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/*
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* Copyright (c) 2003-2009 Nokia Corporation and/or its subsidiary(-ies).
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* All rights reserved.
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* This component and the accompanying materials are made available
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* under the terms of the License "Eclipse Public License v1.0"
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* which accompanies this distribution, and is available
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* at the URL "http://www.eclipse.org/legal/epl-v10.html".
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*
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* Initial Contributors:
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* Nokia Corporation - initial contribution.
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*
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* Contributors:
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*
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* Description:
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*
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*/
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#include <asymmetrickeys.h>
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#include <bigint.h>
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#include <random.h>
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#include <hash.h>
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#include "../common/inlines.h"
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#include "../bigint/mont.h"
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#include "dsakeypairshim.h"
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const TUint SHASIZE = 20;
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const TUint KMinPrimeLength = 512;
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const TUint KMaxPrimeLength = 1024;
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const TUint KPrimeLengthMultiple = 64;
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/* CDSAParameters */
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EXPORT_C const TInteger& CDSAParameters::P(void) const
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{
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return iP;
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}
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EXPORT_C const TInteger& CDSAParameters::Q(void) const
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{
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return iQ;
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}
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EXPORT_C const TInteger& CDSAParameters::G(void) const
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{
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return iG;
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}
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EXPORT_C CDSAParameters::~CDSAParameters(void)
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{
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iP.Close();
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iQ.Close();
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iG.Close();
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}
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EXPORT_C CDSAParameters* CDSAParameters::NewL(RInteger& aP, RInteger& aQ,
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RInteger& aG)
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{
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CDSAParameters* me = new (ELeave) CDSAParameters(aP, aQ, aG);
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return (me);
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}
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EXPORT_C TBool CDSAParameters::ValidatePrimesL(const CDSAPrimeCertificate& aCert)
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const
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{
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TBool result = EFalse;
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RInteger p;
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RInteger q;
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//Regenerate primes using aCert's seed and counter
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TUint counter = aCert.Counter();
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if(!CDSAParameters::GeneratePrimesL(aCert.Seed(), counter, p,
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P().BitCount(), q, ETrue))
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{
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return result;
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}
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//this doesn't leave, no need to push p and q
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if(p == P() && q == Q() && counter == aCert.Counter())
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{
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result = ETrue;
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}
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p.Close();
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q.Close();
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return result;
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}
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EXPORT_C TBool CDSAParameters::ValidPrimeLength(TUint aPrimeBits)
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{
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return (aPrimeBits >= KMinPrimeLength &&
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aPrimeBits <= KMaxPrimeLength &&
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aPrimeBits % KPrimeLengthMultiple == 0);
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}
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EXPORT_C CDSAParameters::CDSAParameters(RInteger& aP, RInteger& aQ,
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RInteger& aG) : iP(aP), iQ(aQ), iG(aG)
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{
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}
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EXPORT_C CDSAParameters::CDSAParameters(void)
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{
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}
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TBool CDSAParameters::GeneratePrimesL(const TDesC8& aSeed, TUint& aCounter,
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RInteger& aP, TUint aL, RInteger& aQ, TBool aUseInputCounter)
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{
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//This follows the steps in FIPS 186-2
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//See DSS Appendix 2.2
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//Note. Step 1 is performed prior to calling GeneratePrimesL, so that this
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//routine can be used for both generation and validation.
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//Step 1. Choose an arbitrary sequence of at least 160 bits and call it
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//SEED. Let g be the length of SEED in bits.
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if(!CDSAParameters::ValidPrimeLength(aL))
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{
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User::Leave(KErrNotSupported);
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}
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CSHA1* sha1 = CSHA1::NewL();
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CleanupStack::PushL(sha1);
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HBufC8* seedBuf = aSeed.AllocLC();
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TPtr8 seed = seedBuf->Des();
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TUint gBytes = aSeed.Size();
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//Note that the DSS's g = BytesToBits(gBytes) ie. the number of random bits
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//in the seed.
