--- /dev/null	Thu Jan 01 00:00:00 1970 +0000
+++ b/crypto/weakcrypto/source/bigint/rinteger.cpp	Wed Jul 08 11:25:26 2009 +0100
@@ -0,0 +1,254 @@
+/*
+* Copyright (c) 2003-2009 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 <bigint.h>
+#include <e32std.h>
+#include <random.h>
+#include "../common/inlines.h"
+
+
+/** 
+ * Copy constructor
+ *
+ * This function performs a shallow copy, 
+ * i.e. the memory holding the integer is not copied.
+ */
+EXPORT_C RInteger::RInteger(const RInteger& aInteger)
+	{
+	*this = aInteger;
+	}
+
+/** 
+ * Assignment operator
+ * 
+ * This function performs a shallow copy, 
+ * i.e. the memory holding the integer is not copied.
+ */
+EXPORT_C RInteger& RInteger::operator=(const RInteger& aInteger)
+	{
+	iSize = aInteger.iSize;
+	iPtr = aInteger.iPtr;
+	return *this;
+	}
+
+
+/** 
+ * Creates a new integer representing 0.
+ * 
+ * @return	An RInteger by value.
+ */
+EXPORT_C RInteger RInteger::NewL(void)
+	{
+	return NewL(TInteger::Zero());
+	}
+
+/** 
+ * Creates a new integer object representing a specified value.
+ * 
+ * @param aValue	A descriptor containing the big-endian binary
+ * 					representation of the value.
+ * @return			An RInteger object representing the value.
+ */
+EXPORT_C RInteger RInteger::NewL(const TDesC8& aValue)
+	{
+	RInteger self;
+	//Construct zero's memory beyond the size of aValue after construction
+	self.CreateNewL(BytesToWords(aValue.Size()));
+	self.Construct(aValue);
+	return self;
+	}
+
+/** 
+ * Creates an exact copy of an \c aInteger object.
+ * 
+ * @param aInteger	The integer you wish to copy
+ * @return			An RInteger object representing an exact copy of 
+ *					aInteger by value.
+ */
+EXPORT_C RInteger RInteger::NewL(const TInteger& aInteger)
+	{
+	RInteger self;
+	//don't need to CleanNewL as we'll copy straight from aInteger
+	self.CreateNewL(aInteger.Size());
+	self.Construct(aInteger);
+	return self;
+	}
+
+/** 
+ * Creates a random integer uniformly distributed over [0, 2^aBits].
+ * 
+ * @param aBits	The number of bits you wish to randomly select.
+ * @param aAttr	Enum specifying whether specific bits in the random number should
+ *				be set.  See TRandomAttribute for more information.
+ * @return		A random RInteger object in the range specified.
+ */
+EXPORT_C RInteger RInteger::NewRandomL(TUint aBits, TRandomAttribute aAttr)
+	{
+	RInteger self;
+	self.CleanNewL(BitsToWords(aBits));
+	CleanupStack::PushL(self);
+	self.RandomizeL(aBits, aAttr);
+	CleanupStack::Pop(&self); 
+	return self;
+	}
+
+/** 
+ * Creates a random integer uniformly distributed over [x | min <= x <= max].
+ * 
+ * @param aMin	The smallest possible value for the random integer (inclusive).
+ * @param aMax	The largest possible value for the random integer (inclusive).
+ * @return		A random RInteger object in the range specified.
+ */
+EXPORT_C RInteger RInteger::NewRandomL(const TInteger& aMin,
+	const TInteger& aMax)
+	{
+	RInteger self;
+	self.CleanNewL(aMax.Size());
+	CleanupStack::PushL(self);
+	self.RandomizeL(aMin, aMax);
+	CleanupStack::Pop(&self);
+	return self;
+	}
+
+/** 
+ * Finds a random prime integer in the range of [2, 2^aBits].
+ *
+ * This is done by picking a random integer and using that as a starting point
+ * for a sequential search for a prime.  To verify the primality of number, 
+ * this algorithm uses a probablistic primality test.  This means that it is
+ * possible, although extremely improbable, that the number returned is a pseudoprime.
