/*************************************************************************** * Copyright 2013 CertiVox UK Ltd. * * This file is part of CertiVox MIRACL Crypto SDK. * * The CertiVox MIRACL Crypto SDK provides developers with an * extensive and efficient set of cryptographic functions. * For further information about its features and functionalities please * refer to http://www.certivox.com * * * The CertiVox MIRACL Crypto SDK is free software: you can * redistribute it and/or modify it under the terms of the * GNU Affero General Public License as published by the * Free Software Foundation, either version 3 of the License, * or (at your option) any later version. * * * The CertiVox MIRACL Crypto SDK is distributed in the hope * that it will be useful, but WITHOUT ANY WARRANTY; without even the * implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. * See the GNU Affero General Public License for more details. * * * You should have received a copy of the GNU Affero General Public * License along with CertiVox MIRACL Crypto SDK. * If not, see . * * You can be released from the requirements of the license by purchasing * a commercial license. Buying such a license is mandatory as soon as you * develop commercial activities involving the CertiVox MIRACL Crypto SDK * without disclosing the source code of your own applications, or shipping * the CertiVox MIRACL Crypto SDK with a closed source product. * * ***************************************************************************/ /* * MIRACL C++ Header file ZZn24.h * * AUTHOR : M. Scott * * NOTE: : Must be used in conjunction with ZZn8.cpp zzn4.cpp zzn2.cpp big.cpp zzn.cpp * : This is designed as a "towering extension", so a ZZn24 consists * : of three ZZn8. * * PURPOSE : Definition of class ZZn24 (Arithmetic over n^24) * * WARNING: This class has been cobbled together for a specific use with * the MIRACL library. It is not complete, and may not work in other * applications */ #ifndef ZZn24_H #define ZZn24_H #include "zzn8.h" class ZZn24 { ZZn8 a,b,c; BOOL unitary; // "unitary" property measns that fast squaring can be used, and inversions are just conjugates BOOL miller; // "miller" property means that arithmetic on this instance can ignore multiplications // or divisions by constants - as instance will eventually be raised to (p-1). public: ZZn24() {miller=unitary=FALSE;} ZZn24(int w) {a=(ZZn8)w; b.clear(); c.clear(); miller=FALSE; if (w==1) unitary=TRUE; else unitary=FALSE;} ZZn24(const ZZn24& w) {a=w.a; b=w.b; c=w.c; miller=w.miller; unitary=w.unitary;} ZZn24(const ZZn8 &x) {a=x; b.clear(); c.clear(); miller=unitary=FALSE;} ZZn24(const ZZn8 &x,const ZZn8& y,const ZZn8& z) {a=x; b=y; c=z; miller=unitary=FALSE;} ZZn24(const ZZn &x) {a=(ZZn8)x; b.clear(); c.clear(); miller=unitary=FALSE;} ZZn24(const Big &x) {a=(ZZn8)x; b.clear(); c.clear(); miller=unitary=FALSE;} void set(const ZZn8 &x,const ZZn8 &y,const ZZn8 &z) {a=x; b=y; c=z; unitary=FALSE;} void set(const ZZn8 &x) {a=x; b.clear(); c.clear();unitary=FALSE;} void set(const ZZn8 &x,const ZZn8 &y) {a=x; b=y; c.clear();unitary=FALSE; } void set1(const ZZn8 &x) {a.clear(); b=x; c.clear();unitary=FALSE;} void set2(const ZZn8 &x) {a.clear(); b.clear(); c=x; unitary=FALSE;} void set(const Big &x) {a=(ZZn8)x; b.clear(); c.clear();unitary=FALSE;} void get(ZZn8 &,ZZn8 &,ZZn8 &) const; void get(ZZn8 &) const; void get1(ZZn8 &) const; void get2(ZZn8 &) const; void clear() {a.clear(); b.clear(); c.clear();} void mark_as_unitary() {miller=FALSE; unitary=TRUE;} void mark_as_miller() {miller=TRUE;} void mark_as_regular() {miller=unitary=FALSE;} BOOL is_unitary() {return unitary;} ZZn24& conj() {a.conj(); b.conj(); b=-b; c.conj(); return *this;} BOOL iszero() const {if (a.iszero() && b.iszero() && c.iszero()) return TRUE; return FALSE; } BOOL isunity() const {if (a.isunity() && b.iszero() && c.iszero()) return TRUE; return FALSE; } // BOOL isminusone() const {if (a.isminusone() && b.iszero()) return TRUE; return FALSE; } ZZn24& powq(const ZZn2&); ZZn24& operator=(int i) {a=i; b.clear(); c.clear(); if (i==1) unitary=TRUE; else unitary=FALSE; return *this;} ZZn24& operator=(const ZZn8& x) {a=x; b.clear(); c.clear(); unitary=FALSE; return *this; } ZZn24& operator=(const ZZn24& x) {a=x.a; b=x.b; c=x.c; miller=x.miller; unitary=x.unitary; return *this; } ZZn24& operator+=(const ZZn8& x) {a+=x; unitary=FALSE; return *this; } ZZn24& operator+=(const ZZn24& x) {a+=x.a; b+=x.b; c+=x.c; unitary=FALSE; return *this; } ZZn24& operator-=(const ZZn8& x) {a-=x; unitary=FALSE; return *this; } ZZn24& operator-=(const ZZn24& x) {a-=x.a; b-=x.b; c-=x.c; unitary=FALSE; return *this; } ZZn24& operator*=(const ZZn24&); ZZn24& operator*=(const ZZn8& x) {a*=x; b*=x; c*=x; unitary=FALSE; return *this; } ZZn24& operator*=(int x) {a*=x; b*=x; c*=x; unitary=FALSE; return *this;} ZZn24& operator/=(const ZZn24&); ZZn24& operator/=(const ZZn8&); friend ZZn24 operator+(const ZZn24&,const ZZn24&); friend ZZn24 operator+(const ZZn24&,const ZZn8&); friend ZZn24 operator-(const ZZn24&,const ZZn24&); friend ZZn24 operator-(const ZZn24&,const ZZn8&); friend ZZn24 operator-(const ZZn24&); friend ZZn24 operator*(const ZZn24&,const ZZn24&); friend ZZn24 operator*(const ZZn24&,const ZZn8&); friend ZZn24 operator*(const ZZn8&,const ZZn24&); friend ZZn24 operator*(int,const ZZn24&); friend ZZn24 operator*(const ZZn24&,int); friend ZZn24 operator/(const ZZn24&,const ZZn24&); friend ZZn24 operator/(const ZZn24&,const ZZn8&); friend ZZn24 tx(const ZZn24&); friend ZZn24 pow(const ZZn24&,const Big&); friend ZZn24 pow(int,const ZZn24*,const Big*); // friend ZZn6 pow(int,const ZZn6*,const Big*); friend ZZn24 inverse(const ZZn24&); friend ZZn24 conj(const ZZn24&); #ifndef MR_NO_RAND friend ZZn24 randn24(void); // random ZZn24 #endif friend BOOL operator==(const ZZn24& x,const ZZn24& y) {if (x.a==y.a && x.b==y.b && x.c==y.c) return TRUE; else return FALSE; } friend BOOL operator!=(const ZZn24& x,const ZZn24& y) {if (x.a!=y.a || x.b!=y.b || x.c!=y.c) return TRUE; else return FALSE; } #ifndef MR_NO_STANDARD_IO friend ostream& operator<<(ostream&,const ZZn24&); #endif ~ZZn24() {} }; #ifndef MR_NO_RAND extern ZZn24 randn24(void); #endif #endif