#ifndef NTL_GF2EX__H #define NTL_GF2EX__H #include #include #include #include #include NTL_OPEN_NNS class GF2EX { public: vec_GF2E rep; /*************************************************************** Constructors, Destructors, and Assignment ****************************************************************/ GF2EX() { } GF2EX(INIT_SIZE_TYPE, long n) { rep.SetMaxLength(n); } GF2EX(const GF2EX& a) : rep(a.rep) { } GF2EX& operator=(const GF2EX& a) { rep = a.rep; return *this; } ~GF2EX() { } void normalize(); // strip leading zeros void SetMaxLength(long n) // pre-allocate space for n coefficients. // Value is unchanged { rep.SetMaxLength(n); } void kill() // free space held by this polynomial. Value becomes 0. { rep.kill(); } static const GF2EX& zero(); inline GF2EX& operator=(long a); inline GF2EX& operator=(GF2 a); inline GF2EX& operator=(const GF2E& a); inline GF2EX(long i, long a); inline GF2EX(long i, GF2 a); inline GF2EX(long i, const GF2E& a); GF2EX(GF2EX& x, INIT_TRANS_TYPE) : rep(x.rep, INIT_TRANS) { } }; /******************************************************************** input and output *********************************************************************/ NTL_SNS istream& operator>>(NTL_SNS istream& s, GF2EX& x); NTL_SNS ostream& operator<<(NTL_SNS ostream& s, const GF2EX& a); /********************************************************** Some utility routines ***********************************************************/ inline long deg(const GF2EX& a) { return a.rep.length() - 1; } const GF2E& coeff(const GF2EX& a, long i); // zero if i not in range void GetCoeff(GF2E& x, const GF2EX& a, long i); // x = a[i], or zero if i not in range const GF2E& LeadCoeff(const GF2EX& a); // zero if a == 0 const GF2E& ConstTerm(const GF2EX& a); // zero if a == 0 void SetCoeff(GF2EX& x, long i, const GF2E& a); void SetCoeff(GF2EX& x, long i, GF2 a); void SetCoeff(GF2EX& x, long i, long a); // x[i] = a, error is raised if i < 0 inline GF2EX::GF2EX(long i, const GF2E& a) { SetCoeff(*this, i, a); } inline GF2EX::GF2EX(long i, GF2 a) { SetCoeff(*this, i, a); } inline GF2EX::GF2EX(long i, long a) { SetCoeff(*this, i, a); } void SetCoeff(GF2EX& x, long i); // x[i] = 1, error is raised if i < 0 void SetX(GF2EX& x); // x is set to the monomial X long IsX(const GF2EX& a); // test if x = X inline void clear(GF2EX& x) // x = 0 { x.rep.SetLength(0); } inline void set(GF2EX& x) // x = 1 { x.rep.SetLength(1); set(x.rep[0]); } inline void swap(GF2EX& x, GF2EX& y) // swap x & y (only pointers are swapped) { swap(x.rep, y.rep); } void random(GF2EX& x, long n); inline GF2EX random_GF2EX(long n) { GF2EX x; random(x, n); NTL_OPT_RETURN(GF2EX, x); } // generate a random polynomial of degree < n void trunc(GF2EX& x, const GF2EX& a, long m); inline GF2EX trunc(const GF2EX& a, long m) { GF2EX x; trunc(x, a, m); NTL_OPT_RETURN(GF2EX, x); } // x = a % X^m void RightShift(GF2EX& x, const GF2EX& a, long n); inline GF2EX RightShift(const GF2EX& a, long n) { GF2EX x; RightShift(x, a, n); NTL_OPT_RETURN(GF2EX, x); } // x = a/X^n void LeftShift(GF2EX& x, const GF2EX& a, long n); inline GF2EX LeftShift(const GF2EX& a, long n) { GF2EX x; LeftShift(x, a, n); NTL_OPT_RETURN(GF2EX, x); } // x = a*X^n #ifndef NTL_TRANSITION inline GF2EX operator>>(const GF2EX& a, long n) { GF2EX x; RightShift(x, a, n); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator<<(const GF2EX& a, long n) { GF2EX x; LeftShift(x, a, n); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX& operator<<=(GF2EX& x, long