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Kotlin conversion: SigningOptions
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parent
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2 changed files with 451 additions and 634 deletions
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// SPDX-FileCopyrightText: 2021 Paul Schaub <vanitasvitae@fsfe.org>
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//
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// SPDX-License-Identifier: Apache-2.0
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package org.pgpainless.encryption_signing;
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import java.util.Collections;
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import java.util.Date;
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import java.util.HashMap;
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import java.util.List;
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import java.util.Map;
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import java.util.Set;
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import javax.annotation.Nonnull;
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import javax.annotation.Nullable;
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import org.bouncycastle.openpgp.PGPException;
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import org.bouncycastle.openpgp.PGPPrivateKey;
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import org.bouncycastle.openpgp.PGPPublicKey;
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import org.bouncycastle.openpgp.PGPSecretKey;
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import org.bouncycastle.openpgp.PGPSecretKeyRing;
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import org.bouncycastle.openpgp.PGPSignatureGenerator;
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import org.bouncycastle.openpgp.operator.PGPContentSignerBuilder;
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import org.pgpainless.PGPainless;
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import org.pgpainless.algorithm.DocumentSignatureType;
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import org.pgpainless.algorithm.HashAlgorithm;
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import org.pgpainless.algorithm.PublicKeyAlgorithm;
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import org.pgpainless.algorithm.negotiation.HashAlgorithmNegotiator;
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import org.pgpainless.exception.KeyException;
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import org.pgpainless.implementation.ImplementationFactory;
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import org.pgpainless.key.OpenPgpFingerprint;
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import org.pgpainless.key.SubkeyIdentifier;
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import org.pgpainless.key.info.KeyRingInfo;
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import org.pgpainless.key.protection.SecretKeyRingProtector;
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import org.pgpainless.key.protection.UnlockSecretKey;
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import org.pgpainless.policy.Policy;
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import org.pgpainless.signature.subpackets.BaseSignatureSubpackets;
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import org.pgpainless.signature.subpackets.SignatureSubpackets;
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import org.pgpainless.signature.subpackets.SignatureSubpacketsHelper;
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public final class SigningOptions {
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/**
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* A method of signing.
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*/
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public static final class SigningMethod {
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private final PGPSignatureGenerator signatureGenerator;
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private final boolean detached;
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private final HashAlgorithm hashAlgorithm;
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private SigningMethod(@Nonnull PGPSignatureGenerator signatureGenerator,
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boolean detached,
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@Nonnull HashAlgorithm hashAlgorithm) {
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this.signatureGenerator = signatureGenerator;
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this.detached = detached;
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this.hashAlgorithm = hashAlgorithm;
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}
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/**
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* Inline-signature method.
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* The resulting signature will be written into the message itself, together with a one-pass-signature packet.
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*
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* @param signatureGenerator signature generator
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* @param hashAlgorithm hash algorithm used to generate the signature
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* @return inline signing method
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*/
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public static SigningMethod inlineSignature(@Nonnull PGPSignatureGenerator signatureGenerator,
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@Nonnull HashAlgorithm hashAlgorithm) {
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return new SigningMethod(signatureGenerator, false, hashAlgorithm);
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}
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/**
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* Detached signing method.
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* The resulting signature will not be added to the message, and instead can be distributed separately
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* to the signed message.
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*
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* @param signatureGenerator signature generator
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* @param hashAlgorithm hash algorithm used to generate the signature
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* @return detached signing method
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*/
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public static SigningMethod detachedSignature(@Nonnull PGPSignatureGenerator signatureGenerator,
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@Nonnull HashAlgorithm hashAlgorithm) {
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return new SigningMethod(signatureGenerator, true, hashAlgorithm);
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}
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public boolean isDetached() {
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return detached;
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}
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public PGPSignatureGenerator getSignatureGenerator() {
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return signatureGenerator;
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}
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public HashAlgorithm getHashAlgorithm() {
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return hashAlgorithm;
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}
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}
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private final Map<SubkeyIdentifier, SigningMethod> signingMethods = new HashMap<>();
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private HashAlgorithm hashAlgorithmOverride;
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private Date evaluationDate = new Date();
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@Nonnull
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public static SigningOptions get() {
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return new SigningOptions();
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}
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/**
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* Override the evaluation date for signing keys with the given date.
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*
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* @param evaluationDate new evaluation date
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* @return this
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*/
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public SigningOptions setEvaluationDate(@Nonnull Date evaluationDate) {
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this.evaluationDate = evaluationDate;
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return this;
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}
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/**
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* Sign the message using an inline signature made by the provided signing key.
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*
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* @param signingKeyProtector protector to unlock the signing key
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* @param signingKey key ring containing the signing key
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* @return this
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*
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* @throws KeyException if something is wrong with the key
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* @throws PGPException if the key cannot be unlocked or a signing method cannot be created
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*/
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@Nonnull
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public SigningOptions addSignature(@Nonnull SecretKeyRingProtector signingKeyProtector,
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@Nonnull PGPSecretKeyRing signingKey)
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throws PGPException {
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return addInlineSignature(signingKeyProtector, signingKey, DocumentSignatureType.BINARY_DOCUMENT);
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}
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/**
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* Add inline signatures with all secret key rings in the provided secret key ring collection.
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*
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* @param secrectKeyDecryptor decryptor to unlock the signing secret keys
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* @param signingKeys collection of signing keys
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* @param signatureType type of signature (binary, canonical text)
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* @return this
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*
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* @throws KeyException if something is wrong with any of the keys
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* @throws PGPException if any of the keys cannot be unlocked or a signing method cannot be created
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*/
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@Nonnull
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public SigningOptions addInlineSignatures(@Nonnull SecretKeyRingProtector secrectKeyDecryptor,
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@Nonnull Iterable<PGPSecretKeyRing> signingKeys,
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@Nonnull DocumentSignatureType signatureType)
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throws KeyException, PGPException {
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for (PGPSecretKeyRing signingKey : signingKeys) {
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addInlineSignature(secrectKeyDecryptor, signingKey, signatureType);
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}
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return this;
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}
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/**
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* Add an inline-signature.
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* Inline signatures are being embedded into the message itself and can be processed in one pass, thanks to the use
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* of one-pass-signature packets.
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*
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* @param secretKeyDecryptor decryptor to unlock the signing secret key
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* @param secretKey signing key
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* @param signatureType type of signature (binary, canonical text)
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* @return this
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*
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* @throws KeyException if something is wrong with the key
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* @throws PGPException if the key cannot be unlocked or the signing method cannot be created
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*/
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@Nonnull
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public SigningOptions addInlineSignature(@Nonnull SecretKeyRingProtector secretKeyDecryptor,
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@Nonnull PGPSecretKeyRing secretKey,
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@Nonnull DocumentSignatureType signatureType)
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throws KeyException, PGPException {
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return addInlineSignature(secretKeyDecryptor, secretKey, null, signatureType);
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}
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/**
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* Add an inline-signature.
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* Inline signatures are being embedded into the message itself and can be processed in one pass, thanks to the use
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* of one-pass-signature packets.
