/*
* Copyright (c) 1998-2009 Nokia Corporation and/or its subsidiary(-ies).
* All rights reserved.
* This component and the accompanying materials are made available
* under the terms of the License "Eclipse Public License v1.0"
* which accompanies this distribution, and is available
* at the URL "http://www.eclipse.org/legal/epl-v10.html".
*
* Initial Contributors:
* Nokia Corporation - initial contribution.
*
* Contributors:
*
* Description:
*
*/
#include "tactionincremental.h"
#include "symmetric.h"
#include "des.h"
CTestAction* CActionIncremental::NewL(RFs& aFs,
CConsoleBase& aConsole,
Output& aOut,
const TTestActionSpec& aTestActionSpec)
{
CTestAction* self = CActionIncremental::NewLC(aFs, aConsole,
aOut, aTestActionSpec);
CleanupStack::Pop();
return self;
}
CTestAction* CActionIncremental::NewLC(RFs& aFs,
CConsoleBase& aConsole,
Output& aOut,
const TTestActionSpec& aTestActionSpec)
{
CActionIncremental* self = new(ELeave) CActionIncremental(aFs, aConsole, aOut);
CleanupStack::PushL(self);
self->ConstructL(aTestActionSpec);
return self;
}
CActionIncremental::~CActionIncremental()
{
}
CActionIncremental::CActionIncremental(RFs& aFs,
CConsoleBase& aConsole,
Output& aOut)
: CCryptoTestAction(aFs, aConsole, aOut)
{}
void CActionIncremental::DoPerformPostrequisiteL()
{
delete iEncryptor;
delete iDecryptor;
}
void CActionIncremental::DoPerformPrerequisiteL()
{
TInt err = KErrNone;
TInt pos = 0;
TPtrC8 incremental = Input::ParseElement(*iBody, KIncrementalStart, KIncrementalEnd, pos, err);
DoInputParseL(incremental);
CBlockTransformation* encryptor = NULL;
CBlockTransformation* decryptor = NULL;
iEncryptor =0;
iDecryptor =0;
switch (iCipherType)
{
case (EDESECB):
{
//If the test is weak key test
if(iExpectedWeakResult == KErrWeakKey)
{
//we expect to leave with KErrWeakKey reason
if(CDES::IsWeakKey(iKey->Des()))
{
User::Leave(KErrWeakKey);
}
else //test is unsuccessful, leave with a different reason
{
User::Leave(KErrGeneral);
}
}
encryptor = CDESEncryptor::NewLC(iKey->Des());
decryptor = CDESDecryptor::NewL(iKey->Des());
CleanupStack::Pop(encryptor);
}
break;
case (EDESCBC):
{
CBlockTransformation* desEncryptor = NULL;
CBlockTransformation* desDecryptor = NULL;
if(iExpectedWeakResult == KErrWeakKey)
{
if(CDES::IsWeakKey(iKey->Des()))
{
User::Leave(KErrWeakKey);
}
else
{
User::Leave(KErrGeneral);
}
}
desEncryptor = CDESEncryptor::NewLC(iKey->Des());
desDecryptor = CDESDecryptor::NewLC(iKey->Des());
encryptor = CModeCBCEncryptor::NewL(desEncryptor, iIV->Des());
CleanupStack::PushL(encryptor);
decryptor = CModeCBCDecryptor::NewL(desDecryptor, iIV->Des());
CleanupStack::Pop(3);
}
break;
case (E3DESECB):
{
encryptor = C3DESEncryptor::NewLC(iKey->Des());
decryptor = C3DESDecryptor::NewL(iKey->Des());
CleanupStack::Pop(encryptor);
}
break;
case (E3DESCBC):
{
CBlockTransformation* the3DESencryptor = NULL;
