Exemple #1
0
void
setup_pattern(
  int                     pattern,
  vsip::Matrix<T, BlockT> img,
  vsip::length_type       row_size,
  vsip::length_type       col_size,
  T                       value)
{
  using vsip::length_type;
  using vsip::index_type;

  length_type rows = img.size(0);
  length_type cols = img.size(1);

  switch(pattern)
  {
  case 1: // checker
    for (index_type y=0; y<rows; y += row_size)
    {
      for (index_type x=0; x<cols; x += col_size)
      {
	T v = (((y / row_size) % 2) ^ ((x / col_size) % 2)) ? value : 0;
	img(Domain<2>(Domain<1>(y, 1, min(row_size, rows-y)),
		      Domain<1>(x, 1, min(col_size, cols-x)))) = T(v);
      }
    }
    break;
  case 2: // rows
    for (index_type y=0; y<rows; y += row_size)
    {
      T v = ((y / row_size) % 2) ? value : 0;
      img(Domain<2>(Domain<1>(y, 1, min(row_size, rows-y)),
		    Domain<1>(0, 1, cols))) = T(v);
    }
    break;
  case 3: // cols
    break;
  case 4: // checker fade
    int scale = 2;
    for (index_type y=0; y<rows; y += row_size)
    {
      for (index_type x=0; x<cols; x += col_size)
      {
	T v = (((y / row_size) % 2) ^ ((x / col_size) % 2)) ? value : 0;
	v = (T)(((float)(scale*rows-y) / (scale*rows)) *
		((float)(scale*cols-x) / (scale*cols)) *
		v);
	img(Domain<2>(Domain<1>(y, 1, min(row_size, rows-y)),
		      Domain<1>(x, 1, min(col_size, cols-x)))) = T(v);
      }
    }
    break;
  }
}
Exemple #2
0
void
prodh(vsip::const_Matrix<T, Block1> a,
      vsip::const_Matrix<T, Block2> b,
      vsip::Matrix      <T, Block3> c)
{
  using vsip::index_type;

  assert(a.size(1) == c.size(0));
  assert(b.size(1) == c.size(1));
  assert(a.size(0) == b.size(0));

  for (index_type i=0; i<c.size(0); ++i)
    for (index_type j=0; j<c.size(1); ++j)
    {
      T tmp = T();
      for (index_type k=0; k<a.size(0); ++k)
	tmp += Test_traits<T>::conj(a.get(k, i)) * b.get(k, j);
      c(i, j) = tmp;
    }
}
Exemple #3
0
float
prod_check(
  vsip::const_Matrix<T, Block1> a,
  vsip::const_Matrix<T, Block2> b,
  vsip::Matrix<T, Block3> c)
{
  using vsip::index_type;
  typedef typename ovxx::scalar_of<T>::type scalar_type;

  assert(a.size(0) == c.size(0));
  assert(b.size(1) == c.size(1));
  assert(a.size(1) == b.size(0));

  float err = 0.f;

  for (index_type i=0; i<c.size(0); ++i)
    for (index_type j=0; j<c.size(1); ++j)
    {
      T           tmp   = T();
      scalar_type guage = scalar_type();

      for (index_type k=0; k<a.size(1); ++k)
      {
	tmp   += a.get(i, k) * b.get(k, j);
	guage += vsip::mag(a.get(i, k)) * vsip::mag(b.get(k, j));
      }

      float err_ij = vsip::mag(tmp - c(i, j)) / 
        test::precision<scalar_type>::eps;
      if (guage > scalar_type())
	err_ij = err_ij/guage;
      err = std::max(err, err_ij);
    }

  return err;
}
Exemple #4
0
void
setup_checker(
  vsip::Matrix<T, BlockT> img,
  vsip::length_type       row_size,
  vsip::length_type       col_size,
  T                       value)
{
  using vsip::length_type;
  using vsip::index_type;

  length_type rows = img.size(0);
  length_type cols = img.size(1);

  for (index_type y=0; y<rows; y += row_size)
  {
    for (index_type x=0; x<cols; x += col_size)
    {
      T v = (((y / row_size) % 2) ^ ((x / col_size) % 2)) ? value : 0;
      img(Domain<2>(Domain<1>(y, 1, min(row_size, rows-y)),
		    Domain<1>(x, 1, min(col_size, cols-x)))) = T(v);
    }
  }
}
Exemple #5
0
void
pwarp_block(
  vsip::const_Matrix<CoeffT, Block1> P,
  vsip::const_Matrix<T, Block2>      in,
  vsip::Matrix<T, Block3>            out)
{
  using vsip::length_type;
  using vsip::index_type;
  using vsip::Domain;
  using vsip_csl::img::impl::apply_proj;
  using std::min;
  using std::max;

  length_type rows = out.size(0);
  length_type cols = out.size(1);

  length_type row_chunk_size = 128;
  length_type col_chunk_size = 128;

  length_type row_quantum = 1;
  length_type col_quantum = 128/sizeof(T);

  for (index_type r=0; r<rows; r += row_chunk_size)
  {
    length_type my_r_size = std::min(row_chunk_size, rows - r);
    for (index_type c=0; c<cols; c += col_chunk_size)
    {
      length_type my_c_size = std::min(col_chunk_size, cols-c);

