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InterpolateTest.h
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InterpolateTest.h
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// Mantid Repository : https://github.com/mantidproject/mantid
//
// Copyright © 2018 ISIS Rutherford Appleton Laboratory UKRI,
// NScD Oak Ridge National Laboratory, European Spallation Source,
// Institut Laue - Langevin & CSNS, Institute of High Energy Physics, CAS
// SPDX - License - Identifier: GPL - 3.0 +
#pragma once
#include <cxxtest/TestSuite.h>
#include "MantidHistogramData/Histogram.h"
#include "MantidHistogramData/Interpolate.h"
#include "MantidHistogramData/LinearGenerator.h"
using namespace Mantid::HistogramData;
class InterpolateTest : public CxxTest::TestSuite {
public:
// This pair of boilerplate methods prevent the suite being created statically
// This means the constructor isn't called when running other tests
static InterpolateTest *createSuite() { return new InterpolateTest(); }
static void destroySuite(InterpolateTest *suite) { delete suite; }
// ---------------------------------------------------------------------------
// Success cases - linear in-place no copy
// ---------------------------------------------------------------------------
void test_interpolateLinearInPlaceDoes_Not_Copy() {
Histogram input(Points(5, LinearGenerator(0, 0.5)), {-2, 0, 0, 0, 2});
auto xAddrBefore = &input.x();
auto yAddrBefore = &input.y();
TS_ASSERT_THROWS_NOTHING(interpolateLinearInplace(input, 4));
TS_ASSERT_EQUALS(xAddrBefore, &input.x());
TS_ASSERT_EQUALS(yAddrBefore, &input.y());
}
// ---------------------------------------------------------------------------
// Success cases - linear, point X data
// ---------------------------------------------------------------------------
void test_interpolateLinearPointDataSet_Stepsize_One_Less_Point_Size() {
Histogram input(Points(5, LinearGenerator(0, 0.5)), {-2, 0, 0, 0, 2});
auto output = interpolateLinear(input, 4);
checkSizesUnchanged(input, output);
std::vector<double> expectedY = {-2., -1., 0., 1., 2.};
checkData(input, output, expectedY, {});
// Inplace
Histogram inOut(input);
TS_ASSERT_THROWS_NOTHING(interpolateLinearInplace(inOut, 4));
checkSizesUnchanged(input, inOut);
checkData(input, inOut, expectedY, {});
}
void test_interpolateLinearPointDataSet_Even_StepSize() {
Histogram input(Points(5, LinearGenerator(0, 0.5)), {-2, 0, 0.5, 0, 2},
CountStandardDeviations{2., 0., 1., 0., 1.});
auto output = interpolateLinear(input, 2);
checkSizesUnchanged(input, output);
std::vector<double> expectedY = {-2., -0.75, 0.5, 1.25, 2.};
std::vector<double> expectedE = {2., 0., 1., 0., 1.};
checkData(input, output, expectedY, expectedE);
// Inplace
Histogram inOut(input);
TS_ASSERT_THROWS_NOTHING(interpolateLinearInplace(inOut, 2));
checkSizesUnchanged(input, inOut);
checkData(input, inOut, expectedY, {});
}
void test_interpolateLinearPointDataSet_Odd_StepSize() {
Histogram input(Points(5, LinearGenerator(0, 0.5)), {-2, 0, 0.0, 0.5, 2});
auto output = interpolateLinear(input, 3);
checkSizesUnchanged(input, output);
std::vector<double> expectedY = {-2., -2 + (2.5 / 1.5) * 0.5, -1. / 3., 0.5, 2.};
checkData(input, output, expectedY, {});
// Inplace
Histogram inOut(input);