CBlockTransformation* the3DESdecryptor = NULL;
the3DESencryptor = C3DESEncryptor::NewLC(iKey->Des());
the3DESdecryptor = C3DESDecryptor::NewLC(iKey->Des());
encryptor = CModeCBCEncryptor::NewL(the3DESencryptor, iIV->Des());
CleanupStack::PushL(encryptor);
decryptor = CModeCBCDecryptor::NewL(the3DESdecryptor, iIV->Des());
CleanupStack::Pop(3);
}
break;
case (EAESECB):
{
encryptor = CAESEncryptor::NewLC(iKey->Des());
decryptor = CAESDecryptor::NewL(iKey->Des());
CleanupStack::Pop(encryptor);
}
break;
case (ERC2ECB):
{
encryptor = CRC2Encryptor::NewLC(iKey->Des(), iEffectiveKeyLen);
decryptor = CRC2Decryptor::NewL(iKey->Des(), iEffectiveKeyLen);
CleanupStack::Pop(encryptor);
}
break;
case (ERC2CBC):
{
encryptor = CRC2Encryptor::NewLC(iKey->Des(), iEffectiveKeyLen);
decryptor = CRC2Decryptor::NewL(iKey->Des(), iEffectiveKeyLen);
CleanupStack::Pop(encryptor);
}
break;
case (ERC4):
{
iEncryptor = CARC4::NewL(*iKey, 0);
iDecryptor = CARC4::NewL(*iKey, 0);
}
break;
case (ECipherNull):
{
iEncryptor = CNullCipher::NewL();
iDecryptor = CNullCipher::NewL();
}
break;
default:
ASSERT(0);
User::Leave(KErrNotSupported);
}
CleanupStack::PushL(encryptor);
CleanupStack::PushL(decryptor);
if(!iEncryptor && !iDecryptor)
{
CPaddingSSLv3* dPadding = CPaddingSSLv3::NewLC(decryptor->BlockSize());
CPaddingSSLv3* ePadding = CPaddingSSLv3::NewLC(encryptor->BlockSize());
iEncryptor = CBufferedEncryptor::NewL(encryptor, ePadding);
CleanupStack::Pop(ePadding);
iDecryptor = CBufferedDecryptor::NewL(decryptor, dPadding);
CleanupStack::Pop(dPadding);
}
CleanupStack::Pop(2, encryptor);
iEResult = HBufC8::NewMaxL(iEncryptor->MaxFinalOutputLength(iInput->Length()));
iDResult = HBufC8::NewMaxL(iDecryptor->MaxFinalOutputLength(iEResult->Size()));
}
void CActionIncremental::DoPerformActionL()
{
TRAPD(res, DoDoPerformActionL())
if(res == KErrNoMemory)
{
iEncryptor->Reset();
iDecryptor->Reset();
}
}
void CActionIncremental::DoDoPerformActionL()
{
__UHEAP_MARK;
iResult = ETrue;
TPtr8 eResultActual = iEResult->Des();
eResultActual.FillZ(eResultActual.MaxLength());
eResultActual.SetLength(0);
TPtr8 dResultActual = iDResult->Des();
dResultActual.FillZ(dResultActual.MaxLength());
dResultActual.SetLength(0);
TInt len = iInput->Length();
for(TInt i=1; i<len; i++)
{
TInt j = 0;
for(; j+i<len; j+=i)
{// encryption in blocks of size i
iEncryptor->Process(iInput->Mid(j,i), eResultActual);
}
iEncryptor->ProcessFinalL(iInput->Mid(j), eResultActual);
j=0;
for(; (j+(len-i))<len; j+=(len-i))
{// Decryption in blocks of size (len - i)
iDecryptor->Process(eResultActual.Mid(j, len-i), dResultActual);
}
iDecryptor->ProcessFinalL(eResultActual.Mid(j), dResultActual);
if(dResultActual != *iInput)
{
iResult = EFalse;
}
eResultActual.FillZ(eResultActual.MaxLength());
dResultActual.FillZ(dResultActual.MaxLength());
eResultActual.SetLength(0);
dResultActual.SetLength(0);
}
__UHEAP_MARKEND;
}