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//This function has made the assumption (for ease of computation) that g%8
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//is 0. Ie the seed is a whole number of random bytes.
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TBuf8<SHASIZE> U;
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TBuf8<SHASIZE> temp;
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const TUint n = (aL-1)/160;
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const TUint b = (aL-1)%160;
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HBufC8* Wbuf = HBufC8::NewMaxLC((n+1) * SHASIZE);
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TUint8* W = const_cast<TUint8*>(Wbuf->Ptr());
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U.Copy(sha1->Final(seed));
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//Step 2. U = SHA-1[SEED] XOR SHA-1[(SEED+1) mod 2^g]
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for(TInt i=gBytes - 1, carry=ETrue; i>=0 && carry; i--)
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{
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//!++(TUint) adds one to the current word which if it overflows to zero
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//sets carry to 1 thus letting the loop continue. It's a poor man's
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//multi-word addition. Swift eh?
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carry = !++(seed[i]);
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}
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temp.Copy(sha1->Final(seed));
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XorBuf(const_cast<TUint8*>(U.Ptr()), temp.Ptr(), SHASIZE);
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//Step 3. Form q from U by setting the most significant bit (2^159)
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//and the least significant bit to 1.
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U[0] |= 0x80;
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U[SHASIZE-1] |= 1;
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aQ = RInteger::NewL(U);
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CleanupStack::PushL(aQ);
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//Step 4. Use a robust primality testing algo to test if q is prime
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//The robust part is the calling codes problem. This will use whatever
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//random number generator you set for the thread. To attempt FIPS 186-2
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//compliance, set a FIPS 186-2 compliant RNG.
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if( !aQ.IsPrimeL() )
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{
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//Step 5. If not exit and get a new seed
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CleanupStack::PopAndDestroy(&aQ);
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CleanupStack::PopAndDestroy(Wbuf);
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CleanupStack::PopAndDestroy(seedBuf);
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CleanupStack::PopAndDestroy(sha1);
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return EFalse;
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}
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TUint counterEnd = aUseInputCounter ? aCounter+1 : 4096;
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//Step 6. Let counter = 0 and offset = 2
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//Note 1. that the DSS speaks of SEED + offset + k because they always
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//refer to a constant SEED. We update our seed as we go so the offset
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//variable has already been added to seed in the previous iterations.
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//Note 2. We've already added 1 to our seed, so the first time through this
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//the offset in DSS speak will be 2.
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for(TUint counter=0; counter < counterEnd; counter++)
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{
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//Step 7. For k=0, ..., n let
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// Vk = SHA-1[(SEED + offset + k) mod 2^g]
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//I'm storing the Vk's inside of a big W buffer.
