add blts
This commit is contained in:
@@ -6,8 +6,11 @@ set(CMAKE_CXX_STANDARD 23)
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add_compile_options(-Wall -Werror -Wpedantic)
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find_package(Eigen3 REQUIRED)
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add_library(autoopt INTERFACE)
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target_include_directories(autoopt INTERFACE include)
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target_link_libraries(autoopt INTERFACE Eigen3::Eigen)
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install(DIRECTORY include/autoopt DESTINATION include)
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@@ -22,6 +22,7 @@
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cmake,
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ninja,
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lib,
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eigen,
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gtest,
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withTests ? false,
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}:
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@@ -46,6 +47,7 @@
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nativeBuildInputs = [
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cmake
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ninja
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eigen
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];
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};
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in
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@@ -0,0 +1,49 @@
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#pragma once
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#include <iostream>
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#include "autoopt/optimization_problem.hpp"
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namespace autoopt {
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template <typename T>
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struct btls_parameters {
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T step_decrease = T{0.5};
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T step_increase = T{1.5};
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T sufficient_decrease = T{1e-2};
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T tolerance = T{1e-9};
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size_t max_iters = 1000;
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};
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template <typename T>
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void btls(optimization_problem<T>& problem,
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const btls_parameters<T>& params = btls_parameters<T>()) {
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Eigen::VectorX<T>& x = problem.x();
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T step_size = T{1.0};
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for (size_t iter = 0; iter < params.max_iters; ++iter) {
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T obj_value = problem.objective(x);
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std::cout << "Iter " << iter << ": obj = " << obj_value
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<< ", x = " << x.transpose() << ", step_size = " << step_size
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<< std::endl;
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Eigen::VectorX<T> grad = -problem.gradient(x);
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Eigen::VectorX<T> step_dir = grad.normalized();
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while (problem.objective(x + step_size * step_dir) >
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obj_value +
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params.sufficient_decrease * step_size * grad.dot(step_dir)) {
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step_size *= params.step_decrease;
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}
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x += step_size * step_dir;
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if (step_size < params.tolerance) {
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break;
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}
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}
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problem.x() = x;
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}
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} // namespace autoopt
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@@ -1,6 +1,6 @@
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#pragma once
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#include <array>
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#include <Eigen/Eigen>
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#include "autoopt/dual.hpp"
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@@ -13,49 +13,46 @@ T derivative(Func&& f, const T& x) {
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return b._dx;
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}
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template <typename T, std::size_t N, class Func>
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std::array<T, N> gradient(Func&& f, const std::array<T, N>& x) {
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std::array<T, N> grad{};
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std::array<dual<T>, N> dual_x{};
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for (std::size_t i = 0; i < N; ++i) {
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dual_x[i] = dual<T>(x[i], T(0));
