/******
* Arithmetic for point groups of elliptic curves
* over GF(p) (source file)
*
* (C) 2007 Martin Doering
*          Christoph Ludwig
*          Falko Strenzke
*     2008 Jack Lloyd
******/

#include <botan/point_gfp.h>
#include <botan/numthry.h>

namespace Botan {

// construct the point at infinity or a random point
PointGFp::PointGFp(const CurveGFp& curve)
   :	mC(curve),
        mX(curve.get_p(), 0),
        mY(curve.get_p(), 1),
        mZ(curve.get_p(), 0),
        mZpow2(curve.get_p(),0),
        mZpow3(curve.get_p(),0),
        mAZpow4(curve.get_p(),0),
        mZpow2_set(false),
        mZpow3_set(false),
        mAZpow4_set(false)
   {
   // first set the point wide pointer

   set_shrd_mod(mC.get_ptr_mod());

   }

// construct a point given its jacobian projective coordinates
PointGFp::PointGFp(const CurveGFp& curve, const GFpElement& x,
                   const GFpElement& y, const GFpElement& z)
   :	mC(curve),
        mX(x),
        mY(y),
        mZ(z),
        mZpow2(curve.get_p(),0),
        mZpow3(curve.get_p(),0),
        mAZpow4(curve.get_p(),0),
        mZpow2_set(false),
        mZpow3_set(false),
        mAZpow4_set(false)
   {
   set_shrd_mod(mC.get_ptr_mod());
   }
PointGFp::PointGFp ( const CurveGFp& curve, const GFpElement& x,
                     const GFpElement& y )
   :mC(curve),
    mX(x),
    mY(y),
    mZ(curve.get_p(),1),
    mZpow2(curve.get_p(),0),
    mZpow3(curve.get_p(),0),
    mAZpow4(curve.get_p(),0),
    mZpow2_set(false),
    mZpow3_set(false),
    mAZpow4_set(false)
   {
   set_shrd_mod(mC.get_ptr_mod());
   }

// copy constructor
PointGFp::PointGFp(const PointGFp& other)
   :	mC(other.mC),
        mX(other.mX),
        mY(other.mY),
        mZ(other.mZ),
        mZpow2(other.mZpow2),
        mZpow3(other.mZpow3),
        mAZpow4(other.mAZpow4),
        mZpow2_set(other.mZpow2_set),
        mZpow3_set(other.mZpow3_set),
        mAZpow4_set(other.mAZpow4_set)
   {
   set_shrd_mod(mC.get_ptr_mod());
   }

// assignment operator
const PointGFp& PointGFp::operator=(PointGFp const& other)
   {
   mC = other.get_curve();
   mX = other.get_jac_proj_x();
   mY = other.get_jac_proj_y();
   mZ = other.get_jac_proj_z();
   mZpow2 = GFpElement(other.mZpow2);
   mZpow3 = GFpElement(other.mZpow3);
   mAZpow4 = GFpElement(other.mAZpow4);
   mZpow2_set = other.mZpow2_set;
   mZpow3_set = other.mZpow3_set;
   mAZpow4_set = other.mAZpow4_set;
   set_shrd_mod(mC.get_ptr_mod());
   return *this;
   }

const PointGFp& PointGFp::assign_within_same_curve(PointGFp const& other)
   {
   mX = other.get_jac_proj_x();
   mY = other.get_jac_proj_y();
   mZ = other.get_jac_proj_z();
   mZpow2_set = false;
   mZpow3_set = false;
   mAZpow4_set = false;
   // the rest stays!
   return *this;
   }

void PointGFp::set_shrd_mod(std::tr1::shared_ptr<GFpModulus> p_mod)
   {
   mX.set_shrd_mod(p_mod);
   mY.set_shrd_mod(p_mod);
   mZ.set_shrd_mod(p_mod);
   mZpow2.set_shrd_mod(p_mod);
   mZpow3.set_shrd_mod(p_mod);
   mAZpow4.set_shrd_mod(p_mod);
   }

void PointGFp::ensure_worksp() const
   {
   if (mp_worksp_gfp_el.get() != 0)
      {
      if ((*mp_worksp_gfp_el).size() == GFPEL_WKSP_SIZE)
         {
         return;
         }
      else
         {
         throw Invalid_State("encountered incorrect size for PointGFp´s GFpElement workspace");
         }
      }

   mp_worksp_gfp_el = std::tr1::shared_ptr<std::vector<GFpElement> >(new std::vector<GFpElement>);
   mp_worksp_gfp_el->reserve(9);
   for (u32bit i=0; i<GFPEL_WKSP_SIZE; i++)
      {
      mp_worksp_gfp_el->push_back(GFpElement(1,0));

