// Ceres Solver - A fast non-linear least squares minimizer
// Copyright 2010, 2011, 2012 Google Inc. All rights reserved.
// http://code.google.com/p/ceres-solver/
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are met:
//
// * Redistributions of source code must retain the above copyright notice,
// this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above copyright notice,
// this list of conditions and the following disclaimer in the documentation
// and/or other materials provided with the distribution.
// * Neither the name of Google Inc. nor the names of its contributors may be
// used to endorse or promote products derived from this software without
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//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
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// POSSIBILITY OF SUCH DAMAGE.
//
// Author: sameeragarwal@google.com (Sameer Agarwal)
#include "ceres/loss_function.h"
#include <cstddef>
#include "glog/logging.h"
#include "gtest/gtest.h"
namespace ceres {
namespace internal {
namespace {
// Helper function for testing a LossFunction callback.
//
// Compares the values of rho'(s) and rho''(s) computed by the
// callback with estimates obtained by symmetric finite differencing
// of rho(s).
void AssertLossFunctionIsValid(const LossFunction& loss, double s) {
CHECK_GT(s, 0);
// Evaluate rho(s), rho'(s) and rho''(s).
double rho[3];
loss.Evaluate(s, rho);
// Use symmetric finite differencing to estimate rho'(s) and
// rho''(s).
const double kH = 1e-4;
// Values at s + kH.
double fwd[3];
// Values at s - kH.
double bwd[3];
loss.Evaluate(s + kH, fwd);
loss.Evaluate(s - kH, bwd);
// First derivative.
const double fd_1 = (fwd[0] - bwd[0]) / (2 * kH);
ASSERT_NEAR(fd_1, rho[1], 1e-6);
// Second derivative.
const double fd_2 = (fwd[0] - 2*rho[0] + bwd[0]) / (kH * kH);
ASSERT_NEAR(fd_2, rho[2], 1e-6);
}
} // namespace
// Try two values of the scaling a = 0.7 and 1.3
// (where scaling makes sense) and of the squared norm
// s = 0.357 and 1.792
//
// Note that for the Huber loss the test exercises both code paths
// (i.e. both small and large values of s).
TEST(LossFunction, TrivialLoss) {
AssertLossFunctionIsValid(TrivialLoss(), 0.357);
AssertLossFunctionIsValid(TrivialLoss(), 1.792);
}
TEST(LossFunction, HuberLoss) {
AssertLossFunctionIsValid(HuberLoss(0.7), 0.357);
AssertLossFunctionIsValid(HuberLoss(0.7), 1.792);
AssertLossFunctionIsValid(HuberLoss(1.3), 0.357);
AssertLossFunctionIsValid(HuberLoss(1.3), 1.792);
}
TEST(LossFunction, SoftLOneLoss) {
AssertLossFunctionIsValid(SoftLOneLoss(0.7), 0.357);
AssertLossFunctionIsValid(SoftLOneLoss(0.7), 1.792);
AssertLossFunctionIsValid(SoftLOneLoss(1.3), 0.357);
AssertLossFunctionIsValid(SoftLOneLoss(1.3), 1.792);
}
TEST(LossFunction, CauchyLoss) {
AssertLossFunctionIsValid(CauchyLoss(0.7), 0.357);
AssertLossFunctionIsValid(CauchyLoss(0.7), 1.792);
AssertLossFunctionIsValid(CauchyLoss(1.3), 0.357);
AssertLossFunctionIsValid(CauchyLoss(1.3), 1.792);
}
TEST(LossFunction, ArctanLoss) {
AssertLossFunctionIsValid(ArctanLoss(0.7), 0.357);
AssertLossFunctionIsValid(ArctanLoss(0.7), 1.792);
AssertLossFunctionIsValid(ArctanLoss(1.3), 0.357);
AssertLossFunctionIsValid(ArctanLoss(1.3), 1.792);
}
TEST(LossFunction, TolerantLoss) {
AssertLossFunctionIsValid(TolerantLoss(0.7, 0.4), 0.357);
AssertLossFunctionIsValid(TolerantLoss(0.7, 0.4), 1.792);
AssertLossFunctionIsValid(TolerantLoss(0.7, 0.4), 55.5);
AssertLossFunctionIsValid(TolerantLoss(1.3, 0.1), 0.357);
AssertLossFunctionIsValid(TolerantLoss(1.3, 0.1), 1.792);
AssertLossFunctionIsValid(TolerantLoss(1.3, 0.1), 55.5);
// Check the value at zero is actually zero.
double rho[3];
TolerantLoss(0.7, 0.4).Evaluate(0.0, rho);
ASSERT_NEAR(rho[0], 0.0, 1e-6);
// Check that loss before and after the approximation threshold are good.