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template <typename T, class Func>
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Eigen::VectorX<T> gradient(Func&& f, const Eigen::VectorX<T>& x) {
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Eigen::VectorX<T> grad{x.size()};
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Eigen::VectorX<dual<T>> dual_x{x.size()};
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for (int i = 0; i < x.size(); ++i) {
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dual_x(i) = dual<T>(x(i), T(0));
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}
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for (std::size_t i = 0; i < N; ++i) {
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dual_x[i]._dx = T(1);
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for (int i = 0; i < x.size(); ++i) {
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dual_x(i)._dx = T(1);
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dual<T> dual_y = f(dual_x);
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grad[i] = dual_y._dx;
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dual_x[i]._dx = T(0);
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grad(i) = dual_y._dx;
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dual_x(i)._dx = T(0);
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}
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return grad;
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}
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template <typename T, std::size_t N, std::size_t M>
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using matrix_t = std::array<std::array<T, M>, N>;
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template <typename T, std::size_t N, std::size_t M, class Func>
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matrix_t<T, M, N> jacobian(Func&& f, const std::array<T, N>& x) {
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matrix_t<T, M, N> jacob{};
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std::array<dual<T>, N> dual_x{};
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for (std::size_t i = 0; i < N; ++i) {
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dual_x[i] = dual<T>(x[i], T(0));
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template <typename T, class Func>
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Eigen::MatrixX<T> jacobian(Func&& f, const Eigen::VectorX<T>& x) {
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Eigen::MatrixX<T> jacob(f(x).size(), x.size());
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Eigen::VectorX<dual<T>> dual_x(x.size());
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for (int i = 0; i < x.size(); ++i) {
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dual_x(i) = dual<T>(x(i), T(0));
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}
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for (std::size_t i = 0; i < N; ++i) {
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dual_x[i]._dx = T(1);
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std::array<dual<T>, M> dual_y = f(dual_x);
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for (std::size_t j = 0; j < M; ++j) {
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jacob[j][i] = dual_y[j]._dx;
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for (int i = 0; i < x.size(); ++i) {
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dual_x(i)._dx = T(1);
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Eigen::VectorX<dual<T>> dual_y = f(dual_x);
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for (int j = 0; j < dual_y.size(); ++j) {
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jacob(j, i) = dual_y(j)._dx;
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}
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dual_x[i]._dx = T(0);
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dual_x(i)._dx = T(0);
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}
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return jacob;
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}
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template <typename T, std::size_t N, class Func>
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matrix_t<T, N, N> hessian(Func&& f, const std::array<T, N>& x) {
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auto helper_func = [&f]<typename U>(const std::array<U, N>& y) {
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return gradient<U, N>(f, y);
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template <typename T, class Func>
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Eigen::MatrixX<T> hessian(Func&& f, const Eigen::VectorX<T>& x) {
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auto helper_func = [&f]<typename U>(const Eigen::VectorX<U>& y) {
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return gradient<U>(f, y);
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};
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return jacobian<T, N, N>(helper_func, x);
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return jacobian<T>(helper_func, x);
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}
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} // namespace autoopt
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@@ -1,108 +1,109 @@
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#pragma once
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#include <array>
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#include <cstddef>
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#include "autoopt/derivative.hpp"
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namespace autoopt {