TS_ASSERT_THROWS_NOTHING(interpolateLinearInplace(inOut, 3));
checkSizesUnchanged(input, inOut);
checkData(input, inOut, expectedY, {});
}
void test_interpolateLinearPointDataSet_Errors_No_Interpolation_Error() {
Histogram input(Points(5, LinearGenerator(0, 0.5)), {-2, 0, 0., 0, 2}, CountStandardDeviations{2., 0., 1., 0., 1.});
auto output = interpolateLinear(input, 2, true);
checkSizesUnchanged(input, output);
std::vector<double> expectedE = {2., sqrt(5) / 2, 1., sqrt(2) / 2, 1.};
checkData(input, output, {}, expectedE);
}
void test_interpolateLinearPointDataSet_CorrelatedErrors_No_Interpolation_Error() {
Histogram input(Points(5, LinearGenerator(0, 0.5)), {-2, 0, 0., 0, 2}, CountStandardDeviations{2., 0., 1., 0., 1.});
auto output = interpolateLinear(input, 2, true, false);
checkSizesUnchanged(input, output);
std::vector<double> expectedE = {2., 1.5, 1., 1., 1.};
checkData(input, output, {}, expectedE);
}
void test_interpolateLinearPointDataSet_Errors() {
Histogram input(Points(5, LinearGenerator(0, 0.5)), {-2, 0, 0.5, 0, 2},
CountStandardDeviations{2., 0., 1., 0., 1.});
auto output = interpolateLinear(input, 2, true);
checkSizesUnchanged(input, output);
std::vector<double> expectedE_source = {2., sqrt(5) / 2, 1., sqrt(2) / 2, 1.};
std::vector<double> expectedE_interp = {0., 0.125, 0., 0.125, 0.};
std::vector<double> expectedE(expectedE_source.size());
for (size_t i = 0; i < expectedE_source.size(); i++) {
expectedE[i] = sqrt(pow(expectedE_source[i], 2) + pow(expectedE_interp[i], 2));
}
checkData(input, output, {}, expectedE);
}
void test_interpolateLinearInplace_interpolates() {
Histogram input(Points(2, LinearGenerator(0, 1.0)), {-0.72, -0.72});
Histogram output(Points(1, LinearGenerator(0.5, 1.0)), {0.0});
interpolateLinearInplace(input, output);
TS_ASSERT_EQUALS(output.y()[0], -0.72)
}
// ---------------------------------------------------------------------------
// Success cases - cspline in-place no copy
// ---------------------------------------------------------------------------
void test_interpolateCSplineInPlaceDoes_Not_Copy() {
Histogram input(Points(7, LinearGenerator(0, 0.5)), {-3, 0, -1, 0, 1, 0, 3});
auto xAddrBefore = &input.x();
auto yAddrBefore = &input.y();
TS_ASSERT_THROWS_NOTHING(interpolateCSplineInplace(input, 2));
TS_ASSERT_EQUALS(xAddrBefore, &input.x());
TS_ASSERT_EQUALS(yAddrBefore, &input.y());
}
// ---------------------------------------------------------------------------
// Success cases - cspline, point X data
// ---------------------------------------------------------------------------
void test_interpolateCSplinePointDataSet_Minimum_Calculated_Points() {
Histogram input(Points(7, LinearGenerator(0, 0.5)), Counts({-3, 0, -4, 0, 4, 0, 3}),
CountStandardDeviations({1., 0., 1., 0., 1., 0., 1.}));
auto output = interpolateCSpline(input, 2);
checkSizesUnchanged(input, output);
std::vector<double> expectedY = {-3, -4.625, -4, 0., 4, 4.625, 3};
checkData(input, output, expectedY, {});
// Inplace
Histogram inOut(input);
TS_ASSERT_THROWS_NOTHING(interpolateCSplineInplace(inOut, 2));
checkSizesUnchanged(input, inOut);
checkData(input, inOut, expectedY, {});
}
void test_interpolateCSplinePointDataSet_Errors() {
Histogram input(Points(7, LinearGenerator(0, 0.5)), Counts({-3, 0, -4, 0, 4, 0, 3}),
