/*
* Implement Heap sort -- direct and indirect sorting
* Based on descriptions in Sedgewick "Algorithms in C"
*
* Copyright (C) 1999 Thomas Walter
*
* 18 February 2000: Modified for GSL by Brian Gough
*
* This is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License as published by the
* Free Software Foundation; either version 3, or (at your option) any
* later version.
*
* This source 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 General Public License
* for more details.
*/
static inline void FUNCTION (my, downheap) (BASE * data, const size_t stride, const size_t N, size_t k);
static inline void FUNCTION (my, downheap2) (BASE * data1, const size_t stride1, BASE * data2, const size_t stride2, const size_t N, size_t k);
static inline void
FUNCTION (my, downheap) (BASE * data, const size_t stride, const size_t N, size_t k)
{
BASE v = data[k * stride];
while (k <= N / 2)
{
size_t j = 2 * k;
if (j < N && data[j * stride] < data[(j + 1) * stride])
{
j++;
}
if (!(v < data[j * stride])) /* avoid infinite loop if nan */
{
break;
}
data[k * stride] = data[j * stride];
k = j;
}
data[k * stride] = v;
}
static inline void
FUNCTION (my, downheap2) (BASE * data1, const size_t stride1, BASE * data2, const size_t stride2, const size_t N, size_t k)
{
BASE v1 = data1[k * stride1];
BASE v2 = data2[k * stride2];
while (k <= N / 2)
{
size_t j = 2 * k;
if (j < N && data1[j * stride1] < data1[(j + 1) * stride1])
{
j++;
}
if (!(v1 < data1[j * stride1])) /* avoid infinite loop if nan */
{
break;
}
data1[k * stride1] = data1[j * stride1];
data2[k * stride2] = data2[j * stride2];
k = j;
}
data1[k * stride1] = v1;
data2[k * stride2] = v2;
}
void
TYPE (gsl_sort) (BASE * data, const size_t stride, const size_t n)
{
size_t N;
size_t k;
if (n == 0)
{
return; /* No data to sort */
}
/* We have n_data elements, last element is at 'n_data-1', first at
'0' Set N to the last element number. */
N = n - 1;
k = N / 2;
k++; /* Compensate the first use of 'k--' */
do
{
k--;
FUNCTION (my, downheap) (data, stride, N, k);
}
while (k > 0);
while (N > 0)
{
/* first swap the elements */
BASE tmp = data[0 * stride];
data[0 * stride] = data[N * stride];
data[N * stride] = tmp;
/* then process the heap */
N--;
FUNCTION (my, downheap) (data, stride, N, 0);
}
}
void
TYPE (gsl_sort_vector) (TYPE (gsl_vector) * v)
{
TYPE (gsl_sort) (v->data, v->stride, v->size) ;
}
void
TYPE (gsl_sort2) (BASE * data1, const size_t stride1, BASE * data2, const size_t stride2, const size_t n)
{
size_t N;
size_t k;
if (n == 0)
{
return; /* No data to sort */
}
/* We have n_data elements, last element is at 'n_data-1', first at
'0' Set N to the last element number. */
N = n - 1;
k = N / 2;
k++; /* Compensate the first use of 'k--' */
do
{
k--;
FUNCTION (my, downheap2) (data1, stride1, data2, stride2, N, k);
}
while (k > 0);
while (N > 0)
{
/* first swap the elements */
BASE tmp;
tmp = data1[0 * stride1];
data1[0 * stride1] = data1[N * stride1];
data1[N * stride1] = tmp;
tmp = data2[0 * stride2];
data2[0 * stride2] = data2[N * stride2];
data2[N * stride2] = tmp;
/* then process the heap */
N--;
FUNCTION (my, downheap2) (data1, stride1, data2, stride2, N, 0);
}
}
void
TYPE (gsl_sort_vector2) (TYPE (gsl_vector) * v1, TYPE (gsl_vector) * v2)
{
TYPE (gsl_sort2) (v1->data, v1->stride, v2->data, v2->stride, v1->size) ;
}