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for(TUint k=0; k<=n; k++)
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{
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for(TInt i=gBytes-1, carry=ETrue; i>=0 && carry; i--)
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{
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carry = !++(seed[i]);
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}
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if(!aUseInputCounter || counter == aCounter)
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{
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TPtr8 Wptr(W+(n-k)*SHASIZE, gBytes);
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Wptr.Copy(sha1->Final(seed));
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}
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}
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if(!aUseInputCounter || counter == aCounter)
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{
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//Step 8. Let W be the integer... and let X = W + 2^(L-1)
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const_cast<TUint8&>((*Wbuf)[SHASIZE - 1 - b/8]) |= 0x80;
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TPtr8 Wptr(W + SHASIZE - 1 - b/8, aL/8, aL/8);
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RInteger X = RInteger::NewL(Wptr);
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CleanupStack::PushL(X);
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//Step 9. Let c = X mod 2q and set p = X - (c-1)
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RInteger twoQ = aQ.TimesL(TInteger::Two());
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CleanupStack::PushL(twoQ);
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RInteger c = X.ModuloL(twoQ);
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CleanupStack::PushL(c);
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--c;
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aP = X.MinusL(c);
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CleanupStack::PopAndDestroy(3, &X); //twoQ, c, X
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CleanupStack::PushL(aP);
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//Step 10 and 11: if p >= 2^(L-1) and p is prime
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if( aP.Bit(aL-1) && aP.IsPrimeL() )
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{
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aCounter = counter;
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CleanupStack::Pop(&aP);
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CleanupStack::Pop(&aQ);
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CleanupStack::PopAndDestroy(Wbuf);
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CleanupStack::PopAndDestroy(seedBuf);
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CleanupStack::PopAndDestroy(sha1);
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return ETrue;
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}
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CleanupStack::PopAndDestroy(&aP);
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}
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}
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CleanupStack::PopAndDestroy(&aQ);
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CleanupStack::PopAndDestroy(Wbuf);
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CleanupStack::PopAndDestroy(seedBuf);
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CleanupStack::PopAndDestroy(sha1);
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return EFalse;
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}
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/* CDSAPublicKey */
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EXPORT_C CDSAPublicKey* CDSAPublicKey::NewL(RInteger& aP, RInteger& aQ,
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RInteger& aG, RInteger& aY)
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{
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CDSAPublicKey* self = new(ELeave) CDSAPublicKey(aP, aQ, aG, aY);
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return self;
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}
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EXPORT_C CDSAPublicKey* CDSAPublicKey::NewLC(RInteger& aP, RInteger& aQ,
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RInteger& aG, RInteger& aY)
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{
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CDSAPublicKey* self = NewL(aP, aQ, aG, aY);
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CleanupStack::PushL(self);
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return self;
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}
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EXPORT_C const TInteger& CDSAPublicKey::Y(void) const
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{
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return iY;
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}
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EXPORT_C CDSAPublicKey::CDSAPublicKey(void)
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{
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}
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EXPORT_C CDSAPublicKey::CDSAPublicKey(RInteger& aP, RInteger& aQ, RInteger& aG,
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RInteger& aY) : CDSAParameters(aP, aQ, aG), iY(aY)
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{
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}
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EXPORT_C CDSAPublicKey::~CDSAPublicKey(void)
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{
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iY.Close();
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}
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/* CDSAPrivateKey */
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EXPORT_C CDSAPrivateKey* CDSAPrivateKey::NewL(RInteger& aP, RInteger& aQ,
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RInteger& aG, RInteger& aX)
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{
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CDSAPrivateKey* self = new(ELeave) CDSAPrivateKey(aP, aQ, aG, aX);
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return self;
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}