      }
   }

// arithmetic operators
PointGFp& PointGFp::operator+=(const PointGFp& rhs)
   {
   if (is_zero())
      {
      *this = rhs;
      return *this;
      }
   if (rhs.is_zero())
      {
      return *this;
      }
   ensure_worksp();

   if (rhs.mZ == *(mC.get_mres_one()))
      {
      //U1 = mX;
      (*mp_worksp_gfp_el)[0].share_assign(mX);

      //S1 = mY;
      (*mp_worksp_gfp_el)[2].share_assign(mY);
      }
   else
      {
      if ((!rhs.mZpow2_set) || (!rhs.mZpow3_set))
         {
         rhs.mZpow2 = rhs.mZ;
         rhs.mZpow2 *= rhs.mZ;
         rhs.mZpow3 = rhs.mZpow2;
         rhs.mZpow3 *= rhs.mZ;

         rhs.mZpow2_set = true;
         rhs.mZpow3_set = true;
         }
      //U1 = mX * rhs.mZpow2;
      (*mp_worksp_gfp_el)[0].share_assign(mX);
      (*mp_worksp_gfp_el)[0] *= rhs.mZpow2;

      //S1 = mY * rhs.mZpow3;
      (*mp_worksp_gfp_el)[2].share_assign(mY);
      (*mp_worksp_gfp_el)[2] *= rhs.mZpow3;

      }
   if (mZ == *(mC.get_mres_one()))
      {
      //U2 = rhs.mX;
      (*mp_worksp_gfp_el)[1].share_assign(rhs.mX);

      //S2 = rhs.mY;
      (*mp_worksp_gfp_el)[3].share_assign(rhs.mY);
      }
   else
      {
      if ((!mZpow2_set) || (!mZpow3_set))
         {
         // precomputation can´t be used, because *this changes anyway
         mZpow2 = mZ;
         mZpow2 *= mZ;

         mZpow3 = mZpow2;
         mZpow3 *= mZ;
         }
      //U2 = rhs.mX * mZpow2;
      (*mp_worksp_gfp_el)[1].share_assign(rhs.mX);
      (*mp_worksp_gfp_el)[1] *= mZpow2;

      //S2 = rhs.mY * mZpow3;
      (*mp_worksp_gfp_el)[3].share_assign(rhs.mY);
      (*mp_worksp_gfp_el)[3] *= mZpow3;

      }
   //GFpElement H(U2 - U1);

   (*mp_worksp_gfp_el)[4].share_assign((*mp_worksp_gfp_el)[1]);
   (*mp_worksp_gfp_el)[4] -= (*mp_worksp_gfp_el)[0];

   //GFpElement r(S2 - S1);
   (*mp_worksp_gfp_el)[5].share_assign((*mp_worksp_gfp_el)[3]);
   (*mp_worksp_gfp_el)[5] -= (*mp_worksp_gfp_el)[2];

   //if(H.is_zero())
   if ((*mp_worksp_gfp_el)[4].is_zero())

      {
      if ((*mp_worksp_gfp_el)[5].is_zero())

         {
         mult2_in_place();
         return *this;
         }
      *this = PointGFp(mC); // setting myself to zero
      return *this;
      }

   //U2 = H * H;
   (*mp_worksp_gfp_el)[1].share_assign((*mp_worksp_gfp_el)[4]);
   (*mp_worksp_gfp_el)[1] *= (*mp_worksp_gfp_el)[4];

   //S2 = U2 * H;
   (*mp_worksp_gfp_el)[3].share_assign((*mp_worksp_gfp_el)[1]);
   (*mp_worksp_gfp_el)[3] *= (*mp_worksp_gfp_el)[4];

   //U2 *= U1;
   (*mp_worksp_gfp_el)[1] *= (*mp_worksp_gfp_el)[0];

   //GFpElement x(r*r - S2 - (U2+U2));
   (*mp_worksp_gfp_el)[6].share_assign((*mp_worksp_gfp_el)[5]);
   (*mp_worksp_gfp_el)[6] *= (*mp_worksp_gfp_el)[5];
   (*mp_worksp_gfp_el)[6] -= (*mp_worksp_gfp_el)[3];
   (*mp_worksp_gfp_el)[6] -= (*mp_worksp_gfp_el)[1];
   (*mp_worksp_gfp_el)[6] -= (*mp_worksp_gfp_el)[1];

   //GFpElement z(S1 * S2);
   (*mp_worksp_gfp_el)[8].share_assign((*mp_worksp_gfp_el)[2]);
   (*mp_worksp_gfp_el)[8] *= (*mp_worksp_gfp_el)[3];

