xref: /aosp_15_r20/external/eigen/unsupported/test/NumericalDiff.cpp (revision bf2c37156dfe67e5dfebd6d394bad8b2ab5804d4) 
1*bf2c3715SXin Li // This file is part of Eigen, a lightweight C++ template library
2*bf2c3715SXin Li // for linear algebra.
3*bf2c3715SXin Li //
4*bf2c3715SXin Li // Copyright (C) 2009 Thomas Capricelli <[email protected]>
5*bf2c3715SXin Li 
6*bf2c3715SXin Li #include <stdio.h>
7*bf2c3715SXin Li 
8*bf2c3715SXin Li #include "main.h"
9*bf2c3715SXin Li #include <unsupported/Eigen/NumericalDiff>
10*bf2c3715SXin Li 
11*bf2c3715SXin Li // Generic functor
12*bf2c3715SXin Li template<typename _Scalar, int NX=Dynamic, int NY=Dynamic>
13*bf2c3715SXin Li struct Functor
14*bf2c3715SXin Li {
15*bf2c3715SXin Li   typedef _Scalar Scalar;
16*bf2c3715SXin Li   enum {
17*bf2c3715SXin Li     InputsAtCompileTime = NX,
18*bf2c3715SXin Li     ValuesAtCompileTime = NY
19*bf2c3715SXin Li   };
20*bf2c3715SXin Li   typedef Matrix<Scalar,InputsAtCompileTime,1> InputType;
21*bf2c3715SXin Li   typedef Matrix<Scalar,ValuesAtCompileTime,1> ValueType;
22*bf2c3715SXin Li   typedef Matrix<Scalar,ValuesAtCompileTime,InputsAtCompileTime> JacobianType;
23*bf2c3715SXin Li 
24*bf2c3715SXin Li   int m_inputs, m_values;
25*bf2c3715SXin Li 
FunctorFunctor26*bf2c3715SXin Li   Functor() : m_inputs(InputsAtCompileTime), m_values(ValuesAtCompileTime) {}
FunctorFunctor27*bf2c3715SXin Li   Functor(int inputs_, int values_) : m_inputs(inputs_), m_values(values_) {}
28*bf2c3715SXin Li 
inputsFunctor29*bf2c3715SXin Li   int inputs() const { return m_inputs; }
valuesFunctor30*bf2c3715SXin Li   int values() const { return m_values; }
31*bf2c3715SXin Li 
32*bf2c3715SXin Li };
33*bf2c3715SXin Li 
34*bf2c3715SXin Li struct my_functor : Functor<double>
35*bf2c3715SXin Li {
my_functormy_functor36*bf2c3715SXin Li     my_functor(void): Functor<double>(3,15) {}
operator ()my_functor37*bf2c3715SXin Li     int operator()(const VectorXd &x, VectorXd &fvec) const
38*bf2c3715SXin Li     {
39*bf2c3715SXin Li         double tmp1, tmp2, tmp3;
40*bf2c3715SXin Li         double y[15] = {1.4e-1, 1.8e-1, 2.2e-1, 2.5e-1, 2.9e-1, 3.2e-1, 3.5e-1,
41*bf2c3715SXin Li             3.9e-1, 3.7e-1, 5.8e-1, 7.3e-1, 9.6e-1, 1.34, 2.1, 4.39};
42*bf2c3715SXin Li 
43*bf2c3715SXin Li         for (int i = 0; i < values(); i++)
44*bf2c3715SXin Li         {
45*bf2c3715SXin Li             tmp1 = i+1;
46*bf2c3715SXin Li             tmp2 = 16 - i - 1;
47*bf2c3715SXin Li             tmp3 = (i>=8)? tmp2 : tmp1;
48*bf2c3715SXin Li             fvec[i] = y[i] - (x[0] + tmp1/(x[1]*tmp2 + x[2]*tmp3));
49*bf2c3715SXin Li         }
50*bf2c3715SXin Li         return 0;
51*bf2c3715SXin Li     }
