Exemplo n.º 1
0
static long SignVerify(CReader & oReader, tPrivKey & key,
	const CByteArray & oCertData, unsigned long ulSignAlgo)
{
	CByteArray oData(1000);
	for (int i = 0; i < 300; i++)
		oData.Append((unsigned char) rand());

	long lHashAlgo = sign2hashAlgo(ulSignAlgo);

	if (lHashAlgo != -1)
	{
		CByteArray oSignature;
	
		CHash oHash;
		oHash.Init((tHashAlgo) lHashAlgo);
		oHash.Update(oData);

		if (ulSignAlgo == SIGN_ALGO_RSA_PKCS)
		{
			// To test SIGN_ALGO_RSA_PKCS, we take as input the SHA1 AID
			// plus the SHA1 hash of oData. This way, we can use OpenSSL's
			// SHA1 signature verification in VerifySignature().
			const unsigned char SHA1_AID[] = {0x30, 0x21, 0x30, 0x09,
				0x06, 0x05, 0x2b, 0x0e, 0x03, 0x02, 0x1a, 0x05, 0x00,0x04, 0x14};
			CByteArray oTobeSigned(SHA1_AID, sizeof(SHA1_AID));
			oTobeSigned.Append(oHash.GetHash());
			oSignature = oReader.Sign(key, ulSignAlgo, oTobeSigned);
		}
		else
			oSignature = oReader.Sign(key, ulSignAlgo, oHash);

		bool bVerified = VerifySignature(oData, oSignature, oCertData, ulSignAlgo);

		return bVerified ? 0 : 1;
	}
	else
	{
		printf("      Signature algo %s can't be tested yet\n", SignAlgo2String(ulSignAlgo));
		return 0;
	}
}
Exemplo n.º 2
0
static CByteArray HashAndSign(CReader & oReader, const tPrivKey & key,
	unsigned long signAlgo, const CByteArray & oData)
{
	tHashAlgo hashAlgo;
	if (signAlgo == SIGN_ALGO_MD5_RSA_PKCS)
		hashAlgo = ALGO_MD5;
	else if (signAlgo == SIGN_ALGO_SHA1_RSA_PKCS)
		hashAlgo = ALGO_SHA1;
	else if (signAlgo == SIGN_ALGO_SHA256_RSA_PKCS)
		hashAlgo = ALGO_SHA256;
	else
	{
		printf("Unsupport signature algorithm %d, can't sign\n", signAlgo);
		return CByteArray();
	}

	CHash oHash;
	oHash.Init(hashAlgo);
	oHash.Update(oData);

	return oReader.Sign(key, signAlgo, oHash);
}
Exemplo n.º 3
0
ENDI * GetEndiInfo(EUI64 * pId)
{
    ENDI   *pEndi;
    int         nIndex;

    nIndex = g_EndListHash.Find(pId, sizeof(EUI64));
    if (nIndex == -1)
    {
        pEndi = (ENDI *) MALLOC(sizeof(ENDI));
        memset(pEndi, 0, sizeof(ENDI));
        memcpy(&pEndi->id, pId, sizeof(EUI64));
        pEndi->stream.pszBuffer = (char *)MALLOC(1024);
        memset(pEndi->stream.pszBuffer, 0, 1024);

        pEndi->position = (int)g_EndiList.AddTail(pEndi);

        g_EndListHash.Update(pId, sizeof(EUI64), pEndi->position);

        return pEndi;
    }

    pEndi = g_EndiList.Get((POSITION)nIndex);
    return pEndi;
}
TVerdict CHashIncrementalHashWithCopyStep::doTestStepL()
	{
	if (TestStepResult()==EPass)
		{
		
		//Assume faliure, unless all is successful
		SetTestStepResult(EFail);
		
		INFO_PRINTF1(_L("*** Hash - Incremental Hash with Copy ***"));
		INFO_PRINTF2(_L("HEAP CELLS: %d"), User::CountAllocCells());
		
		TVariantPtrC algorithmUid;
		TVariantPtrC operationModeUid;
		TPtrC sourcePath;
		TPtrC expectedHash;
		
		//Extract the Test Case ID parameter from the specified INI file
		if(!GetStringFromConfig(ConfigSection(),KConfigAlgorithmUid,algorithmUid) ||
			!GetStringFromConfig(ConfigSection(),KConfigOperationMode,operationModeUid) ||
			!GetStringFromConfig(ConfigSection(),KConfigSourcePath,sourcePath) ||
			!GetStringFromConfig(ConfigSection(),KConfigExHashHmacValue,expectedHash))
			{
			ERR_PRINTF1(_L("** Error: Failed to Load Configuration Parameters **"));
			SetTestStepResult(EFail);
			}
		else
			{
			//Create a pointer for the Hash Implementation Object
			CHash* hashImpl = NULL;
			
			//Retrieve a Hash Factory Object					
			TRAPD(err,CHashFactory::CreateHashL(hashImpl,
												algorithmUid,
												operationModeUid,
												NULL,
												NULL));  				
	
			if(hashImpl && (err == KErrNone))
				{
				
				//Push the Hash Implementation Object onto the Cleanup Stack
				CleanupStack::PushL(hashImpl);
				
				RFs fsSession;
				
				//Create a connection to the file server	
				err = fsSession.Connect();
					
				if(err != KErrNone)
					{
					ERR_PRINTF2(_L("*** Error: File Server Connection - %d ***"), err);
					SetTestStepResult(EFail);
					}	
				else
					{
					RFile sourceFile;
					CleanupClosePushL(sourceFile);
	    			
