/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* * This file is part of the LibreOffice project. * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. * * This file incorporates work covered by the following license notice: * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed * with this work for additional information regarding copyright * ownership. The ASF licenses this file to you under the Apache * License, Version 2.0 (the "License"); you may not use this file * except in compliance with the License. You may obtain a copy of * the License at http://www.apache.org/licenses/LICENSE-2.0 . */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if HAVE_FEATURE_GPGME # include # include # include #endif using ::com::sun::star::uno::Sequence; using ::com::sun::star::uno::Exception; using ::com::sun::star::uno::Reference; using ::com::sun::star::task::PasswordRequestMode; using ::com::sun::star::task::PasswordRequestMode_PASSWORD_ENTER; using ::com::sun::star::task::PasswordRequestMode_PASSWORD_REENTER; using ::com::sun::star::task::XInteractionHandler; using ::com::sun::star::task::XInteractionRequest; using namespace ::com::sun::star; namespace comphelper { static uno::Sequence< sal_Int8 > GeneratePBKDF2Hash( std::u16string_view aPassword, const uno::Sequence< sal_Int8 >& aSalt, sal_Int32 nCount, sal_Int32 nHashLength ) { uno::Sequence< sal_Int8 > aResult; if ( !aPassword.empty() && aSalt.hasElements() && nCount && nHashLength ) { OString aBytePass = OUStringToOString( aPassword, RTL_TEXTENCODING_UTF8 ); // FIXME this is subject to the SHA1-bug tdf#114939 - see also // RequestPassword() in filedlghelper.cxx aResult.realloc( 16 ); rtl_digest_PBKDF2( reinterpret_cast < sal_uInt8 * > ( aResult.getArray() ), aResult.getLength(), reinterpret_cast < const sal_uInt8 * > ( aBytePass.getStr() ), aBytePass.getLength(), reinterpret_cast < const sal_uInt8 * > ( aSalt.getConstArray() ), aSalt.getLength(), nCount ); } return aResult; } IDocPasswordVerifier::~IDocPasswordVerifier() { } uno::Sequence< beans::PropertyValue > DocPasswordHelper::GenerateNewModifyPasswordInfo( std::u16string_view aPassword ) { uno::Sequence< beans::PropertyValue > aResult; uno::Sequence< sal_Int8 > aSalt = GenerateRandomByteSequence( 16 ); sal_Int32 const nPBKDF2IterationCount = 100000; uno::Sequence< sal_Int8 > aNewHash = GeneratePBKDF2Hash(aPassword, aSalt, nPBKDF2IterationCount, 16); if ( aNewHash.hasElements() ) { aResult = { comphelper::makePropertyValue("algorithm-name", OUString( "PBKDF2" )), comphelper::makePropertyValue("salt", aSalt), comphelper::makePropertyValue("iteration-count", nPBKDF2IterationCount), comphelper::makePropertyValue("hash", aNewHash) }; } return aResult; } uno::Sequence DocPasswordHelper::GenerateNewModifyPasswordInfoOOXML(std::u16string_view aPassword) { uno::Sequence aResult; if (!aPassword.empty()) { uno::Sequence aSalt = GenerateRandomByteSequence(16); OUStringBuffer aBuffer(22); comphelper::Base64::encode(aBuffer, aSalt); OUString sSalt = aBuffer.makeStringAndClear(); sal_Int32 const nIterationCount = 100000; OUString sAlgorithm("SHA-512"); const OUString sHash(GetOoxHashAsBase64(OUString(aPassword), sSalt, nIterationCount, comphelper::Hash::IterCount::APPEND, sAlgorithm)); if (!sHash.isEmpty()) { aResult = { comphelper::makePropertyValue("algorithm-name", sAlgorithm), comphelper::makePropertyValue("salt", sSalt), comphelper::makePropertyValue("iteration-count", nIterationCount), comphelper::makePropertyValue("hash", sHash) }; } } return