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* <p>
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* This method uses the passed in user-id to select user-specific hash algorithms.
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*
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* @param secretKeyDecryptor decryptor to unlock the signing secret key
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* @param secretKey signing key
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* @param userId user-id of the signer
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* @param signatureType signature type (binary, canonical text)
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* @return this
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*
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* @throws KeyException if something is wrong with the key
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* @throws PGPException if the key cannot be unlocked or the signing method cannot be created
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*/
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@Nonnull
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public SigningOptions addInlineSignature(@Nonnull SecretKeyRingProtector secretKeyDecryptor,
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@Nonnull PGPSecretKeyRing secretKey,
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@Nullable CharSequence userId,
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@Nonnull DocumentSignatureType signatureType)
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throws KeyException, PGPException {
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return addInlineSignature(secretKeyDecryptor, secretKey, userId, signatureType, null);
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}
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/**
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* Add an inline-signature.
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* Inline signatures are being embedded into the message itself and can be processed in one pass, thanks to the use
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* of one-pass-signature packets.
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* <p>
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* This method uses the passed in user-id to select user-specific hash algorithms.
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*
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* @param secretKeyDecryptor decryptor to unlock the signing secret key
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* @param secretKey signing key
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* @param userId user-id of the signer
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* @param signatureType signature type (binary, canonical text)
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* @param subpacketsCallback callback to modify the hashed and unhashed subpackets of the signature
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* @return this
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*
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* @throws KeyException if the key is invalid
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* @throws PGPException if the key cannot be unlocked or the signing method cannot be created
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*/
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@Nonnull
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public SigningOptions addInlineSignature(@Nonnull SecretKeyRingProtector secretKeyDecryptor,
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@Nonnull PGPSecretKeyRing secretKey,
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@Nullable CharSequence userId,
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@Nonnull DocumentSignatureType signatureType,
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@Nullable BaseSignatureSubpackets.Callback subpacketsCallback)
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throws KeyException, PGPException {
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KeyRingInfo keyRingInfo = PGPainless.inspectKeyRing(secretKey, evaluationDate);
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if (userId != null && !keyRingInfo.isUserIdValid(userId)) {
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throw new KeyException.UnboundUserIdException(
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OpenPgpFingerprint.of(secretKey),
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userId.toString(),
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keyRingInfo.getLatestUserIdCertification(userId),
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keyRingInfo.getUserIdRevocation(userId)
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);
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}
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List<PGPPublicKey> signingPubKeys = keyRingInfo.getSigningSubkeys();
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if (signingPubKeys.isEmpty()) {
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throw new KeyException.UnacceptableSigningKeyException(OpenPgpFingerprint.of(secretKey));
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}
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for (PGPPublicKey signingPubKey : signingPubKeys) {
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PGPSecretKey signingSecKey = secretKey.getSecretKey(signingPubKey.getKeyID());
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if (signingSecKey == null) {
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throw new KeyException.MissingSecretKeyException(OpenPgpFingerprint.of(secretKey), signingPubKey.getKeyID());
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}
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PGPPrivateKey signingSubkey = UnlockSecretKey.unlockSecretKey(signingSecKey, secretKeyDecryptor);
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Set<HashAlgorithm> hashAlgorithms = userId != null ? keyRingInfo.getPreferredHashAlgorithms(userId)
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: keyRingInfo.getPreferredHashAlgorithms(signingPubKey.getKeyID());
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HashAlgorithm hashAlgorithm = negotiateHashAlgorithm(hashAlgorithms, PGPainless.getPolicy());
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addSigningMethod(secretKey, signingSubkey, subpacketsCallback, hashAlgorithm, signatureType, false);
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}
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return this;
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}
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/**
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* Create a binary inline signature using the signing key with the given keyId.
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*
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* @param secretKeyDecryptor decryptor to unlock the secret key
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* @param secretKey secret key ring
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* @param keyId keyId of the signing (sub-)key
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* @return builder
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* @throws PGPException if the secret key cannot be unlocked or if no signing method can be created.
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* @throws KeyException.UnacceptableSigningKeyException if the key ring does not carry any signing-capable subkeys
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* @throws KeyException.MissingSecretKeyException if the key ring does not contain the identified secret key
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*/
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@Nonnull
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public SigningOptions addInlineSignature(@Nonnull SecretKeyRingProtector secretKeyDecryptor,
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@Nonnull PGPSecretKeyRing secretKey,
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long keyId) throws PGPException {
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return addInlineSignature(secretKeyDecryptor, secretKey, keyId, DocumentSignatureType.BINARY_DOCUMENT, null);
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}
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/**
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* Create an inline signature using the signing key with the given keyId.
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*
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* @param secretKeyDecryptor decryptor to unlock the secret key
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* @param secretKey secret key ring
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* @param keyId keyId of the signing (sub-)key
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* @param signatureType signature type
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* @param subpacketsCallback callback to modify the signatures subpackets
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* @return builder
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* @throws PGPException if the secret key cannot be unlocked or if no signing method can be created.
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* @throws KeyException.UnacceptableSigningKeyException if the key ring does not carry any signing-capable subkeys
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* @throws KeyException.MissingSecretKeyException if the key ring does not contain the identified secret key
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*/
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@Nonnull
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public SigningOptions addInlineSignature(@Nonnull SecretKeyRingProtector secretKeyDecryptor,
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@Nonnull PGPSecretKeyRing secretKey,
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long keyId,
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@Nonnull DocumentSignatureType signatureType,
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@Nullable BaseSignatureSubpackets.Callback subpacketsCallback) throws PGPException {
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KeyRingInfo keyRingInfo = PGPainless.inspectKeyRing(secretKey, evaluationDate);
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List<PGPPublicKey> signingPubKeys = keyRingInfo.getSigningSubkeys();
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if (signingPubKeys.isEmpty()) {
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throw new KeyException.UnacceptableSigningKeyException(OpenPgpFingerprint.of(secretKey));
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}
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for (PGPPublicKey signingPubKey : signingPubKeys) {
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if (signingPubKey.getKeyID() == keyId) {
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PGPSecretKey signingSecKey = secretKey.getSecretKey(signingPubKey.getKeyID());
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if (signingSecKey == null) {
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throw new KeyException.MissingSecretKeyException(OpenPgpFingerprint.of(secretKey), signingPubKey.getKeyID());
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}
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PGPPrivateKey signingSubkey = UnlockSecretKey.unlockSecretKey(signingSecKey, secretKeyDecryptor);
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Set<HashAlgorithm> hashAlgorithms = keyRingInfo.getPreferredHashAlgorithms(signingPubKey.getKeyID());
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HashAlgorithm hashAlgorithm = negotiateHashAlgorithm(hashAlgorithms, PGPainless.getPolicy());
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addSigningMethod(secretKey, signingSubkey, subpacketsCallback, hashAlgorithm, signatureType, false);
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return this;
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}
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}
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throw new KeyException.MissingSecretKeyException(OpenPgpFingerprint.of(secretKey), keyId);
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}
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/**
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* Add detached signatures with all key rings from the provided secret key ring collection.