   //GFpElement y(r * (U2-x) - z);
   (*mp_worksp_gfp_el)[7].share_assign((*mp_worksp_gfp_el)[1]);
   (*mp_worksp_gfp_el)[7] -= (*mp_worksp_gfp_el)[6];
   (*mp_worksp_gfp_el)[7] *= (*mp_worksp_gfp_el)[5];
   (*mp_worksp_gfp_el)[7] -= (*mp_worksp_gfp_el)[8];

   if (mZ == *(mC.get_mres_one()))
      {
      if (rhs.mZ != *(mC.get_mres_one()))
         {
         //z = rhs.mZ * H;
         (*mp_worksp_gfp_el)[8].share_assign(rhs.mZ);
         (*mp_worksp_gfp_el)[8] *= (*mp_worksp_gfp_el)[4];
         }
      else
         {
         //z = H;
         (*mp_worksp_gfp_el)[8].share_assign((*mp_worksp_gfp_el)[4]);
         }
      }
   else if (rhs.mZ != *(mC.get_mres_one()))
      {
      //U1 = mZ * rhs.mZ;
      (*mp_worksp_gfp_el)[0].share_assign(mZ);
      (*mp_worksp_gfp_el)[0] *= rhs.mZ;

      //z = U1 * H;
      (*mp_worksp_gfp_el)[8].share_assign((*mp_worksp_gfp_el)[0]);
      (*mp_worksp_gfp_el)[8] *= (*mp_worksp_gfp_el)[4];

      }
   else
      {
      //z = mZ * H;
      (*mp_worksp_gfp_el)[8].share_assign(mZ);
      (*mp_worksp_gfp_el)[8] *= (*mp_worksp_gfp_el)[4];

      }
   mZpow2_set = false;
   mZpow3_set = false;
   mAZpow4_set = false;

   mX = (*mp_worksp_gfp_el)[6];
   mY = (*mp_worksp_gfp_el)[7];
   mZ = (*mp_worksp_gfp_el)[8];

   return *this;

   }
PointGFp& PointGFp::operator-=(const PointGFp& rhs)
   {
   PointGFp minus_rhs = PointGFp(rhs).negate();

   if (is_zero())
      {
      *this = minus_rhs;
      }
   else
      {
      *this += minus_rhs;
      }
   return *this;
   }

PointGFp& PointGFp::mult_this_secure(const BigInt& scalar,
                                     const BigInt& /*point_order*/,
                                     const BigInt& /*max_secr*/)
   {
   // NOTE: FS: so far this is code duplication of op*=.
   // we have to see how we deal with this.
   // fact is that we will probably modify this function
   // while evaluating the countermeasures
   // whereas we probably will not start modifying the
   // function operator*=.
   // however, in the end both should be merged.

   // use montgomery mult. in this operation
   this->turn_on_sp_red_mul();

   std::tr1::shared_ptr<PointGFp> H(new PointGFp(this->mC));
   std::tr1::shared_ptr<PointGFp> tmp; // used for AADA

   PointGFp P(*this);
   BigInt m(scalar);

   if (m < BigInt(0))
      {
      m = -m;
      P.negate();
      }
   if (P.is_zero() || (m == BigInt(0)))
      {
      *this = *H;
      return *this;
      }
   if (m == BigInt(1))
      {
      return *this;
      }
   //
#ifdef CM_AADA
#ifndef CM_RAND_EXP
   int max_secr_bits = max_secr.bits();
#endif
#endif

   int mul_bits = m.bits(); // this is used for a determined number of loop runs in
   // the mult_loop where leading zero´s are padded if necessary.
   // Here we assign the value that will be used when no countermeasures are specified
#ifdef CM_RAND_EXP
   u32bit rand_r_bit_len = 20; // Coron(99) proposes 20 bit for r

#ifdef CM_AADA

   BigInt r_max(1);

#endif // CM_AADA

   // use randomized exponent
#ifdef TA_COLL_T
   static BigInt r_randexp;
   if (new_rand)
      {
      r_randexp = random_integer(rand_r_bit_len);
      }
   //assert(!r_randexp.is_zero());
#else
   BigInt r_randexp(random_integer(rand_r_bit_len));
#endif

   m += r_randexp * point_order;
   // determine mul_bits...
#ifdef CM_AADA
   // AADA with rand. Exp.
   //assert(rand_r_bit_len > 0);
   r_max <<= rand_r_bit_len;
   r_max -= 1;
   //assert(r_max.bits() == rand_r_bit_len);
   mul_bits = (max_secr + point_order * r_max).bits();
#else
   // rand. Exp. without AADA
   mul_bits = m.bits();
#endif // CM_AADA


