successfully be verified.
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If you provided the senders certificate for the purpose of signature verification via `verifyWith(_)`, you now
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probably want to check, if the message was actually signed by the sender by checking `result.getVerifications()`.
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:::{note}
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Signature verification will be discussed in more detail in section "Verifications".
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:::
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If the message was encrypted symmetrically using a password, you can also decrypt is symmetrically by calling
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`withPassword(String password)` before the `ciphertext(_)` method call. This method call can be repeated multiple
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times. The implementation will try different passwords until it finds a matching one.
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### Sign a Message
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There are three different main ways of signing a message:
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* Inline Signatures
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* Cleartext Signatures
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* Detached Signatures
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An inline-signature will be part of the message itself (e.g. like with messages that are encrypted *and* signed).
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Inline-signed messages are not human-readable without prior processing.
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A cleartext signature makes use of the [cleartext signature framework](https://datatracker.ietf.org/doc/html/rfc4880#section-7).
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Messages signed in this way do have an ASCII armor header and footer, yet the content of the message is still
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human-readable without special software.
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Lastly, a detached signature can be distributed as an extra file alongside the message without altering it.
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This is useful if the plaintext itself cannot be modified (e.g. if a binary file is signed).
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The SOP API can generate all of those signature types.
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#### Inline-Signatures
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Let's start with an inline signature:
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```java
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byte[] signingKey = ...;
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byte[] message = ...;
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byte[] inlineSignedMessage = sop.inlineSign()
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.mode(InlineSignAs.Text) // or 'Binary'
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.key(signingKey)
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.withKeyPassword("fnord")
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.data(message)
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.getBytes();
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```
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You can choose between two different signature formats which can be set using `mode(InlineSignAs mode)`.
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The default value is `Binary`. You can also set it to `Text` which signals to the receiver that the data is
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UTF8 text.
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:::{note}
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For inline signatures, do NOT set the `mode()` to `CleartextSigned`, as that will create message which uses the
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cleartext signature framework (see further below).
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:::
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You must provide at least one signing key using `key(_)` in order to be able to sign the message.
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If any key is password protected, you need to provide its password using `withKeyPassword(_)` which
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can be called multiple times to provide multiple passwords.
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Once you provide the plaintext using `data(_)` with either a byte array or an `InputStream` as argument,
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you will get a `Ready` object back, from which the signed message can be retrieved as usual.
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By default, the signed message will be ASCII armored. This can be disabled by calling `noArmor()`
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before the `data(_)` method call.
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#### Cleartext Signatures
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A cleartext-signed message can be generated in a similar way to an inline-signed message, however,
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there are is one subtle difference:
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```java
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byte[] signingKey = ...;
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byte[] message = ...;
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byte[] cleartextSignedMessage = sop.inlineSign()
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.mode(InlineSignAs.CleartextSigned) // This MUST be set
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.key(signingKey)
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.withKeyPassword("fnord")
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.data(message)
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.getBytes();
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```
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:::{important}
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In order to produce a cleartext-signed message, the signature mode MUST be set to `CleartextSigned`
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by calling `mode(InlineSignAs.CleartextSigned)`.
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:::
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:::{note}
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Calling `noArmor()` will have no effect for cleartext-signed messages, so such method call will be ignored.
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:::
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#### Detached Signatures
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As the name suggests, detached signatures are detached from the message itself and can be distributed separately.
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To produce a detached signature, the `detachedSign()` API is used:
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```java
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byte[] signingKey = ...;
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byte[] message = ...;
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ReadyWithResult<SigningResult> readyWithResult = sop.detachedSign()
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.key(signingKey)
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.withKeyPassword("fnord")
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.data(message);
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```
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Here you have the choice, how you want to write out the signature.
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If you want to write the signature to an `OutputStream`, you can do the following:
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```java
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OutputStream out = ...;
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SigningResult result = readyWithResult.writeTo(out);
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```
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If instead you want to get the signature as a byte array, do this instead:
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```java
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ByteArrayAndResult<SigningResult> bytesAndResult = readyWithResult.toByteArrayAndResult();
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SigningResult result = bytesAndResult.getResult();
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byte[] detachedSignature = bytesAndResult.getBytes();
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```
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In any case, the detached signature can now be distributed alongside the original message.
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By default, the resulting detached signature will be ASCII armored. This can be disabled by calling `noArmor()`
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prior to calling `data(_)`.
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The `SigningResult` object you got back in both cases contains information about the signature.
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### Verify a Signature
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In order to verify signed messages, there are two API endpoints available.