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*
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* @param secretKeyDecryptor decryptor to unlock the secret signing keys
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* @param signingKeys collection of signing key rings
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* @param signatureType type of the signature (binary, canonical text)
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* @return this
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*
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* @throws KeyException if something is wrong with any of the keys
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* @throws PGPException if any of the keys cannot be validated or unlocked, or if any signing method cannot be created
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*/
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@Nonnull
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public SigningOptions addDetachedSignatures(@Nonnull SecretKeyRingProtector secretKeyDecryptor,
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@Nonnull Iterable<PGPSecretKeyRing> signingKeys,
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@Nonnull DocumentSignatureType signatureType)
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throws PGPException {
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for (PGPSecretKeyRing signingKey : signingKeys) {
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addDetachedSignature(secretKeyDecryptor, signingKey, signatureType);
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}
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return this;
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}
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/**
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* Create a detached signature.
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* The signature will be of type {@link DocumentSignatureType#BINARY_DOCUMENT}.
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*
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* @param secretKeyDecryptor decryptor to unlock the secret signing key
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* @param signingKey signing key
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* @return this
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*
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* @throws KeyException if something is wrong with the key
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* @throws PGPException if the key cannot be validated or unlocked, or if no signature method can be created
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*/
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@Nonnull
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public SigningOptions addDetachedSignature(@Nonnull SecretKeyRingProtector secretKeyDecryptor,
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@Nonnull PGPSecretKeyRing signingKey)
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throws PGPException {
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return addDetachedSignature(secretKeyDecryptor, signingKey, DocumentSignatureType.BINARY_DOCUMENT);
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}
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/**
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* Create a detached signature.
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* Detached signatures are not being added into the PGP message itself.
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* Instead, they can be distributed separately to the message.
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* Detached signatures are useful if the data that is being signed shall not be modified (e.g. when signing a file).
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*
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* @param secretKeyDecryptor decryptor to unlock the secret signing key
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* @param secretKey signing key
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* @param signatureType type of data that is signed (binary, canonical text)
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* @return this
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*
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* @throws KeyException if something is wrong with the key
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* @throws PGPException if the key cannot be validated or unlocked, or if no signature method can be created
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*/
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@Nonnull
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public SigningOptions addDetachedSignature(@Nonnull SecretKeyRingProtector secretKeyDecryptor,
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@Nonnull PGPSecretKeyRing secretKey,
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@Nonnull DocumentSignatureType signatureType)
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throws PGPException {
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return addDetachedSignature(secretKeyDecryptor, secretKey, null, signatureType);
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}
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/**
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* Create a detached signature.
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* Detached signatures are not being added into the PGP message itself.
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* Instead, they can be distributed separately to the message.
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* Detached signatures are useful if the data that is being signed shall not be modified (e.g. when signing a file).
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* <p>
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* This method uses the passed in user-id to select user-specific hash algorithms.
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*
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* @param secretKeyDecryptor decryptor to unlock the secret signing key
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* @param secretKey signing key
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* @param userId user-id
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* @param signatureType type of data that is signed (binary, canonical text)
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* @return this
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*
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* @throws KeyException if something is wrong with the key
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* @throws PGPException if the key cannot be validated or unlocked, or if no signature method can be created
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*/
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@Nonnull
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public SigningOptions addDetachedSignature(@Nonnull SecretKeyRingProtector secretKeyDecryptor,
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@Nonnull PGPSecretKeyRing secretKey,
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@Nullable CharSequence userId,
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@Nonnull DocumentSignatureType signatureType)
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throws PGPException {
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return addDetachedSignature(secretKeyDecryptor, secretKey, userId, signatureType, null);
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}
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/**
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* Create a detached signature.
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* Detached signatures are not being added into the PGP message itself.
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* Instead, they can be distributed separately to the message.
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* Detached signatures are useful if the data that is being signed shall not be modified (e.g. when signing a file).
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* <p>
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* This method uses the passed in user-id to select user-specific hash algorithms.
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*
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* @param secretKeyDecryptor decryptor to unlock the secret signing key
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* @param secretKey signing key
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* @param userId user-id
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* @param signatureType type of data that is signed (binary, canonical text)
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* @param subpacketCallback callback to modify hashed and unhashed subpackets of the signature
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* @return this
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*
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* @throws KeyException if something is wrong with the key
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* @throws PGPException if the key cannot be validated or unlocked, or if no signature method can be created
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*/
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@Nonnull
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public SigningOptions addDetachedSignature(@Nonnull SecretKeyRingProtector secretKeyDecryptor,
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@Nonnull PGPSecretKeyRing secretKey,
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@Nullable CharSequence userId,
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@Nonnull DocumentSignatureType signatureType,
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@Nullable BaseSignatureSubpackets.Callback subpacketCallback)
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throws PGPException {
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KeyRingInfo keyRingInfo = PGPainless.inspectKeyRing(secretKey, evaluationDate);
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if (userId != null && !keyRingInfo.isUserIdValid(userId)) {
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throw new KeyException.UnboundUserIdException(
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OpenPgpFingerprint.of(secretKey),
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userId.toString(),
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keyRingInfo.getLatestUserIdCertification(userId),
|
||||
keyRingInfo.getUserIdRevocation(userId)
|
||||
);
|
||||
}
|
||||
|
||||
List<PGPPublicKey> signingPubKeys = keyRingInfo.getSigningSubkeys();
|
||||
if (signingPubKeys.isEmpty()) {
|
||||
throw new KeyException.UnacceptableSigningKeyException(OpenPgpFingerprint.of(secretKey));
|
||||
}
|
||||
|
||||
for (PGPPublicKey signingPubKey : signingPubKeys) {
|
||||
PGPSecretKey signingSecKey = secretKey.getSecretKey(signingPubKey.getKeyID());
|
||||
if (signingSecKey == null) {
|
||||
throw new KeyException.MissingSecretKeyException(OpenPgpFingerprint.of(secretKey), signingPubKey.getKeyID());
|
||||
}
|
||||
PGPPrivateKey signingSubkey = UnlockSecretKey.unlockSecretKey(signingSecKey, secretKeyDecryptor);
|
||||
Set<HashAlgorithm> hashAlgorithms = userId != null ? keyRingInfo.getPreferredHashAlgorithms(userId)
|
||||
: keyRingInfo.getPreferredHashAlgorithms(signingPubKey.getKeyID());
|
||||
HashAlgorithm hashAlgorithm = negotiateHashAlgorithm(hashAlgorithms, PGPainless.getPolicy());
|
||||
addSigningMethod(secretKey, signingSubkey, subpacketCallback, hashAlgorithm, signatureType, true);
|
||||
}
|
||||
|
||||
return this;
|
||||
}
|
||||
|
||||
/**
|
||||
* Create a detached binary signature using the signing key with the given keyId.
|
||||
*
|
||||
* @param secretKeyDecryptor decryptor to unlock the secret key
|
||||
* @param secretKey secret key ring
|
||||
* @param keyId keyId of the signing (sub-)key
|
||||
* @return builder
|
||||
* @throws PGPException if the secret key cannot be unlocked or if no signing method can be created.