#endif // CM_RAND_EXP

   // determine mul_bits...
#if (CM_AADA == 1 && CM_RAND_EXP != 1)

   mul_bits = max_secr_bits;
#endif // CM_AADA without CM_RAND_EXP

   //assert(mul_bits != 0);


   H = mult_loop(mul_bits-1, m, H, tmp, P);

   if (!H->is_zero()) // cannot convert if H == O
      {
      *this = H->get_z_to_one();
      }else
      {
      *this = *H;
      }
   mX.turn_off_sp_red_mul();
   mY.turn_off_sp_red_mul();
   mZ.turn_off_sp_red_mul();
   return *this;
   }

PointGFp& PointGFp::operator*=(const BigInt& scalar)
   {
   // use montgomery mult. in this operation

   this->turn_on_sp_red_mul();

   PointGFp H(this->mC); // create as zero
   H.turn_on_sp_red_mul();
   PointGFp P(*this);
   P.turn_on_sp_red_mul();
   BigInt m(scalar);
   if (m < BigInt(0))
      {
      m = -m;
      P.negate();
      }
   if (P.is_zero() || (m == BigInt(0)))
      {
      *this = H;
      return *this;
      }
   if (m == BigInt(1))
      {
      //*this == P already
      return *this;
      }

   const int l = m.bits() - 1;
   for (int i=l; i >=0; i--)
      {

      H.mult2_in_place();
      if (m.get_bit(i))
         {
         H += P;
         }
      }

   if (!H.is_zero()) // cannot convert if H == O
      {
      *this = H.get_z_to_one();
      }else
      {
      *this = H;
      }
   return *this;
   }

inline std::tr1::shared_ptr<PointGFp> PointGFp::mult_loop(int l,
                                                          const BigInt& m,
                                                          std::tr1::shared_ptr<PointGFp> H,
                                                          std::tr1::shared_ptr<PointGFp> tmp,
                                                          const PointGFp& P)
   {
   //assert(l >= (int)m.bits()- 1);
   tmp = H;
   std::tr1::shared_ptr<PointGFp> to_add(new PointGFp(P)); // we just need some point
   // so that we can use op=
   // inside the loop
   for (int i=l; i >=0; i--)
      {
      H->mult2_in_place();

#ifndef CM_AADA

      if (m.get_bit(i))
         {
         *H += P;
         }
#else // (CM_AADA is in)

      if (H.get() == to_add.get())
         {
         to_add = tmp; // otherwise all pointers might point to the same object
         // and we always need two objects to be able to switch around
         }
      to_add->assign_within_same_curve(*H);
      tmp = H;
      *tmp += P; // tmp already points to H

      if (m.get_bit(i))
         {
         H = tmp; // NOTE: assign the pointer, not the value!
         // (so that the operation is fast and thus as difficult
         // to detect as possible)
         }
      else
         {
         H = to_add; // NOTE: this is necessary, because the assignment
         // "*tmp = ..." already changed what H pointed to


         }
#endif // CM_AADA

      }
   return H;
   }

PointGFp& PointGFp::negate()
   {
   if (!is_zero())
      {
      mY.negate();
      }
   return *this;
   }

// *this *= 2
PointGFp& PointGFp::mult2_in_place()
   {
   if (is_zero())
      {
      return *this;
      }
   if (mY.is_zero())
      {

      *this = PointGFp(mC); // setting myself to zero
      return *this;
      }
   ensure_worksp();

   (*mp_worksp_gfp_el)[0].share_assign(mY);
   (*mp_worksp_gfp_el)[0] *= mY;

   //GFpElement S(mX * z);
   (*mp_worksp_gfp_el)[1].share_assign(mX);
   (*mp_worksp_gfp_el)[1] *= (*mp_worksp_gfp_el)[0];

   //GFpElement x(S + S);
   (*mp_worksp_gfp_el)[2].share_assign((*mp_worksp_gfp_el)[1]);
   (*mp_worksp_gfp_el)[2] += (*mp_worksp_gfp_el)[1];

   //S = x + x;
   (*mp_worksp_gfp_el)[1].share_assign((*mp_worksp_gfp_el)[2]);
   (*mp_worksp_gfp_el)[1] += (*mp_worksp_gfp_el)[2];

   if (!mAZpow4_set)
      {
      if (mZ == *(mC.get_mres_one()))
         {
         mAZpow4 = mC.get_mres_a();
         mAZpow4_set = true;
         }
      else
         {
         if (!mZpow2_set)
            {
            mZpow2 = mZ;
            mZpow2 *= mZ;

            mZpow2_set = true;
            }
         //x = mZpow2 * mZpow2;
         (*mp_worksp_gfp_el)[2].share_assign(mZpow2);
         (*mp_worksp_gfp_el)[2] *= mZpow2;