n) { LeftShift(x, x, n); return x; } inline GF2EX& operator>>=(GF2EX& x, long n) { RightShift(x, x, n); return x; } #endif void diff(GF2EX& x, const GF2EX& a); inline GF2EX diff(const GF2EX& a) { GF2EX x; diff(x, a); NTL_OPT_RETURN(GF2EX, x); } // x = derivative of a void MakeMonic(GF2EX& x); void reverse(GF2EX& c, const GF2EX& a, long hi); inline GF2EX reverse(const GF2EX& a, long hi) { GF2EX x; reverse(x, a, hi); NTL_OPT_RETURN(GF2EX, x); } inline void reverse(GF2EX& c, const GF2EX& a) { reverse(c, a, deg(a)); } inline GF2EX reverse(const GF2EX& a) { GF2EX x; reverse(x, a); NTL_OPT_RETURN(GF2EX, x); } inline void VectorCopy(vec_GF2E& x, const GF2EX& a, long n) { VectorCopy(x, a.rep, n); } inline vec_GF2E VectorCopy(const GF2EX& a, long n) { return VectorCopy(a.rep, n); } /******************************************************************* conversion routines ********************************************************************/ void conv(GF2EX& x, long a); void conv(GF2EX& x, GF2 a); void conv(GF2EX& x, const GF2E& a); void conv(GF2EX& x, const ZZ& a); #ifndef NTL_TRANSITION void conv(GF2EX& x, const GF2X& a); #endif void conv(GF2EX& x, const vec_GF2E& a); inline GF2EX to_GF2EX(long a) { GF2EX x; conv(x, a); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX to_GF2EX(GF2 a) { GF2EX x; conv(x, a); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX to_GF2EX(const GF2E& a) { GF2EX x; conv(x, a); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX to_GF2EX(const ZZ& a) { GF2EX x; conv(x, a); NTL_OPT_RETURN(GF2EX, x); } #ifndef NTL_TRANSITION inline GF2EX to_GF2EX(GF2X& a) { GF2EX x; conv(x, a); NTL_OPT_RETURN(GF2EX, x); } #endif inline GF2EX to_GF2EX(const vec_GF2E& a) { GF2EX x; conv(x, a); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX& GF2EX::operator=(const GF2E& a) { conv(*this, a); return *this; } inline GF2EX& GF2EX::operator=(GF2 a) { conv(*this, a); return *this; } inline GF2EX& GF2EX::operator=(long a) { conv(*this, a); return *this; } /************************************************************* Comparison **************************************************************/ long IsZero(const GF2EX& a); long IsOne(const GF2EX& a); inline long operator==(const GF2EX& a, const GF2EX& b) { return a.rep == b.rep; } long operator==(const GF2EX& a, const GF2E& b); long operator==(const GF2EX& a, GF2 b); long operator==(const GF2EX& a, long b); inline long operator==(const GF2E& a, const GF2EX& b) { return b == a; } inline long operator==(GF2 a, const GF2EX& b) { return b == a; } inline long operator==(long a, const GF2EX& b) { return b == a; } inline long operator!=(const GF2EX& a, const GF2EX& b) { return !(a == b); } inline long operator!=(const GF2EX& a, const GF2E& b) { return !(a == b); } inline long operator!=(const GF2EX& a, GF2 b) { return !(a == b); } inline long operator!=(const GF2EX& a, long b) { return !(a == b); } inline long operator!=(const GF2E& a, const GF2EX& b) { return !(a == b); } inline long operator!=(GF2 a, const GF2EX& b) { return !(a == b); } inline long operator!=(long a, const GF2EX& b) { return !