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LatAnalyze/lib/Functional/TabFunction.cpp

165 lines
5.0 KiB
C++

/*
* TabFunction.cpp, part of LatAnalyze 3
*
* Copyright (C) 2013 - 2020 Antonin Portelli
*
* LatAnalyze 3 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 of the License, or
* (at your option) any later version.
*
* LatAnalyze 3 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.
*
* You should have received a copy of the GNU General Public License
* along with LatAnalyze 3. If not, see <http://www.gnu.org/licenses/>.
*/
#include <LatAnalyze/Functional/TabFunction.hpp>
#include <LatAnalyze/includes.hpp>
using namespace std;
using namespace Latan;
/******************************************************************************
* TabFunction implementation *
******************************************************************************/
// constructors ////////////////////////////////////////////////////////////////
TabFunction::TabFunction(const DVec &x, const DVec &y,
const InterpType interpType)
{
setData(x, y);
setInterpolationType(interpType);
}
// access //////////////////////////////////////////////////////////////////////
void TabFunction::setData(const DVec &x, const DVec &y)
{
if (x.size() != y.size())
{
LATAN_ERROR(Size, "tabulated function x/y data size mismatch");
}
FOR_VEC(x, i)
{
value_[x(i)] = y(i);
}
}
void TabFunction::setInterpolationType(const InterpType interpType)
{
interpType_ = interpType;
}
// function call ///////////////////////////////////////////////////////////////
double TabFunction::operator()(const double *arg) const
{
double result = 0.0, x = arg[0];
if ((x < value_.begin()->first) or (x >= value_.rbegin()->first)) {
LATAN_ERROR(Range, "tabulated function variable out of range "
"(x= " + strFrom(x) + " not in ["
+ strFrom(value_.begin()->first) + ", "
+ strFrom(value_.rbegin()->first) + "])");
}
auto i = value_.equal_range(x);
auto low = (x == i.first->first) ? i.first : prev(i.first);
auto high = i.second;
switch (interpType_) {
case InterpType::LINEAR: {
double x_a, x_b, y_a, y_b;
x_a = low->first;
x_b = high->first;
y_a = low->second;
y_b = high->second;
result = y_a + (x - x_a) * (y_b - y_a) / (x_b - x_a);
break;
}
case InterpType::NEAREST: {
result = nearest(x)->second;
break;
}
case InterpType::QUADRATIC: {
double xs[3], ys[3], ds[3], d01, d02, d12;
auto it = nearest(x);
if (it == value_.begin()) {
it = next(it);
}
else if (it == prev(value_.end())) {
it = prev(it);
}
xs[0] = prev(it)->first;
ys[0] = prev(it)->second;
xs[1] = it->first;
ys[1] = it->second;
xs[2] = next(it)->first;
ys[2] = next(it)->second;
ds[0] = x - xs[0];
ds[1] = x - xs[1];
ds[2] = x - xs[2];
d01 = xs[0] - xs[1];
d02 = xs[0] - xs[2];
d12 = xs[1] - xs[2];
// Lagrange polynomial coefficient computation
result = ds[1]/d01*ds[2]/d02*ys[0]
-ds[0]/d01*ds[2]/d12*ys[1]
+ds[0]/d02*ds[1]/d12*ys[2];
break;
}
default:
int intType = static_cast<int>(interpType_);
LATAN_ERROR(Implementation, "unsupported interpolation type in "
"tabulated function: "
+ strFrom(intType));
}
return result;
}
// DoubleFunction factory //////////////////////////////////////////////////////
DoubleFunction TabFunction::makeFunction(const bool makeHardCopy) const
{
DoubleFunction res;
if (makeHardCopy)
{
TabFunction copy(*this);
res.setFunction([copy](const double *x){return copy(x);}, 1);
}
else
{
res.setFunction([this](const double *x){return (*this)(x);}, 1);
}
return res;
}
DoubleFunction Latan::interpolate(const DVec &x, const DVec &y,
const InterpType interpType)
{
return TabFunction(x, y, interpType).makeFunction();
}
map<double, double>::const_iterator TabFunction::nearest(const double x) const
{
map<double, double>::const_iterator ret;
auto i = value_.equal_range(x);
auto low = (x == i.first->first) ? i.first : prev(i.first);
auto high = i.second;
if (fabs(high->first - x) < fabs(low->first - x)) {
ret = high;
}
else {
ret = low;
}
return ret;
}