         //mAZpow4 = mC.get_mres_a() * x;
         mAZpow4 = mC.get_mres_a();
         mAZpow4 *= (*mp_worksp_gfp_el)[2];

         }

      }

   //GFpElement y(mX * mX);
   (*mp_worksp_gfp_el)[3].share_assign(mX);
   (*mp_worksp_gfp_el)[3] *= mX;

   //GFpElement M(y + y + y + mAZpow4);
   (*mp_worksp_gfp_el)[4].share_assign((*mp_worksp_gfp_el)[3]);
   (*mp_worksp_gfp_el)[4] += (*mp_worksp_gfp_el)[3];
   (*mp_worksp_gfp_el)[4] += (*mp_worksp_gfp_el)[3];
   (*mp_worksp_gfp_el)[4] += mAZpow4;

   //x = M * M - (S+S);
   (*mp_worksp_gfp_el)[2].share_assign((*mp_worksp_gfp_el)[4]);
   (*mp_worksp_gfp_el)[2] *= (*mp_worksp_gfp_el)[4];
   (*mp_worksp_gfp_el)[2] -= (*mp_worksp_gfp_el)[1];
   (*mp_worksp_gfp_el)[2] -= (*mp_worksp_gfp_el)[1];

   //y = z * z;
   (*mp_worksp_gfp_el)[3].share_assign((*mp_worksp_gfp_el)[0]);
   (*mp_worksp_gfp_el)[3] *= (*mp_worksp_gfp_el)[0];

   //GFpElement U(y + y);
   (*mp_worksp_gfp_el)[5].share_assign((*mp_worksp_gfp_el)[3]);
   (*mp_worksp_gfp_el)[5] += (*mp_worksp_gfp_el)[3];

   //z = U + U;
   (*mp_worksp_gfp_el)[0].share_assign((*mp_worksp_gfp_el)[5]);
   (*mp_worksp_gfp_el)[0] += (*mp_worksp_gfp_el)[5];

   //U = z + z;
   (*mp_worksp_gfp_el)[5].share_assign((*mp_worksp_gfp_el)[0]);
   (*mp_worksp_gfp_el)[5] += (*mp_worksp_gfp_el)[0];

   //y = M * (S - x) - U;
   (*mp_worksp_gfp_el)[3].share_assign((*mp_worksp_gfp_el)[1]);
   (*mp_worksp_gfp_el)[3] -= (*mp_worksp_gfp_el)[2];
   (*mp_worksp_gfp_el)[3] *= (*mp_worksp_gfp_el)[4];
   (*mp_worksp_gfp_el)[3] -= (*mp_worksp_gfp_el)[5];

   if (mZ != *(mC.get_mres_one()))
      {
      //z = mY * mZ;
      (*mp_worksp_gfp_el)[0].share_assign(mY);
      (*mp_worksp_gfp_el)[0] *= mZ;

      }
   else
      {
      //z = mY;
      (*mp_worksp_gfp_el)[0].share_assign(mY);

      }
   //z = z + z;
   (*mp_worksp_gfp_el)[6].share_assign((*mp_worksp_gfp_el)[0]);
   (*mp_worksp_gfp_el)[0] += (*mp_worksp_gfp_el)[6];

   //mX = x;
   //mY = y;
   //mZ = z;
   mX = (*mp_worksp_gfp_el)[2];
   mY = (*mp_worksp_gfp_el)[3];
   mZ = (*mp_worksp_gfp_el)[0];

   mZpow2_set = false;
   mZpow3_set = false;
   mAZpow4_set = false;
   return *this;
   }

void PointGFp::turn_on_sp_red_mul() const
   {
   mX.turn_on_sp_red_mul();
   mY.turn_on_sp_red_mul();
   mZ.turn_on_sp_red_mul();

   // also pretransform, otherwise
   // we might have bad results with respect to
   // performance because
   // additions/subtractions in mult2_in_place()
   // and op+= spread untransformed GFpElements
   mX.get_mres();
   mY.get_mres();
   mZ.get_mres();

   mZpow2.turn_on_sp_red_mul();
   mZpow3.turn_on_sp_red_mul();
   mAZpow4.turn_on_sp_red_mul();
   }
// getters

/**
* returns a point equivalent to *this but were
* Z has value one, i.e. x and y correspond to
* their values in affine coordinates
*
* Distributed under the terms of the Botan license
*/
PointGFp const PointGFp::get_z_to_one() const
   {
   return PointGFp(*this).set_z_to_one();
   }