(a == b); } /*************************************************************** Addition ****************************************************************/ void add(GF2EX& x, const GF2EX& a, const GF2EX& b); // x = a + b void add(GF2EX& x, const GF2EX& a, const GF2E& b); void add(GF2EX& x, const GF2EX& a, GF2 b); void add(GF2EX& x, const GF2EX& a, long); inline void add(GF2EX& x, const GF2E& a, const GF2EX& b) { add(x, b, a); } inline void add(GF2EX& x, GF2 a, const GF2EX& b) { add(x, b, a); } inline void add(GF2EX& x, long a, const GF2EX& b) { add(x, b, a); } inline void sub(GF2EX& x, const GF2EX& a, const GF2EX& b) { add(x, a, b); } inline void sub(GF2EX& x, const GF2EX& a, const GF2E& b) { add(x, a, b); } inline void sub(GF2EX& x, const GF2EX& a, GF2 b) { add(x, a, b); } inline void sub(GF2EX& x, const GF2EX& a, long b) { add(x, a, b); } inline void sub(GF2EX& x, const GF2E& a, const GF2EX& b) { add(x, a, b); } inline void sub(GF2EX& x, GF2 a, const GF2EX& b) { add(x, a, b); } inline void sub(GF2EX& x, long a, const GF2EX& b) { add(x, a, b); } inline void negate(GF2EX& x, const GF2EX& a) { x = a; } inline GF2EX operator+(const GF2EX& a, const GF2EX& b) { GF2EX x; add(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator+(const GF2EX& a, const GF2E& b) { GF2EX x; add(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator+(const GF2EX& a, GF2 b) { GF2EX x; add(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator+(const GF2EX& a, long b) { GF2EX x; add(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator+(const GF2E& a, const GF2EX& b) { GF2EX x; add(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator+(GF2 a, const GF2EX& b) { GF2EX x; add(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator+(long a, const GF2EX& b) { GF2EX x; add(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator-(const GF2EX& a, const GF2EX& b) { GF2EX x; sub(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator-(const GF2EX& a, const GF2E& b) { GF2EX x; sub(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator-(const GF2EX& a, GF2 b) { GF2EX x; sub(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator-(const GF2EX& a, long b) { GF2EX x; sub(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator-(const GF2E& a, const GF2EX& b) { GF2EX x; sub(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator-(GF2 a, const GF2EX& b) { GF2EX x; sub(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator-(long a, const GF2EX& b) { GF2EX x; sub(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX& operator+=(GF2EX& x, const GF2EX& b) { add(x, x, b); return x; } inline GF2EX& operator+=(GF2EX& x, const GF2E& b) { add(x, x, b); return x; } inline GF2EX& operator+=(GF2EX& x, GF2 b) { add(x, x, b); return x; } inline GF2EX& operator+=(GF2EX& x, long b) { add(x, x, b); return x; } inline GF2EX& operator-=(GF2EX& x, const GF2EX& b) { sub(x, x, b); return x; } inline GF2EX& operator-=(GF2EX& x, const GF2E& b) { sub(x, x, b); return x; } inline GF2EX& operator-=(GF2EX& x, GF2 b) { sub(x, x, b); return x; } inline GF2EX& operator-=(GF2EX& x, long b) { sub(x, x, b); return x; } inline GF2EX operator-(const GF2EX& a) { GF2EX x; negate(x, a); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX& operator++(GF2EX& x) { add(x, x, 1); return x; } inline void operator++(GF2EX& x, int) { add(x, x, 1); } inline GF2EX& operator--(GF2EX& x) { sub(x, x, 1); return x; } inline void operator--(GF2EX& x, int) { sub(x, x, 1); } /***************************************************************** Multiplication ******************************************************************/ void mul(GF2EX& x, const GF2EX& a, const GF2EX& b); // x = a * b void sqr(GF2EX& x, const GF2EX& a); inline GF2EX sqr(const GF2EX& a) { GF2EX x; sqr(x, a); NTL_OPT_RETURN(GF2EX, x); } // x = a^2 void mul(GF2EX & x, const GF2EX& a, const GF2E& b); void