/*
* Copyright (c) 2001-2009 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:
* testinteger.cpp
* Implementation for testing TInteger encoding/decoding
*
*/
#include "testbigint.h"
#include "tasn1normaltest.h"
#include <asn1enc.h>
#include <asn1dec.h>
#include <e32cons.h>
CTestBigInt* CTestBigInt::NewL(CASN1NormalTest &aASN1Action)
{
CTestBigInt* test = new (ELeave) CTestBigInt(aASN1Action);
return test;
}
CTestBigInt::CTestBigInt(CASN1NormalTest &aASN1Action) : CTestBase(aASN1Action)
{
};
void CTestBigInt::GetName(TDes& aBuf)
{
aBuf.Copy(_L("Test BigInteger"));
}
void CTestBigInt::FillParameterArray(void)
{
iParameters->Append(CTestParameter::EInt);
}
// This function can leave
TBool CTestBigInt::PerformTest(CConsoleBase& aConsole, const RInteger& aTest, const TInt &aTestNumber, const TInt &aTotalTests)
{
// Make the value to encode
RInteger encodedValue = RInteger::NewL(0);
CleanupStack::PushL(encodedValue);
encodedValue.CopyL(aTest);
// Make the encoder
CASN1EncBigInt* encoder = CASN1EncBigInt::NewLC(encodedValue);
// Prepare a buffer
HBufC8* buf = HBufC8::NewMaxLC(encoder->LengthDER());
TPtr8 tBuf = buf->Des();
// Write into the buffer
TUint writeLength = 0;
encoder->WriteDERL(tBuf, writeLength);
// Read it out again
TASN1DecInteger decoder;
TInt readLength = 0;
RInteger decodedValue = decoder.DecodeDERLongL(tBuf, readLength);
CleanupStack::PushL(decodedValue);
//Check that a positive integer has not been encoded as negative - DEF038956
TBool negEncodeErr = EFalse;
RInteger null = RInteger::NewL(0);
CleanupStack::PushL(null);
if (aTest > null)
{
HBufC8* originalValue = aTest.BufferLC();
TPtrC8 tOriginalValue = originalValue->Des();
//determine which byte to check (should a leading zero byte have been added)
if ((*originalValue)[0] & 0x80)
{
//for example 000000FF, aTest value FF, *buf 020200FF need to confirm (*buf)[2] is 00
//encoder->LengthDER() = 4, tOriginalValue.Length() = 1
if ((*buf)[encoder->LengthDER() - tOriginalValue.Length() - 1] != 0)
{
negEncodeErr = ETrue;
}
}
else
{
//for example 0000007F, aTest value 7F, *buf 02027F need to confirm leading bit (*buf)[2] not set
//encoder->LengthDER() = 3, tOriginalValue.Length() = 1
if ((*buf)[encoder->LengthDER() - tOriginalValue.Length()] & 0x80)
{
negEncodeErr = ETrue;
}
}
CleanupStack::PopAndDestroy(); //originalValue
}
CleanupStack::PopAndDestroy(&null); //null
// Check lengths of reads + values
if ((writeLength != STATIC_CAST(TUint, readLength)) || !(decodedValue == encodedValue) || (negEncodeErr))
//if(1)
{
aConsole.Printf(_L("\nERROR! Problem integer: \n"));
OutputIntegerL(aConsole, encodedValue);
OutputIntegerL(aConsole, decodedValue);
OutputEncodingL(aConsole, tBuf);
iASN1Action.ReportProgressL(KErrASN1EncodingError, aTestNumber, aTotalTests);
CleanupStack::PopAndDestroy(4, &encodedValue); // decodedValue, buf, encoder, encodedValue
return(EFalse);
}
else
{
iASN1Action.ReportProgressL(KErrNone, aTestNumber, aTotalTests);
CleanupStack::PopAndDestroy(4, &encodedValue); // decodedValue, buf, encoder, encodedValue
return(ETrue);
}
}
void CTestBigInt::OutputIntegerL(CConsoleBase& aConsole, RInteger& aInt)
{
aConsole.Printf(_L("Bytes() = "));
TBuf<10> bytes;
bytes.AppendNum(aInt.ByteCount());
bytes.Append(_L(", "));
aConsole.Printf(bytes);
aConsole.Printf(_L("Bits() = "));
TBuf<10> bits;
bits.AppendNum(aInt.BitCount());
bits.Append(_L(", "));
aConsole.Printf(bits);
HBufC8* buf = aInt.BufferLC();
TPtr8 ptr = buf->Des();
TInt size = ptr.Length();
for (TInt i = 0; i < size; ++i)
{
TBuf<10> tbuf;
tbuf.AppendNumFixedWidth(ptr[i], EHex, 2);
aConsole.Printf(tbuf);
}
RInteger null = RInteger::NewL(0);
if (aInt < null)
{
ASSERT(EFalse); // Shouldn't happen for new crypto api - no signed integers
aConsole.Printf(_L(" (-ve)"));
}
else
{
aConsole.Printf(_L(" (+ve)"));
}
null.Close();
aConsole.Printf(_L("\n"));
CleanupStack::PopAndDestroy(); // buf;
}
TBool CTestBigInt::PerformTestsL(CConsoleBase& aConsole)
{
const TInt KMaxBits = 2048;
CTestParameter* test;
TInt totalTests, currentTest=0;
if(!CountTests(totalTests)) return(EFalse);
for(TInt pos = 0; pos < iValues->Count(); pos++)
{
test = (*iValues)[pos];
switch(test->GetType())
{
case CTestParameter::EInt :
{
CIntTestParameter *rangeInt = REINTERPRET_CAST(CIntTestParameter*, test);
RInteger encodedValue;
encodedValue = RInteger::NewL(rangeInt->Value());
CleanupStack::PushL(encodedValue);
if(PerformTest(aConsole, encodedValue, currentTest, totalTests))
CleanupStack::PopAndDestroy(&encodedValue);
else
{
CleanupStack::PopAndDestroy(&encodedValue);
return(EFalse);
};
currentTest++;
break;
}
case CTestParameter::EIntRange :
{
CIntRangeTestParameter *rangeInt = REINTERPRET_CAST(CIntRangeTestParameter*, test);
for(TInt test = rangeInt->Start(); test <= rangeInt->Finish(); test++)
{
RInteger encodedValue;
encodedValue = RInteger::NewL(test);
CleanupStack::PushL(encodedValue);
if(PerformTest(aConsole, encodedValue, currentTest, totalTests))
CleanupStack::PopAndDestroy(&encodedValue);
else
{
CleanupStack::PopAndDestroy(&encodedValue);
return(EFalse);
}
currentTest++;
};
break;
}
case CTestParameter::ERandom :
{
CRandomTestParameter *randomInt = REINTERPRET_CAST(CRandomTestParameter*, test);
for(TInt test = 0; test <= randomInt->Interations(); test++)
{
RInteger encodedValue;
encodedValue = RInteger::NewRandomL((test % KMaxBits) + 1, TInteger::EAllBitsRandom);
CleanupStack::PushL(encodedValue);
if(PerformTest(aConsole, encodedValue, currentTest, totalTests))
CleanupStack::PopAndDestroy(&encodedValue);
else
{
CleanupStack::PopAndDestroy(&encodedValue);
return(EFalse);
}
currentTest++;
}
break;
}
default:
{
return EFalse;
}
}
}
iASN1Action.ReportProgressL(KErrNone, totalTests, totalTests);
return(ETrue);
};