// Ceres Solver - A fast non-linear least squares minimizer
// Copyright 2023 Google Inc. All rights reserved.
// http://ceres-solver.org/
//
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// modification, are permitted provided that the following conditions are met:
//
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//
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// Author: sameeragarwal@google.com (Sameer Agarwal)
#include <cmath>
#include <limits>
#include <memory>
#include "ceres/dynamic_numeric_diff_cost_function.h"
#include "ceres/internal/eigen.h"
#include "ceres/manifold.h"
#include "ceres/numeric_diff_options.h"
#include "ceres/types.h"
#include "gmock/gmock.h"
#include "gtest/gtest.h"
namespace ceres {
// Matchers and macros to simplify testing of custom Manifold objects using the
// gtest testing framework.
//
// Testing a Manifold has two parts.
//
// 1. Checking that Manifold::Plus() and Manifold::Minus() are correctly
// defined. This requires per manifold tests.
//
// 2. The other methods of the manifold have mathematical properties that make
// them compatible with Plus() and Minus(), as described in [1].
//
// To verify these general requirements for a custom Manifold, use the
// EXPECT_THAT_MANIFOLD_INVARIANTS_HOLD() macro from within a gtest test. Note
// that additional domain-specific tests may also be prudent, e.g to verify the
// behaviour of a Quaternion Manifold about pi.
//
// [1] "Integrating Generic Sensor Fusion Algorithms with Sound State
// Representations through Encapsulation of Manifolds", C. Hertzberg,
// R. Wagner, U. Frese and L. Schroder, https://arxiv.org/pdf/1107.1119.pdf
// Verifies the general requirements for a custom Manifold are satisfied to
// within the specified (numerical) tolerance.
//
// Example usage for a custom Manifold: ExampleManifold:
//
// TEST(ExampleManifold, ManifoldInvariantsHold) {
// constexpr double kTolerance = 1.0e-9;
// ExampleManifold manifold;
// ceres::Vector x = ceres::Vector::Zero(manifold.AmbientSize());
// ceres::Vector y = ceres::Vector::Zero(manifold.AmbientSize());
// ceres::Vector delta = ceres::Vector::Zero(manifold.TangentSize());
// EXPECT_THAT_MANIFOLD_INVARIANTS_HOLD(manifold, x, delta, y, kTolerance);
// }
#define EXPECT_THAT_MANIFOLD_INVARIANTS_HOLD(manifold, x, delta, y, tolerance) \
::ceres::Vector zero_tangent = \
::ceres::Vector::Zero(manifold.TangentSize()); \
EXPECT_THAT(manifold, ::ceres::XPlusZeroIsXAt(x, tolerance)); \
EXPECT_THAT(manifold, ::ceres::XMinusXIsZeroAt(x, tolerance)); \
EXPECT_THAT(manifold, ::ceres::MinusPlusIsIdentityAt(x, delta, tolerance)); \
EXPECT_THAT(manifold, \
::ceres::MinusPlusIsIdentityAt(x, zero_tangent, tolerance)); \
EXPECT_THAT(manifold, ::ceres::PlusMinusIsIdentityAt(x, x, tolerance)); \
EXPECT_THAT(manifold, ::ceres::PlusMinusIsIdentityAt(x, y, tolerance)); \
EXPECT_THAT(manifold, ::ceres::HasCorrectPlusJacobianAt(x, tolerance)); \
EXPECT_THAT(manifold, ::ceres::HasCorrectMinusJacobianAt(x, tolerance)); \
EXPECT_THAT(manifold, ::ceres::MinusPlusJacobianIsIdentityAt(x, tolerance)); \
EXPECT_THAT(manifold, \
::ceres::HasCorrectRightMultiplyByPlusJacobianAt(x, tolerance));
// Checks that the invariant Plus(x, 0) == x holds.
MATCHER_P2(XPlusZeroIsXAt, x, tolerance, "") {
const int ambient_size = arg.AmbientSize();
const int tangent_size = arg.TangentSize();
Vector actual = Vector::Zero(ambient_size);
Vector zero = Vector::Zero(tangent_size);
EXPECT_TRUE(arg.Plus(x.data(), zero.data(), actual.data()));
const double n = (actual - Vector{x}).norm();
const double d = x.norm();
const double diffnorm = (d == 0.0) ? n : (n / d);
if (diffnorm > tolerance) {
*result_listener << "\nexpected (x): " << x.transpose()
<< "\nactual: " << actual.transpose()
<< "\ndiffnorm: " << diffnorm;
return false;
}
return true;
}
// Checks that the invariant Minus(x, x) == 0 holds.