mul(GF2EX & x, const GF2EX& a, GF2 b); void mul(GF2EX & x, const GF2EX& a, long b); inline void mul(GF2EX& x, const GF2E& a, const GF2EX& b) { mul(x, b, a); } inline void mul(GF2EX& x, GF2 a, const GF2EX& b) { mul(x, b, a); } inline void mul(GF2EX& x, long a, const GF2EX& b) { mul(x, b, a); } void MulTrunc(GF2EX& x, const GF2EX& a, const GF2EX& b, long n); inline GF2EX MulTrunc(const GF2EX& a, const GF2EX& b, long n) { GF2EX x; MulTrunc(x, a, b, n); NTL_OPT_RETURN(GF2EX, x); } // x = a * b % X^n void SqrTrunc(GF2EX& x, const GF2EX& a, long n); inline GF2EX SqrTrunc(const GF2EX& a, long n) { GF2EX x; SqrTrunc(x, a, n); NTL_OPT_RETURN(GF2EX, x); } // x = a*a % X^n inline GF2EX operator*(const GF2EX& a, const GF2EX& b) { GF2EX x; mul(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator*(const GF2EX& a, const GF2E& b) { GF2EX x; mul(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator*(const GF2EX& a, GF2 b) { GF2EX x; mul(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator*(const GF2EX& a, long b) { GF2EX x; mul(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator*(const GF2E& a, const GF2EX& b) { GF2EX x; mul(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator*(GF2 a, const GF2EX& b) { GF2EX x; mul(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator*(long a, const GF2EX& b) { GF2EX x; mul(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX& operator*=(GF2EX& x, const GF2EX& b) { mul(x, x, b); return x; } inline GF2EX& operator*=(GF2EX& x, const GF2E& b) { mul(x, x, b); return x; } inline GF2EX& operator*=(GF2EX& x, GF2 b) { mul(x, x, b); return x; } inline GF2EX& operator*=(GF2EX& x, long b) { mul(x, x, b); return x; } void power(GF2EX& x, const GF2EX& a, long e); inline GF2EX power(const GF2EX& a, long e) { GF2EX x; power(x, a, e); NTL_OPT_RETURN(GF2EX, x); } /************************************************************* Division **************************************************************/ void DivRem(GF2EX& q, GF2EX& r, const GF2EX& a, const GF2EX& b); // q = a/b, r = a%b void div(GF2EX& q, const GF2EX& a, const GF2EX& b); void div(GF2EX& q, const GF2EX& a, const GF2E& b); void div(GF2EX& q, const GF2EX& a, GF2 b); void div(GF2EX& q, const GF2EX& a, long b); // q = a/b void rem(GF2EX& r, const GF2EX& a, const GF2EX& b); // r = a%b long divide(GF2EX& q, const GF2EX& a, const GF2EX& b); // if b | a, sets q = a/b and returns 1; otherwise returns 0 long divide(const GF2EX& a, const GF2EX& b); // if b | a, sets q = a/b and returns 1; otherwise returns 0 void InvTrunc(GF2EX& x, const GF2EX& a, long m); inline GF2EX InvTrunc(const GF2EX& a, long m) { GF2EX x; InvTrunc(x, a, m); NTL_OPT_RETURN(GF2EX, x); } // computes x = a^{-1} % X^m // constant term must be non-zero inline GF2EX operator/(const GF2EX& a, const GF2EX& b) { GF2EX x; div(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator/(const GF2EX& a, const GF2E& b) { GF2EX x; div(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator/(const GF2EX& a, GF2 b) { GF2EX x; div(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator/(const GF2EX& a, long b) { GF2EX x; div(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX& operator/=(GF2EX& x, const GF2EX& b) { div(x, x, b); return x; } inline GF2EX& operator/=(GF2EX& x, const GF2E& b) { div(x, x, b); return x; } inline GF2EX& operator/=(GF2EX& x, GF2 b) { div(x, x, b); return x; } inline GF2EX& operator/=(GF2EX& x, long b) { div(x, x, b); return x; } inline GF2EX operator%(const