/**
* changes the representation of *this so that
* Z has value one, i.e. x and y correspond to
* their values in affine coordinates.
* returns *this.
*/
const PointGFp& PointGFp::set_z_to_one() const
   {
   if (!(mZ.get_value() == BigInt(1)) && !(mZ.get_value() == BigInt(0)))
      {
      GFpElement z = inverse(mZ);
      GFpElement z2 = z * z;
      z *= z2;
      GFpElement x = mX * z2;
      GFpElement y = mY * z;
      mZ = GFpElement(mC.get_p(), BigInt(1));
      mX = x;
      mY = y;
      }
   else
      {
      if (mZ.get_value() == BigInt(0))
         {
         throw Illegal_Transformation("cannot convert Z to one");
         }
      }
   return *this; // mZ = 1 already
   }

const CurveGFp PointGFp::get_curve() const
   {
   return mC;
   }

GFpElement const PointGFp::get_affine_x() const
   {

   if (is_zero())
      {
      throw Illegal_Transformation("cannot convert to affine");

      }
   /*if(!mZpow2_set)
   {*/
   mZpow2 = mZ * mZ;
   mZpow2_set = true;
   //}
   //assert(mZpow2 == mZ*mZ);
   GFpElement z2 = mZpow2;
   return mX * z2.inverse_in_place();
   }

GFpElement const PointGFp::get_affine_y() const
   {

   if (is_zero())
      {
      throw Illegal_Transformation("cannot convert to affine");

      }
   /*if(!mZpow3_set )
   {*/
   mZpow3 = mZ * mZ * mZ;
   mZpow3_set = true;
   //}
   //assert(mZpow3 == mZ * mZ *mZ);
   GFpElement z3 = mZpow3;
   return mY * z3.inverse_in_place();
   }

GFpElement const PointGFp::get_jac_proj_x() const
   {
   return GFpElement(mX);
   }

GFpElement const PointGFp::get_jac_proj_y() const
   {
   return GFpElement(mY);
   }

GFpElement const PointGFp::get_jac_proj_z() const
   {
   return GFpElement(mZ);
   }

// Is this the point at infinity?
bool PointGFp::is_zero() const
   {
   return(mX.is_zero() && mZ.is_zero());
   //NOTE: the calls to GFpElement::is_zero() instead of getting the value and
   // and comparing it are import because they do not provoke backtransformations
   // to the ordinary residue.
   }

// Is the point still on the curve??
// (If everything is correct, the point is always on its curve; then the
// function will return silently. If Oskar managed to corrupt this object's state,
// then it will throw an exception.)

void PointGFp::check_invariants() const
   {
   if (is_zero())
      {
      return;
      }
   const GFpElement y2 = mY * mY;
   const GFpElement x3 = mX * mX * mX;

   if (mZ.get_value() == BigInt(1))
      {
      GFpElement ax = mC.get_a() * mX;
      if(y2 != (x3 + ax + mC.get_b()))
         {
         throw Illegal_Point();
         }

      }

   mZpow2 = mZ * mZ;
   mZpow2_set = true;
   mZpow3 = mZpow2 * mZ;
   mZpow3_set = true;
   mAZpow4 = mZpow3 * mZ * mC.get_a();
   mAZpow4_set = true;
   const GFpElement aXZ4 = mAZpow4 * mX;
   const GFpElement bZ6 = mC.get_b() * mZpow3 * mZpow3;

   if (y2 != (x3 + aXZ4 + bZ6))
      throw Illegal_Point();
   }

// swaps the states of *this and other, does not throw!
void PointGFp::swap(PointGFp& other)
   {
   mC.swap(other.mC);
   mX.swap(other.mX);
   mY.swap(other.mY);
   mZ.swap(other.mZ);
   mZpow2.swap(other.mZpow2);
   mZpow3.swap(other.mZpow3);
   mAZpow4.swap(other.mAZpow4);
   std::swap<bool>(mZpow2_set, other.mZpow2_set);
   std::swap<bool>(mZpow3_set, other.mZpow3_set);
   std::swap<bool>(mAZpow4_set, other.mAZpow4_set);
   }

PointGFp const mult2(const PointGFp& point)
   {
   return (PointGFp(point)).mult2_in_place();
   }

bool operator==(const PointGFp& lhs, PointGFp const& rhs)
   {
   if (lhs.is_zero() && rhs.is_zero())
      {
      return true;
      }
   if ((lhs.is_zero() && !rhs.is_zero()) || (!lhs.is_zero() && rhs.is_zero()))
      {
      return false;
      }
   // neither operand is zero, so we can call get_z_to_one()
   //assert(!lhs.is_zero());
   //assert(!rhs.is_zero());
   PointGFp aff_lhs = lhs.get_z_to_one();
   PointGFp aff_rhs = rhs.get_z_to_one();
   return (aff_lhs.get_curve() == aff_rhs.get_curve() &&
           aff_lhs.get_jac_proj_x() == aff_rhs.get_jac_proj_x() &&
           aff_lhs.get_jac_proj_y() == aff_rhs.get_jac_proj_y());
   }

