// hkdf.h - written and placed in public domain by Jeffrey Walton. /// \file hkdf.h /// \brief Classes for HKDF from RFC 5869 /// \since Crypto++ 5.6.3 #ifndef CRYPTOPP_HKDF_H #define CRYPTOPP_HKDF_H #include "cryptlib.h" #include "secblock.h" #include "hmac.h" NAMESPACE_BEGIN(CryptoPP) /// \brief Extract-and-Expand Key Derivation Function (HKDF) /// \tparam T HashTransformation class /// \sa Cryptographic Extraction and Key Derivation: The HKDF Scheme /// and HMAC-based Extract-and-Expand Key Derivation Function (HKDF) /// \since Crypto++ 5.6.3 template class HKDF : public KeyDerivationFunction { public: virtual ~HKDF() {} static std::string StaticAlgorithmName () { const std::string name(std::string("HKDF(") + std::string(T::StaticAlgorithmName()) + std::string(")")); return name; } // KeyDerivationFunction interface std::string AlgorithmName() const { return StaticAlgorithmName(); } // KeyDerivationFunction interface size_t MaxDerivedLength() const { return static_cast(T::DIGESTSIZE) * 255; } // KeyDerivationFunction interface size_t GetValidDerivedLength(size_t keylength) const; // KeyDerivationFunction interface size_t DeriveKey(byte *derived, size_t derivedLen, const byte *secret, size_t secretLen, const NameValuePairs& params) const; /// \brief Derive a key from a seed /// \param derived the derived output buffer /// \param derivedLen the size of the derived buffer, in bytes /// \param secret the seed input buffer /// \param secretLen the size of the secret buffer, in bytes /// \param salt the salt input buffer /// \param saltLen the size of the salt buffer, in bytes /// \param info the additional input buffer /// \param infoLen the size of the info buffer, in bytes /// \returns the number of iterations performed /// \throws InvalidDerivedLength if derivedLen is invalid for the scheme /// \details DeriveKey() provides a standard interface to derive a key from /// a seed and other parameters. Each class that derives from KeyDerivationFunction /// provides an overload that accepts most parameters used by the derivation function. /// \details salt and info can be nullptr with 0 length. /// HKDF is unusual in that a non-NULL salt with length 0 is different than a /// NULL salt. A NULL salt causes HKDF to use a string of 0's /// of length T::DIGESTSIZE for the salt. /// \details HKDF always returns 1 because it only performs 1 iteration. Other /// derivation functions, like PBKDF's, will return more interesting values. size_t DeriveKey(byte *derived, size_t derivedLen, const byte *secret, size_t secretLen, const byte *salt, size_t saltLen, const byte* info, size_t infoLen) const; protected: // KeyDerivationFunction interface const Algorithm & GetAlgorithm() const { return *this; } // If salt is absent (NULL), then use the NULL vector. Missing is different than // EMPTY (Non-NULL, 0 length). The length of s_NullVector used depends on the Hash // function. SHA-256 will use 32 bytes of s_NullVector. typedef byte NullVectorType[T::DIGESTSIZE]; static const NullVectorType& GetNullVector() { static const NullVectorType s_NullVector = {0}; return s_NullVector; } }; template size_t HKDF::GetValidDerivedLength(size_t keylength) const { if (keylength > MaxDerivedLength()) return MaxDerivedLength(); return keylength; } template size_t HKDF::DeriveKey(byte *derived, size_t derivedLen, const byte *secret, size_t secretLen, const NameValuePairs& params) const { CRYPTOPP_ASSERT(secret && secretLen); CRYPTOPP_ASSERT(derived && derivedLen); CRYPTOPP_ASSERT(derivedLen <= MaxDerivedLength()); ConstByteArrayParameter p; SecByteBlock salt, info; if (params.GetValue("Salt", p)) salt.Assign(p.begin(), p.size()); else salt.Assign(GetNullVector(), T::DIGESTSIZE); if (params.GetValue("Info", p)) info.Assign(p.begin(), p.size()); else info.Assign(GetNullVector(), 0); return DeriveKey(derived, derivedLen, secret, secretLen, salt.begin(), salt.size(), info.begin(), info.size()); } template size_t HKDF::DeriveKey(byte *derived, size_t derivedLen, const byte *secret, size_t secretLen, const byte *salt, size_t saltLen, const byte* info, size_t infoLen) const { CRYPTOPP_ASSERT(secret && secretLen); CRYPTOPP_ASSERT(derived && derivedLen); CRYPTOPP_ASSERT(derivedLen <= MaxDerivedLength()); ThrowIfInvalidDerivedLength(derivedLen); // key is PRK from the RFC, salt is IKM from the RFC HMAC hmac; SecByteBlock key(T::DIGESTSIZE), buffer(T::DIGESTSIZE); // Extract hmac.SetKey(salt, saltLen); hmac.CalculateDigest(key, secret, secretLen); // Key hmac.SetKey(key.begin(), key.size()); byte block = 0; // Expand while (derivedLen > 0) { if (block++) {hmac.Update(buffer, buffer.size());} if (infoLen) {hmac.Update(info, infoLen);} hmac.CalculateDigest(buffer, &block, 1); #if CRYPTOPP_MSC_VERSION const size_t digestSize = static_cast(T::DIGESTSIZE); const size_t segmentLen = STDMIN(derivedLen, digestSize); memcpy_s(derived, segmentLen, buffer, segmentLen); #else const size_t digestSize = static_cast(T::DIGESTSIZE); const size_t segmentLen = STDMIN(derivedLen, digestSize); std::memcpy(derived, buffer, segmentLen); #endif derived += segmentLen; derivedLen -= segmentLen; } return 1; } NAMESPACE_END #endif // CRYPTOPP_HKDF_H