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template <typename T, size_t N>
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template <typename T>
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struct optimization_problem {
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virtual std::array<T, N> initial_guess() = 0;
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virtual Eigen::VectorX<T>& initial_guess() = 0;
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virtual Eigen::VectorX<T>& x() = 0;
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virtual T objective(const std::array<T, N>& params) = 0;
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virtual std::array<T, N> gradient(const std::array<T, N>& params) = 0;
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virtual matrix_t<T, N, N> hessian(const std::array<T, N>& params) = 0;
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virtual T objective(const Eigen::VectorX<T>& params) = 0;
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virtual Eigen::VectorX<T> gradient(const Eigen::VectorX<T>& params) = 0;
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virtual Eigen::MatrixX<T> hessian(const Eigen::VectorX<T>& params) = 0;
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};
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template <typename T, size_t N, class Func>
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struct auto_diff_optimization_problem : public optimization_problem<T, N> {
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template <typename T, class Func>
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struct auto_diff_optimization_problem : public optimization_problem<T> {
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Func _objective_func;
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std::array<T, N> _initial_guess;
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Eigen::VectorX<T> _initial_guess;
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Eigen::VectorX<T> _x;
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auto_diff_optimization_problem(
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Func objective_func, std::array<T, N> initial_guess = std::array<T, N>{})
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: _objective_func(objective_func), _initial_guess(initial_guess) {}
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Func objective_func, Eigen::VectorX<T> initial_guess = Eigen::VectorX<T>{})
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: _objective_func(objective_func), _initial_guess(initial_guess), _x(initial_guess) {}
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std::array<T, N> initial_guess() override { return _initial_guess; }
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Eigen::VectorX<T>& initial_guess() override { return _initial_guess; }
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T objective(const std::array<T, N>& params) override {
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Eigen::VectorX<T>& x() override { return _x; }
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T objective(const Eigen::VectorX<T>& params) override {
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return _objective_func(params);
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}
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std::array<T, N> gradient(const std::array<T, N>& params) override {
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return autoopt::gradient<T, N>(_objective_func, params);
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Eigen::VectorX<T> gradient(const Eigen::VectorX<T>& params) override {
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return autoopt::gradient<T>(_objective_func, params);
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}
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matrix_t<T, N, N> hessian(const std::array<T, N>& params) override {
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return autoopt::hessian<T, N>(_objective_func, params);
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Eigen::MatrixX<T> hessian(const Eigen::VectorX<T>& params) override {
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return autoopt::hessian<T>(_objective_func, params);
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}
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};
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template <typename T, size_t N>
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template <typename T>
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struct log_barrier_optimization_problem
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: public optimization_problem<T, N> {
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optimization_problem<T, N>& _base_problem;
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std::array<T, N> _delta;
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: public optimization_problem<T> {
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optimization_problem<T>& _base_problem;
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Eigen::VectorX<T> _delta;
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T _barrier_strength;
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log_barrier_optimization_problem(
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optimization_problem<T, N>& base_problem,
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std::array<T, N> delta,
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optimization_problem<T>& base_problem,
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Eigen::VectorX<T> delta,
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T barrier_strength = T{1e-3})
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: _base_problem(base_problem),