aResult; } uno::Sequence< beans::PropertyValue > DocPasswordHelper::ConvertPasswordInfo( const uno::Sequence< beans::PropertyValue >& aInfo ) { uno::Sequence< beans::PropertyValue > aResult; OUString sAlgorithm, sHash, sSalt, sCount; sal_Int32 nAlgorithm = 0; for ( const auto & prop : aInfo ) { if ( prop.Name == "cryptAlgorithmSid" ) { prop.Value >>= sAlgorithm; nAlgorithm = sAlgorithm.toInt32(); } else if ( prop.Name == "salt" ) prop.Value >>= sSalt; else if ( prop.Name == "cryptSpinCount" ) prop.Value >>= sCount; else if ( prop.Name == "hash" ) prop.Value >>= sHash; } if (nAlgorithm == 1) sAlgorithm = "MD2"; else if (nAlgorithm == 2) sAlgorithm = "MD4"; else if (nAlgorithm == 3) sAlgorithm = "MD5"; else if (nAlgorithm == 4) sAlgorithm = "SHA-1"; else if (nAlgorithm == 5) sAlgorithm = "MAC"; else if (nAlgorithm == 6) sAlgorithm = "RIPEMD"; else if (nAlgorithm == 7) sAlgorithm = "RIPEMD-160"; else if (nAlgorithm == 9) sAlgorithm = "HMAC"; else if (nAlgorithm == 12) sAlgorithm = "SHA-256"; else if (nAlgorithm == 13) sAlgorithm = "SHA-384"; else if (nAlgorithm == 14) sAlgorithm = "SHA-512"; if ( !sCount.isEmpty() ) { sal_Int32 nCount = sCount.toInt32(); aResult = { comphelper::makePropertyValue("algorithm-name", sAlgorithm), comphelper::makePropertyValue("salt", sSalt), comphelper::makePropertyValue("iteration-count", nCount), comphelper::makePropertyValue("hash", sHash) }; } return aResult; } bool DocPasswordHelper::IsModifyPasswordCorrect( std::u16string_view aPassword, const uno::Sequence< beans::PropertyValue >& aInfo ) { bool bResult = false; if ( !aPassword.empty() && aInfo.hasElements() ) { OUString sAlgorithm; uno::Any aSalt, aHash; sal_Int32 nCount = 0; for ( const auto & prop : aInfo ) { if ( prop.Name == "algorithm-name" ) prop.Value >>= sAlgorithm; else if ( prop.Name == "salt" ) aSalt = prop.Value; else if ( prop.Name == "iteration-count" ) prop.Value >>= nCount; else if ( prop.Name == "hash" ) aHash = prop.Value; } if ( sAlgorithm == "PBKDF2" ) { uno::Sequence aIntSalt, aIntHash; aSalt >>= aIntSalt; aHash >>= aIntHash; if (aIntSalt.hasElements() && nCount > 0 && aIntHash.hasElements()) { uno::Sequence aNewHash = GeneratePBKDF2Hash(aPassword, aIntSalt, nCount, aIntHash.getLength()); for (sal_Int32 nInd = 0; nInd < aNewHash.getLength() && nInd < aIntHash.getLength() && aNewHash[nInd] == aIntHash[nInd]; nInd++) { if (nInd == aNewHash.getLength() - 1 && nInd == aIntHash.getLength() - 1) bResult = true; } } } else if (nCount > 0) { OUString sSalt, sHash; aSalt >>= sSalt; aHash >>= sHash; if (!sSalt.isEmpty() && !sHash.isEmpty()) { const OUString aNewHash(GetOoxHashAsBase64(OUString(aPassword), sSalt, nCount, comphelper::Hash::IterCount::APPEND, sAlgorithm)); if (!aNewHash.isEmpty()) bResult = aNewHash == sHash; } } } return bResult; } sal_uInt32 DocPasswordHelper::GetWordHashAsUINT32( std::u16string_view aUString ) { static const sal_uInt16 pInitialCode[] = { 0xE1F0, // 1 0x1D0F, // 2 0xCC9C, // 3 0x84C0, // 4 0x110C, // 5 0x0E10, // 6 0xF1CE, // 7 0x313E, // 8 0x1872, // 9 0xE139, // 10 0xD40F, // 11 0x84F9, // 12 0x280C, // 13 0xA96A, // 14 0x4EC3 // 15 }; static const sal_uInt16 pEncryptionMatrix[15][7] = { { 0xAEFC, 0x4DD9, 0x9BB2, 0x2745, 0x4E8A, 0x9D14, 0x2A09}, // last-14 { 0x7B61, 0xF6C2, 0xFDA5, 0xEB6B, 0xC6F7, 0x9DCF, 0x2BBF}, // last-13 { 0x4563, 0x8AC6, 0x05AD, 0x0B5A, 