|
||||
* @throws KeyException.UnacceptableSigningKeyException if the key ring does not carry any signing-capable subkeys
|
||||
* @throws KeyException.MissingSecretKeyException if the key ring does not contain the identified secret key
|
||||
*/
|
||||
@Nonnull
|
||||
public SigningOptions addDetachedSignature(@Nonnull SecretKeyRingProtector secretKeyDecryptor,
|
||||
@Nonnull PGPSecretKeyRing secretKey,
|
||||
long keyId) throws PGPException {
|
||||
return addDetachedSignature(secretKeyDecryptor, secretKey, keyId, DocumentSignatureType.BINARY_DOCUMENT, null);
|
||||
}
|
||||
|
||||
/**
|
||||
* Create a detached signature using the signing key with the given keyId.
|
||||
*
|
||||
* @param secretKeyDecryptor decryptor to unlock the secret key
|
||||
* @param secretKey secret key ring
|
||||
* @param keyId keyId of the signing (sub-)key
|
||||
* @param signatureType signature type
|
||||
* @param subpacketsCallback callback to modify the signatures subpackets
|
||||
* @return builder
|
||||
* @throws PGPException if the secret key cannot be unlocked or if no signing method can be created.
|
||||
* @throws KeyException.UnacceptableSigningKeyException if the key ring does not carry any signing-capable subkeys
|
||||
* @throws KeyException.MissingSecretKeyException if the key ring does not contain the identified secret key
|
||||
*/
|
||||
@Nonnull
|
||||
public SigningOptions addDetachedSignature(@Nonnull SecretKeyRingProtector secretKeyDecryptor,
|
||||
@Nonnull PGPSecretKeyRing secretKey,
|
||||
long keyId,
|
||||
@Nonnull DocumentSignatureType signatureType,
|
||||
@Nullable BaseSignatureSubpackets.Callback subpacketsCallback) throws PGPException {
|
||||
KeyRingInfo keyRingInfo = PGPainless.inspectKeyRing(secretKey, evaluationDate);
|
||||
|
||||
List<PGPPublicKey> signingPubKeys = keyRingInfo.getSigningSubkeys();
|
||||
if (signingPubKeys.isEmpty()) {
|
||||
throw new KeyException.UnacceptableSigningKeyException(OpenPgpFingerprint.of(secretKey));
|
||||
}
|
||||
|
||||
for (PGPPublicKey signingPubKey : signingPubKeys) {
|
||||
if (signingPubKey.getKeyID() == keyId) {
|
||||
|
||||
PGPSecretKey signingSecKey = secretKey.getSecretKey(signingPubKey.getKeyID());
|
||||
if (signingSecKey == null) {
|
||||
throw new KeyException.MissingSecretKeyException(OpenPgpFingerprint.of(secretKey), signingPubKey.getKeyID());
|
||||
}
|
||||
PGPPrivateKey signingSubkey = UnlockSecretKey.unlockSecretKey(signingSecKey, secretKeyDecryptor);
|
||||
Set<HashAlgorithm> hashAlgorithms = keyRingInfo.getPreferredHashAlgorithms(signingPubKey.getKeyID());
|
||||
HashAlgorithm hashAlgorithm = negotiateHashAlgorithm(hashAlgorithms, PGPainless.getPolicy());
|
||||
addSigningMethod(secretKey, signingSubkey, subpacketsCallback, hashAlgorithm, signatureType, true);
|
||||
return this;
|
||||
}
|
||||
}
|
||||
|
||||
throw new KeyException.MissingSecretKeyException(OpenPgpFingerprint.of(secretKey), keyId);
|
||||
}
|
||||
|
||||
private void addSigningMethod(@Nonnull PGPSecretKeyRing secretKey,
|
||||
@Nonnull PGPPrivateKey signingSubkey,
|
||||
@Nullable BaseSignatureSubpackets.Callback subpacketCallback,
|
||||
@Nonnull HashAlgorithm hashAlgorithm,
|
||||
@Nonnull DocumentSignatureType signatureType,
|
||||
boolean detached)
|
||||
throws PGPException {
|
||||
SubkeyIdentifier signingKeyIdentifier = new SubkeyIdentifier(secretKey, signingSubkey.getKeyID());
|
||||
PGPSecretKey signingSecretKey = secretKey.getSecretKey(signingSubkey.getKeyID());
|
||||
PublicKeyAlgorithm publicKeyAlgorithm = PublicKeyAlgorithm.requireFromId(signingSecretKey.getPublicKey().getAlgorithm());
|
||||
int bitStrength = signingSecretKey.getPublicKey().getBitStrength();
|
||||
if (!PGPainless.getPolicy().getPublicKeyAlgorithmPolicy().isAcceptable(publicKeyAlgorithm, bitStrength)) {
|
||||
throw new KeyException.UnacceptableSigningKeyException(
|
||||
new KeyException.PublicKeyAlgorithmPolicyException(
|
||||
OpenPgpFingerprint.of(secretKey), signingSecretKey.getKeyID(), publicKeyAlgorithm, bitStrength));
|
||||
}
|
||||
|
||||
PGPSignatureGenerator generator = createSignatureGenerator(signingSubkey, hashAlgorithm, signatureType);
|
||||
|
||||
// Subpackets
|
||||
SignatureSubpackets hashedSubpackets = SignatureSubpackets.createHashedSubpackets(signingSecretKey.getPublicKey());
|
||||
SignatureSubpackets unhashedSubpackets = SignatureSubpackets.createEmptySubpackets();
|
||||
if (subpacketCallback != null) {
|
||||
subpacketCallback.modifyHashedSubpackets(hashedSubpackets);
|
||||
subpacketCallback.modifyUnhashedSubpackets(unhashedSubpackets);
|
||||
}
|
||||
generator.setHashedSubpackets(SignatureSubpacketsHelper.toVector(hashedSubpackets));
|
||||
generator.setUnhashedSubpackets(SignatureSubpacketsHelper.toVector(unhashedSubpackets));
|
||||
|
||||
SigningMethod signingMethod = detached ?
|
||||
SigningMethod.detachedSignature(generator, hashAlgorithm) :
|
||||
SigningMethod.inlineSignature(generator, hashAlgorithm);
|
||||
signingMethods.put(signingKeyIdentifier, signingMethod);
|
||||
}
|
||||
|
||||
/**
|
||||
* Negotiate, which hash algorithm to use.
|
||||
* <p>
|
||||
* This method gives the highest priority to the algorithm override, which can be set via {@link #overrideHashAlgorithm(HashAlgorithm)}.
|
||||
* After that, the signing keys hash algorithm preferences are iterated to find the first acceptable algorithm.
|
||||
* Lastly, should no acceptable algorithm be found, the {@link Policy Policies} default signature hash algorithm is
|
||||
* used as a fallback.
