Exemplo n.º 1
0
template <> int svpcvp(Options &o, ZZ_mat<mpz_t> &b, const vector<Z_NR<mpz_t>> &target)
{
  const char *format = o.output_format ? o.output_format : "s";
  IntVect sol_coord;    // In the LLL-reduced basis
  IntVect sol_coord_2;  // In the initial basis
  IntVect solution;
  IntMatrix u;
  bool with_coord     = strchr(format, 'c') != NULL;
  bool with_coord_std = strchr(format, 's') != NULL;
  int flags           = SVP_DEFAULT | (o.verbose ? SVP_VERBOSE : 0);
  int flagsLLL        = LLL_DEFAULT | (o.verbose ? LLL_VERBOSE : 0);
  int status;

  if (!o.no_lll)
  {
    if (with_coord)
    {
      status = lll_reduction(b, u, LLL_DEF_DELTA, LLL_DEF_ETA, LM_WRAPPER, FT_DEFAULT, 0, flagsLLL);
    }
    else
    {
      status = lll_reduction(b, LLL_DEF_DELTA, LLL_DEF_ETA, LM_WRAPPER, FT_DEFAULT, 0, flagsLLL);
    }
    if (status != RED_SUCCESS)
    {
      cerr << "LLL reduction failed: " << get_red_status_str(status) << endl;
      return status;
    }
  }

  if (target.empty())
    status = shortest_vector(b, sol_coord, SVPM_PROVED, flags);
  else
    status = closest_vector(b, target, sol_coord, flags);

  if (status != RED_SUCCESS)
  {
    cerr << "Failure: " << get_red_status_str(status) << endl;
    return status;
  }
  if (with_coord)
  {
    if (o.no_lll)
      sol_coord_2 = sol_coord;
    else
      vector_matrix_product(sol_coord_2, sol_coord, u);
  }
  if (with_coord_std)
  {
    vector_matrix_product(solution, sol_coord, b);
  }

  for (int i = 0; format[i]; i++)
  {
    switch (format[i])
    {
    case 'c':
      cout << sol_coord_2 << endl;
      break;
    case 's':
      cout << solution << endl;
      break;
    case 't':
      cout << status << endl;
      break;
    case ' ':
      cout << endl;
      break;
    }
  }
  return status;
}
Exemplo n.º 2
0
template<class Z> Obj dofplll(Obj gapmat, Obj lllargs, Obj svpargs)
{
  if (!IS_PLIST(gapmat)) return INTOBJ_INT(-1);
  Int numrows = LEN_PLIST(gapmat), numcols = -1;

  for (int i = 1; i <= numrows; i++) {
    Obj row = ELM_PLIST(gapmat,i);
    if (numcols == -1)
      numcols = LEN_PLIST(row);
    if (numcols != LEN_PLIST(row))
      return INTOBJ_INT(-1);
  }
  if (numcols <= 0)
    return INTOBJ_INT(-1);

  ZZ_mat<Z> mat(numrows, numcols);
  for (int i = 1; i <= numrows; i++)
    for (int j = 1; j <= numcols; j++)
      SET_INTOBJ(mat[i-1][j-1], ELM_PLIST(ELM_PLIST(gapmat,i),j));

  if (lllargs != Fail) {
    double delta = 0.99;
    double eta = 0.51;
    LLLMethod method = LM_WRAPPER;
    FloatType floatType = FT_DEFAULT;
    int precision = 0;
    int flags = LLL_DEFAULT;

    if (lllargs != True) {
      if (!IS_PLIST(lllargs) || LEN_PLIST(lllargs) != 6) return INTOBJ_INT(-20);

