AnalysisSystemForRadionucli.../include/armadillo_bits/spop_max_meat.hpp

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// Copyright (C) 2012-2015 National ICT Australia (NICTA)
//
// This Source Code Form is subject to the terms of the Mozilla Public
// License, v. 2.0. If a copy of the MPL was not distributed with this
// file, You can obtain one at http://mozilla.org/MPL/2.0/.
// -------------------------------------------------------------------
//
// Written by Conrad Sanderson - http://conradsanderson.id.au
// Written by Ryan Curtin
//! \addtogroup spop_max
//! @{
template<typename T1>
inline
void
spop_max::apply(SpMat<typename T1::elem_type>& out, const SpOp<T1,spop_max>& in)
{
arma_extra_debug_sigprint();
const uword dim = in.aux_uword_a;
arma_debug_check( (dim > 1), "max(): parameter 'dim' must be 0 or 1" );
const SpProxy<T1> p(in.m);
const uword p_n_rows = p.get_n_rows();
const uword p_n_cols = p.get_n_cols();
if( (p_n_rows == 0) || (p_n_cols == 0) || (p.get_n_nonzero() == 0) )
{
if(dim == 0) { out.zeros((p_n_rows > 0) ? 1 : 0, p_n_cols); }
if(dim == 1) { out.zeros(p_n_rows, (p_n_cols > 0) ? 1 : 0); }
return;
}
spop_max::apply_proxy(out, p, dim);
}
template<typename T1>
inline
void
spop_max::apply_proxy
(
SpMat<typename T1::elem_type>& out,
const SpProxy<T1>& p,
const uword dim,
const typename arma_not_cx<typename T1::elem_type>::result* junk
)
{
arma_extra_debug_sigprint();
arma_ignore(junk);
typedef typename T1::elem_type eT;
typename SpProxy<T1>::const_iterator_type it = p.begin();
typename SpProxy<T1>::const_iterator_type it_end = p.end();
const uword p_n_cols = p.get_n_cols();
const uword p_n_rows = p.get_n_rows();
if(dim == 0) // find the maximum in each column
{
Row<eT> value(p_n_cols, fill::zeros);
urowvec count(p_n_cols, fill::zeros);
while(it != it_end)
{
const uword col = it.col();
value[col] = (count[col] == 0) ? (*it) : (std::max)(value[col], (*it));
count[col]++;
++it;
}
for(uword col=0; col<p_n_cols; ++col)
{
if(count[col] < p_n_rows) { value[col] = (std::max)(value[col], eT(0)); }
}
out = value;
}
else
if(dim == 1) // find the maximum in each row
{
Col<eT> value(p_n_rows, fill::zeros);
ucolvec count(p_n_rows, fill::zeros);
while(it != it_end)
{
const uword row = it.row();
value[row] = (count[row] == 0) ? (*it) : (std::max)(value[row], (*it));
count[row]++;
++it;
}
for(uword row=0; row<p_n_rows; ++row)
{
if(count[row] < p_n_cols) { value[row] = (std::max)(value[row], eT(0)); }
}
out = value;
}
}
template<typename T1>
inline
typename T1::elem_type
spop_max::vector_max
(
const T1& x,
const typename arma_not_cx<typename T1::elem_type>::result* junk
)
{
arma_extra_debug_sigprint();
arma_ignore(junk);
typedef typename T1::elem_type eT;
const SpProxy<T1> p(x);
if(p.get_n_elem() == 0)
{
arma_debug_check(true, "max(): object has no elements");
return Datum<eT>::nan;
}
if(p.get_n_nonzero() == 0) { return eT(0); }
if(SpProxy<T1>::must_use_iterator == false)
{
// direct access of values
if(p.get_n_nonzero() == p.get_n_elem())
{
return op_max::direct_max(p.get_values(), p.get_n_nonzero());
}
else
{
return std::max(eT(0), op_max::direct_max(p.get_values(), p.get_n_nonzero()));
}
}
else
{
// use iterator
typename SpProxy<T1>::const_iterator_type it = p.begin();
typename SpProxy<T1>::const_iterator_type it_end = p.end();
eT result = (*it);
++it;
while(it != it_end)
{
if((*it) > result) { result = (*it); }
++it;
}
if(p.get_n_nonzero() == p.get_n_elem())
{
return result;
}
else
{
return std::max(eT(0), result);
}
}
}
template<typename T1>
inline
typename arma_not_cx<typename T1::elem_type>::result
spop_max::max(const SpBase<typename T1::elem_type, T1>& X)
{
arma_extra_debug_sigprint();
typedef typename T1::elem_type eT;
const SpProxy<T1> P(X.get_ref());
const uword n_elem = P.get_n_elem();
const uword n_nonzero = P.get_n_nonzero();
if(n_elem == 0)
{
arma_debug_check(true, "max(): object has no elements");
return Datum<eT>::nan;
}
eT max_val = priv::most_neg<eT>();
if(SpProxy<T1>::must_use_iterator)
{
// We have to iterate over the elements.
typedef typename SpProxy<T1>::const_iterator_type it_type;
it_type it = P.begin();
it_type it_end = P.end();
while (it != it_end)
{
if ((*it) > max_val) { max_val = *it; }
++it;
}
}
else
{
// We can do direct access of the values, row_indices, and col_ptrs.