|
||||
*
|
||||
* @param preferences preferences
|
||||
* @param policy policy
|
||||
* @return selected hash algorithm
|
||||
*/
|
||||
@Nonnull
|
||||
private HashAlgorithm negotiateHashAlgorithm(@Nonnull Set<HashAlgorithm> preferences,
|
||||
@Nonnull Policy policy) {
|
||||
if (hashAlgorithmOverride != null) {
|
||||
return hashAlgorithmOverride;
|
||||
}
|
||||
|
||||
return HashAlgorithmNegotiator.negotiateSignatureHashAlgorithm(policy)
|
||||
.negotiateHashAlgorithm(preferences);
|
||||
}
|
||||
|
||||
@Nonnull
|
||||
private PGPSignatureGenerator createSignatureGenerator(@Nonnull PGPPrivateKey privateKey,
|
||||
@Nonnull HashAlgorithm hashAlgorithm,
|
||||
@Nonnull DocumentSignatureType signatureType)
|
||||
throws PGPException {
|
||||
int publicKeyAlgorithm = privateKey.getPublicKeyPacket().getAlgorithm();
|
||||
PGPContentSignerBuilder signerBuilder = ImplementationFactory.getInstance()
|
||||
.getPGPContentSignerBuilder(publicKeyAlgorithm, hashAlgorithm.getAlgorithmId());
|
||||
PGPSignatureGenerator signatureGenerator = new PGPSignatureGenerator(signerBuilder);
|
||||
signatureGenerator.init(signatureType.getSignatureType().getCode(), privateKey);
|
||||
|
||||
return signatureGenerator;
|
||||
}
|
||||
|
||||
/**
|
||||
* Return a map of key-ids and signing methods.
|
||||
* For internal use.
|
||||
*
|
||||
* @return signing methods
|
||||
*/
|
||||
@Nonnull
|
||||
Map<SubkeyIdentifier, SigningMethod> getSigningMethods() {
|
||||
return Collections.unmodifiableMap(signingMethods);
|
||||
}
|
||||
|
||||
/**
|
||||
* Override hash algorithm negotiation by dictating which hash algorithm needs to be used.
|
||||
* If no override has been set, an accetable algorithm will be negotiated instead.
|
||||
* <p>
|
||||
* Note: To override the hash algorithm for signing, call this method *before* calling
|
||||
* {@link #addInlineSignature(SecretKeyRingProtector, PGPSecretKeyRing, DocumentSignatureType)} or
|
||||
* {@link #addDetachedSignature(SecretKeyRingProtector, PGPSecretKeyRing, DocumentSignatureType)}.
|
||||
*
|
||||
* @param hashAlgorithmOverride override hash algorithm
|
||||
* @return this
|
||||
*/
|
||||
@Nonnull
|
||||
public SigningOptions overrideHashAlgorithm(@Nonnull HashAlgorithm hashAlgorithmOverride) {
|
||||
this.hashAlgorithmOverride = hashAlgorithmOverride;
|
||||
return this;
|
||||
}
|
||||
|
||||
/**
|
||||
* Return the hash algorithm override (or null if no override is set).
|
||||
*
|
||||
* @return hash algorithm override
|
||||
*/
|
||||
@Nullable
|
||||
public HashAlgorithm getHashAlgorithmOverride() {
|
||||
return hashAlgorithmOverride;
|
||||
}
|
||||
}
|
|
@ -0,0 +1,451 @@
|
|||
// SPDX-FileCopyrightText: 2023 Paul Schaub <vanitasvitae@fsfe.org>
|
||||
//
|
||||
// SPDX-License-Identifier: Apache-2.0
|
||||
|
||||
package org.pgpainless.encryption_signing
|
||||
|
||||
import org.bouncycastle.openpgp.*
|
||||
import org.pgpainless.PGPainless.Companion.getPolicy
|
||||
import org.pgpainless.PGPainless.Companion.inspectKeyRing
|
||||
import org.pgpainless.algorithm.DocumentSignatureType
|
||||
import org.pgpainless.algorithm.HashAlgorithm
|
||||
import org.pgpainless.algorithm.PublicKeyAlgorithm.Companion.requireFromId
|
||||
import org.pgpainless.algorithm.negotiation.HashAlgorithmNegotiator.Companion.negotiateSignatureHashAlgorithm
|
||||
import org.pgpainless.exception.KeyException
|
||||
import org.pgpainless.exception.KeyException.*
|
||||
import org.pgpainless.implementation.ImplementationFactory
|
||||
import org.pgpainless.key.OpenPgpFingerprint.Companion.of
|
||||
import org.pgpainless.key.SubkeyIdentifier
|
||||
import org.pgpainless.key.protection.SecretKeyRingProtector
|
||||
import org.pgpainless.key.protection.UnlockSecretKey.Companion.unlockSecretKey
|
||||
import org.pgpainless.policy.Policy
|
||||
import org.pgpainless.signature.subpackets.BaseSignatureSubpackets.Callback
|
||||
import org.pgpainless.signature.subpackets.SignatureSubpackets
|
||||
import org.pgpainless.signature.subpackets.SignatureSubpacketsHelper
|
||||
import java.util.*
|
||||
|
||||
class SigningOptions {
|
||||
|
||||
val signingMethods: Map<SubkeyIdentifier, SigningMethod> = mutableMapOf()
|
||||
private var _hashAlgorithmOverride: HashAlgorithm? = null
|
||||
private var _evaluationDate: Date = Date()
|
||||
|
||||
val hashAlgorithmOverride: HashAlgorithm?
|
||||
get() = _hashAlgorithmOverride
|
||||
|
||||
/**
|
||||
* Override hash algorithm negotiation by dictating which hash algorithm needs to be used.
|
||||
* If no override has been set, an acceptable algorithm will be negotiated instead.
|
||||
* Note: To override the hash algorithm for signing, call this method *before* calling
|
||||
* [addInlineSignature] or [addDetachedSignature].
|
||||
*
|
||||
* @param hashAlgorithmOverride override hash algorithm
|
||||
* @return this
|
||||
*/
|
||||
fun overrideHashAlgorithm(hashAlgorithmOverride: HashAlgorithm) = apply {
|
||||
_hashAlgorithmOverride = hashAlgorithmOverride
|
||||
}
|
||||
|
||||
val evaluationDate: Date
|
||||
get() = _evaluationDate
|
||||
|
||||
/**
|
||||
* Override the evaluation date for signing keys with the given date.
|
||||
*
|
||||
* @param evaluationDate new evaluation date
|
||||
* @return this
|
||||
*/
|
||||
fun setEvaluationDate(evaluationDate: Date) = apply {
|
||||
_evaluationDate = evaluationDate
|
||||
}
|
||||
|
||||
/**
|
||||
* Sign the message using an inline signature made by the provided signing key.
|
||||
*
|
||||
* @param signingKeyProtector protector to unlock the signing key
|
||||
* @param signingKey key ring containing the signing key
|
||||
* @return this
|
||||
*
|
||||
* @throws KeyException if something is wrong with the key
|
||||
* @throws PGPException if the key cannot be unlocked or a signing method cannot be created
|
||||
*/
|
||||
@Throws(KeyException::class, PGPException::class)
|
||||
fun addSignature(signingKeyProtector: SecretKeyRingProtector, signingKey: PGPSecretKeyRing) = apply {
|
||||
addInlineSignature(signingKeyProtector, signingKey, null, DocumentSignatureType.BINARY_DOCUMENT)
|
||||
}
|
||||
|
||||
/**
|
||||
* Add inline signatures with all secret key rings in the provided secret key ring collection.