CountStandardDeviations{2., 0., 1., 0., 1., 0., 2.});
auto output = interpolateCSpline(input, 2, true);
checkSizesUnchanged(input, output);
// expect errors to follow formula:
// yint = A * y1 + B * y2 + C * ypp1 + D * ypp2;
// eyint = sqrt (A^2*e1^2 + B^2*e2^2 + 2*A*C*ey1ypp1 + "*B*D*ey2ypp2 *
// C^2*eypp1^2 + D^2*eypp2^2);
std::vector<double> expectedE = {2., 0, 1., 0, 1., 0., 2.};
double A = 0.5;
double B = 0.5;
double C = -0.0625;
double D = -0.0625;
expectedE[1] =
sqrt(A * A * pow(2., 2) + B * B * pow(1., 2) + 2 * A * C * 0 + 2 * B * D * 2.8 + C * C * 0 + D * D * 19.36);
expectedE[3] = sqrt(A * A * pow(1., 2) + B * B * pow(1., 2) + 2 * A * C * 2.8 + 2 * B * D * 2.8 + C * C * 19.36 +
D * D * 19.36);
expectedE[5] =
sqrt(A * A * pow(1., 2) + B * B * pow(2., 2) + 2 * A * C * 2.8 + 2 * B * D * 0 + C * C * 19.36 + D * D * 0);
checkData(input, output, {}, expectedE);
}
void test_interpolateCSplinePointDataSet_CorrelatedErrors() {
Histogram input(Points(7, LinearGenerator(0, 0.5)), Counts({-3, 0, -4, 0, 4, 0, 3}),
CountStandardDeviations{2., 0., 1., 0., 1., 0., 2.});
auto output = interpolateCSpline(input, 2, true, false);
checkSizesUnchanged(input, output);
std::vector<double> expectedE = {2., 1.5, 1., 1., 1., 1.5, 2.};
checkData(input, output, {}, expectedE);
}
void test_interpolateCSplineInplace_interpolates() {
Histogram input(Points(3, LinearGenerator(0, 1.0)), {-0.72, -0.72, -0.72});
Histogram output(Points(1, LinearGenerator(0.1, 1.0)), {0.0});
interpolateCSplineInplace(input, output);
TS_ASSERT_EQUALS(output.y()[0], -0.72);
}
// ---------------------------------------------------------------------------
// Success cases - linear edge X data
// ---------------------------------------------------------------------------
void test_interpolateLinearEdgeDataSet_Stepsize_One_Less_Point_Size() {
Histogram input(BinEdges(6, LinearGenerator(-0.25, 0.5)), Counts({-2, 0, 0, 0, 2}));
auto output = interpolateLinear(input, 4);
checkSizesUnchanged(input, output);
std::vector<double> expectedY = {-2., -1., 0., 1., 2.};
checkData(input, output, expectedY, {});
// Inplace
Histogram inOut(input);
TS_ASSERT_THROWS_NOTHING(interpolateLinearInplace(inOut, 4));
checkSizesUnchanged(input, inOut);
checkData(input, inOut, expectedY, {});
}
void test_interpolateLinearEdgeDataSet_Even_StepSize() {
Histogram input(BinEdges(6, LinearGenerator(-0.25, 0.5)), {-2, 0, 0.5, 0, 2});
auto output = interpolateLinear(input, 2);
checkSizesUnchanged(input, output);
std::vector<double> expectedY = {-2., -0.75, 0.5, 1.25, 2.};
checkData(input, output, expectedY, {});
// Inplace
Histogram inOut(input);
TS_ASSERT_THROWS_NOTHING(interpolateLinearInplace(inOut, 2));
checkSizesUnchanged(input, inOut);
checkData(input, inOut, expectedY, {});
}
void test_interpolateLinearEdgeDataSet_Odd_StepSize() {
Histogram input(BinEdges(6, LinearGenerator(-0.25, 0.5)), {-2, 0, 0.0, 0.5, 2});
Histogram output = interpolateLinear(input, 3);
checkSizesUnchanged(input, output);
std::vector<double> expectedY = {-2., -2 + (2.5 / 1.5) * 0.5, -1. / 3., 0.5, 2.};
checkData(input, output, expectedY, {});
// Inplace
Histogram inOut(input);
TS_ASSERT_THROWS_NOTHING(interpolateLinearInplace(inOut, 3));
checkSizesUnchanged(input, inOut);
checkData(input, inOut, expectedY, {});