GF2EX& a, const GF2EX& b) { GF2EX x; rem(x, a, b); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX& operator%=(GF2EX& x, const GF2EX& b) { rem(x, x, b); return x; } /*********************************************************** GCD's ************************************************************/ void GCD(GF2EX& x, const GF2EX& a, const GF2EX& b); inline GF2EX GCD(const GF2EX& a, const GF2EX& b) { GF2EX x; GCD(x, a, b); NTL_OPT_RETURN(GF2EX, x); } // x = GCD(a, b), x is always monic (or zero if a==b==0). void XGCD(GF2EX& d, GF2EX& s, GF2EX& t, const GF2EX& a, const GF2EX& b); // d = gcd(a,b), a s + b t = d /************************************************************* Modular Arithmetic without pre-conditioning **************************************************************/ // arithmetic mod f. // all inputs and outputs are polynomials of degree less than deg(f). // ASSUMPTION: f is assumed monic, and deg(f) > 0. // NOTE: if you want to do many computations with a fixed f, // use the GF2EXModulus data structure and associated routines below. void MulMod(GF2EX& x, const GF2EX& a, const GF2EX& b, const GF2EX& f); inline GF2EX MulMod(const GF2EX& a, const GF2EX& b, const GF2EX& f) { GF2EX x; MulMod(x, a, b, f); NTL_OPT_RETURN(GF2EX, x); } // x = (a * b) % f void SqrMod(GF2EX& x, const GF2EX& a, const GF2EX& f); inline GF2EX SqrMod(const GF2EX& a, const GF2EX& f) { GF2EX x; SqrMod(x, a, f); NTL_OPT_RETURN(GF2EX, x); } // x = a^2 % f void MulByXMod(GF2EX& x, const GF2EX& a, const GF2EX& f); inline GF2EX MulByXMod(const GF2EX& a, const GF2EX& f) { GF2EX x; MulByXMod(x, a, f); NTL_OPT_RETURN(GF2EX, x); } // x = (a * X) mod f void InvMod(GF2EX& x, const GF2EX& a, const GF2EX& f); inline GF2EX InvMod(const GF2EX& a, const GF2EX& f) { GF2EX x; InvMod(x, a, f); NTL_OPT_RETURN(GF2EX, x); } // x = a^{-1} % f, error is a is not invertible long InvModStatus(GF2EX& x, const GF2EX& a, const GF2EX& f); // if (a, f) = 1, returns 0 and sets x = a^{-1} % f // otherwise, returns 1 and sets x = (a, f) /****************************************************************** Modular Arithmetic with Pre-conditioning *******************************************************************/ // If you need to do a lot of arithmetic modulo a fixed f, // build GF2EXModulus F for f. This pre-computes information about f // that speeds up the computation a great deal. class GF2EXModulus { public: GF2EXModulus(); ~GF2EXModulus() { } GF2EXModulus(const GF2EX& ff); GF2EX f; // the modulus operator const GF2EX& () const { return f; } const GF2EX& val() const { return f; } long n; // deg(f) long method; // GF2EX_MOD_PLAIN or GF2EX_MOD_MUL GF2EX h0; GF2E hlc; GF2EX f0; vec_GF2E tracevec; }; inline long deg(const GF2EXModulus& F) { return F.n; } void build(GF2EXModulus& F, const GF2EX& f); void rem(GF2EX& r, const GF2EX& a, const GF2EXModulus& F); void DivRem(GF2EX& q, GF2EX& r, const GF2EX& a, const GF2EXModulus& F); void div(GF2EX& q, const GF2EX& a, const GF2EXModulus& F); void MulMod(GF2EX& c, const GF2EX& a, const GF2EX& b, const GF2EXModulus& F); inline GF2EX MulMod(const GF2EX& a, const GF2EX& b, const GF2EXModulus& F) { GF2EX x; MulMod(x, a, b, F); NTL_OPT_RETURN(GF2EX, x); } void SqrMod(GF2EX& c, const GF2EX& a, const GF2EXModulus& F); inline GF2EX SqrMod(const GF2EX& a, const GF2EXModulus& F) { GF2EX x; SqrMod(x, a, F); NTL_OPT_RETURN(GF2EX, x); } void PowerMod(GF2EX& h, const GF2EX& g, const ZZ& e, const GF2EXModulus& F); inline void PowerMod(GF2EX& h, const