|
||||
*
|
||||
* @param signingKeyProtector decryptor to unlock the signing secret keys
|
||||
* @param signingKeys collection of signing keys
|
||||
* @param signatureType type of signature (binary, canonical text)
|
||||
* @return this
|
||||
*
|
||||
* @throws KeyException if something is wrong with any of the keys
|
||||
* @throws PGPException if any of the keys cannot be unlocked or a signing method cannot be created
|
||||
*/
|
||||
@Throws(KeyException::class, PGPException::class)
|
||||
fun addInlineSignatures(signingKeyProtector: SecretKeyRingProtector,
|
||||
signingKeys: Iterable<PGPSecretKeyRing>,
|
||||
signatureType: DocumentSignatureType) = apply {
|
||||
signingKeys.forEach {
|
||||
addInlineSignature(signingKeyProtector, it, null, signatureType)
|
||||
}
|
||||
}
|
||||
|
||||
|
||||
/**
|
||||
* Add an inline-signature.
|
||||
* Inline signatures are being embedded into the message itself and can be processed in one pass, thanks to the use
|
||||
* of one-pass-signature packets.
|
||||
*
|
||||
* @param signingKeyProtector decryptor to unlock the signing secret key
|
||||
* @param signingKey signing key
|
||||
* @param signatureType type of signature (binary, canonical text)
|
||||
* @return this
|
||||
*
|
||||
* @throws KeyException if something is wrong with the key
|
||||
* @throws PGPException if the key cannot be unlocked or the signing method cannot be created
|
||||
*/
|
||||
@Throws(KeyException::class, PGPException::class)
|
||||
fun addInlineSignature(signingKeyProtector: SecretKeyRingProtector,
|
||||
signingKey: PGPSecretKeyRing,
|
||||
signatureType: DocumentSignatureType) = apply {
|
||||
addInlineSignature(signingKeyProtector, signingKey, null, signatureType)
|
||||
}
|
||||
|
||||
/**
|
||||
* Add an inline-signature.
|
||||
* Inline signatures are being embedded into the message itself and can be processed in one pass, thanks to the use
|
||||
* of one-pass-signature packets.
|
||||
* <p>
|
||||
* This method uses the passed in user-id to select user-specific hash algorithms.
|
||||
*
|
||||
* @param signingKeyProtector decryptor to unlock the signing secret key
|
||||
* @param signingKey signing key
|
||||
* @param userId user-id of the signer
|
||||
* @param signatureType signature type (binary, canonical text)
|
||||
* @param subpacketsCallback callback to modify the hashed and unhashed subpackets of the signature
|
||||
* @return this
|
||||
*
|
||||
* @throws KeyException if the key is invalid
|
||||
* @throws PGPException if the key cannot be unlocked or the signing method cannot be created
|
||||
*/
|
||||
@Throws(KeyException::class, PGPException::class)
|
||||
@JvmOverloads
|
||||
fun addInlineSignature(signingKeyProtector: SecretKeyRingProtector,
|
||||
signingKey: PGPSecretKeyRing,
|
||||
userId: CharSequence? = null,
|
||||
signatureType: DocumentSignatureType = DocumentSignatureType.BINARY_DOCUMENT,
|
||||
subpacketsCallback: Callback? = null) = apply {
|
||||
val keyRingInfo = inspectKeyRing(signingKey, evaluationDate)
|
||||
if (userId != null && !keyRingInfo.isUserIdValid(userId)) {
|
||||
throw UnboundUserIdException(
|
||||
of(signingKey),
|
||||
userId.toString(),
|
||||
keyRingInfo.getLatestUserIdCertification(userId),
|
||||
keyRingInfo.getUserIdRevocation(userId)
|
||||
)
|
||||
}
|
||||
|
||||
val signingPubKeys = keyRingInfo.signingSubkeys
|
||||
if (signingPubKeys.isEmpty()) {
|
||||
throw UnacceptableSigningKeyException(of(signingKey))
|
||||
}
|
||||
|
||||
for (signingPubKey in signingPubKeys) {
|
||||
val signingSecKey: PGPSecretKey = signingKey.getSecretKey(signingPubKey.keyID)
|
||||
?: throw MissingSecretKeyException(of(signingKey), signingPubKey.keyID)
|
||||
val signingSubkey: PGPPrivateKey = unlockSecretKey(signingSecKey, signingKeyProtector)
|
||||
val hashAlgorithms =
|
||||
if (userId != null) keyRingInfo.getPreferredHashAlgorithms(userId)
|
||||
else keyRingInfo.getPreferredHashAlgorithms(signingPubKey.keyID)
|
||||
val hashAlgorithm: HashAlgorithm = negotiateHashAlgorithm(hashAlgorithms, getPolicy())
|
||||
addSigningMethod(signingKey, signingSubkey, hashAlgorithm, signatureType, false, subpacketsCallback)
|
||||
}
|
||||
}
|
||||
|
||||
/**
|
||||
* Create an inline signature using the signing key with the given keyId.
|
||||
*
|
||||
* @param signingKeyProtector decryptor to unlock the secret key
|
||||
* @param signingKey secret key ring
|
||||
* @param keyId keyId of the signing (sub-)key
|
||||
* @param signatureType signature type
|
||||
* @param subpacketsCallback callback to modify the signatures subpackets
|
||||
* @return builder
|
||||
* @throws PGPException if the secret key cannot be unlocked or if no signing method can be created.
|
||||
* @throws KeyException.UnacceptableSigningKeyException if the key ring does not carry any signing-capable subkeys
|
||||
* @throws KeyException.MissingSecretKeyException if the key ring does not contain the identified secret key
|
||||
*/
|
||||
@Throws(KeyException::class, PGPException::class)
|
||||
@JvmOverloads
|
||||
fun addInlineSignature(signingKeyProtector: SecretKeyRingProtector,
|
||||
signingKey: PGPSecretKeyRing,
|
||||
keyId: Long,
|
||||
signatureType: DocumentSignatureType = DocumentSignatureType.BINARY_DOCUMENT,
|
||||
subpacketsCallback: Callback? = null) = apply {
|
||||
val keyRingInfo = inspectKeyRing(signingKey, evaluationDate)
|
||||
val signingPubKeys = keyRingInfo.signingSubkeys
|
||||
if (signingPubKeys.isEmpty()) {
|
||||
throw UnacceptableSigningKeyException(of(signingKey))
|
||||
}
|
||||
|
||||
for (signingPubKey in signingPubKeys) {
|
||||
if (signingPubKey.keyID != keyId) {
|
||||
continue
|
||||
}
|
||||
|
||||
val signingSecKey = signingKey.getSecretKey(signingPubKey.keyID)
|
||||
?: throw MissingSecretKeyException(of(signingKey), signingPubKey.keyID)
|
||||
val signingSubkey = unlockSecretKey(signingSecKey, signingKeyProtector)
|
||||
val hashAlgorithms = keyRingInfo.getPreferredHashAlgorithms(signingPubKey.keyID)
|
||||
val hashAlgorithm: HashAlgorithm = negotiateHashAlgorithm(hashAlgorithms, getPolicy())
|
||||
addSigningMethod(signingKey, signingSubkey, hashAlgorithm, signatureType, false, subpacketsCallback)
|
||||
return this
|
||||
}
|
||||
throw MissingSecretKeyException(of(signingKey), keyId)
|
||||
}
|
||||
|
||||
/**
|
||||
* Add detached signatures with all key rings from the provided secret key ring collection.
