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// luc.cpp - written and placed in the public domain by Wei Dai
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#include "pch.h"
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#include "luc.h"
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#include "asn.h"
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#include "nbtheory.h"
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#include "sha.h"
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#include "algparam.h"
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NAMESPACE_BEGIN(CryptoPP)
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void LUC_TestInstantiations()
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{
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LUC_HMP<SHA>::Signer t1;
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LUCFunction t2;
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InvertibleLUCFunction t3;
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}
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void DL_Algorithm_LUC_HMP::Sign(const DL_GroupParameters<Integer> ¶ms, const Integer &x, const Integer &k, const Integer &e, Integer &r, Integer &s) const
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{
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const Integer &q = params.GetSubgroupOrder();
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r = params.ExponentiateBase(k);
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s = (k + x*(r+e)) % q;
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}
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bool DL_Algorithm_LUC_HMP::Verify(const DL_GroupParameters<Integer> ¶ms, const DL_PublicKey<Integer> &publicKey, const Integer &e, const Integer &r, const Integer &s) const
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{
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Integer p = params.GetGroupOrder()-1;
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const Integer &q = params.GetSubgroupOrder();
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Integer Vsg = params.ExponentiateBase(s);
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Integer Vry = publicKey.ExponentiatePublicElement((r+e)%q);
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return (Vsg*Vsg + Vry*Vry + r*r) % p == (Vsg * Vry * r + 4) % p;
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}
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Integer DL_BasePrecomputation_LUC::Exponentiate(const DL_GroupPrecomputation<Element> &group, const Integer &exponent) const
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{
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return Lucas(exponent, m_g, static_cast<const DL_GroupPrecomputation_LUC &>(group).GetModulus());
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}
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void DL_GroupParameters_LUC::SimultaneousExponentiate(Element *results, const Element &base, const Integer *exponents, unsigned int exponentsCount) const
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{
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for (unsigned int i=0; i<exponentsCount; i++)
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results[i] = Lucas(exponents[i], base, GetModulus());
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}
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void LUCFunction::BERDecode(BufferedTransformation &bt)
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{
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BERSequenceDecoder seq(bt);
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m_n.BERDecode(seq);
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m_e.BERDecode(seq);
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seq.MessageEnd();
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}
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void LUCFunction::DEREncode(BufferedTransformation &bt) const
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{
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DERSequenceEncoder seq(bt);
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m_n.DEREncode(seq);
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m_e.DEREncode(seq);
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seq.MessageEnd();
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}
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Integer LUCFunction::ApplyFunction(const Integer &x) const
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{
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DoQuickSanityCheck();
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return Lucas(m_e, x, m_n);
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}
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bool LUCFunction::Validate(RandomNumberGenerator &rng, unsigned int level) const
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{
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bool pass = true;
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pass = pass && m_n > Integer::One() && m_n.IsOdd();
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pass = pass && m_e > Integer::One() && m_e.IsOdd() && m_e < m_n;
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return pass;
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}
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bool LUCFunction::GetVoidValue(const char *name, const std::type_info &valueType, void *pValue) const
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{
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return GetValueHelper(this, name, valueType, pValue).Assignable()
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CRYPTOPP_GET_FUNCTION_ENTRY(Modulus)
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CRYPTOPP_GET_FUNCTION_ENTRY(PublicExponent)
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;
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}
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void LUCFunction::AssignFrom(const NameValuePairs &source)
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{
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AssignFromHelper(this, source)
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CRYPTOPP_SET_FUNCTION_ENTRY(Modulus)
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CRYPTOPP_SET_FUNCTION_ENTRY(PublicExponent)
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;
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}
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// *****************************************************************************
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// private key operations:
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class LUCPrimeSelector : public PrimeSelector
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{
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public:
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LUCPrimeSelector(const Integer &e) : m_e(e) {}
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bool IsAcceptable(const Integer &candidate) const
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{
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return RelativelyPrime(m_e, candidate+1) && RelativelyPrime(m_e, candidate-1);
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}
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Integer m_e;
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};
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void InvertibleLUCFunction::GenerateRandom(RandomNumberGenerator &rng, const NameValuePairs &alg)