GF2EX& g, long e, const GF2EXModulus& F) { PowerMod(h, g, ZZ_expo(e), F); } inline GF2EX PowerMod(const GF2EX& g, const ZZ& e, const GF2EXModulus& F) { GF2EX x; PowerMod(x, g, e, F); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX PowerMod(const GF2EX& g, long e, const GF2EXModulus& F) { GF2EX x; PowerMod(x, g, e, F); NTL_OPT_RETURN(GF2EX, x); } void PowerXMod(GF2EX& hh, const ZZ& e, const GF2EXModulus& F); inline void PowerXMod(GF2EX& h, long e, const GF2EXModulus& F) { PowerXMod(h, ZZ_expo(e), F); } inline GF2EX PowerXMod(const ZZ& e, const GF2EXModulus& F) { GF2EX x; PowerXMod(x, e, F); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX PowerXMod(long e, const GF2EXModulus& F) { GF2EX x; PowerXMod(x, e, F); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX operator%(const GF2EX& a, const GF2EXModulus& F) { GF2EX x; rem(x, a, F); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX& operator%=(GF2EX& x, const GF2EXModulus& F) { rem(x, x, F); return x; } inline GF2EX operator/(const GF2EX& a, const GF2EXModulus& F) { GF2EX x; div(x, a, F); NTL_OPT_RETURN(GF2EX, x); } inline GF2EX& operator/=(GF2EX& x, const GF2EXModulus& F) { div(x, x, F); return x; } /***************************************************************** vectors of GF2EX's *****************************************************************/ NTL_vector_decl(GF2EX,vec_GF2EX) NTL_eq_vector_decl(GF2EX,vec_GF2EX) NTL_io_vector_decl(GF2EX,vec_GF2EX) /******************************************************* Evaluation and related problems ********************************************************/ void BuildFromRoots(GF2EX& x, const vec_GF2E& a); inline GF2EX BuildFromRoots(const vec_GF2E& a) { GF2EX x; BuildFromRoots(x, a); NTL_OPT_RETURN(GF2EX, x); } // computes the polynomial (X-a[0]) ... (X-a[n-1]), where n = a.length() void eval(GF2E& b, const GF2EX& f, const GF2E& a); inline GF2E eval(const GF2EX& f, const GF2E& a) { GF2E x; eval(x, f, a); NTL_OPT_RETURN(GF2E, x); } // b = f(a) void eval(vec_GF2E& b, const GF2EX& f, const vec_GF2E& a); inline vec_GF2E eval(const GF2EX& f, const vec_GF2E& a) { vec_GF2E x; eval(x, f, a); NTL_OPT_RETURN(vec_GF2E, x); } // b[i] = f(a[i]) inline void eval(GF2E& b, const GF2X& f, const GF2E& a) { conv(b, CompMod(f, rep(a), GF2E::modulus())); } inline GF2E eval(const GF2X& f, const GF2E& a) { GF2E x; eval(x, f, a); NTL_OPT_RETURN(GF2E, x); } // b = f(a) void interpolate(GF2EX& f, const vec_GF2E& a, const vec_GF2E& b); inline GF2EX interpolate(const vec_GF2E& a, const vec_GF2E& b) { GF2EX x; interpolate(x, a, b); NTL_OPT_RETURN(GF2EX, x); } // computes f such that f(a[i]) = b[i] /********************************************************** Modular Composition and Minimal Polynomials ***********************************************************/ // algorithms for computing g(h) mod f void CompMod(GF2EX& x, const GF2EX& g, const GF2EX& h, const GF2EXModulus& F); inline GF2EX CompMod(const GF2EX& g, const GF2EX& h, const GF2EXModulus& F) { GF2EX x; CompMod(x, g, h, F); NTL_OPT_RETURN(GF2EX, x); } // x = g(h) mod f void Comp2Mod(GF2EX& x1, GF2EX& x2, const GF2EX& g1, const GF2EX& g2, const GF2EX& h, const GF2EXModulus& F); // xi = gi(h) mod f (i=1,2) void Comp3Mod(GF2EX& x1, GF2EX& x2, GF2EX& x3, const GF2EX& g1, const GF2EX& g2, const GF2EX& g3, const GF2EX& h, const GF2EXModulus& F); // xi = gi(h) mod f (i=1..3) // The routine build (see below) which is implicitly called // by the various compose and UpdateMap routines builds a table // of