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_delta(delta),
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_barrier_strength(barrier_strength) {}
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std::array<T, N> initial_guess() override {
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Eigen::VectorX<T>& initial_guess() override {
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return _base_problem.initial_guess();
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}
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T objective(const std::array<T, N>& params) override {
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Eigen::VectorX<T>& x() override {
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return _base_problem.x();
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}
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T objective(const Eigen::VectorX<T>& params) override {
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T base_obj = _base_problem.objective(params);
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T barrier = barrier_term(params);
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return base_obj + barrier;
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}
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std::array<T, N> gradient(const std::array<T, N>& params) override {
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Eigen::VectorX<T> gradient(const Eigen::VectorX<T>& params) override {
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auto base_grad = _base_problem.gradient(params);
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std::array<T, N> barrier_grad = autoopt::gradient<T, N>(
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[this]<typename U>(const std::array<U, N>& p) {
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Eigen::VectorX<T> barrier_grad = autoopt::gradient<T>(
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[this]<typename U>(const Eigen::VectorX<U>& p) {
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return barrier_term<U>(p);
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},
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params);
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std::array<T, N> total_grad;
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for (size_t i = 0; i < N; ++i) {
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total_grad[i] = base_grad[i] + barrier_grad[i];
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}
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Eigen::VectorX<T> total_grad(params.size());
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total_grad = base_grad + barrier_grad;
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return total_grad;
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}
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matrix_t<T, N, N> hessian(const std::array<T, N>& params) override {
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Eigen::MatrixX<T> hessian(const Eigen::VectorX<T>& params) override {
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auto base_hess = _base_problem.hessian(params);
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matrix_t<T, N, N> barrier_hess = autoopt::hessian<T, N>(
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[this]<typename U>(const std::array<U, N>& p) {
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Eigen::MatrixX<T> barrier_hess = autoopt::hessian<T>(
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[this]<typename U>(const Eigen::VectorX<U>& p) {
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return barrier_term<U>(p);
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},
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params);
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matrix_t<T, N, N> total_hess;
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for (size_t i = 0; i < N; ++i) {
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for (size_t j = 0; j < N; ++j) {
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total_hess[i][j] = base_hess[i][j] + barrier_hess[i][j];
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}
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}
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Eigen::MatrixX<T> total_hess(params.size(), params.size());
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total_hess = base_hess + barrier_hess;
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return total_hess;
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}
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private:
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template <typename U>
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U barrier_term(const std::array<U, N>& params) {
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U barrier_term(const Eigen::VectorX<U>& params) {
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U barrier = U{0};
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for (size_t i = 0; i < N; ++i) {
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U lb = _base_problem.initial_guess()[i] - _delta[i];
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U ub = _base_problem.initial_guess()[i] + _delta[i];
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barrier = barrier + std::log(params[i] - lb) + std::log(ub - params[i]);
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for (int i = 0; i < params.size(); ++i) {
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U lb = U{_base_problem.initial_guess()(i) - _delta(i)};
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U ub = U{_base_problem.initial_guess()(i) + _delta(i)};
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barrier = barrier + std::log(params(i) - lb) + std::log(ub - params(i));