+ *
+ * @param aBits	The number of bits you wish to randomly select your prime from.
+ * @param aAttr	Enum specifying whether specific bits in the random number should
+ *				be set.  See TRandomAttribute for more information.
+ * @return		A random RInteger representing a probable prime (with very high
+ *				probablity) in the range specified.
+ */
+EXPORT_C RInteger RInteger::NewPrimeL(TUint aBits, TRandomAttribute aAttr)
+	{
+	RInteger self;
+	self.CleanNewL(BitsToWords(aBits));
+	CleanupStack::PushL(self);
+	self.PrimeRandomizeL(aBits, aAttr);
+	CleanupStack::Pop(&self);
+	return self;
+	}
+
+/** 
+ * Creates a new integer from the value represented by \c aInteger.
+ * 
+ * @param aInteger	A signed word sized integer.
+ * @return			An RInteger representation of aInteger by value.
+ */
+EXPORT_C RInteger RInteger::NewL(TInt aInteger)
+	{
+	RInteger self;
+	self.CreateNewL(2);
+	self.Construct(aInteger);
+	return self;
+	}
+
+/** 
+ * Creates a new integer from the value represented by \c aInteger.
+ *
+ * @param aInteger	An unsigned word sized integer.
+ * @return			An RInteger representation of aInteger by value.
+ */
+EXPORT_C RInteger RInteger::NewL(TUint aInteger)
+	{
+	RInteger self;
+	self.CreateNewL(2);
+	self.Construct(aInteger);
+	return self;
+	}
+
+/** 
+ * Creates a new integer with a preallocated internal storage of \c aNumWords all
+ * initialised to zero.
+ *
+ * The resulting RInteger object is logically equivalent to RInteger::NewL(0).
+ * The only difference is that the internal storage requirements have been 
+ * specified to be larger than the default. This is useful if you are about 
+ * to perform an operation on this integer, that you know the resulting size
+ * requirements of, and wish to avoid a heap resize.
+ *
+ * @param aNumWords	The number of words for to preallocated and zero fill.
+ * @return			An RInteger object representing 0 with a preallocated 
+ *					zero-filled internal storage of aNumWords.
+ */
+EXPORT_C RInteger RInteger::NewEmptyL(TUint aNumWords)
+	{
+	RInteger self;
+	self.CleanNewL(aNumWords);
+	//There's no construct as there isn't anything to do
+	return self;
+	}
+
+/**
+ * Creates an RInteger object with no associated internal (heap) storage.
+ * 
+ * All data members are initialised to zero.  It is safe (although not strictly necessary)
+ * to push such an RInteger object onto the CleanupStack.  This is useful, for example, if
+ * you want to pass an RInteger object by reference into a function and have it create
+ * the representation of the actual integer for you.  
+ *
+ * Note that performing any operation on such an RInteger object other than the default
+ * assignment operator or copy constructor will panic your code.
+ * 
+ * @return	A stack based class that has no associated internal storage and thus
+ *			does not represent any number.
+ */
+EXPORT_C RInteger::RInteger(void)  
+	{
+	}
+
+/** 
+ * An overloaded TCleanupItem() allowing the RIntegers to be pushed,
+ * popped, and destroyed via the CleanupStack like any other CBase derived object.
+ */
+EXPORT_C RInteger::operator TCleanupItem(void)
+	{
+	return TCleanupItem(&RInteger::CallClose, this);
+	}
+
+/** 
+ * Helper function registered with the cleanup stack that just calls Close() for
+ * this RInteger object.
+ * 
+ * @param aPtr	A pointer to the object for which clean-up is to be performed. 
+ */
+EXPORT_C void RInteger::CallClose(TAny* aPtr)
+	{
+	((RInteger*)aPtr)->Close();	
+	}
+
+/** 
+ * Zeros and then frees any memory owned by this RInteger object.
+ *  
+ * An RInteger object that has been closed can safely fall off the stack.
+ */
+EXPORT_C void RInteger::Close(void)
+	{
+	if (iPtr)
+		{
+		Mem::FillZ(Ptr(), Size()*4);
+		User::Free(Ptr());
+		iSize = 0;
+		iPtr = NULL;
+		}
+	}