polynomials. // If GF2EXArgBound > 0, then the table is limited in // size to approximamtely that many KB. // If GF2EXArgBound <= 0, then it is ignored, and space is allocated // so as to maximize speed. // Initially, GF2EXArgBound = 0. // If a single h is going to be used with many g's // then you should build a GF2EXArgument for h, // and then use the compose routine below. // build computes and stores h, h^2, ..., h^m mod f. // After this pre-computation, composing a polynomial of degree // roughly n with h takes n/m multiplies mod f, plus n^2 // scalar multiplies. // Thus, increasing m increases the space requirement and the pre-computation // time, but reduces the composition time. // If GF2EXArgBound > 0, a table of size less than m may be built. struct GF2EXArgument { vec_GF2EX H; }; extern long GF2EXArgBound; void build(GF2EXArgument& H, const GF2EX& h, const GF2EXModulus& F, long m); // m must be > 0, otherwise an error is raised void CompMod(GF2EX& x, const GF2EX& g, const GF2EXArgument& H, const GF2EXModulus& F); inline GF2EX CompMod(const GF2EX& g, const GF2EXArgument& H, const GF2EXModulus& F) { GF2EX x; CompMod(x, g, H, F); NTL_OPT_RETURN(GF2EX, x); } void MinPolySeq(GF2EX& h, const vec_GF2E& a, long m); inline GF2EX MinPolySeq(const vec_GF2E& a, long m) { GF2EX x; MinPolySeq(x, a, m); NTL_OPT_RETURN(GF2EX, x); } void MinPolyMod(GF2EX& hh, const GF2EX& g, const GF2EXModulus& F); inline GF2EX MinPolyMod(const GF2EX& g, const GF2EXModulus& F) { GF2EX x; MinPolyMod(x, g, F); NTL_OPT_RETURN(GF2EX, x); } void MinPolyMod(GF2EX& hh, const GF2EX& g, const GF2EXModulus& F, long m); inline GF2EX MinPolyMod(const GF2EX& g, const GF2EXModulus& F, long m) { GF2EX x; MinPolyMod(x, g, F, m); NTL_OPT_RETURN(GF2EX, x); } void ProbMinPolyMod(GF2EX& hh, const GF2EX& g, const GF2EXModulus& F); inline GF2EX ProbMinPolyMod(const GF2EX& g, const GF2EXModulus& F) { GF2EX x; ProbMinPolyMod(x, g, F); NTL_OPT_RETURN(GF2EX, x); } void ProbMinPolyMod(GF2EX& hh, const GF2EX& g, const GF2EXModulus& F, long m); inline GF2EX ProbMinPolyMod(const GF2EX& g, const GF2EXModulus& F, long m) { GF2EX x; ProbMinPolyMod(x, g, F, m); NTL_OPT_RETURN(GF2EX, x); } void IrredPolyMod(GF2EX& h, const GF2EX& g, const GF2EXModulus& F); inline GF2EX IrredPolyMod(const GF2EX& g, const GF2EXModulus& F) { GF2EX x; IrredPolyMod(x, g, F); NTL_OPT_RETURN(GF2EX, x); } void IrredPolyMod(GF2EX& h, const GF2EX& g, const GF2EXModulus& F, long m); inline GF2EX IrredPolyMod(const GF2EX& g, const GF2EXModulus& F, long m) { GF2EX x; IrredPolyMod(x, g, F, m); NTL_OPT_RETURN(GF2EX, x); } struct GF2EXTransMultiplier { GF2EX f0, fbi, b; long shamt, shamt_fbi, shamt_b; }; void build(GF2EXTransMultiplier& B, const GF2EX& b, const GF2EXModulus& F); void TransMulMod(GF2EX& x, const GF2EX& a, const GF2EXTransMultiplier& B, const GF2EXModulus& F); void UpdateMap(vec_GF2E& x, const vec_GF2E& a, const GF2EXTransMultiplier& B, const GF2EXModulus& F); inline vec_GF2E UpdateMap(const vec_GF2E& a, const GF2EXTransMultiplier& B, const GF2EXModulus& F) { vec_GF2E x; UpdateMap(x, a, B, F); NTL_OPT_RETURN(vec_GF2E, x); } void ProjectPowers(vec_GF2E& x, const vec_GF2E& a, long k, const GF2EXArgument& H, const GF2EXModulus& F); inline vec_GF2E ProjectPowers(const vec_GF2E& a, long k, const GF2EXArgument& H, const GF2EXModulus& F) { vec_GF2E x; ProjectPowers(x, a, k, H, F); NTL_OPT_RETURN(vec_GF2E, x); } void ProjectPowers(vec_GF2E& x, const vec_GF2E& a, long k, const GF2EX& h, const GF2EXModulus& F); inline