cuberite-2a/CryptoPP/ecp.h

#ifndef CRYPTOPP_ECP_H
#define CRYPTOPP_ECP_H

#include "modarith.h"
#include "eprecomp.h"
#include "smartptr.h"
#include "pubkey.h"

NAMESPACE_BEGIN(CryptoPP)

//! Elliptical Curve Point
struct CRYPTOPP_DLL ECPPoint
{
	ECPPoint() : identity(true) {}
	ECPPoint(const Integer &x, const Integer &y)
		: identity(false), x(x), y(y) {}

	bool operator==(const ECPPoint &t) const
		{return (identity && t.identity) || (!identity && !t.identity && x==t.x && y==t.y);}
	bool operator< (const ECPPoint &t) const
		{return identity ? !t.identity : (!t.identity && (x<t.x || (x==t.x && y<t.y)));}

	bool identity;
	Integer x, y;
};

CRYPTOPP_DLL_TEMPLATE_CLASS AbstractGroup<ECPPoint>;

//! Elliptic Curve over GF(p), where p is prime
class CRYPTOPP_DLL ECP : public AbstractGroup<ECPPoint>
{
public:
	typedef ModularArithmetic Field;
	typedef Integer FieldElement;
	typedef ECPPoint Point;

	ECP() {}
	ECP(const ECP &ecp, bool convertToMontgomeryRepresentation = false);
	ECP(const Integer &modulus, const FieldElement &a, const FieldElement &b)
		: m_fieldPtr(new Field(modulus)), m_a(a.IsNegative() ? modulus+a : a), m_b(b) {}
	// construct from BER encoded parameters
	// this constructor will decode and extract the the fields fieldID and curve of the sequence ECParameters
	ECP(BufferedTransformation &bt);

	// encode the fields fieldID and curve of the sequence ECParameters
	void DEREncode(BufferedTransformation &bt) const;

	bool Equal(const Point &P, const Point &Q) const;
	const Point& Identity() const;
	const Point& Inverse(const Point &P) const;
	bool InversionIsFast() const {return true;}
	const Point& Add(const Point &P, const Point &Q) const;
	const Point& Double(const Point &P) const;
	Point ScalarMultiply(const Point &P, const Integer &k) const;
	Point CascadeScalarMultiply(const Point &P, const Integer &k1, const Point &Q, const Integer &k2) const;
	void SimultaneousMultiply(Point *results, const Point &base, const Integer *exponents, unsigned int exponentsCount) const;

	Point Multiply(const Integer &k, const Point &P) const
		{return ScalarMultiply(P, k);}
	Point CascadeMultiply(const Integer &k1, const Point &P, const Integer &k2, const Point &Q) const
		{return CascadeScalarMultiply(P, k1, Q, k2);}

	bool ValidateParameters(RandomNumberGenerator &rng, unsigned int level=3) const;
	bool VerifyPoint(const Point &P) const;

	unsigned int EncodedPointSize(bool compressed = false) const
		{return 1 + (compressed?1:2)*GetField().MaxElementByteLength();}
	// returns false if point is compressed and not valid (doesn't check if uncompressed)
	bool DecodePoint(Point &P, BufferedTransformation &bt, size_t len) const;
	bool DecodePoint(Point &P, const byte *encodedPoint, size_t len) const;
	void EncodePoint(byte *encodedPoint, const Point &P, bool compressed) const;
	void EncodePoint(BufferedTransformation &bt, const Point &P, bool compressed) const;

	Point BERDecodePoint(BufferedTransformation &bt) const;
	void DEREncodePoint(BufferedTransformation &bt, const Point &P, bool compressed) const;

	Integer FieldSize() const {return GetField().GetModulus();}
	const Field & GetField() const {return *m_fieldPtr;}
	const FieldElement & GetA() const {return m_a;}
	const FieldElement & GetB() const {return m_b;}

	bool operator==(const ECP &rhs) const
		{return GetField() == rhs.GetField() && m_a == rhs.m_a && m_b == rhs.m_b;}

private:
	clonable_ptr<Field> m_fieldPtr;
	FieldElement m_a, m_b;
	mutable Point m_R;
};