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}
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return -U{_barrier_strength} * barrier;
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}
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+42
-36
@@ -50,58 +50,63 @@ TEST(DualTest, DerivativeFunction) {
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}
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TEST(DualTest, GradientFunction) {
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auto func = []<typename T>(const std::array<T, 2>& x) {
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return x[0] * x[0] + std::sin(x[1]);
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auto func = []<typename T>(const Eigen::VectorX<T>& x) {
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return x(0) * x(0) + std::sin(x(1));
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};
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std::array<double, 2> point = {1.0, 0.0};
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std::array<double, 2> grad = gradient(func, point);
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Eigen::VectorX<double> point(2);
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point << 1.0, 0.0;
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Eigen::VectorX<double> grad = gradient(func, point);
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EXPECT_DOUBLE_EQ(grad[0], 2.0 * point[0]); // d/dx1
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EXPECT_DOUBLE_EQ(grad[1], std::cos(point[1])); // d/dx2
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EXPECT_DOUBLE_EQ(grad(0), 2.0 * point(0)); // d/dx1
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EXPECT_DOUBLE_EQ(grad(1), std::cos(point(1))); // d/dx2
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}
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TEST(DualTest, JacobianFunction) {
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auto func = []<typename T>(const std::array<T, 2>& x) {
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return std::array<T, 2>{x[0] * x[0], std::sin(x[1])};
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auto func = []<typename T>(const Eigen::VectorX<T>& x) {
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Eigen::VectorX<T> y(2);
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y << x(0) * x(0), std::sin(x(1));
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return y;
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};
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std::array<double, 2> point = {1.0, 0.0};
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auto jacob = jacobian<double, 2, 2>(func, point);
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Eigen::VectorX<double> point(2);
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point << 1.0, 0.0;
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auto jacob = jacobian<double>(func, point);
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EXPECT_DOUBLE_EQ(jacob[0][0], 2.0 * point[0]); // d(f1)/d(x1)
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EXPECT_DOUBLE_EQ(jacob[0][1], 0.0); // d(f1)/d(x2)
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EXPECT_DOUBLE_EQ(jacob[1][0], 0.0); // d(f2)/d(x1)
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EXPECT_DOUBLE_EQ(jacob[1][1], std::cos(point[1])); // d(f2)/d(x2)
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EXPECT_DOUBLE_EQ(jacob(0, 0), 2.0 * point(0)); // d(f1)/d(x1)
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EXPECT_DOUBLE_EQ(jacob(0, 1), 0.0); // d(f1)/d(x2)
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EXPECT_DOUBLE_EQ(jacob(1, 0), 0.0); // d(f2)/d(x1)
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EXPECT_DOUBLE_EQ(jacob(1, 1), std::cos(point(1))); // d(f2)/d(x2)
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}
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TEST(DualTest, HessianFunction) {
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auto func = []<typename T>(const std::array<T, 2>& x) {
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return x[0] * x[0] + x[1] * x[1];
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auto func = []<typename T>(const Eigen::VectorX<T>& x) {
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return x(0) * x(0) + x(1) * x(1);
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};
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std::array<double, 2> point = {1.0, 2.0};
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auto hess = hessian<double, 2>(func, point);
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Eigen::VectorX<double> point(2);
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point << 1.0, 2.0;
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auto hess = hessian<double>(func, point);
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EXPECT_DOUBLE_EQ(hess[0][0], 2.0); // d²f/dx1²
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EXPECT_DOUBLE_EQ(hess[0][1], 0.0); // d²f/dx1dx2
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EXPECT_DOUBLE_EQ(hess[1][0], 0.0); // d²f/dx2dx1
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EXPECT_DOUBLE_EQ(hess[1][1], 2.0); // d²f/dx2²
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EXPECT_DOUBLE_EQ(hess(0, 0), 2.0); // d²f/dx1²
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EXPECT_DOUBLE_EQ(hess(0, 1), 0.0); // d²f/dx1dx2
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EXPECT_DOUBLE_EQ(hess(1, 0), 0.0); // d²f/dx2dx1
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EXPECT_DOUBLE_EQ(hess(1, 1), 2.0); // d²f/dx2²
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}