MATCHER_P2(XMinusXIsZeroAt, x, tolerance, "") {
const int tangent_size = arg.TangentSize();
Vector actual = Vector::Zero(tangent_size);
EXPECT_TRUE(arg.Minus(x.data(), x.data(), actual.data()));
const double diffnorm = actual.norm();
if (diffnorm > tolerance) {
*result_listener << "\nx: " << x.transpose() //
<< "\nexpected: 0 0 0"
<< "\nactual: " << actual.transpose()
<< "\ndiffnorm: " << diffnorm;
return false;
}
return true;
}
// Helper struct to curry Plus(x, .) so that it can be numerically
// differentiated.
struct PlusFunctor {
PlusFunctor(const Manifold& manifold, const double* x)
: manifold(manifold), x(x) {}
bool operator()(double const* const* parameters, double* x_plus_delta) const {
return manifold.Plus(x, parameters[0], x_plus_delta);
}
const Manifold& manifold;
const double* x;
};
// Checks that the output of PlusJacobian matches the one obtained by
// numerically evaluating D_2 Plus(x,0).
MATCHER_P2(HasCorrectPlusJacobianAt, x, tolerance, "") {
const int ambient_size = arg.AmbientSize();
const int tangent_size = arg.TangentSize();
NumericDiffOptions options;
options.ridders_relative_initial_step_size = 1e-4;
DynamicNumericDiffCostFunction<PlusFunctor, RIDDERS> cost_function(
new PlusFunctor(arg, x.data()), TAKE_OWNERSHIP, options);
cost_function.AddParameterBlock(tangent_size);
cost_function.SetNumResiduals(ambient_size);
Vector zero = Vector::Zero(tangent_size);
double* parameters[1] = {zero.data()};
Vector x_plus_zero = Vector::Zero(ambient_size);
Matrix expected = Matrix::Zero(ambient_size, tangent_size);
double* jacobians[1] = {expected.data()};
EXPECT_TRUE(
cost_function.Evaluate(parameters, x_plus_zero.data(), jacobians));
Matrix actual = Matrix::Random(ambient_size, tangent_size);
EXPECT_TRUE(arg.PlusJacobian(x.data(), actual.data()));
const double n = (actual - expected).norm();
const double d = expected.norm();
const double diffnorm = (d == 0.0) ? n : n / d;
if (diffnorm > tolerance) {
*result_listener << "\nx: " << x.transpose() << "\nexpected: \n"
<< expected << "\nactual:\n"
<< actual << "\ndiff:\n"
<< expected - actual << "\ndiffnorm : " << diffnorm;
return false;
}
return true;
}
// Checks that the invariant Minus(Plus(x, delta), x) == delta holds.
MATCHER_P3(MinusPlusIsIdentityAt, x, delta, tolerance, "") {
const int ambient_size = arg.AmbientSize();
const int tangent_size = arg.TangentSize();
Vector x_plus_delta = Vector::Zero(ambient_size);
EXPECT_TRUE(arg.Plus(x.data(), delta.data(), x_plus_delta.data()));
Vector actual = Vector::Zero(tangent_size);
EXPECT_TRUE(arg.Minus(x_plus_delta.data(), x.data(), actual.data()));
const double n = (actual - Vector{delta}).norm();
const double d = delta.norm();
const double diffnorm = (d == 0.0) ? n : (n / d);
if (diffnorm > tolerance) {
*result_listener << "\nx: " << x.transpose()
<< "\nexpected: " << delta.transpose()
<< "\nactual:" << actual.transpose()
<< "\ndiff:" << (delta - actual).transpose()
<< "\ndiffnorm: " << diffnorm;
return false;
}
return true;
}
// Checks that the invariant Plus(Minus(y, x), x) == y holds.
MATCHER_P3(PlusMinusIsIdentityAt, x, y, tolerance, "") {
const int ambient_size = arg.AmbientSize();
const int tangent_size = arg.TangentSize();
Vector y_minus_x = Vector::Zero(tangent_size);
EXPECT_TRUE(arg.Minus(y.data(), x.data(), y_minus_x.data()));
Vector actual = Vector::Zero(ambient_size);
EXPECT_TRUE(arg.Plus(x.data(), y_minus_x.data(), actual.data()));
const double n = (actual - Vector{y}).norm();
const double d = y.norm();
const double diffnorm = (d == 0.0) ? n : (n / d);
if (diffnorm > tolerance) {
*result_listener << "\nx: " << x.transpose()
<< "\nexpected: " << y.transpose()
<< "\nactual:" << actual.transpose()
<< "\ndiff:" << (y - actual).transpose()
<< "\ndiffnorm: " << diffnorm;
return false;
}
return true;
}
// Helper struct to curry Minus(., x) so that it can be numerically
// differentiated.
struct MinusFunctor {
MinusFunctor(const Manifold& manifold, const double* x)
: manifold(manifold), x(x) {}
bool operator()(double const* const* parameters, double* y_minus_x) const {
return manifold.Minus(parameters[0], x, y_minus_x);
}
const Manifold& manifold;
const double* x;
};
// Checks that the output of MinusJacobian matches the one obtained by
// numerically evaluating D_1 Minus(x,x).