0x16B4, 0x2D68, 0x5AD0}, // last-12 { 0x0375, 0x06EA, 0x0DD4, 0x1BA8, 0x3750, 0x6EA0, 0xDD40}, // last-11 { 0xD849, 0xA0B3, 0x5147, 0xA28E, 0x553D, 0xAA7A, 0x44D5}, // last-10 { 0x6F45, 0xDE8A, 0xAD35, 0x4A4B, 0x9496, 0x390D, 0x721A}, // last-9 { 0xEB23, 0xC667, 0x9CEF, 0x29FF, 0x53FE, 0xA7FC, 0x5FD9}, // last-8 { 0x47D3, 0x8FA6, 0x8FA6, 0x1EDA, 0x3DB4, 0x7B68, 0xF6D0}, // last-7 { 0xB861, 0x60E3, 0xC1C6, 0x93AD, 0x377B, 0x6EF6, 0xDDEC}, // last-6 { 0x45A0, 0x8B40, 0x06A1, 0x0D42, 0x1A84, 0x3508, 0x6A10}, // last-5 { 0xAA51, 0x4483, 0x8906, 0x022D, 0x045A, 0x08B4, 0x1168}, // last-4 { 0x76B4, 0xED68, 0xCAF1, 0x85C3, 0x1BA7, 0x374E, 0x6E9C}, // last-3 { 0x3730, 0x6E60, 0xDCC0, 0xA9A1, 0x4363, 0x86C6, 0x1DAD}, // last-2 { 0x3331, 0x6662, 0xCCC4, 0x89A9, 0x0373, 0x06E6, 0x0DCC}, // last-1 { 0x1021, 0x2042, 0x4084, 0x8108, 0x1231, 0x2462, 0x48C4} // last }; sal_uInt32 nResult = 0; size_t nLen = aUString.size(); if ( nLen ) { if ( nLen > 15 ) nLen = 15; sal_uInt16 nHighResult = pInitialCode[nLen - 1]; sal_uInt16 nLowResult = 0; for ( size_t nInd = 0; nInd < nLen; nInd++ ) { // NO Encoding during conversion! // The specification says that the low byte should be used in case it is not NULL char nHighChar = static_cast( aUString[nInd] >> 8 ); char nLowChar = static_cast( aUString[nInd] & 0xFF ); char nChar = nLowChar ? nLowChar : nHighChar; for ( int nMatrixInd = 0; nMatrixInd < 7; ++nMatrixInd ) { if ( ( nChar & ( 1 << nMatrixInd ) ) != 0 ) nHighResult = nHighResult ^ pEncryptionMatrix[15 - nLen + nInd][nMatrixInd]; } nLowResult = ( ( ( nLowResult >> 14 ) & 0x0001 ) | ( ( nLowResult << 1 ) & 0x7FFF ) ) ^ nChar; } nLowResult = static_cast( ( ( ( nLowResult >> 14 ) & 0x001 ) | ( ( nLowResult << 1 ) & 0x7FF ) ) ^ nLen ^ 0xCE4B ); nResult = ( nHighResult << 16 ) | nLowResult; } return nResult; } sal_uInt16 DocPasswordHelper::GetXLHashAsUINT16( std::u16string_view aUString, rtl_TextEncoding nEnc ) { sal_uInt16 nResult = 0; OString aString = OUStringToOString( aUString, nEnc ); if ( !aString.isEmpty() && aString.getLength() <= SAL_MAX_UINT16 ) { for ( sal_Int32 nInd = aString.getLength() - 1; nInd >= 0; nInd-- ) { nResult = ( ( nResult >> 14 ) & 0x01 ) | ( ( nResult << 1 ) & 0x7FFF ); nResult ^= aString[nInd]; } nResult = ( ( nResult >> 14 ) & 0x01 ) | ( ( nResult << 1 ) & 0x7FFF ); nResult ^= ( 0x8000 | ( 'N' << 8 ) | 'K' ); nResult ^= aString.getLength(); } return nResult; } Sequence< sal_Int8 > DocPasswordHelper::GetXLHashAsSequence( std::u16string_view aUString ) { sal_uInt16 nHash = GetXLHashAsUINT16( aUString ); return {sal_Int8(nHash >> 8), sal_Int8(nHash & 0xFF)}; } std::vector DocPasswordHelper::GetOoxHashAsVector( const OUString& rPassword, const std::vector& rSaltValue, sal_uInt32 nSpinCount, comphelper::Hash::IterCount eIterCount, std::u16string_view rAlgorithmName) { comphelper::HashType eType; if (rAlgorithmName == u"SHA-512" || rAlgorithmName == u"SHA512") eType = comphelper::HashType::SHA512; else if (rAlgorithmName == u"SHA-256" || rAlgorithmName == u"SHA256") eType = comphelper::HashType::SHA256; else if (rAlgorithmName == u"SHA-1" || rAlgorithmName == u"SHA1") // "SHA1" might be in the wild eType = comphelper::HashType::SHA1; else if (rAlgorithmName == u"MD5") eType = comphelper::HashType::MD5; else return std::vector(); return comphelper::Hash::calculateHash( rPassword, rSaltValue, nSpinCount, eIterCount, eType); } css::uno::Sequence DocPasswordHelper::GetOoxHashAsSequence( const