// arithmetic operators
PointGFp operator+(const PointGFp& lhs, PointGFp const& rhs)
   {
   PointGFp tmp(lhs);
   return tmp += rhs;
   }

PointGFp operator-(const PointGFp& lhs, PointGFp const& rhs)
   {
   PointGFp tmp(lhs);
   return tmp -= rhs;
   }

PointGFp operator-(const PointGFp& lhs)
   {
   return PointGFp(lhs).negate();
   }

PointGFp operator*(const BigInt& scalar, const PointGFp& point)
   {
   PointGFp result(point);
   return result *= scalar;
   }

PointGFp operator*(const PointGFp& point, const BigInt& scalar)
   {
   PointGFp result(point);
   return result *= scalar;
   }

PointGFp mult_point_secure(const PointGFp& point, const BigInt& scalar,
                           const BigInt& point_order, const BigInt& max_secret)
   {
   PointGFp result(point);
   result.mult_this_secure(scalar, point_order, max_secret);
   return result;
   }

// encoding and decoding
SecureVector<byte> EC2OSP(const PointGFp& point, byte format)
   {
   SecureVector<byte> result;
   if (format == PointGFp::UNCOMPRESSED)
      {
      result = encode_uncompressed(point);
      }
   else if (format == PointGFp::COMPRESSED)
      {
      result = encode_compressed(point);

      }
   else if (format == PointGFp::HYBRID)
      {
      result = encode_hybrid(point);
      }
   else
      {
      throw Format_Error("illegal point encoding format specification");
      }
   return result;
   }
SecureVector<byte> encode_compressed(const PointGFp& point)
   {


   if (point.is_zero())
      {
      SecureVector<byte> result (1);
      result[0] = 0;
      return result;

      }
   u32bit l = point.get_curve().get_p().bits();
   int dummy = l & 7;
   if (dummy != 0)
      {
      l += 8 - dummy;
      }
   l /= 8;
   SecureVector<byte> result (l+1);
   result[0] = 2;
   BigInt x = point.get_affine_x().get_value();
   SecureVector<byte> bX = BigInt::encode_1363(x, l);
   result.copy(1, bX.begin(), bX.size());
   BigInt y = point.get_affine_y().get_value();
   if (y.get_bit(0))
      {
      result[0] |= 1;
      }
   return result;
   }


SecureVector<byte> encode_uncompressed(const PointGFp& point)
   {
   if (point.is_zero())
      {
      SecureVector<byte> result (1);
      result[0] = 0;
      return result;
      }
   u32bit l = point.get_curve().get_p().bits();
   int dummy = l & 7;
   if (dummy != 0)
      {
      l += 8 - dummy;
      }
   l /= 8;
   SecureVector<byte> result (2*l+1);
   result[0] = 4;
   BigInt x = point.get_affine_x().get_value();
   BigInt y = point.get_affine_y().get_value();
   SecureVector<byte> bX = BigInt::encode_1363(x, l);
   SecureVector<byte> bY = BigInt::encode_1363(y, l);
   result.copy(1, bX.begin(), l);
   result.copy(l+1, bY.begin(), l);
   return result;

   }

SecureVector<byte> encode_hybrid(const PointGFp& point)
   {
   if (point.is_zero())
      {
      SecureVector<byte> result (1);
      result[0] = 0;
      return result;
      }
   u32bit l = point.get_curve().get_p().bits();
   int dummy = l & 7;
   if (dummy != 0)
      {
      l += 8 - dummy;
      }
   l /= 8;
   SecureVector<byte> result (2*l+1);
   result[0] = 6;
   BigInt x = point.get_affine_x().get_value();
   BigInt y = point.get_affine_y().get_value();
   SecureVector<byte> bX = BigInt::encode_1363(x, l);
   SecureVector<byte> bY = BigInt::encode_1363(y, l);
   result.copy(1, bX.begin(), bX.size());
   result.copy(l+1, bY.begin(), bY.size());
   if (y.get_bit(0))
      {
      result[0] |= 1;
      }
   return result;
   }

PointGFp OS2ECP(MemoryRegion<byte> const& os, const CurveGFp& curve)
   {
   if (os.size() == 1 && os[0] == 0)
      {
      return PointGFp(curve); // return zero
      }
   SecureVector<byte> bX;
   SecureVector<byte> bY;