CRYPTOPP_DLL_TEMPLATE_CLASS DL_FixedBasePrecomputationImpl<ECP::Point>;
CRYPTOPP_DLL_TEMPLATE_CLASS DL_GroupPrecomputation<ECP::Point>;

template <class T> class EcPrecomputation;

//! ECP precomputation
template<> class EcPrecomputation<ECP> : public DL_GroupPrecomputation<ECP::Point>
{
public:
	typedef ECP EllipticCurve;
	
	// DL_GroupPrecomputation
	bool NeedConversions() const {return true;}
	Element ConvertIn(const Element &P) const
		{return P.identity ? P : ECP::Point(m_ec->GetField().ConvertIn(P.x), m_ec->GetField().ConvertIn(P.y));};
	Element ConvertOut(const Element &P) const
		{return P.identity ? P : ECP::Point(m_ec->GetField().ConvertOut(P.x), m_ec->GetField().ConvertOut(P.y));}
	const AbstractGroup<Element> & GetGroup() const {return *m_ec;}
	Element BERDecodeElement(BufferedTransformation &bt) const {return m_ec->BERDecodePoint(bt);}
	void DEREncodeElement(BufferedTransformation &bt, const Element &v) const {m_ec->DEREncodePoint(bt, v, false);}

	// non-inherited
	void SetCurve(const ECP &ec)
	{
		m_ec.reset(new ECP(ec, true));
		m_ecOriginal = ec;
	}
	const ECP & GetCurve() const {return *m_ecOriginal;}

private:
	value_ptr<ECP> m_ec, m_ecOriginal;
};

NAMESPACE_END

#endif
Implemented 1.3.2 protocol encryption using CryptoPP, up to Client Status packet (http://wiki.vg/Protocol_FAQ step 14) git-svn-id: http://mc-server.googlecode.com/svn/trunk@808 0a769ca7-a7f5-676a-18bf-c427514a06d6 2012-08-30 17:06:13 -04:00			`#ifndef CRYPTOPP_ECP_H`
			`#define CRYPTOPP_ECP_H`

			`#include "modarith.h"`
			`#include "eprecomp.h"`
			`#include "smartptr.h"`
			`#include "pubkey.h"`

			`NAMESPACE_BEGIN(CryptoPP)`

			`//! Elliptical Curve Point`
			`struct CRYPTOPP_DLL ECPPoint`
			`{`
			`ECPPoint() : identity(true) {}`
			`ECPPoint(const Integer &x, const Integer &y)`
			`: identity(false), x(x), y(y) {}`

			`bool operator==(const ECPPoint &t) const`
			`{return (identity && t.identity) \|\| (!identity && !t.identity && x==t.x && y==t.y);}`
			`bool operator< (const ECPPoint &t) const`
			`{return identity ? !t.identity : (!t.identity && (x<t.x \|\| (x==t.x && y<t.y)));}`

			`bool identity;`
			`Integer x, y;`
			`};`

			`CRYPTOPP_DLL_TEMPLATE_CLASS AbstractGroup<ECPPoint>;`

			`//! Elliptic Curve over GF(p), where p is prime`
			`class CRYPTOPP_DLL ECP : public AbstractGroup<ECPPoint>`
			`{`
			`public:`
			`typedef ModularArithmetic Field;`
			`typedef Integer FieldElement;`
			`typedef ECPPoint Point;`

			`ECP() {}`
			`ECP(const ECP &ecp, bool convertToMontgomeryRepresentation = false);`
			`ECP(const Integer &modulus, const FieldElement &a, const FieldElement &b)`
			`: m_fieldPtr(new Field(modulus)), m_a(a.IsNegative() ? modulus+a : a), m_b(b) {}`
			`// construct from BER encoded parameters`
			`// this constructor will decode and extract the the fields fieldID and curve of the sequence ECParameters`
			`ECP(BufferedTransformation &bt);`

			`// encode the fields fieldID and curve of the sequence ECParameters`
			`void DEREncode(BufferedTransformation &bt) const;`