}
// ---------------------------------------------------------------------------
// Success cases - cspline edge X data
// ---------------------------------------------------------------------------
void test_interpolateCSplineEdgeDataSet_Minimum_Calculated_Points() {
Histogram input(BinEdges(8, LinearGenerator(-0.25, 0.5)), Counts({-3, 0, -1, 0, 1, 0, 3}));
auto output = interpolateCSpline(input, 2);
checkSizesUnchanged(input, output);
std::vector<double> expectedY = {-3, -2, -1, 0, 1, 2, 3};
checkData(input, output, expectedY, {});
// Inplace
Histogram inOut(input);
TS_ASSERT_THROWS_NOTHING(interpolateCSplineInplace(inOut, 2));
checkSizesUnchanged(input, inOut);
checkData(input, inOut, expectedY, {});
}
// ---------------------------------------------------------------------------
// Success cases - Point data with frequencies
// single test case as whitebox testing tells us the algorithm
// is the same
// ---------------------------------------------------------------------------
void test_interpolateLinearPointFrequencyData_Stepsize_One_Less_Point_Size() {
Histogram input(Points(5, LinearGenerator(0., 0.5)), Frequencies({-2, 0, 0, 0, 2}));
auto output = interpolateLinear(input, 4);
checkSizesUnchanged(input, output);
std::vector<double> expectedY = {-2., -1., 0., 1., 2.};
checkData(input, output, expectedY, {});
// Inplace
Histogram inOut(input);
TS_ASSERT_THROWS_NOTHING(interpolateLinearInplace(inOut, 4));
checkSizesUnchanged(input, inOut);
checkData(input, inOut, expectedY, {});
}
// ---------------------------------------------------------------------------
// Common checking code
// ---------------------------------------------------------------------------
void checkSizesUnchanged(const Histogram &input, const Histogram &output) {
TS_ASSERT_EQUALS(input.y().size(), output.y().size());
TS_ASSERT_EQUALS(input.x().size(), output.x().size());
}
void checkData(const Histogram &input, const Histogram &output, const std::vector<double> &expectedY,
const std::vector<double> &expectedE) {
TS_ASSERT_EQUALS(input.x(), output.x());
TS_ASSERT_EQUALS(input.xMode(), output.xMode());
TS_ASSERT_EQUALS(input.yMode(), output.yMode());
const auto &outY = output.y();
const auto &outE = output.e();
if (expectedY.size() > 0) {
TS_ASSERT_EQUALS(outY.size(), expectedY.size());
}
if (expectedE.size() > 0) {
TS_ASSERT_EQUALS(outE.size(), expectedE.size());
}
for (size_t i = 0; i < expectedY.size(); ++i) {
TS_ASSERT_DELTA(expectedY[i], outY[i], 1e-14);
}
for (size_t i = 0; i < expectedE.size(); ++i) {
TS_ASSERT_DELTA(expectedE[i], outE[i], 1e-14);
}
}
// ---------------------------------------------------------------------------
// Failure cases - linear
// ---------------------------------------------------------------------------
void test_interpolatelinear_throws_for_undefined_ymode_type() {
TS_ASSERT_THROWS(interpolateLinear(Histogram(Points(10, LinearGenerator(0, 0.5))), 10), const std::runtime_error &);
}
void test_interpolatelinear_throws_if_number_points_less_than_3() {
TS_ASSERT_THROWS(interpolateLinear(Histogram(Points(2, LinearGenerator(0, 0.5)), {-2, 2}), 1),
const std::runtime_error &);
TS_ASSERT_THROWS(interpolateLinear(Histogram(Points(2, LinearGenerator(0, 0.5))), 1), const std::runtime_error &);
}