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{
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int modulusSize = 2048;
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alg.GetIntValue("ModulusSize", modulusSize) || alg.GetIntValue("KeySize", modulusSize);
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if (modulusSize < 16)
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throw InvalidArgument("InvertibleLUCFunction: specified modulus size is too small");
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m_e = alg.GetValueWithDefault("PublicExponent", Integer(17));
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if (m_e < 5 || m_e.IsEven())
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throw InvalidArgument("InvertibleLUCFunction: invalid public exponent");
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LUCPrimeSelector selector(m_e);
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AlgorithmParameters primeParam = MakeParametersForTwoPrimesOfEqualSize(modulusSize)
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("PointerToPrimeSelector", selector.GetSelectorPointer());
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m_p.GenerateRandom(rng, primeParam);
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m_q.GenerateRandom(rng, primeParam);
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m_n = m_p * m_q;
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m_u = m_q.InverseMod(m_p);
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}
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void InvertibleLUCFunction::Initialize(RandomNumberGenerator &rng, unsigned int keybits, const Integer &e)
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{
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GenerateRandom(rng, MakeParameters("ModulusSize", (int)keybits)("PublicExponent", e));
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}
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void InvertibleLUCFunction::BERDecode(BufferedTransformation &bt)
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{
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BERSequenceDecoder seq(bt);
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Integer version(seq);
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if (!!version) // make sure version is 0
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BERDecodeError();
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m_n.BERDecode(seq);
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m_e.BERDecode(seq);
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m_p.BERDecode(seq);
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m_q.BERDecode(seq);
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m_u.BERDecode(seq);
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seq.MessageEnd();
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}
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void InvertibleLUCFunction::DEREncode(BufferedTransformation &bt) const
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{
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DERSequenceEncoder seq(bt);
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const byte version[] = {INTEGER, 1, 0};
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seq.Put(version, sizeof(version));
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m_n.DEREncode(seq);
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m_e.DEREncode(seq);
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m_p.DEREncode(seq);
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m_q.DEREncode(seq);
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m_u.DEREncode(seq);
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seq.MessageEnd();
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}
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Integer InvertibleLUCFunction::CalculateInverse(RandomNumberGenerator &rng, const Integer &x) const
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{
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// not clear how to do blinding with LUC
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DoQuickSanityCheck();
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return InverseLucas(m_e, x, m_q, m_p, m_u);
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}
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bool InvertibleLUCFunction::Validate(RandomNumberGenerator &rng, unsigned int level) const
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{
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bool pass = LUCFunction::Validate(rng, level);
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pass = pass && m_p > Integer::One() && m_p.IsOdd() && m_p < m_n;
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pass = pass && m_q > Integer::One() && m_q.IsOdd() && m_q < m_n;
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pass = pass && m_u.IsPositive() && m_u < m_p;
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if (level >= 1)
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{
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pass = pass && m_p * m_q == m_n;
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pass = pass && RelativelyPrime(m_e, m_p+1);
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pass = pass && RelativelyPrime(m_e, m_p-1);
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pass = pass && RelativelyPrime(m_e, m_q+1);
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pass = pass && RelativelyPrime(m_e, m_q-1);
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pass = pass && m_u * m_q % m_p == 1;
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}
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if (level >= 2)
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pass = pass && VerifyPrime(rng, m_p, level-2) && VerifyPrime(rng, m_q, level-2);
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return pass;
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}
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bool InvertibleLUCFunction::GetVoidValue(const char *name, const std::type_info &valueType, void *pValue) const
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{
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return GetValueHelper<LUCFunction>(this, name, valueType, pValue).Assignable()
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CRYPTOPP_GET_FUNCTION_ENTRY(Prime1)
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CRYPTOPP_GET_FUNCTION_ENTRY(Prime2)
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CRYPTOPP_GET_FUNCTION_ENTRY(MultiplicativeInverseOfPrime2ModPrime1)
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;
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}
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void InvertibleLUCFunction::AssignFrom(const NameValuePairs &source)
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{
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AssignFromHelper<LUCFunction>(this, source)
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CRYPTOPP_SET_FUNCTION_ENTRY(Prime1)
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CRYPTOPP_SET_FUNCTION_ENTRY(Prime2)
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CRYPTOPP_SET_FUNCTION_ENTRY(MultiplicativeInverseOfPrime2ModPrime1)
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;
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}
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NAMESPACE_END
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