OUString& rPassword, std::u16string_view rSaltValue, sal_uInt32 nSpinCount, comphelper::Hash::IterCount eIterCount, std::u16string_view rAlgorithmName) { std::vector aSaltVec; if (!rSaltValue.empty()) { css::uno::Sequence aSaltSeq; comphelper::Base64::decode( aSaltSeq, rSaltValue); aSaltVec = comphelper::sequenceToContainer>( aSaltSeq); } std::vector hash( GetOoxHashAsVector( rPassword, aSaltVec, nSpinCount, eIterCount, rAlgorithmName)); return comphelper::containerToSequence( hash); } OUString DocPasswordHelper::GetOoxHashAsBase64( const OUString& rPassword, std::u16string_view rSaltValue, sal_uInt32 nSpinCount, comphelper::Hash::IterCount eIterCount, std::u16string_view rAlgorithmName) { css::uno::Sequence aSeq( GetOoxHashAsSequence( rPassword, rSaltValue, nSpinCount, eIterCount, rAlgorithmName)); OUStringBuffer aBuf((aSeq.getLength()+2)/3*4); comphelper::Base64::encode( aBuf, aSeq); return aBuf.makeStringAndClear(); } /*static*/ uno::Sequence< sal_Int8 > DocPasswordHelper::GenerateRandomByteSequence( sal_Int32 nLength ) { uno::Sequence< sal_Int8 > aResult( nLength ); rtlRandomPool aRandomPool = rtl_random_createPool (); rtl_random_getBytes ( aRandomPool, aResult.getArray(), nLength ); rtl_random_destroyPool ( aRandomPool ); return aResult; } /*static*/ uno::Sequence< sal_Int8 > DocPasswordHelper::GenerateStd97Key( std::u16string_view aPassword, const uno::Sequence< sal_Int8 >& aDocId ) { uno::Sequence< sal_Int8 > aResultKey; if ( !aPassword.empty() && aDocId.getLength() == 16 ) { sal_uInt16 pPassData[16] = {}; sal_Int32 nPassLen = std::min< sal_Int32 >( aPassword.size(), 15 ); memcpy( pPassData, aPassword.data(), nPassLen * sizeof(pPassData[0]) ); aResultKey = GenerateStd97Key( pPassData, aDocId ); } return aResultKey; } /*static*/ uno::Sequence< sal_Int8 > DocPasswordHelper::GenerateStd97Key( const sal_uInt16 pPassData[16], const uno::Sequence< sal_Int8 >& aDocId ) { uno::Sequence< sal_Int8 > aResultKey; if ( aDocId.getLength() == 16 ) aResultKey = GenerateStd97Key(pPassData, reinterpret_cast(aDocId.getConstArray())); return aResultKey; } /*static*/ uno::Sequence< sal_Int8 > DocPasswordHelper::GenerateStd97Key( const sal_uInt16 pPassData[16], const sal_uInt8 pDocId[16] ) { uno::Sequence< sal_Int8 > aResultKey; if ( pPassData[0] ) { sal_uInt8 pKeyData[64] = {}; sal_Int32 nInd = 0; // Fill PassData into KeyData. for ( nInd = 0; nInd < 16 && pPassData[nInd]; nInd++) { pKeyData[2*nInd] = sal::static_int_cast< sal_uInt8 >( (pPassData[nInd] >> 0) & 0xff ); pKeyData[2*nInd + 1] = sal::static_int_cast< sal_uInt8 >( (pPassData[nInd] >> 8) & 0xff ); } pKeyData[2*nInd] = 0x80; pKeyData[56] = sal::static_int_cast< sal_uInt8 >( nInd << 4 ); // Fill raw digest of KeyData into KeyData. rtlDigest hDigest = rtl_digest_create ( rtl_Digest_AlgorithmMD5 ); (void)rtl_digest_updateMD5 ( hDigest, pKeyData, sizeof(pKeyData)); (void)rtl_digest_rawMD5 ( hDigest, pKeyData, RTL_DIGEST_LENGTH_MD5); // Update digest with KeyData and Unique. for ( nInd = 0; nInd < 16; nInd++ ) { rtl_digest_updateMD5( hDigest, pKeyData, 5 ); rtl_digest_updateMD5( hDigest, pDocId, 16 ); } // Update digest with padding. pKeyData[16] = 0x80; memset( pKeyData + 17, 0, sizeof(pKeyData) - 17 ); pKeyData[56] = 0x80; pKeyData[57] = 0x0a; rtl_digest_updateMD5( hDigest, &(pKeyData[16]), sizeof(pKeyData) - 16 ); // Fill raw digest of above updates aResultKey.realloc( RTL_DIGEST_LENGTH_MD5 ); rtl_digest_rawMD5 ( hDigest, reinterpret_cast(aResultKey.getArray()), aResultKey.getLength() ); // Erase KeyData array and leave. rtl_secureZeroMemory (pKeyData, sizeof(pKeyData)); rtl_digest_destroy(hDigest); } return aResultKey; } /*static*/ css::uno::Sequence< css::beans::NamedValue > DocPasswordHelper::requestAndVerifyDocPassword( IDocPasswordVerifier& rVerifier, const css::uno::Sequence< css::beans::NamedValue >& rMediaEncData, const OUString& rMediaPassword, const Reference< XInteractionHandler >& rxInteractHandler, const OUString& rDocumentUrl, DocPasswordRequestType eRequestType, const std::vector< OUString >* pDefaultPasswords, bool* pbIsDefaultPassword ) { css::uno::Sequence< css::beans::NamedValue > aEncData; OUString aPassword; DocPasswordVerifierResult eResult = DocPasswordVerifierResult::WrongPassword; sal_Int32 nMediaEncDataCount = rMediaEncData.getLength(); // tdf#93389: if the document is being restored from autorecovery, we need to add encryption // data also for real document type. // TODO: get real filter name here (from CheckPasswd_Impl), to only add necessary data bool bForSalvage = false; if (nMediaEncDataCount) { for (auto& val : rMediaEncData) { if (val.Name == "ForSalvage") { --nMediaEncDataCount; // don't consider this element below val.Value >>= bForSalvage; break; } } } // first, try provided default passwords if( pbIsDefaultPassword ) *pbIsDefaultPassword = false; if( pDefaultPasswords ) { for( const auto& rPassword : *pDefaultPasswords ) { OSL_ENSURE( !rPassword.isEmpty(), "DocPasswordHelper::requestAndVerifyDocPassword - unexpected empty default password" ); if( !rPassword.isEmpty() ) { eResult = rVerifier.verifyPassword( rPassword, aEncData ); if (eResult == DocPasswordVerifierResult::OK) { aPassword = rPassword; if (pbIsDefaultPassword) *pbIsDefaultPassword = true; } if( eResult != DocPasswordVerifierResult::WrongPassword ) break; } } } // try media encryption data (skip, if result is OK or ABORT) if( eResult == DocPasswordVerifierResult::WrongPassword ) { if (nMediaEncDataCount) { eResult = rVerifier.verifyEncryptionData( rMediaEncData ); if( eResult == DocPasswordVerifierResult::OK ) aEncData = rMediaEncData; } } // try media password (skip, if result is OK or ABORT) if( eResult == DocPasswordVerifierResult::WrongPassword ) { if( !rMediaPassword.isEmpty() ) { eResult = rVerifier.verifyPassword( rMediaPassword, aEncData ); if (eResult == DocPasswordVerifierResult::OK) aPassword = rMediaPassword; } } // request a password (skip, if result is OK or ABORT) if( (eResult == DocPasswordVerifierResult::WrongPassword) && rxInteractHandler.is() ) try { PasswordRequestMode eRequestMode = PasswordRequestMode_PASSWORD_ENTER; while( eResult == DocPasswordVerifierResult::WrongPassword ) { rtl::Reference pRequest = new DocPasswordRequest( eRequestType, eRequestMode, rDocumentUrl ); rxInteractHandler->handle( pRequest ); if( pRequest->isPassword() ) { if( !pRequest->getPassword().isEmpty() ) eResult = rVerifier.verifyPassword( pRequest->getPassword(), aEncData ); if (eResult == DocPasswordVerifierResult::OK) aPassword = pRequest->getPassword(); } else { eResult = DocPasswordVerifierResult::Abort; } eRequestMode = PasswordRequestMode_PASSWORD_REENTER; } } catch( Exception& ) { } if (eResult == DocPasswordVerifierResult::OK && !aPassword.isEmpty()) { if (std::find_if(std::cbegin(aEncData), std::cend(aEncData), [](const css::beans::NamedValue& val) { return val.Name == PACKAGE_ENCRYPTIONDATA_SHA256UTF8; }) == std::cend(aEncData)) { // tdf#118639: We need ODF encryption data for autorecovery, where password // will already be unavailable, so generate and append it here aEncData = comphelper::concatSequences( aEncData, OStorageHelper::CreatePackageEncryptionData(aPassword)); } if (bForSalvage) { // TODO: add individual methods for different target filter, and only call what's needed // 1. Prepare binary MS formats encryption data auto aUniqueID = GenerateRandomByteSequence(16); auto aEnc97Key = GenerateStd97Key(aPassword, aUniqueID); // 2. Add MS binary and OOXML encryption data to result aEncData = comphelper::concatSequences( aEncData, std::initializer_list{ { "STD97EncryptionKey", css::uno::Any(aEnc97Key) }, { "STD97UniqueID", css::uno::Any(aUniqueID) }, { "OOXPassword", css::uno::Any(aPassword) }, }); } } return (eResult == DocPasswordVerifierResult::OK) ? aEncData : uno::Sequence< beans::NamedValue >(); } /*static*/ uno::Sequence< css::beans::NamedValue > DocPasswordHelper::decryptGpgSession( const uno::Sequence< uno::Sequence< beans::NamedValue > >& rGpgProperties ) { #if HAVE_FEATURE_GPGME if ( !rGpgProperties.hasElements() ) return uno::Sequence< beans::NamedValue >(); uno::Sequence< beans::NamedValue > aEncryptionData; std::unique_ptr ctx; GpgME::initializeLibrary(); GpgME::Error err = GpgME::checkEngine(GpgME::OpenPGP); if (err) throw uno::RuntimeException("The GpgME library failed to initialize for the OpenPGP protocol."); ctx.reset( GpgME::Context::createForProtocol(GpgME::OpenPGP) ); if (ctx == nullptr) throw uno::RuntimeException("The GpgME library failed to initialize for the OpenPGP protocol."); ctx->setArmor(false); const uno::Sequence < beans::NamedValue > *pSequence = rGpgProperties.getConstArray(); const sal_Int32 nLength = rGpgProperties.getLength(); for ( sal_Int32 i = 0; i < nLength ; i++, pSequence++ ) { const beans::NamedValue *pValues = pSequence->getConstArray(); if ( pSequence->getLength() == 3 ) { // take CipherValue and try to decrypt that - stop after // the first successful decryption // ctx is setup now, let's decrypt the lot! uno::Sequence < sal_Int8 > aVector; pValues[2].Value >>= aVector; GpgME::Data cipher( reinterpret_cast(aVector.getConstArray()), size_t(aVector.getLength()), false); GpgME::Data plain; GpgME::DecryptionResult crypt_res = ctx->decrypt( cipher, plain); // NO_SECKEY -> skip // BAD_PASSPHRASE -> retry? off_t result = plain.seek(0,SEEK_SET); (void) result; assert(result == 0); int len=0, curr=0; char buf; while( (curr=plain.read(&buf, 1)) ) len += curr; if(crypt_res.error() || !len) continue; // can't use this key, take next one uno::Sequence < sal_Int8 > aKeyValue(len); result = plain.seek(0,SEEK_SET); assert(result == 0); if( plain.read(aKeyValue.getArray(), len) != len ) throw uno::RuntimeException("The GpgME library failed to read the encrypted value."); SAL_INFO("comphelper.crypto", "Extracted gpg session key of length: " << len); aEncryptionData = { { PACKAGE_ENCRYPTIONDATA_SHA256UTF8, uno::Any(aKeyValue) } }; break; } } if ( aEncryptionData.hasElements() ) { uno::Sequence< beans::NamedValue > aContainer{ { "GpgInfos", uno::Any(rGpgProperties) }, { "EncryptionKey", uno::Any(aEncryptionData) } }; return aContainer; } #else (void)rGpgProperties; #endif return uno::Sequence< beans::NamedValue >(); } } // namespace comphelper /* vim:set shiftwidth=4 softtabstop=4 expandtab: */