// A threshold of 36.7 is used by the implementation.
AssertLossFunctionIsValid(TolerantLoss(20.0, 1.0), 20.0 + 36.6);
AssertLossFunctionIsValid(TolerantLoss(20.0, 1.0), 20.0 + 36.7);
AssertLossFunctionIsValid(TolerantLoss(20.0, 1.0), 20.0 + 36.8);
AssertLossFunctionIsValid(TolerantLoss(20.0, 1.0), 20.0 + 1000.0);
}
TEST(LossFunction, ComposedLoss) {
{
HuberLoss f(0.7);
CauchyLoss g(1.3);
ComposedLoss c(&f, DO_NOT_TAKE_OWNERSHIP, &g, DO_NOT_TAKE_OWNERSHIP);
AssertLossFunctionIsValid(c, 0.357);
AssertLossFunctionIsValid(c, 1.792);
}
{
CauchyLoss f(0.7);
HuberLoss g(1.3);
ComposedLoss c(&f, DO_NOT_TAKE_OWNERSHIP, &g, DO_NOT_TAKE_OWNERSHIP);
AssertLossFunctionIsValid(c, 0.357);
AssertLossFunctionIsValid(c, 1.792);
}
}
TEST(LossFunction, ScaledLoss) {
// Wrap a few loss functions, and a few scale factors. This can't combine
// construction with the call to AssertLossFunctionIsValid() because Apple's
// GCC is unable to eliminate the copy of ScaledLoss, which is not copyable.
{
ScaledLoss scaled_loss(NULL, 6, TAKE_OWNERSHIP);
AssertLossFunctionIsValid(scaled_loss, 0.323);
}
{
ScaledLoss scaled_loss(new TrivialLoss(), 10, TAKE_OWNERSHIP);
AssertLossFunctionIsValid(scaled_loss, 0.357);
}
{
ScaledLoss scaled_loss(new HuberLoss(0.7), 0.1, TAKE_OWNERSHIP);
AssertLossFunctionIsValid(scaled_loss, 1.792);
}
{
ScaledLoss scaled_loss(new SoftLOneLoss(1.3), 0.1, TAKE_OWNERSHIP);
AssertLossFunctionIsValid(scaled_loss, 1.792);
}
{
ScaledLoss scaled_loss(new CauchyLoss(1.3), 10, TAKE_OWNERSHIP);
AssertLossFunctionIsValid(scaled_loss, 1.792);
}
{
ScaledLoss scaled_loss(new ArctanLoss(1.3), 10, TAKE_OWNERSHIP);
AssertLossFunctionIsValid(scaled_loss, 1.792);
}
{
ScaledLoss scaled_loss(
new TolerantLoss(1.3, 0.1), 10, TAKE_OWNERSHIP);
AssertLossFunctionIsValid(scaled_loss, 1.792);
}
{
ScaledLoss scaled_loss(
new ComposedLoss(
new HuberLoss(0.8), TAKE_OWNERSHIP,
new TolerantLoss(1.3, 0.5), TAKE_OWNERSHIP), 10, TAKE_OWNERSHIP);
AssertLossFunctionIsValid(scaled_loss, 1.792);
}
}
TEST(LossFunction, LossFunctionWrapper) {
// Initialization
HuberLoss loss_function1(1.0);
LossFunctionWrapper loss_function_wrapper(new HuberLoss(1.0),
TAKE_OWNERSHIP);
double s = 0.862;
double rho_gold[3];
double rho[3];
loss_function1.Evaluate(s, rho_gold);
loss_function_wrapper.Evaluate(s, rho);
for (int i = 0; i < 3; ++i) {
EXPECT_NEAR(rho[i], rho_gold[i], 1e-12);
}
// Resetting
HuberLoss loss_function2(0.5);
loss_function_wrapper.Reset(new HuberLoss(0.5), TAKE_OWNERSHIP);
loss_function_wrapper.Evaluate(s, rho);
loss_function2.Evaluate(s, rho_gold);
for (int i = 0; i < 3; ++i) {
EXPECT_NEAR(rho[i], rho_gold[i], 1e-12);
}
// Not taking ownership.
HuberLoss loss_function3(0.3);
loss_function_wrapper.Reset(&loss_function3, DO_NOT_TAKE_OWNERSHIP);
loss_function_wrapper.Evaluate(s, rho);
loss_function3.Evaluate(s, rho_gold);
for (int i = 0; i < 3; ++i) {
EXPECT_NEAR(rho[i], rho_gold[i], 1e-12);
}
}
} // namespace internal
} // namespace ceres