   GFpElement x(1,0);
   GFpElement y(1,0);
   GFpElement z(1,0);

   const byte pc = os[0];
   BigInt bi_dec_x;
   BigInt bi_dec_y;
   switch (pc)
      {
      case 2:
      case 3:
         //compressed form
         bX = SecureVector<byte>(os.size() - 1);
         bX.copy(os.begin()+1, os.size()-1);

         /* Problem wäre, wenn decode() das erste bit als Vorzeichen interpretiert.
         *---------------------
         * AW(FS): decode() interpretiert das erste Bit nicht als Vorzeichen
         */
         bi_dec_x = BigInt::decode(bX, bX.size());
         x = GFpElement(curve.get_p(), bi_dec_x);
         bool yMod2;
         yMod2 = (pc & 1) == 1;
         y = PointGFp::decompress(yMod2, x, curve);
         break;
      case 4:
         // uncompressed form
         int l;
         l = (os.size() -1)/2;
         bX = SecureVector<byte>(l);
         bY = SecureVector<byte>(l);
         bX.copy(os.begin()+1, l);
         bY.copy(os.begin()+1+l, l);
         bi_dec_x = BigInt::decode(bX.begin(), bX.size());

         bi_dec_y = BigInt::decode(bY.begin(),bY.size());
         x = GFpElement(curve.get_p(), bi_dec_x);
         y = GFpElement(curve.get_p(), bi_dec_y);
         break;

      case 6:
      case 7:
         //hybrid form
         l = (os.size() - 1)/2;
         bX = SecureVector<byte>(l);
         bY = SecureVector<byte>(l);
         bX.copy(os.begin() + 1, l);
         bY.copy(os.begin()+1+l, l);
         yMod2 = (pc & 0x01) == 1;
         if (!(PointGFp::decompress(yMod2, x, curve) == y))
            {
            throw Illegal_Point("error during decoding hybrid format");
            }
         break;
      default:
         throw Format_Error("encountered illegal format specification while decoding point");
      }
   z = GFpElement(curve.get_p(), BigInt(1));
   //assert((x.is_trf_to_mres() && x.is_use_montgm()) || !x.is_trf_to_mres());
   //assert((y.is_trf_to_mres() && y.is_use_montgm()) || !y.is_trf_to_mres());
   //assert((z.is_trf_to_mres() && z.is_use_montgm()) || !z.is_trf_to_mres());
   PointGFp result(curve, x, y, z);
   result.check_invariants();
   //assert((result.get_jac_proj_x().is_trf_to_mres() && result.get_jac_proj_x().is_use_montgm()) || !result.get_jac_proj_x().is_trf_to_mres());
   //assert((result.get_jac_proj_y().is_trf_to_mres() && result.get_jac_proj_y().is_use_montgm()) || !result.get_jac_proj_y().is_trf_to_mres());
   //assert((result.get_jac_proj_z().is_trf_to_mres() && result.get_jac_proj_z().is_use_montgm()) || !result.get_jac_proj_z().is_trf_to_mres());
   return result;
   }

GFpElement PointGFp::decompress(bool yMod2, const GFpElement& x,
                                const CurveGFp& curve)
   {
   BigInt xVal = x.get_value();
   BigInt xpow3 = xVal * xVal * xVal;
   BigInt g = curve.get_a().get_value() * xVal;
   g += xpow3;
   g += curve.get_b().get_value();
   g = g%curve.get_p();
   BigInt z = ressol(g, curve.get_p());

   if(z < 0)
      throw Illegal_Point("error during decompression");

   bool zMod2 = z.get_bit(0);
   if ((zMod2 && ! yMod2) || (!zMod2 && yMod2))
      {
      z = curve.get_p() - z;
      }
   return GFpElement(curve.get_p(),z);
   }

PointGFp const create_random_point(RandomNumberGenerator& rng,
                                   const CurveGFp& curve)
   {

   // create a random point
   GFpElement mX(1,1);
   GFpElement mY(1,1);
   GFpElement mZ(1,1);
   GFpElement minusOne(curve.get_p(), BigInt(BigInt::Negative,1));
   mY = minusOne;
   GFpElement y2(1,1);
   GFpElement x(1,1);

   while (mY == minusOne)
      {
      BigInt value(rng, curve.get_p().bits());
      mX = GFpElement(curve.get_p(),value);
      y2 = curve.get_a() * mX;
      x = mX * mX;
      x *= mX;
      y2 += (x + curve.get_b());

      value = ressol(y2.get_value(), curve.get_p());

      if(value < 0)
         mY = minusOne;
      else
         mY = GFpElement(curve.get_p(), value);
      }
   mZ = GFpElement(curve.get_p(), BigInt(1));

   return PointGFp(curve, mX, mY, mZ);
   }

} // namespace Botan