			`bool Equal(const Point &P, const Point &Q) const;`
			`const Point& Identity() const;`
			`const Point& Inverse(const Point &P) const;`
			`bool InversionIsFast() const {return true;}`
			`const Point& Add(const Point &P, const Point &Q) const;`
			`const Point& Double(const Point &P) const;`
			`Point ScalarMultiply(const Point &P, const Integer &k) const;`
			`Point CascadeScalarMultiply(const Point &P, const Integer &k1, const Point &Q, const Integer &k2) const;`
			`void SimultaneousMultiply(Point results, const Point &base, const Integer exponents, unsigned int exponentsCount) const;`

			`Point Multiply(const Integer &k, const Point &P) const`
			`{return ScalarMultiply(P, k);}`
			`Point CascadeMultiply(const Integer &k1, const Point &P, const Integer &k2, const Point &Q) const`
			`{return CascadeScalarMultiply(P, k1, Q, k2);}`

			`bool ValidateParameters(RandomNumberGenerator &rng, unsigned int level=3) const;`
			`bool VerifyPoint(const Point &P) const;`

			`unsigned int EncodedPointSize(bool compressed = false) const`
			`{return 1 + (compressed?1:2)*GetField().MaxElementByteLength();}`
			`// returns false if point is compressed and not valid (doesn't check if uncompressed)`
			`bool DecodePoint(Point &P, BufferedTransformation &bt, size_t len) const;`
			`bool DecodePoint(Point &P, const byte *encodedPoint, size_t len) const;`
			`void EncodePoint(byte *encodedPoint, const Point &P, bool compressed) const;`
			`void EncodePoint(BufferedTransformation &bt, const Point &P, bool compressed) const;`

			`Point BERDecodePoint(BufferedTransformation &bt) const;`
			`void DEREncodePoint(BufferedTransformation &bt, const Point &P, bool compressed) const;`

			`Integer FieldSize() const {return GetField().GetModulus();}`
			`const Field & GetField() const {return *m_fieldPtr;}`
			`const FieldElement & GetA() const {return m_a;}`
			`const FieldElement & GetB() const {return m_b;}`

			`bool operator==(const ECP &rhs) const`
			`{return GetField() == rhs.GetField() && m_a == rhs.m_a && m_b == rhs.m_b;}`

			`private:`
			`clonable_ptr<Field> m_fieldPtr;`
			`FieldElement m_a, m_b;`
			`mutable Point m_R;`
			`};`

			`CRYPTOPP_DLL_TEMPLATE_CLASS DL_FixedBasePrecomputationImpl<ECP::Point>;`
			`CRYPTOPP_DLL_TEMPLATE_CLASS DL_GroupPrecomputation<ECP::Point>;`

			`template <class T> class EcPrecomputation;`

			`//! ECP precomputation`
			`template<> class EcPrecomputation<ECP> : public DL_GroupPrecomputation<ECP::Point>`
			`{`
			`public:`
			`typedef ECP EllipticCurve;`

			`// DL_GroupPrecomputation`
			`bool NeedConversions() const {return true;}`
			`Element ConvertIn(const Element &P) const`
			`{return P.identity ? P : ECP::Point(m_ec->GetField().ConvertIn(P.x), m_ec->GetField().ConvertIn(P.y));};`
			`Element ConvertOut(const Element &P) const`
			`{return P.identity ? P : ECP::Point(m_ec->GetField().ConvertOut(P.x), m_ec->GetField().ConvertOut(P.y));}`
			`const AbstractGroup<Element> & GetGroup() const {return *m_ec;}`
			`Element BERDecodeElement(BufferedTransformation &bt) const {return m_ec->BERDecodePoint(bt);}`
			`void DEREncodeElement(BufferedTransformation &bt, const Element &v) const {m_ec->DEREncodePoint(bt, v, false);}`

			`// non-inherited`
			`void SetCurve(const ECP &ec)`
			`{`
			`m_ec.reset(new ECP(ec, true));`
			`m_ecOriginal = ec;`
			`}`
			`const ECP & GetCurve() const {return *m_ecOriginal;}`

			`private:`
			`value_ptr<ECP> m_ec, m_ecOriginal;`
			`};`

			`NAMESPACE_END`

			`#endif`