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EXPORT_C CDSAPrivateKey* CDSAPrivateKey::NewLC(RInteger& aP, RInteger& aQ,
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RInteger& aG, RInteger& aX)
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{
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CDSAPrivateKey* self = NewL(aP, aQ, aG, aX);
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CleanupStack::PushL(self);
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return self;
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}
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EXPORT_C const TInteger& CDSAPrivateKey::X(void) const
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{
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return iX;
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}
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EXPORT_C CDSAPrivateKey::CDSAPrivateKey(RInteger& aP, RInteger& aQ, RInteger& aG,
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RInteger& aX) : CDSAParameters(aP, aQ, aG), iX(aX)
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{
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}
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EXPORT_C CDSAPrivateKey::~CDSAPrivateKey(void)
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{
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iX.Close();
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}
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/* CDSAKeyPair */
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EXPORT_C CDSAKeyPair* CDSAKeyPair::NewL(TUint aKeyBits)
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{
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CDSAKeyPairShim* self = CDSAKeyPairShim::NewLC(aKeyBits);
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CleanupStack::Pop();
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return self;
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}
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EXPORT_C CDSAKeyPair* CDSAKeyPair::NewLC(TUint aKeyBits)
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{
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CDSAKeyPairShim* self = CDSAKeyPairShim::NewLC(aKeyBits);
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return self;
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}
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EXPORT_C const CDSAPublicKey& CDSAKeyPair::PublicKey(void) const
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{
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return *iPublic;
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}
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EXPORT_C const CDSAPrivateKey& CDSAKeyPair::PrivateKey(void) const
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{
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return *iPrivate;
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}
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EXPORT_C CDSAKeyPair::~CDSAKeyPair(void)
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{
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delete iPublic;
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delete iPrivate;
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delete iPrimeCertificate;
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}
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EXPORT_C CDSAKeyPair::CDSAKeyPair(void)
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{
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}
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EXPORT_C const CDSAPrimeCertificate& CDSAKeyPair::PrimeCertificate(void) const
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{
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return *iPrimeCertificate;
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}
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/* CDSAPrimeCertificate */
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EXPORT_C CDSAPrimeCertificate* CDSAPrimeCertificate::NewL(const TDesC8& aSeed,
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TUint aCounter)
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{
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CDSAPrimeCertificate* self = NewLC(aSeed, aCounter);
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CleanupStack::Pop();
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return self;
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}
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EXPORT_C CDSAPrimeCertificate* CDSAPrimeCertificate::NewLC(const TDesC8& aSeed,
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TUint aCounter)
|
|
|
354 |
{
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|
|
355 |
CDSAPrimeCertificate* self = new(ELeave) CDSAPrimeCertificate(aCounter);
|
|
|
356 |
CleanupStack::PushL(self);
|
|
|
357 |
self->ConstructL(aSeed);
|
|
|
358 |
return self;
|
|
|
359 |
}
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|
|
360 |
|
|
|
361 |
EXPORT_C const TDesC8& CDSAPrimeCertificate::Seed(void) const
|
|
|
362 |
{
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|
|
363 |
return *iSeed;
|
|
|
364 |
}
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|
|
365 |
|
|
|
366 |
EXPORT_C TUint CDSAPrimeCertificate::Counter(void) const
|
|
|
367 |
{
|
|
|
368 |
return iCounter;
|
|
|
369 |
}
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|
|
370 |
|
|
|
371 |
EXPORT_C CDSAPrimeCertificate::~CDSAPrimeCertificate(void)
|
|
|
372 |
{
|
|
|
373 |
delete const_cast<HBufC8*>(iSeed);
|
|
|
374 |
}
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|
|
375 |
|
|
|
376 |
void CDSAPrimeCertificate::ConstructL(const TDesC8& aSeed)
|
|
|
377 |
{
|
|
|
378 |
iSeed = aSeed.AllocL();
|
|
|
379 |
}
|
|
|
380 |
|
|
|
381 |
EXPORT_C CDSAPrimeCertificate::CDSAPrimeCertificate(TUint aCounter)
|
|
|
382 |
: iCounter(aCounter)
|
|
|
383 |
{
|
|
|
384 |
}
|
|
|
385 |
|
|
|
386 |
// Over taken by shim version. so, exclude it from coverage.
|
|
|
387 |
#ifdef _BullseyeCoverage
|
|
|
388 |
#pragma suppress_warnings on
|
|
|
389 |
#pragma BullseyeCoverage off
|
|
|
390 |
#pragma suppress_warnings off
|
|
|
391 |
#endif
|
|
|
392 |
void CDSAKeyPair::ConstructL(TUint /*aPBits*/)
|
|
|
393 |
{
|
|
|
394 |
}
|
|
|
395 |
|
|
|
396 |
// Unused exported and protected method can be excluded from coverage.
|
|
|
397 |
EXPORT_C CDSAPrimeCertificate::CDSAPrimeCertificate(void)
|
|
|
398 |
{
|
|
|
399 |
}
|
|
|
400 |
|
|
|
401 |
EXPORT_C CDSAPrivateKey::CDSAPrivateKey(void)
|
|
|
402 |
{
|
|
|
403 |
}
|