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#### Inline and Cleartext Signatures
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To verify inline-signed messages, or messages that make use of the cleartext signature framework,
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use the `inlineVerify()` API:
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```java
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byte[] signingCert = ...;
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byte[] signedMessage = ...;
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ReadyWithResult<List<Verification>> readyWithResult = sop.inlineVerify()
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.cert(signingCert)
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.data(signedMessage);
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```
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The `cert(_)` method MUST be called at least once. It takes either a byte array or an `InputStream` containing
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an OpenPGP certificate.
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If you are not sure, which certificate was used to sign the message, you can provide multiple certificates.
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It is also possible to reject signatures that were not made within a certain time window by calling
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`notBefore(Date timestamp)` and/or `notAfter(Date timestamp)`.
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Signatures made before the `notBefore(_)` or after the `notAfter(_)` constraints will be rejected.
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You can now either write out the plaintext message to an `OutputStream`...
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```java
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OutputStream out = ...;
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List<Verifications> verifications = readyWithResult.writeTo(out);
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```
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... or you can acquire the plaintext message as a byte array directly:
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```java
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ByteArrayAndResult<List<Verifications>> bytesAndResult = readyWithResult.toByteArrayAndResult();
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byte[] plaintextMessage = bytesAndResult.getBytes();
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List<Verifications> verifications = bytesAndResult.getResult();
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```
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In both cases, the plaintext message will have the signatures stripped.
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#### Detached Signatures
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To verify detached signatures (signatures that come separate from the message itself), you can use the
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`detachedVerify()` API:
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```java
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byte[] signingCert = ...;
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byte[] message = ...;
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byte[] detachedSignature = ...;
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List<Verification> verifications = sop.detachedVerify()
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.cert(signingCert)
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.signatures(detachedSignature)
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.data(signedMessage);
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```
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You can provide one or more OpenPGP certificates using `cert(_)`, providing either a byte array or an `InputStream`.
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The detached signatures need to be provided separately using the `signatures(_)` method call.
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You can provide as many detached signatures as you like, and those can be binary or ASCII armored.
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Like with Inline Signatures, you can constrain the time window for signature validity using
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`notAfter(_)` and `notBefore(_)`.
|
|
|
|
#### Verifications
|
|
|
|
In all above cases, the `verifications` list will contain `Verification` objects for each verifiable, valid signature.
|
|
Those objects contain information about the signatures:
|
|
`verification.getSigningCertFingerprint()` will return the fingerprint of the certificate that created the signature.
|
|
`verification.getSigningKeyFingerprint()` will return the fingerprint of the used signing subkey within that certificate.
|
|
|
|
### Detach Signatures from Messages
|
|
|
|
It is also possible, to detach inline or cleartext signatures from signed messages to transform them into
|
|
detached signatures.
|
|
The same way you can turn inline or cleartext signed messages into plaintext messages.
|
|
|
|
To detach signatures from messages, use the `inlineDetach()` API:
|
|
|
|
```java
|
|
byte[] signedMessage = ...;
|
|
|
|
ReadyWithResult<Signatures> readyWithResult = sop.inlineDetach()
|
|
.message(signedMessage);
|
|
ByteArrayAndResult<Signatures> bytesAndResult = readyWithResult.toByteArrayAndResult();
|
|
|
|
byte[] plaintext = bytesAndResult.getBytes();
|
|
Signatures signatures = bytesAndResult.getResult();
|
|
byte[] encodedSignatures = signatures.getBytes();
|
|
```
|
|
|
|
By default, the signatures output will be ASCII armored. This can be disabled by calling `noArmor()`
|
|
prior to `message(_)`.
|
|
|
|
The detached signatures can now be verified like in the section above.
|
|
|
|
### Explore Profiles
|
|
|
|
Certain operations allow modification of their behaviour by selecting between different profiles.
|
|
An example for this is the `generateKey()` operation, where different profiles result in different algorithms used
|
|
during key generation.
|
|
|
|
To explore, which profiles are supported by a certain operation, you can use the `listProfiles()` operation.
|
|
For example, this is how you can get a list of profiles supported by the `generateKey()` operation:
|
|
|
|
```java
|
|
List<Profile> profiles = sop.listProfiles().subcommand("generate-key");
|
|
```
|
|
|
|
:::{note}
|
|
As you can see, the argument passed into the `subcommand()` method must match the operation name as defined in the
|
|
[Stateless OpenPGP Protocol specification](https://datatracker.ietf.org/doc/draft-dkg-openpgp-stateless-cli/).
|
|
:::
|
|
|
|
At the time of writing (the latest revision of the SOP spec is 06), only `generate-key` and `encrypt` accept profiles. |