52*bf2c3715SXin Li 
actual_dfmy_functor53*bf2c3715SXin Li     int actual_df(const VectorXd &x, MatrixXd &fjac) const
54*bf2c3715SXin Li     {
55*bf2c3715SXin Li         double tmp1, tmp2, tmp3, tmp4;
56*bf2c3715SXin Li         for (int i = 0; i < values(); i++)
57*bf2c3715SXin Li         {
58*bf2c3715SXin Li             tmp1 = i+1;
59*bf2c3715SXin Li             tmp2 = 16 - i - 1;
60*bf2c3715SXin Li             tmp3 = (i>=8)? tmp2 : tmp1;
61*bf2c3715SXin Li             tmp4 = (x[1]*tmp2 + x[2]*tmp3); tmp4 = tmp4*tmp4;
62*bf2c3715SXin Li             fjac(i,0) = -1;
63*bf2c3715SXin Li             fjac(i,1) = tmp1*tmp2/tmp4;
64*bf2c3715SXin Li             fjac(i,2) = tmp1*tmp3/tmp4;
65*bf2c3715SXin Li         }
66*bf2c3715SXin Li         return 0;
67*bf2c3715SXin Li     }
68*bf2c3715SXin Li };
69*bf2c3715SXin Li 
test_forward()70*bf2c3715SXin Li void test_forward()
71*bf2c3715SXin Li {
72*bf2c3715SXin Li     VectorXd x(3);
73*bf2c3715SXin Li     MatrixXd jac(15,3);
74*bf2c3715SXin Li     MatrixXd actual_jac(15,3);
75*bf2c3715SXin Li     my_functor functor;
76*bf2c3715SXin Li 
77*bf2c3715SXin Li     x << 0.082, 1.13, 2.35;
78*bf2c3715SXin Li 
79*bf2c3715SXin Li     // real one
80*bf2c3715SXin Li     functor.actual_df(x, actual_jac);
81*bf2c3715SXin Li //    std::cout << actual_jac << std::endl << std::endl;
82*bf2c3715SXin Li 
83*bf2c3715SXin Li     // using NumericalDiff
84*bf2c3715SXin Li     NumericalDiff<my_functor> numDiff(functor);
85*bf2c3715SXin Li     numDiff.df(x, jac);
86*bf2c3715SXin Li //    std::cout << jac << std::endl;
87*bf2c3715SXin Li 
88*bf2c3715SXin Li     VERIFY_IS_APPROX(jac, actual_jac);
89*bf2c3715SXin Li }
90*bf2c3715SXin Li 
test_central()91*bf2c3715SXin Li void test_central()
92*bf2c3715SXin Li {
93*bf2c3715SXin Li     VectorXd x(3);
94*bf2c3715SXin Li     MatrixXd jac(15,3);
95*bf2c3715SXin Li     MatrixXd actual_jac(15,3);
96*bf2c3715SXin Li     my_functor functor;
97*bf2c3715SXin Li 
98*bf2c3715SXin Li     x << 0.082, 1.13, 2.35;
99*bf2c3715SXin Li 
100*bf2c3715SXin Li     // real one
101*bf2c3715SXin Li     functor.actual_df(x, actual_jac);
102*bf2c3715SXin Li 
103*bf2c3715SXin Li     // using NumericalDiff
104*bf2c3715SXin Li     NumericalDiff<my_functor,Central> numDiff(functor);
105*bf2c3715SXin Li     numDiff.df(x, jac);
106*bf2c3715SXin Li 
107*bf2c3715SXin Li     VERIFY_IS_APPROX(jac, actual_jac);
108*bf2c3715SXin Li }
109*bf2c3715SXin Li 
EIGEN_DECLARE_TEST(NumericalDiff)110*bf2c3715SXin Li EIGEN_DECLARE_TEST(NumericalDiff)
111*bf2c3715SXin Li {
112*bf2c3715SXin Li     CALL_SUBTEST(test_forward());
113*bf2c3715SXin Li     CALL_SUBTEST(test_central());
114*bf2c3715SXin Li }
115