	    			//Open the specified source file		
	    			err = sourceFile.Open(fsSession,sourcePath, EFileRead);
	    					
	    			if(err != KErrNone)
						{
						ERR_PRINTF2(_L("*** Error: Opening Source File - %d ***"), err);
						SetTestStepResult(EFail);
						}
					else
						{
						
						TInt sourceLength = 0;
						TInt readPosition = 0;
						TInt readIncrement = 0;
						TBool hashComplete = EFalse;
						TBool hashCopied = EFalse;
						TPtrC8 hashStr;
						
						CHash* hashCopyImpl = NULL;
						
						User::LeaveIfError(sourceFile.Size(sourceLength));
						
						//Divide the total size of the source file up into individual equal sized blocks to read
						//over several increments
						readIncrement = sourceLength/KDataReadBlocks;
						
						do 
							{							
							//Create a heap based descriptor to store the data
							HBufC8* sourceData = HBufC8::NewL(readIncrement);
							CleanupStack::PushL(sourceData);
							TPtr8 sourcePtr = sourceData->Des();
							
							//Read in a block of data from the source file from the current position
							err = sourceFile.Read(readPosition,sourcePtr,readIncrement);
							
							//Update the read position by adding the number of bytes read
							readPosition += readIncrement;
							
							if(readPosition == readIncrement)
								{
								//Read in the first block from the data file into the Hash implementation object
								hashImpl->Hash(*sourceData);
								INFO_PRINTF2(_L("Intial Hash - Bytes Read: %d"), readPosition);
								}
							else if(readPosition >= sourceLength)
								{
								//Reading in the final block, constructs the complete hash value and returns it within a TPtrC8
								hashStr.Set(hashCopyImpl->Final(*sourceData));
								
								//Sets the Complete Flag to ETrue in order to drop out of the loop
								hashComplete = ETrue;
								
								TInt totalRead = (readPosition - readIncrement) + (*sourceData).Length();
								INFO_PRINTF2(_L("Final Hash - Bytes Read: %d"),totalRead);
								}
							//If the read position is half the source length and the implementation
							//object hasn't already been copied
							else if((readPosition >= sourceLength/2) && (hashCopied == EFalse))
								{
								//Update the hash message before copying
								hashImpl->Update(*sourceData);
								
								INFO_PRINTF1(_L("Copying Hash Object..."));
								
								//Create a Copy of the existing Hash Object and all internal state of the message digest
								hashCopyImpl = hashImpl->CopyL();
								
								hashCopied = ETrue;
								
								INFO_PRINTF2(_L("*** HASH COPY - Bytes Read: %d ***"), readPosition);
								}
							else
								{
								//Update the message data within the Hash object with the new block
								if(hashCopied == EFalse)
									{
									hashImpl->Update(*sourceData);
									INFO_PRINTF2(_L("Hash Update - Bytes Read: %d"), readPosition);		
									}
								else
									{
									hashCopyImpl->Update(*sourceData);
									INFO_PRINTF2(_L("Hash Update (Copy) - Bytes Read: %d"), readPosition);		
									}
								}
							
							CleanupStack::PopAndDestroy(sourceData);
							
								
							}while(hashComplete == EFalse);
						
						//Create a NULL TCharacteristics pointer
						const TCharacteristics* charsPtr(NULL);
						
						//Retrieve the characteristics for the hash implementation object
						TRAP_LOG(err, hashImpl->GetCharacteristicsL(charsPtr));
						
						//Static cast the characteristics to type THashCharacteristics
						const THashCharacteristics* hashCharsPtr = static_cast<const THashCharacteristics*>(charsPtr);
						
						//The hash output size is returned in Bits, divide by 8 to get the Byte size
						TInt hashSize = hashCharsPtr->iOutputSize/8;
						
						//Retrieve the final 8bit hash value and convert to 16bit												
						HBufC* hashData = HBufC::NewLC(hashSize);
						TPtr hashPtr = hashData->Des();
						
						//Copy the hashed content into the heap based descriptor
						hashPtr.Copy(hashStr);
						
					 	//Take the 16bit descriptor and convert the string to hexadecimal
						TVariantPtrC convertHash;
						convertHash.Set(hashPtr);
						HBufC* hashResult = convertHash.HexStringLC();
						
						INFO_PRINTF2(_L("*** Hashed Data: %S ***"),&*hashResult);
						INFO_PRINTF2(_L("*** Expected Hash: %S ***"),&expectedHash);
						
						//If the returned hash value matches the expected hash, Pass the test		
						if(*hashResult == expectedHash)
							{
							INFO_PRINTF1(_L("*** Hash - Incremental Hash with Copy : PASS ***"));
							SetTestStepResult(EPass);	
							}
						else
							{
							ERR_PRINTF2(_L("*** FAIL: Hashed and Expected Value Mismatch  ***"), err);
							SetTestStepResult(EFail);	
							}
								
						CleanupStack::PopAndDestroy(hashResult);
						CleanupStack::PopAndDestroy(hashData);						
						
						delete hashCopyImpl;
						}
					
					//Cleanup the Source RFile	
					CleanupStack::PopAndDestroy();	
					}

				fsSession.Close();	
				
				CleanupStack::PopAndDestroy(hashImpl);
				}
			else
				{
				ERR_PRINTF2(_L("*** FAIL: Failed to Create Hash Object - %d ***"), err);
				SetTestStepResult(EFail);	
				}
			}
			
		}
		
	INFO_PRINTF2(_L("HEAP CELLS: %d"), User::CountAllocCells());
	return TestStepResult();
	}