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struct opti_func {
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std::vector<std::array<double, 2>> test_data;
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std::vector<Eigen::Vector2<double>> test_data;
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// loss function
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template <typename T>
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T operator()(const std::array<T, 3>& params) const {
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T operator()(const Eigen::VectorX<T>& params) const {
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T sum = T(0);
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for (const auto& data_point : test_data) {
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T x = T{data_point[0]};
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T y_true = T{data_point[1]};
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T a = params[0];
|
||||
T b = params[1];
|
||||
T c = params[2];
|
||||
T x = T{data_point(0)};
|
||||
T y_true = T{data_point(1)};
|
||||
T a = params(0);
|
||||
T b = params(1);
|
||||
T c = params(2);
|
||||
T y_pred = a * x * x + b * x + c;
|
||||
T error = y_pred - y_true;
|
||||
sum = sum + error * error;
|
||||
@@ -120,18 +125,19 @@ TEST(DualTest, OptimizationFunction) {
|
||||
{4.0, 4.0},
|
||||
};
|
||||
|
||||
std::array<double, 3> params = {1.0, -4.0, 4.0};
|
||||
Eigen::VectorX<double> params(3);
|
||||
params << 1.0, -4.0, 4.0;
|
||||
|
||||
auto grad = gradient<double, 3>(f, params);
|
||||
auto grad = gradient<double>(f, params);
|
||||
|
||||
EXPECT_DOUBLE_EQ(grad[0], 0.0); // dL/da
|
||||
EXPECT_DOUBLE_EQ(grad[1], 0.0); // dL/db
|
||||
EXPECT_DOUBLE_EQ(grad[2], 0.0); // dL/dc
|
||||
EXPECT_DOUBLE_EQ(grad(0), 0.0); // dL/da
|
||||
EXPECT_DOUBLE_EQ(grad(1), 0.0); // dL/db
|
||||
EXPECT_DOUBLE_EQ(grad(2), 0.0); // dL/dc
|
||||
|
||||
auto hess = hessian<double, 3>(f, params);
|
||||
auto hess = hessian<double>(f, params);
|
||||
for (std::size_t i = 0; i < 3; ++i) {
|
||||
for (std::size_t j = 0; j < 3; ++j) {
|
||||
EXPECT_GE(hess[i][j], 0.0); // Hessian should be positive semi-definite
|
||||
EXPECT_GE(hess(i, j), 0.0); // Hessian should be positive semi-definite
|
||||
}
|
||||
}
|
||||
}
|
||||
|
||||
+24
-30
@@ -3,6 +3,7 @@
|
||||
#include <autoopt/ellipse.hpp>
|
||||
#include <autoopt/optimization_problem.hpp>
|
||||
#include <autoopt/util.hpp>
|
||||
#include <autoopt/btls.hpp>
|
||||
#include <iomanip>
|
||||
#include <iostream>
|
||||
|
||||
@@ -21,11 +22,12 @@ TEST(Ellipse, ParamGradient) {
|
||||
std::vector<std::pair<double, double>> data_points = {
|
||||
{-10.0, -0.001}, {0.0, 0.0}, {10, 0.0009}};
|
||||
|
||||
std::array<double, 4> params = {100, 1000, deg2rad(1.0), 0.0};
|
||||
Eigen::VectorX<double> params(4);
|
||||
params << 100, 1000, deg2rad(1.0), 0.0;
|
||||
|
||||
auto loss_func = [&data_points]<typename T>(const std::array<T, 4>& p) {
|
||||
ellipse<T> e{T{p[0]}, T{p[1]}, T{p[2]}};
|
||||
quadric<T> q = e.to_quadric().rotated_by(T{p[3]});
|
||||
auto loss_func = [&data_points]<typename T>(const Eigen::VectorX<T>& p) {
|
||||
ellipse<T> e{T{p(0)}, T{p(1)}, T{p(2)}};
|
||||
quadric<T> q = e.to_quadric().rotated_by(T{p(3)});
|
||||
T loss = T{0};
|
||||
for (const auto& [x, y_true] : data_points) {
|
||||
T y_pred = q.slope_at(T{x});
|
||||
@@ -35,44 +37,36 @@ TEST(Ellipse, ParamGradient) {
|
||||
return loss / T(data_points.size());
|
||||
};
|
||||
|
||||
auto_diff_optimization_problem<double, 4, decltype(loss_func)> problem(loss_func, params);
|
||||
auto_diff_optimization_problem<double, decltype(loss_func)> problem(loss_func, params);
|
||||
|
||||
auto grad = problem.gradient(params);
|
||||
EXPECT_NEAR(grad[0], -2.0789313126683308e-10, 1e-15); // d/d(left_arm)
|
||||
EXPECT_NEAR(grad[1], -1.7464984353858657e-12, 1e-15); // d/d(right_arm)
|
||||
EXPECT_NEAR(grad[2], 1.2013025455499119e-06, 1e-15); // d/d(entrance_angle)
|
||||
EXPECT_NEAR(grad[3], -2.0332702665822054e-05, 1e-15); // d/d(rotation_angle)
|
||||
|
||||
std::cout << "Gradient:\n";
|
||||
for (size_t i = 0; i < 4; ++i) {
|
||||
std::cout << grad[i] << "\n";
|
||||
}
|
||||
std::cout << grad << std::endl;
|
||||
|
||||
EXPECT_NEAR(grad(0), -2.0789313126683308e-10, 1e-15); // d/d(left_arm)
|
||||
EXPECT_NEAR(grad(1), -1.7464984353858657e-12, 1e-15); // d/d(right_arm)
|
||||
EXPECT_NEAR(grad(2), 1.2013025455499119e-06, 1e-15); // d/d(entrance_angle)
|
||||
EXPECT_NEAR(grad(3), -2.0332702665822054e-05, 1e-15); // d/d(rotation_angle)
|
||||
|
||||
auto hess = problem.hessian(params);
|
||||
|
||||
// set formatting for easier reading
|
||||
std::cout << std::scientific;
|
||||
// set field width for alignment
|
||||
std::cout << "Hessian matrix:\n";
|
||||
std::cout << hess << std::endl;
|
||||
|
||||
for (size_t i = 0; i < 4; ++i) {
|
||||
;
|
||||
for (size_t j = 0; j < 4; ++j) {
|
||||
std::cout << std::setprecision(5) << std::setw(15) << hess[i][j];
|
||||
}
|
||||
std::cout << "\n";
|
||||
}
|
||||
Eigen::VectorX<double> params_delta(4);
|
||||
params_delta << 1.0, 1.0, deg2rad(0.1), deg2rad(0.1);
|
||||
|
||||
params(0) += 0.9; // left_arm
|
||||
|
||||
// log barrier
|
||||
log_barrier_optimization_problem<double, 4> log_barrier_problem(
|
||||
log_barrier_optimization_problem<double> log_barrier_problem(
|
||||
problem,
|
||||
{1.0, 1.0, deg2rad(0.1), deg2rad(0.1)},
|
||||
params_delta,
|
||||
1e-3);
|
||||
|
||||
auto log_barrier_grad = log_barrier_problem.gradient(params);
|
||||
|
||||
std::cout << "Log Barrier Gradient:\n";
|
||||
for (size_t i = 0; i < 4; ++i) {
|
||||
std::cout << log_barrier_grad[i] << "\n";
|
||||
}
|
||||
std::cout << "Log barrier gradient:" << std::endl;
|
||||
std::cout << log_barrier_grad << std::endl;
|
||||
|
||||
btls(problem);
|
||||
}
|
||||
Reference in New Issue
Block a user