      CoeffT u00, v00;
      CoeffT u01, v01;
      CoeffT u10, v10;
      CoeffT u11, v11;
      apply_proj<CoeffT>(P, c+0*my_c_size, r+0*my_r_size, u00, v00);
      apply_proj<CoeffT>(P, c+0*my_c_size, r+1*my_r_size, u01, v01);
      apply_proj<CoeffT>(P, c+1*my_c_size, r+0*my_r_size, u10, v10);
      apply_proj<CoeffT>(P, c+1*my_c_size, r+1*my_r_size, u11, v11);

      CoeffT min_u = max(CoeffT(0), min(min(u00, u01), min(u10, u11)));
      CoeffT min_v = max(CoeffT(0), min(min(v00, v01), min(v10, v11)));
      CoeffT max_u = min(CoeffT(in.size(1)-1), max(max(u00, u01),max(u10, u11)));
      CoeffT max_v = min(CoeffT(in.size(0)-1), max(max(v00, v01),max(v10, v11)));

      index_type in_r0 = quantize_floor((index_type)floorf(min_v), row_quantum);
      index_type in_c0 = quantize_floor((index_type)floorf(min_u), col_quantum);
      index_type in_r1 = quantize_ceil((index_type)ceilf(max_v), row_quantum,in.size(0)-1);
      index_type in_c1 = quantize_ceil((index_type)ceilf(max_u), col_quantum,in.size(1)-1);

      Domain<2> in_dom(Domain<1>(in_r0, 1, in_r1 - in_r0 + 1),
		       Domain<1>(in_c0, 1, in_c1 - in_c0 + 1));

      length_type out_r0 = r;
      length_type out_c0 = c;
      Domain<2> out_dom(Domain<1>(out_r0, 1, my_r_size),
			Domain<1>(out_c0, 1, my_c_size));

      pwarp_offset(P,
		   in(in_dom),   in_r0,  in_c0,
		   out(out_dom), out_r0, out_c0);
    }
  }
}
void
corr(
  vsip::bias_type               bias,
  vsip::support_region_type     sup,
  vsip::const_Matrix<T, Block1> ref,
  vsip::const_Matrix<T, Block2> in,
  vsip::Matrix<T, Block3>       out)
{
  using vsip::index_type;
  using vsip::length_type;
  using vsip::stride_type;
  using vsip::Matrix;
  using vsip::Domain;
  using vsip::unbiased;

  typedef typename vsip::impl::Scalar_of<T>::type scalar_type;

  length_type Mr = ref.size(0);
  length_type Mc = ref.size(1);
  length_type Nr = in.size(0);
  length_type Nc = in.size(1);
  length_type Pr = out.size(0);
  length_type Pc = out.size(1);

  length_type expected_Pr = corr_output_size(sup, Mr, Nr);
  length_type expected_Pc = corr_output_size(sup, Mc, Nc);
  stride_type shift_r     = expected_shift(sup, Mr);
  stride_type shift_c     = expected_shift(sup, Mc);

  assert(expected_Pr == Pr);
  assert(expected_Pc == Pc);

  Matrix<T> sub(Mr, Mc);
  Domain<1> sub_dom_r;
  Domain<1> sub_dom_c;
  Domain<1> in_dom_r;
  Domain<1> in_dom_c;

  // compute correlation
  for (index_type r=0; r<Pr; ++r)
  {
    stride_type pos_r = static_cast<stride_type>(r) + shift_r;

    for (index_type c=0; c<Pc; ++c)
    {

      stride_type pos_c = static_cast<stride_type>(c) + shift_c;

      scalar_type scale = scalar_type(1);

      if (pos_r < 0)
      {
	sub_dom_r = Domain<1>(-pos_r, 1, Mr + pos_r); 
	in_dom_r  = Domain<1>(0, 1, Mr+pos_r);
	scale *= scalar_type(Mr + pos_r);
      }
      else if (pos_r + Mr > Nr)
      {
	sub_dom_r = Domain<1>(0, 1, Nr-pos_r);
	in_dom_r  = Domain<1>(pos_r, 1, Nr-pos_r);
	scale *= scalar_type(Nr - pos_r);
      }
      else
      {
	sub_dom_r = Domain<1>(0, 1, Mr);
	in_dom_r  = Domain<1>(pos_r, 1, Mr);
	scale *= scalar_type(Mr);
      }

      if (pos_c < 0)
      {
	sub_dom_c = Domain<1>(-pos_c, 1, Mc + pos_c); 
	in_dom_c  = Domain<1>(0, 1, Mc+pos_c);
	scale *= scalar_type(Mc + pos_c);
      }
      else if (pos_c + Mc > Nc)
      {
	sub_dom_c = Domain<1>(0, 1, Nc-pos_c);
	in_dom_c  = Domain<1>(pos_c, 1, Nc-pos_c);
	scale *= scalar_type(Nc - pos_c);
      }
      else
      {
	sub_dom_c = Domain<1>(0, 1, Mc);
	in_dom_c  = Domain<1>(pos_c, 1, Mc);
	scale *= scalar_type(Mc);
      }

      sub = T();
      sub(Domain<2>(sub_dom_r, sub_dom_c)) = in(Domain<2>(in_dom_r, in_dom_c));
      
      T val = sumval(ref * impl_conj(sub));
      if (bias == unbiased)
	val /= scale;
      
      out(r, c) = val;
    }
  }
}