|
||||
*
|
||||
* @param signingKeyProtector decryptor to unlock the secret signing keys
|
||||
* @param signingKeys collection of signing key rings
|
||||
* @param signatureType type of the signature (binary, canonical text)
|
||||
* @return this
|
||||
*
|
||||
* @throws KeyException if something is wrong with any of the keys
|
||||
* @throws PGPException if any of the keys cannot be validated or unlocked, or if any signing method cannot be created
|
||||
*/
|
||||
@Throws(KeyException::class, PGPException::class)
|
||||
fun addDetachedSignatures(signingKeyProtector: SecretKeyRingProtector,
|
||||
signingKeys: Iterable<PGPSecretKeyRing>,
|
||||
signatureType: DocumentSignatureType) = apply {
|
||||
signingKeys.forEach {
|
||||
addDetachedSignature(signingKeyProtector, it, null, signatureType)
|
||||
}
|
||||
}
|
||||
|
||||
/**
|
||||
* Create a detached signature.
|
||||
* Detached signatures are not being added into the PGP message itself.
|
||||
* Instead, they can be distributed separately to the message.
|
||||
* Detached signatures are useful if the data that is being signed shall not be modified (e.g. when signing a file).
|
||||
*
|
||||
* @param signingKeyProtector decryptor to unlock the secret signing key
|
||||
* @param signingKey signing key
|
||||
* @param signatureType type of data that is signed (binary, canonical text)
|
||||
* @return this
|
||||
*
|
||||
* @throws KeyException if something is wrong with the key
|
||||
* @throws PGPException if the key cannot be validated or unlocked, or if no signature method can be created
|
||||
*/
|
||||
@Throws(KeyException::class, PGPException::class)
|
||||
fun addDetachedSignature(signingKeyProtector: SecretKeyRingProtector,
|
||||
signingKey: PGPSecretKeyRing,
|
||||
signatureType: DocumentSignatureType) = apply {
|
||||
addDetachedSignature(signingKeyProtector, signingKey, null, signatureType)
|
||||
}
|
||||
|
||||
/**
|
||||
* Create a detached signature.
|
||||
* Detached signatures are not being added into the PGP message itself.
|
||||
* Instead, they can be distributed separately to the message.
|
||||
* Detached signatures are useful if the data that is being signed shall not be modified (e.g. when signing a file).
|
||||
* <p>
|
||||
* This method uses the passed in user-id to select user-specific hash algorithms.
|
||||
*
|
||||
* @param signingKeyProtector decryptor to unlock the secret signing key
|
||||
* @param signingKey signing key
|
||||
* @param userId user-id
|
||||
* @param signatureType type of data that is signed (binary, canonical text)
|
||||
* @param subpacketCallback callback to modify hashed and unhashed subpackets of the signature
|
||||
* @return this
|
||||
*
|
||||
* @throws KeyException if something is wrong with the key
|
||||
* @throws PGPException if the key cannot be validated or unlocked, or if no signature method can be created
|
||||
*/
|
||||
@JvmOverloads
|
||||
@Throws(KeyException::class, PGPException::class)
|
||||
fun addDetachedSignature(signingKeyProtector: SecretKeyRingProtector,
|
||||
signingKey: PGPSecretKeyRing,
|
||||
userId: String? = null,
|
||||
signatureType: DocumentSignatureType = DocumentSignatureType.BINARY_DOCUMENT,
|
||||
subpacketCallback: Callback? = null) = apply {
|
||||
val keyRingInfo = inspectKeyRing(signingKey, evaluationDate)
|
||||
if (userId != null && !keyRingInfo.isUserIdValid(userId)) {
|
||||
throw UnboundUserIdException(
|
||||
of(signingKey),
|
||||
userId.toString(),
|
||||
keyRingInfo.getLatestUserIdCertification(userId),
|
||||
keyRingInfo.getUserIdRevocation(userId)
|
||||
)
|
||||
}
|
||||
|
||||
val signingPubKeys = keyRingInfo.signingSubkeys
|
||||
if (signingPubKeys.isEmpty()) {
|
||||
throw UnacceptableSigningKeyException(of(signingKey))
|
||||
}
|
||||
|
||||
for (signingPubKey in signingPubKeys) {
|
||||
val signingSecKey: PGPSecretKey = signingKey.getSecretKey(signingPubKey.keyID)
|
||||
?: throw MissingSecretKeyException(of(signingKey), signingPubKey.keyID)
|
||||
val signingSubkey: PGPPrivateKey = unlockSecretKey(signingSecKey, signingKeyProtector)
|
||||
val hashAlgorithms =
|
||||
if (userId != null) keyRingInfo.getPreferredHashAlgorithms(userId)
|
||||
else keyRingInfo.getPreferredHashAlgorithms(signingPubKey.keyID)
|
||||
val hashAlgorithm: HashAlgorithm = negotiateHashAlgorithm(hashAlgorithms, getPolicy())
|
||||
addSigningMethod(signingKey, signingSubkey, hashAlgorithm, signatureType, true, subpacketCallback)
|
||||
}
|
||||
}
|
||||
|
||||
/**
|
||||
* Create a detached signature using the signing key with the given keyId.
|
||||
*
|
||||
* @param signingKeyProtector decryptor to unlock the secret key
|
||||
* @param signingKey secret key ring
|
||||
* @param keyId keyId of the signing (sub-)key
|
||||
* @param signatureType signature type
|
||||
* @param subpacketsCallback callback to modify the signatures subpackets
|
||||
* @return builder
|
||||
* @throws PGPException if the secret key cannot be unlocked or if no signing method can be created.