// We don't need the location of the max value, so we can just call out to
// other functions...
max_val = op_max::direct_max(P.get_values(), n_nonzero);
}
if(n_elem == n_nonzero)
{
return max_val;
}
else
{
return std::max(eT(0), max_val);
}
}
template<typename T1>
inline
typename arma_not_cx<typename T1::elem_type>::result
spop_max::max_with_index(const SpProxy<T1>& P, uword& index_of_max_val)
{
arma_extra_debug_sigprint();
typedef typename T1::elem_type eT;
const uword n_elem = P.get_n_elem();
const uword n_nonzero = P.get_n_nonzero();
const uword n_rows = P.get_n_rows();
if(n_elem == 0)
{
arma_debug_check(true, "max(): object has no elements");
return Datum<eT>::nan;
}
eT max_val = priv::most_neg<eT>();
if(SpProxy<T1>::must_use_iterator)
{
// We have to iterate over the elements.
typedef typename SpProxy<T1>::const_iterator_type it_type;
it_type it = P.begin();
it_type it_end = P.end();
while (it != it_end)
{
if ((*it) > max_val)
{
max_val = *it;
index_of_max_val = it.row() + it.col() * n_rows;
}
++it;
}
}
else
{
// We can do direct access.
max_val = op_max::direct_max(P.get_values(), n_nonzero, index_of_max_val);
// Convert to actual position in matrix.
const uword row = P.get_row_indices()[index_of_max_val];
uword col = 0;
while (P.get_col_ptrs()[++col] <= index_of_max_val) { }
index_of_max_val = (col - 1) * n_rows + row;
}
if(n_elem != n_nonzero)
{
max_val = std::max(eT(0), max_val);
// If the max_val is a nonzero element, we need its actual position in the matrix.
if(max_val == eT(0))
{
// Find first zero element.
uword last_row = 0;
uword last_col = 0;
typedef typename SpProxy<T1>::const_iterator_type it_type;
it_type it = P.begin();
it_type it_end = P.end();
while (it != it_end)
{
// Have we moved more than one position from the last place?
if ((it.col() == last_col) && (it.row() - last_row > 1))
{
index_of_max_val = it.col() * n_rows + last_row + 1;
break;
}
else if ((it.col() >= last_col + 1) && (last_row < n_rows - 1))
{
index_of_max_val = last_col * n_rows + last_row + 1;
break;
}
else if ((it.col() == last_col + 1) && (it.row() > 0))
{
index_of_max_val = it.col() * n_rows;
break;
}
else if (it.col() > last_col + 1)
{
index_of_max_val = (last_col + 1) * n_rows;
break;
}
last_row = it.row();
last_col = it.col();
++it;
}
}
}
return max_val;
}
template<typename T1>
inline
void
spop_max::apply_proxy
(
SpMat<typename T1::elem_type>& out,
const SpProxy<T1>& p,
const uword dim,
const typename arma_cx_only<typename T1::elem_type>::result* junk
)
{
arma_extra_debug_sigprint();
arma_ignore(junk);
typedef typename T1::elem_type eT;
typedef typename get_pod_type<eT>::result T;
typename SpProxy<T1>::const_iterator_type it = p.begin();
typename SpProxy<T1>::const_iterator_type it_end = p.end();
const uword p_n_cols = p.get_n_cols();
const uword p_n_rows = p.get_n_rows();
if(dim == 0) // find the maximum in each column
{
Row<eT> rawval(p_n_cols, fill::zeros);
Row< T> absval(p_n_cols, fill::zeros);
while(it != it_end)
{
const uword col = it.col();
const eT& v = (*it);
const T a = std::abs(v);
if(a > absval[col])
{
absval[col] = a;
rawval[col] = v;
}
++it;
}
out = rawval;
}
else
if(dim == 1) // find the maximum in each row
{
Col<eT> rawval(p_n_rows, fill::zeros);
Col< T> absval(p_n_rows, fill::zeros);
while(it != it_end)
{
const uword row = it.row();
const eT& v = (*it);
const T a = std::abs(v);
if(a > absval[row])
{
absval[row] = a;
rawval[row] = v;
}
++it;
}
out = rawval;
}
}
template<typename T1>
inline
typename T1::elem_type
spop_max::vector_max
(
const T1& x,
const typename arma_cx_only<typename T1::elem_type>::result* junk
)
{
arma_extra_debug_sigprint();
arma_ignore(junk);
typedef typename T1::elem_type eT;
typedef typename get_pod_type<eT>::result T;
const SpProxy<T1> p(x);
if(p.get_n_elem() == 0)
{
arma_debug_check(true, "max(): object has no elements");
return Datum<eT>::nan;
}
if(p.get_n_nonzero() == 0) { return eT(0); }
if(SpProxy<T1>::must_use_iterator == false)
{
// direct access of values
if(p.get_n_nonzero() == p.get_n_elem())
{
return op_max::direct_max(p.get_values(), p.get_n_nonzero());