void test_interpolatelinearinplace_throws_if_input_has_less_than_2_points() {
Histogram input(Points(1, LinearGenerator(0.1, 0.1)), {-2});
Histogram output(Points(1, LinearGenerator(0.1, 0.1)));
TS_ASSERT_THROWS(interpolateLinearInplace(input, output), const std::runtime_error &)
}
void test_interpolatelinear_throws_if_stepsize_greater_or_equal_number_points() {
TS_ASSERT_THROWS(interpolateLinear(Histogram(Points(6, LinearGenerator(0, 0.5))), 6), const std::runtime_error &);
TS_ASSERT_THROWS(interpolateLinear(Histogram(Points(6, LinearGenerator(0, 0.5))), 7), const std::runtime_error &);
}
void test_interpolateLinearPointDataSet_Errors_Too_Few_Points() {
Histogram input(Points(5, LinearGenerator(0, 0.5)), {-2, 0, 0, 0, 2}, CountStandardDeviations{1., 0., 0., 0., 1.});
TS_ASSERT_THROWS(interpolateLinear(input, 4, true), const std::runtime_error &);
}
// ---------------------------------------------------------------------------
// Failure cases - cspline
// ---------------------------------------------------------------------------
void test_interpolatecspline_throws_for_undefined_ymode_type() {
TS_ASSERT_THROWS(interpolateCSpline(Histogram(Points(10, LinearGenerator(0, 0.5))), 10),
const std::runtime_error &);
}
void test_interpolatecspline_throws_if_less_than_4_calculated_points() {
TS_ASSERT_THROWS(interpolateCSpline(Histogram(Points(2, LinearGenerator(0, 0.5))), 1), const std::runtime_error &);
TS_ASSERT_THROWS(interpolateCSpline(Histogram(Points(3, LinearGenerator(0, 0.5))), 1), const std::runtime_error &);
}
void test_interpolatecsplineinplace_throws_if_input_has_less_than_3_points() {
Histogram input(Points(2, LinearGenerator(0, 1.0)));
Histogram output(Points(5, LinearGenerator(0.1, 0.1)));
TS_ASSERT_THROWS(interpolateCSplineInplace(input, output), const std::runtime_error &)
}
void test_interpolatecspline_throws_if_stepsize_greater_or_equal_number_points() {
TS_ASSERT_THROWS(interpolateCSpline(Histogram(Points(6, LinearGenerator(0, 0.5))), 6), const std::runtime_error &);
TS_ASSERT_THROWS(interpolateCSpline(Histogram(Points(6, LinearGenerator(0, 0.5))), 7), const std::runtime_error &);
}
};
// ---------------------------------------------------------------------------
// Performance test
// ---------------------------------------------------------------------------
class InterpolateTestPerformance : public CxxTest::TestSuite {
public:
// This pair of boilerplate methods prevent the suite being created statically
// This means the constructor isn't called when running other tests
static InterpolateTestPerformance *createSuite() { return new InterpolateTestPerformance(); }
static void destroySuite(InterpolateTestPerformance *suite) { delete suite; }
InterpolateTestPerformance() : hist(BinEdges(binSize, LinearGenerator(0, 1))) {
Counts counts(binSize - 1, LinearGenerator(10, 0.1));
hist.setCounts(counts);
CountStandardDeviations errors(binSize - 1, LinearGenerator(10, 0.1));
hist.setCountStandardDeviations(errors);
}
void testInterpolateLinearSmallStep() {
for (size_t i = 0; i < nIters; i++)
interpolateLinear(hist, 2);
}
void testInterpolateSplineSmallStep() {
for (size_t i = 0; i < nIters; i++)
interpolateCSpline(hist, 2);
}
private:
const size_t binSize = 10000;
const size_t nIters = 5000;
Histogram hist;
};