MATCHER_P2(HasCorrectMinusJacobianAt, x, tolerance, "") {
const int ambient_size = arg.AmbientSize();
const int tangent_size = arg.TangentSize();
Vector y = x;
Vector y_minus_x = Vector::Zero(tangent_size);
NumericDiffOptions options;
options.ridders_relative_initial_step_size = 1e-4;
DynamicNumericDiffCostFunction<MinusFunctor, RIDDERS> cost_function(
new MinusFunctor(arg, x.data()), TAKE_OWNERSHIP, options);
cost_function.AddParameterBlock(ambient_size);
cost_function.SetNumResiduals(tangent_size);
double* parameters[1] = {y.data()};
Matrix expected = Matrix::Zero(tangent_size, ambient_size);
double* jacobians[1] = {expected.data()};
EXPECT_TRUE(cost_function.Evaluate(parameters, y_minus_x.data(), jacobians));
Matrix actual = Matrix::Random(tangent_size, ambient_size);
EXPECT_TRUE(arg.MinusJacobian(x.data(), actual.data()));
const double n = (actual - expected).norm();
const double d = expected.norm();
const double diffnorm = (d == 0.0) ? n : (n / d);
if (diffnorm > tolerance) {
*result_listener << "\nx: " << x.transpose() << "\nexpected: \n"
<< expected << "\nactual:\n"
<< actual << "\ndiff:\n"
<< expected - actual << "\ndiffnorm: " << diffnorm;
return false;
}
return true;
}
// Checks that D_delta Minus(Plus(x, delta), x) at delta = 0 is an identity
// matrix.
MATCHER_P2(MinusPlusJacobianIsIdentityAt, x, tolerance, "") {
const int ambient_size = arg.AmbientSize();
const int tangent_size = arg.TangentSize();
Matrix plus_jacobian(ambient_size, tangent_size);
EXPECT_TRUE(arg.PlusJacobian(x.data(), plus_jacobian.data()));
Matrix minus_jacobian(tangent_size, ambient_size);
EXPECT_TRUE(arg.MinusJacobian(x.data(), minus_jacobian.data()));
const Matrix actual = minus_jacobian * plus_jacobian;
const Matrix expected = Matrix::Identity(tangent_size, tangent_size);
const double n = (actual - expected).norm();
const double d = expected.norm();
const double diffnorm = n / d;
if (diffnorm > tolerance) {
*result_listener << "\nx: " << x.transpose() << "\nexpected: \n"
<< expected << "\nactual:\n"
<< actual << "\ndiff:\n"
<< expected - actual << "\ndiffnorm: " << diffnorm;
return false;
}
return true;
}
// Verify that the output of RightMultiplyByPlusJacobian is ambient_matrix *
// plus_jacobian.
MATCHER_P2(HasCorrectRightMultiplyByPlusJacobianAt, x, tolerance, "") {
const int ambient_size = arg.AmbientSize();
const int tangent_size = arg.TangentSize();
constexpr int kMinNumRows = 0;
constexpr int kMaxNumRows = 3;
for (int num_rows = kMinNumRows; num_rows <= kMaxNumRows; ++num_rows) {
Matrix plus_jacobian = Matrix::Random(ambient_size, tangent_size);
EXPECT_TRUE(arg.PlusJacobian(x.data(), plus_jacobian.data()));
Matrix ambient_matrix = Matrix::Random(num_rows, ambient_size);
Matrix expected = ambient_matrix * plus_jacobian;
Matrix actual = Matrix::Random(num_rows, tangent_size);
EXPECT_TRUE(arg.RightMultiplyByPlusJacobian(
x.data(), num_rows, ambient_matrix.data(), actual.data()));
const double n = (actual - expected).norm();
const double d = expected.norm();
const double diffnorm = (d == 0.0) ? n : (n / d);
if (diffnorm > tolerance) {
*result_listener << "\nx: " << x.transpose() << "\nambient_matrix : \n"
<< ambient_matrix << "\nplus_jacobian : \n"
<< plus_jacobian << "\nexpected: \n"
<< expected << "\nactual:\n"
<< actual << "\ndiff:\n"
<< expected - actual << "\ndiffnorm : " << diffnorm;
return false;
}
}
return true;
}
} // namespace ceres