vec_GF2E ProjectPowers(const vec_GF2E& a, long k, const GF2EX& H, const GF2EXModulus& F) { vec_GF2E x; ProjectPowers(x, a, k, H, F); NTL_OPT_RETURN(vec_GF2E, x); } inline void project(GF2E& x, const vec_GF2E& a, const GF2EX& b) { InnerProduct(x, a, b.rep); } inline GF2E project(const vec_GF2E& a, const GF2EX& b) { GF2E x; InnerProduct(x, a, b.rep); NTL_OPT_RETURN(GF2E, x); } /********************************************************** Modular Composition and Minimal Polynomials in towers ***********************************************************/ // composition void CompTower(GF2EX& x, const GF2X& g, const GF2EXArgument& A, const GF2EXModulus& F); inline GF2EX CompTower(const GF2X& g, const GF2EXArgument& A, const GF2EXModulus& F) { GF2EX x; CompTower(x, g, A, F); NTL_OPT_RETURN(GF2EX, x); } void CompTower(GF2EX& x, const GF2X& g, const GF2EX& h, const GF2EXModulus& F); inline GF2EX CompTower(const GF2X& g, const GF2EX& h, const GF2EXModulus& F) { GF2EX x; CompTower(x, g, h, F); NTL_OPT_RETURN(GF2EX, x); } // prob min poly void ProbMinPolyTower(GF2X& h, const GF2EX& g, const GF2EXModulus& F, long m); inline GF2X ProbMinPolyTower(const GF2EX& g, const GF2EXModulus& F, long m) { GF2X x; ProbMinPolyTower(x, g, F, m); NTL_OPT_RETURN(GF2X, x); } inline void ProbMinPolyTower(GF2X& h, const GF2EX& g, const GF2EXModulus& F) { ProbMinPolyTower(h, g, F, deg(F)*GF2E::degree()); } inline GF2X ProbMinPolyTower(const GF2EX& g, const GF2EXModulus& F) { GF2X x; ProbMinPolyTower(x, g, F); NTL_OPT_RETURN(GF2X, x); } // min poly void MinPolyTower(GF2X& h, const GF2EX& g, const GF2EXModulus& F, long m); inline GF2X MinPolyTower(const GF2EX& g, const GF2EXModulus& F, long m) { GF2X x; MinPolyTower(x, g, F, m); NTL_OPT_RETURN(GF2X, x); } inline void MinPolyTower(GF2X& h, const GF2EX& g, const GF2EXModulus& F) { MinPolyTower(h, g, F, deg(F)*GF2E::degree()); } inline GF2X MinPolyTower(const GF2EX& g, const GF2EXModulus& F) { GF2X x; MinPolyTower(x, g, F); NTL_OPT_RETURN(GF2X, x); } // irred poly void IrredPolyTower(GF2X& h, const GF2EX& g, const GF2EXModulus& F, long m); inline GF2X IrredPolyTower(const GF2EX& g, const GF2EXModulus& F, long m) { GF2X x; IrredPolyTower(x, g, F, m); NTL_OPT_RETURN(GF2X, x); } inline void IrredPolyTower(GF2X& h, const GF2EX& g, const GF2EXModulus& F) { IrredPolyTower(h, g, F, deg(F)*GF2E::degree()); } inline GF2X IrredPolyTower(const GF2EX& g, const GF2EXModulus& F) { GF2X x; IrredPolyTower(x, g, F); NTL_OPT_RETURN(GF2X, x); } /***************************************************************** Traces, norms, resultants ******************************************************************/ void TraceVec(vec_GF2E& S, const GF2EX& f); inline vec_GF2E TraceVec(const GF2EX& f) { vec_GF2E x; TraceVec(x, f); NTL_OPT_RETURN(vec_GF2E, x); } void TraceMod(GF2E& x, const GF2EX& a, const GF2EXModulus& F); inline GF2E TraceMod(const GF2EX& a, const GF2EXModulus& F) { GF2E x; TraceMod(x, a, F); NTL_OPT_RETURN(GF2E, x); } void TraceMod(GF2E& x, const GF2EX& a, const GF2EX& f); inline GF2E TraceMod(const GF2EX& a, const GF2EX& f) { GF2E x; TraceMod(x, a, f); NTL_OPT_RETURN(GF2E, x); } void NormMod(GF2E& x, const GF2EX& a, const GF2EX& f); inline GF2E NormMod(const GF2EX& a, const GF2EX& f) { GF2E x; NormMod(x, a, f); NTL_OPT_RETURN(GF2E, x); } void resultant(GF2E& rres, const GF2EX& a, const GF2EX& b); inline GF2E resultant(const GF2EX& a, const GF2EX& b) { GF2E x; resultant(x, a, b); NTL_OPT_RETURN(GF2E, x); } NTL_CLOSE_NNS #endif