/* * Elliptic curves over GF(p) * * (C) 2007 Martin Doering, Christoph Ludwig, Falko Strenzke * 2010-2011,2012,2014 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #ifndef BOTAN_GFP_CURVE_H_ #define BOTAN_GFP_CURVE_H_ #include #include namespace Botan { class BOTAN_UNSTABLE_API CurveGFp_Repr { public: virtual ~CurveGFp_Repr() = default; virtual const BigInt& get_p() const = 0; virtual const BigInt& get_a() const = 0; virtual const BigInt& get_b() const = 0; virtual size_t get_p_words() const = 0; virtual size_t get_ws_size() const = 0; virtual bool is_one(const BigInt& x) const = 0; virtual bool a_is_zero() const = 0; virtual bool a_is_minus_3() const = 0; /* * Returns to_curve_rep(get_a()) */ virtual const BigInt& get_a_rep() const = 0; /* * Returns to_curve_rep(get_b()) */ virtual const BigInt& get_b_rep() const = 0; /* * Returns to_curve_rep(1) */ virtual const BigInt& get_1_rep() const = 0; virtual BigInt invert_element(const BigInt& x, secure_vector& ws) const = 0; virtual void to_curve_rep(BigInt& x, secure_vector& ws) const = 0; virtual void from_curve_rep(BigInt& x, secure_vector& ws) const = 0; virtual void curve_mul(BigInt& z, const BigInt& x, const BigInt& y, secure_vector& ws) const = 0; virtual void curve_mul_words(BigInt& z, const word x_words[], const size_t x_size, const BigInt& y, secure_vector& ws) const = 0; virtual void curve_sqr(BigInt& z, const BigInt& x, secure_vector& ws) const = 0; }; /** * This class represents an elliptic curve over GF(p) * * There should not be any reason for applications to use this type. * If you need EC primitives use the interfaces EC_Group and PointGFp * * It is likely this class will be removed entirely in a future major * release. */ class BOTAN_UNSTABLE_API CurveGFp final { public: /** * Create an uninitialized CurveGFp */ CurveGFp() = default; /** * Construct the elliptic curve E: y^2 = x^3 + ax + b over GF(p) * @param p prime number of the field * @param a first coefficient * @param b second coefficient */ CurveGFp(const BigInt& p, const BigInt& a, const BigInt& b) : m_repr(choose_repr(p, a, b)) { } CurveGFp(const CurveGFp&) = default; CurveGFp& operator=(const CurveGFp&) = default; /** * @return curve coefficient a */ const BigInt& get_a() const { return m_repr->get_a(); } /** * @return curve coefficient b */ const BigInt& get_b() const { return m_repr->get_b(); } /** * Get prime modulus of the field of the curve * @return prime modulus of the field of the curve */ const BigInt& get_p() const { return m_repr->get_p(); } size_t get_p_words() const { return m_repr->get_p_words(); } size_t get_ws_size() const { return m_repr->get_ws_size(); } const BigInt& get_a_rep() const { return m_repr->get_a_rep(); } const BigInt& get_b_rep() const { return m_repr->get_b_rep(); } const BigInt& get_1_rep() const { return m_repr->get_1_rep(); } bool a_is_minus_3() const { return m_repr->a_is_minus_3(); } bool a_is_zero() const { return m_repr->a_is_zero(); } bool is_one(const BigInt& x) const { return m_repr->is_one(x); } BigInt invert_element(const BigInt& x, secure_vector& ws) const { return m_repr->invert_element(x, ws); } void to_rep(BigInt& x, secure_vector& ws) const { m_repr->to_curve_rep(x, ws); } void from_rep(BigInt& x, secure_vector& ws) const { m_repr->from_curve_rep(x, ws); } BigInt from_rep(const BigInt& x, secure_vector& ws) const { BigInt xt(x); m_repr->from_curve_rep(xt, ws); return xt; } // TODO: from_rep taking && ref void mul(BigInt& z, const BigInt& x, const BigInt& y, secure_vector& ws) const { m_repr->curve_mul(z, x, y, ws); } void mul(BigInt& z, const word x_w[], size_t x_size, const BigInt& y, secure_vector& ws) const { m_repr->curve_mul_words(z, x_w, x_size, y, ws); } void sqr(BigInt& z, const BigInt& x, secure_vector& ws) const { m_repr->curve_sqr(z, x, ws); } BigInt mul(const BigInt& x, const BigInt& y, secure_vector& ws) const { return mul_to_tmp(x, y, ws); } BigInt sqr(const BigInt& x, secure_vector& ws) const { return sqr_to_tmp(x, ws); } BigInt mul_to_tmp(const BigInt& x, const BigInt& y, secure_vector& ws) const { BigInt z; m_repr->curve_mul(z, x, y, ws); return z; } BigInt sqr_to_tmp(const BigInt& x, secure_vector& ws) const { BigInt z; m_repr->curve_sqr(z, x, ws); return z; } void swap(CurveGFp& other) { std::swap(m_repr, other.m_repr); } /** * Equality operator * @param lhs a curve * @param rhs a curve * @return true iff lhs is the same as rhs */ inline bool operator==(const CurveGFp& other) const { if(m_repr.get() == other.m_repr.get()) return true; return (get_p() == other.get_p()) && (get_a() == other.get_a()) && (get_b() == other.get_b()); } private: static std::shared_ptr choose_repr(const BigInt& p, const BigInt& a, const BigInt& b); std::shared_ptr m_repr; }; inline bool operator!=(const CurveGFp& lhs, const CurveGFp& rhs) { return !(lhs == rhs); } } namespace std { template<> inline void swap(Botan::CurveGFp& curve1, Botan::CurveGFp& curve2) BOTAN_NOEXCEPT { curve1.swap(curve2); } } // namespace std #endif