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#include "SymbolMatrix.hpp"
#include "../Helper.hpp"
#include <cstdlib>
#include <cstring>
#include <cmath>
static inline int32_t imin(int32_t a, int32_t b)
{
return (a < b) ? a : b;
}
static inline int32_t imax(int32_t a, int32_t b)
{
return (a > b) ? a : b;
}
/* Macros */
#define memFree(ptr) free((void*)(ptr))
#define memFree_null(ptr) do \
{ \
memFree( ptr ); \
(ptr) = nullptr; \
} while(0)
void symbol_matrix_init(symbol_matrix_t* matrix)
{
memset(matrix, 0, sizeof(symbol_matrix_t));
return;
}
void symbol_matrix_deinit(symbol_matrix_t* matrix)
{
if (matrix->m_sndetab != nullptr)
{
memFree_null(matrix->m_sndetab);
}
if (matrix->m_cblktab != nullptr)
{
memFree_null(matrix->m_cblktab);
}
if (matrix->m_bloktab != nullptr)
{
memFree_null(matrix->m_bloktab);
}
if (matrix->m_browtab != nullptr)
{
memFree_null(matrix->m_browtab);
}
memset(matrix, 0, sizeof(symbol_matrix_t));
return;
}
#include <iostream>
void symbol_matrix_print_stats(symbol_matrix_t* matrix)
{
symbol_cblk_t* cblk;
symbol_blok_t* blok;
int32_t itercblk, dof;
int32_t sndenbr, cblknbr, bloknbr;
int32_t cblkmin, cblkmax;
int32_t blokmin, blokmax;
double cblkavg1, blokavg1;
double cblkavg2, blokavg2;
size_t mem = 0;
sndenbr = matrix->m_sndenbr;
cblknbr = matrix->m_cblknbr;
bloknbr = matrix->m_bloknbr;
cblkmin = INT32_MAX;
cblkmax = 0;
cblkavg1 = 0.0;
cblkavg2 = 0.0;
blokmin = INT32_MAX;
blokmax = 0;
blokavg1 = 0.0;
blokavg2 = 0.0;
cblk = matrix->m_cblktab;
blok = matrix->m_bloktab;
for (itercblk = 0; itercblk < cblknbr; ++itercblk, ++cblk)
{
int32_t iterblok = cblk[0].m_bloknum + 1;
int32_t lbloknum = cblk[1].m_bloknum;
int32_t colnbr = cblk->m_lcolnum - cblk->m_fcolnum + 1;
cblkmin = imin(cblkmin, colnbr);
cblkmax = imax(cblkmax, colnbr);
cblkavg1 += colnbr;
cblkavg2 += colnbr * colnbr;
blok++;
/* Only extra diagonal */
for (; iterblok < lbloknum; ++iterblok, ++blok)
{
int32_t rownbr = blok->m_lrownum - blok->m_frownum + 1;
blokmin = imin(blokmin, rownbr);
blokmax = imax(blokmax, rownbr);
blokavg1 += rownbr;
blokavg2 += rownbr * rownbr;
}
}
dof = matrix->m_dof;
if (dof < 1)
{
Helper::log(LogStatus::WARNING, "DOF lower than 1 so statistics might be wrong !");
dof = 1;
}
blokmin *= dof;
blokmax *= dof;
cblkmin *= dof;
cblkmax *= dof;
cblkavg1 = (cblkavg1 * (double)dof) / (double)cblknbr;
blokavg1 = (blokavg1 * (double)dof) / (double)bloknbr;
cblkavg2 = sqrt( ((cblkavg2 * (double)dof * (double)dof) / (double)cblknbr) - cblkavg1 * cblkavg1);
blokavg2 = sqrt( ((blokavg2 * (double)dof * (double)dof) / (double)bloknbr) - blokavg1 * blokavg1);
/* Compute symbol matrix space */
mem = sizeof(symbol_matrix_t);
mem += sizeof(symbol_cblk_t) * (cblknbr + 1);
mem += sizeof(symbol_blok_t) * matrix->m_bloknbr;
mem += sizeof(int32_t) * bloknbr;
Helper::set_infos(
"Symbol Matrix statistics:\n"
" Number of superndoes %10ld\n"
" Number of cblk %10ld\n"
" Number of blok %10ld\n"
" Cblk width min %10ld\n"
" Cblk width max %10ld\n"
" Cblk width avg %11.2lf\n"
" Cblk width stdev %11.2lf\n"
" Blok height min %10ld\n"
" Blok height max %10ld\n"
" Blok height avg %11.2lf\n"
" Blok height stdev %11.2lf\n"
" Matrix structure space %11.2lf %cB\n",
(long)sndenbr, (long)cblknbr, (long)bloknbr,
(long)cblkmin, (long)cblkmax, cblkavg1, cblkavg2,
(long)blokmin, (long)blokmax, blokavg1, blokavg2,
print_get_value( mem ), print_get_units( mem ) );
}
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