|
||||
* @throws KeyException.UnacceptableSigningKeyException if the key ring does not carry any signing-capable subkeys
|
||||
* @throws KeyException.MissingSecretKeyException if the key ring does not contain the identified secret key
|
||||
*/
|
||||
@Throws(KeyException::class, PGPException::class)
|
||||
@JvmOverloads
|
||||
fun addDetachedSignature(signingKeyProtector: SecretKeyRingProtector,
|
||||
signingKey: PGPSecretKeyRing,
|
||||
keyId: Long,
|
||||
signatureType: DocumentSignatureType = DocumentSignatureType.BINARY_DOCUMENT,
|
||||
subpacketsCallback: Callback? = null) = apply {
|
||||
val keyRingInfo = inspectKeyRing(signingKey, evaluationDate)
|
||||
|
||||
val signingPubKeys = keyRingInfo.signingSubkeys
|
||||
if (signingPubKeys.isEmpty()) {
|
||||
throw UnacceptableSigningKeyException(of(signingKey))
|
||||
}
|
||||
|
||||
for (signingPubKey in signingPubKeys) {
|
||||
if (signingPubKey.keyID == keyId) {
|
||||
val signingSecKey: PGPSecretKey = signingKey.getSecretKey(signingPubKey.keyID)
|
||||
?: throw MissingSecretKeyException(of(signingKey), signingPubKey.keyID)
|
||||
val signingSubkey: PGPPrivateKey = unlockSecretKey(signingSecKey, signingKeyProtector)
|
||||
val hashAlgorithms = keyRingInfo.getPreferredHashAlgorithms(signingPubKey.keyID)
|
||||
val hashAlgorithm: HashAlgorithm = negotiateHashAlgorithm(hashAlgorithms, getPolicy())
|
||||
addSigningMethod(signingKey, signingSubkey, hashAlgorithm, signatureType, true, subpacketsCallback)
|
||||
return this
|
||||
}
|
||||
}
|
||||
|
||||
throw MissingSecretKeyException(of(signingKey), keyId)
|
||||
}
|
||||
|
||||
private fun addSigningMethod(signingKey: PGPSecretKeyRing,
|
||||
signingSubkey: PGPPrivateKey,
|
||||
hashAlgorithm: HashAlgorithm,
|
||||
signatureType: DocumentSignatureType,
|
||||
detached: Boolean,
|
||||
subpacketCallback: Callback? = null) {
|
||||
val signingKeyIdentifier = SubkeyIdentifier(signingKey, signingSubkey.keyID)
|
||||
val signingSecretKey: PGPSecretKey = signingKey.getSecretKey(signingSubkey.keyID)
|
||||
val publicKeyAlgorithm = requireFromId(signingSecretKey.publicKey.algorithm)
|
||||
val bitStrength = signingSecretKey.publicKey.bitStrength
|
||||
if (!getPolicy().publicKeyAlgorithmPolicy.isAcceptable(publicKeyAlgorithm, bitStrength)) {
|
||||
throw UnacceptableSigningKeyException(
|
||||
PublicKeyAlgorithmPolicyException(
|
||||
of(signingKey), signingSecretKey.keyID, publicKeyAlgorithm, bitStrength))
|
||||
}
|
||||
|
||||
val generator: PGPSignatureGenerator = createSignatureGenerator(signingSubkey, hashAlgorithm, signatureType)
|
||||
|
||||
// Subpackets
|
||||
val hashedSubpackets = SignatureSubpackets.createHashedSubpackets(signingSecretKey.publicKey)
|
||||
val unhashedSubpackets = SignatureSubpackets.createEmptySubpackets()
|
||||
if (subpacketCallback != null) {
|
||||
subpacketCallback.modifyHashedSubpackets(hashedSubpackets)
|
||||
subpacketCallback.modifyUnhashedSubpackets(unhashedSubpackets)
|
||||
}
|
||||
generator.setHashedSubpackets(SignatureSubpacketsHelper.toVector(hashedSubpackets))
|
||||
generator.setUnhashedSubpackets(SignatureSubpacketsHelper.toVector(unhashedSubpackets))
|
||||
|
||||
val signingMethod =
|
||||
if (detached) SigningMethod.detachedSignature(generator, hashAlgorithm)
|
||||
else SigningMethod.inlineSignature(generator, hashAlgorithm)
|
||||
(signingMethods as MutableMap)[signingKeyIdentifier] = signingMethod
|
||||
}
|
||||
|
||||
/**
|
||||
* Negotiate, which hash algorithm to use.
|
||||
*
|
||||
*
|
||||
* This method gives the highest priority to the algorithm override, which can be set via [.overrideHashAlgorithm].
|
||||
* After that, the signing keys hash algorithm preferences are iterated to find the first acceptable algorithm.
|
||||
* Lastly, should no acceptable algorithm be found, the [Policies][Policy] default signature hash algorithm is
|
||||
* used as a fallback.
|
||||
*
|
||||
* @param preferences preferences
|
||||
* @param policy policy
|
||||
* @return selected hash algorithm
|
||||
*/
|
||||
private fun negotiateHashAlgorithm(preferences: Set<HashAlgorithm>,
|
||||
policy: Policy): HashAlgorithm {
|
||||
return _hashAlgorithmOverride ?: negotiateSignatureHashAlgorithm(policy).negotiateHashAlgorithm(preferences)
|
||||
}
|
||||
|
||||
@Throws(PGPException::class)
|
||||
private fun createSignatureGenerator(privateKey: PGPPrivateKey,
|
||||
hashAlgorithm: HashAlgorithm,
|
||||
signatureType: DocumentSignatureType): PGPSignatureGenerator {
|
||||
return ImplementationFactory.getInstance()
|
||||
.getPGPContentSignerBuilder(privateKey.publicKeyPacket.algorithm, hashAlgorithm.algorithmId)
|
||||
.let { csb ->
|
||||
PGPSignatureGenerator(csb).also { it.init(signatureType.signatureType.code, privateKey) }
|
||||
}
|
||||
}
|
||||
|
||||
|
||||
companion object {
|
||||
@JvmStatic
|
||||
fun get() = SigningOptions()
|
||||
}
|
||||
|
||||
/**
|
||||
* A method of signing.
|
||||
*/
|
||||
class SigningMethod private constructor(
|
||||
val signatureGenerator: PGPSignatureGenerator,
|
||||
val isDetached: Boolean,
|
||||
val hashAlgorithm: HashAlgorithm
|
||||
) {
|
||||
companion object {
|
||||
|
||||
/**
|
||||
* Inline-signature method.
|
||||
* The resulting signature will be written into the message itself, together with a one-pass-signature packet.
|
||||
*
|
||||
* @param signatureGenerator signature generator
|
||||
* @param hashAlgorithm hash algorithm used to generate the signature
|
||||
* @return inline signing method
|
||||
*/
|
||||
@JvmStatic
|
||||
fun inlineSignature(signatureGenerator: PGPSignatureGenerator, hashAlgorithm: HashAlgorithm) =
|
||||
SigningMethod(signatureGenerator, false, hashAlgorithm)
|
||||
|
||||
/**
|
||||
* Detached signing method.
|
||||
* The resulting signature will not be added to the message, and instead can be distributed separately
|
||||
* to the signed message.
|
||||
*
|
||||
* @param signatureGenerator signature generator
|
||||
* @param hashAlgorithm hash algorithm used to generate the signature
|
||||
* @return detached signing method
|
||||
*/
|
||||
@JvmStatic
|
||||
fun detachedSignature(signatureGenerator: PGPSignatureGenerator, hashAlgorithm: HashAlgorithm) =
|
||||
SigningMethod(signatureGenerator, true, hashAlgorithm)
|
||||
}
|
||||
}
|
||||
}
|
Loading…
Reference in a new issue