}
else
{
const eT val1 = eT(0);
const eT val2 = op_max::direct_max(p.get_values(), p.get_n_nonzero());
return ( std::abs(val1) >= std::abs(val2) ) ? val1 : val2;
}
}
else
{
// use iterator
typename SpProxy<T1>::const_iterator_type it = p.begin();
typename SpProxy<T1>::const_iterator_type it_end = p.end();
eT best_val_orig = *it;
T best_val_abs = std::abs(best_val_orig);
++it;
while(it != it_end)
{
eT val_orig = *it;
T val_abs = std::abs(val_orig);
if(val_abs > best_val_abs)
{
best_val_abs = val_abs;
best_val_orig = val_orig;
}
++it;
}
if(p.get_n_nonzero() == p.get_n_elem())
{
return best_val_orig;
}
else
{
const eT val1 = eT(0);
return ( std::abs(val1) >= best_val_abs ) ? val1 : best_val_orig;
}
}
}
template<typename T1>
inline
typename arma_cx_only<typename T1::elem_type>::result
spop_max::max(const SpBase<typename T1::elem_type, T1>& X)
{
arma_extra_debug_sigprint();
typedef typename T1::elem_type eT;
typedef typename get_pod_type<eT>::result T;
const SpProxy<T1> P(X.get_ref());
const uword n_elem = P.get_n_elem();
const uword n_nonzero = P.get_n_nonzero();
if(n_elem == 0)
{
arma_debug_check(true, "max(): object has no elements");
return Datum<eT>::nan;
}
T max_val = priv::most_neg<T>();
eT ret_val;
if(SpProxy<T1>::must_use_iterator)
{
// We have to iterate over the elements.
typedef typename SpProxy<T1>::const_iterator_type it_type;
it_type it = P.begin();
it_type it_end = P.end();
while (it != it_end)
{
const T tmp_val = std::abs(*it);
if (tmp_val > max_val)
{
max_val = tmp_val;
ret_val = *it;
}
++it;
}
}
else
{
// We can do direct access of the values, row_indices, and col_ptrs.
// We don't need the location of the max value, so we can just call out to
// other functions...
ret_val = op_max::direct_max(P.get_values(), n_nonzero);
max_val = std::abs(ret_val);
}
if(n_elem == n_nonzero)
{
return max_val;
}
else
{
if (T(0) > max_val)
return eT(0);
else
return ret_val;
}
}
template<typename T1>
inline
typename arma_cx_only<typename T1::elem_type>::result
spop_max::max_with_index(const SpProxy<T1>& P, uword& index_of_max_val)
{
arma_extra_debug_sigprint();
typedef typename T1::elem_type eT;
typedef typename get_pod_type<eT>::result T;
const uword n_elem = P.get_n_elem();
const uword n_nonzero = P.get_n_nonzero();
const uword n_rows = P.get_n_rows();
if(n_elem == 0)
{
arma_debug_check(true, "max(): object has no elements");
return Datum<eT>::nan;
}
T max_val = priv::most_neg<T>();
if(SpProxy<T1>::must_use_iterator)
{
// We have to iterate over the elements.
typedef typename SpProxy<T1>::const_iterator_type it_type;
it_type it = P.begin();
it_type it_end = P.end();
while (it != it_end)
{
const T tmp_val = std::abs(*it);
if (tmp_val > max_val)
{
max_val = tmp_val;
index_of_max_val = it.row() + it.col() * n_rows;
}
++it;
}
}
else
{
// We can do direct access.
max_val = std::abs(op_max::direct_max(P.get_values(), n_nonzero, index_of_max_val));
// Convert to actual position in matrix.
const uword row = P.get_row_indices()[index_of_max_val];
uword col = 0;
while (P.get_col_ptrs()[++col] <= index_of_max_val) { }
index_of_max_val = (col - 1) * n_rows + row;
}
if(n_elem != n_nonzero)
{
max_val = std::max(T(0), max_val);
// If the max_val is a nonzero element, we need its actual position in the matrix.
if(max_val == T(0))
{
// Find first zero element.
uword last_row = 0;
uword last_col = 0;
typedef typename SpProxy<T1>::const_iterator_type it_type;
it_type it = P.begin();
it_type it_end = P.end();
while (it != it_end)
{
// Have we moved more than one position from the last place?
if ((it.col() == last_col) && (it.row() - last_row > 1))
{
index_of_max_val = it.col() * n_rows + last_row + 1;
break;
}
else if ((it.col() >= last_col + 1) && (last_row < n_rows - 1))
{
index_of_max_val = last_col * n_rows + last_row + 1;
break;
}
else if ((it.col() == last_col + 1) && (it.row() > 0))
{
index_of_max_val = it.col() * n_rows;
break;
}
else if (it.col() > last_col + 1)
{
index_of_max_val = (last_col + 1) * n_rows;
break;
}
last_row = it.row();
last_col = it.col();
++it;
}
}
}
return P[index_of_max_val];
}
//! @}