      Obj v = ELM_PLIST(lllargs,1);
      if (IS_MACFLOAT(v)) delta = VAL_MACFLOAT(v);
      else if (v != Fail) return INTOBJ_INT(-21);

      v = ELM_PLIST(lllargs,2);
      if (IS_MACFLOAT(v)) eta = VAL_MACFLOAT(v);
      else if (v != Fail) return INTOBJ_INT(-22);

      v = ELM_PLIST(lllargs,3);
      if (v == INTOBJ_INT(0)) method = LM_WRAPPER;
      else if (v == INTOBJ_INT(1)) method = LM_PROVED;
      else if (v == INTOBJ_INT(2)) method = LM_HEURISTIC;
      else if (v == INTOBJ_INT(3)) method = LM_FAST;
      else if (v != Fail) return INTOBJ_INT(-23);

      v = ELM_PLIST(lllargs,4);
      if (v == INTOBJ_INT(0)) floatType = FT_DEFAULT;
      else if (v == INTOBJ_INT(1)) floatType = FT_DOUBLE;
      else if (v == INTOBJ_INT(2)) floatType = FT_DPE;
      else if (v == INTOBJ_INT(3)) floatType = FT_MPFR;
      else if (v != Fail) return INTOBJ_INT(-24);

      v = ELM_PLIST(lllargs,5);
      if (IS_INTOBJ(v)) precision = INT_INTOBJ(v);
      else if (v != Fail) return INTOBJ_INT(-25);

      v = ELM_PLIST(lllargs,6);
      if (IS_INTOBJ(v)) flags = INT_INTOBJ(v);
      else if (v != Fail) return INTOBJ_INT(-26);
    }
    int result = lll_reduction(mat, delta, eta, method, floatType, precision, flags);

    if (result != RED_SUCCESS)
      return INTOBJ_INT(10*result+1);
  }

  if (svpargs != Fail) {
    SVPMethod method = SVPM_PROVED;
    int flags = SVP_DEFAULT;

    // __asm__ ("int3");
    if (svpargs != True) {
      if (!IS_PLIST(svpargs) || LEN_PLIST(svpargs) != 2) return INTOBJ_INT(-30);

      Obj v = ELM_PLIST(svpargs,1);
      if (v == INTOBJ_INT(0)) method = SVPM_PROVED;
      else if (v == INTOBJ_INT(1)) method = SVPM_FAST;
      else if (v != Fail) return INTOBJ_INT(-31);

      v = ELM_PLIST(svpargs,2);
      if (IS_INTOBJ(v)) flags = INT_INTOBJ(v);
      else if (v != Fail) return INTOBJ_INT(-32);
    }

    vector<Integer> sol(numrows);
    IntMatrix svpmat(numrows,numcols);

    for (int i = 0; i < numrows; i++)
      for (int j = 0; j < numcols; j++)
	SET_Z(svpmat[i][j],mat[i][j]);

    int result = shortest_vector(svpmat, sol, method, flags);

    if (result != RED_SUCCESS)
      return INTOBJ_INT(10*result+2);

    Obj gapvec;
    if (lllargs == Fail) { // return coordinates of shortest vector in mat
      gapvec = NEW_PLIST(T_PLIST,numrows);
      SET_LEN_PLIST(gapvec,numrows);
      for (int i = 1; i <= numrows; i++) {
	Obj v = GET_INTOBJ(sol[i-1]);
	SET_ELM_PLIST(gapvec,i,v);
      }
    } else { // return shortest vector
      gapvec = NEW_PLIST(T_PLIST,numcols);
      SET_LEN_PLIST(gapvec,numcols);
      for (int i = 1; i <= numcols; i++) {
	Integer s;
	s = 0;
	for (int j = 0; j < numrows; j++)
	  s.addmul(sol[j],svpmat[j][i-1]);
	Obj v = GET_INTOBJ(s);
	SET_ELM_PLIST(gapvec,i,v);
      }
    }
    return gapvec;
  }

  gapmat = NEW_PLIST(T_PLIST,numrows);
  SET_LEN_PLIST(gapmat,numrows);
  for (int i = 1; i <= numrows; i++) {
    Obj gaprow = NEW_PLIST(T_PLIST,numcols);
    SET_LEN_PLIST(gaprow,numcols);
    SET_ELM_PLIST(gapmat,i,gaprow);
    for (int j = 1; j <= numcols; j++) {
      Obj v = GET_INTOBJ(mat[i-1][j-1]);
      SET_ELM_PLIST(gaprow,j,v);
    }
  }
  return gapmat;
}