PrusaSlicer-NonPlainar/tests/libslic3r/test_optimizers.cpp

#include <catch2/catch.hpp>
#include <test_utils.hpp>

#include <libslic3r/Optimize/BruteforceOptimizer.hpp>

#include <libslic3r/Optimize/NLoptOptimizer.hpp>

void check_opt_result(double score, double ref, double abs_err, double rel_err)
{
    double abs_diff = std::abs(score - ref);
    double rel_diff = std::abs(abs_diff / std::abs(ref));

    bool abs_reached = abs_diff < abs_err;
    bool rel_reached = rel_diff < rel_err;
    bool precision_reached = abs_reached || rel_reached;
    REQUIRE(precision_reached);
}

template<class Opt> void test_sin(Opt &&opt)
{
    using namespace Slic3r::opt;

    auto optfunc = [](const auto &in) {
        auto [phi] = in;

        return std::sin(phi);
    };

    auto init = initvals({PI});
    auto optbounds = bounds({ {0., 2 * PI}});

    Result result_min = opt.to_min().optimize(optfunc, init, optbounds);
    Result result_max = opt.to_max().optimize(optfunc, init, optbounds);

    check_opt_result(result_min.score, -1., 1e-2, 1e-4);
    check_opt_result(result_max.score,  1., 1e-2, 1e-4);
}

template<class Opt> void test_sphere_func(Opt &&opt)
{
    using namespace Slic3r::opt;

    Result result = opt.to_min().optimize([](const auto &in) {
        auto [x, y] = in;

        return x * x + y * y + 1.;
    }, initvals({.6, -0.2}), bounds({{-1., 1.}, {-1., 1.}}));

    check_opt_result(result.score, 1., 1e-2, 1e-4);
}

TEST_CASE("Test brute force optimzer for basic 1D and 2D functions", "[Opt]") {
    using namespace Slic3r::opt;

    Optimizer<AlgBruteForce> opt;

    test_sin(opt);
    test_sphere_func(opt);
}
fixing optimizer and concurrency::reduce 2020-08-31 16:53:44 +00:00			`#include <catch2/catch.hpp>`
			`#include <test_utils.hpp>`

			`#include <libslic3r/Optimize/BruteforceOptimizer.hpp>`

			`#include <libslic3r/Optimize/NLoptOptimizer.hpp>`

			`void check_opt_result(double score, double ref, double abs_err, double rel_err)`
			`{`
			`double abs_diff = std::abs(score - ref);`
			`double rel_diff = std::abs(abs_diff / std::abs(ref));`

			`bool abs_reached = abs_diff < abs_err;`
			`bool rel_reached = rel_diff < rel_err;`
			`bool precision_reached = abs_reached \|\| rel_reached;`
			`REQUIRE(precision_reached);`
			`}`

			`template<class Opt> void test_sin(Opt &&opt)`
			`{`
			`using namespace Slic3r::opt;`

			`auto optfunc = [](const auto &in) {`
			`auto [phi] = in;`

			`return std::sin(phi);`
			`};`

			`auto init = initvals({PI});`
			`auto optbounds = bounds({ {0., 2 * PI}});`

			`Result result_min = opt.to_min().optimize(optfunc, init, optbounds);`
			`Result result_max = opt.to_max().optimize(optfunc, init, optbounds);`

			`check_opt_result(result_min.score, -1., 1e-2, 1e-4);`
			`check_opt_result(result_max.score, 1., 1e-2, 1e-4);`
			`}`

			`template<class Opt> void test_sphere_func(Opt &&opt)`
			`{`
			`using namespace Slic3r::opt;`

			`Result result = opt.to_min().optimize([](const auto &in) {`
			`auto [x, y] = in;`

			`return x * x + y * y + 1.;`
			`}, initvals({.6, -0.2}), bounds({{-1., 1.}, {-1., 1.}}));`

			`check_opt_result(result.score, 1., 1e-2, 1e-4);`
			`}`

			`TEST_CASE("Test brute force optimzer for basic 1D and 2D functions", "[Opt]") {`
			`using namespace Slic3r::opt;`

			`Optimizer<AlgBruteForce> opt;`

			`test_sin(opt);`
			`test_sphere_func(opt);`
			`}`