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/*
* Software License Agreement (BSD License)
*
* Copyright (c) 2011-2014, Willow Garage, Inc.
* Copyright (c) 2014-2016, Open Source Robotics Foundation
* All rights reserved.
*
* 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.
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* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
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* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
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* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
/** @author Jia Pan */
#include <gtest/gtest.h>
#include "fcl/config.h"
#include "fcl/broadphase/broadphase_bruteforce.h"
#include "fcl/broadphase/broadphase_spatialhash.h"
#include "fcl/broadphase/broadphase_SaP.h"
#include "fcl/broadphase/broadphase_SSaP.h"
#include "fcl/broadphase/broadphase_interval_tree.h"
#include "fcl/broadphase/broadphase_dynamic_AABB_tree.h"
#include "fcl/broadphase/broadphase_dynamic_AABB_tree_array.h"
#include "fcl/broadphase/detail/sparse_hash_table.h"
#include "fcl/broadphase/detail/spatial_hash.h"
#include "fcl/geometry/geometric_shape_to_BVH_model.h"
#include "test_fcl_utility.h"
#if USE_GOOGLEHASH
#include <sparsehash/sparse_hash_map>
#include <sparsehash/dense_hash_map>
#include <hash_map>
#endif
#include <iostream>
#include <iomanip>
using namespace fcl;
/// @brief Generate environment with 3 * n objects for self distance, so we try to make sure none of them collide with each other.
template <typename S>
void generateSelfDistanceEnvironments(std::vector<CollisionObject<S>*>& env, S env_scale, std::size_t n);
/// @brief Generate environment with 3 * n objects for self distance, but all in meshes.
template <typename S>
void generateSelfDistanceEnvironmentsMesh(std::vector<CollisionObject<S>*>& env, S env_scale, std::size_t n);
/// @brief test for broad phase distance
template <typename S>
void broad_phase_distance_test(S env_scale, std::size_t env_size, std::size_t query_size, bool use_mesh = false);
/// @brief test for broad phase self distance
template <typename S>
void broad_phase_self_distance_test(S env_scale, std::size_t env_size, bool use_mesh = false);
template <typename S>
S getDELTA() { return 0.01; }
#if USE_GOOGLEHASH
template<typename U, typename V>
struct GoogleSparseHashTable : public google::sparse_hash_map<U, V, std::tr1::hash<size_t>, std::equal_to<size_t> > {};
template<typename U, typename V>
struct GoogleDenseHashTable : public google::dense_hash_map<U, V, std::tr1::hash<size_t>, std::equal_to<size_t> >
{
GoogleDenseHashTable() : google::dense_hash_map<U, V, std::tr1::hash<size_t>, std::equal_to<size_t> >()
{
this->set_empty_key(nullptr);
}
};
#endif
/// check broad phase distance
GTEST_TEST(FCL_BROADPHASE, test_core_bf_broad_phase_distance)
{
#ifdef NDEBUG
broad_phase_distance_test<double>(200, 100, 100);
broad_phase_distance_test<double>(200, 1000, 100);
broad_phase_distance_test<double>(2000, 100, 100);
broad_phase_distance_test<double>(2000, 1000, 100);
#else
broad_phase_distance_test<double>(200, 10, 10);
broad_phase_distance_test<double>(200, 100, 10);
broad_phase_distance_test<double>(2000, 10, 10);
broad_phase_distance_test<double>(2000, 100, 10);
#endif
}
/// check broad phase self distance
GTEST_TEST(FCL_BROADPHASE, test_core_bf_broad_phase_self_distance)
{
#ifdef NDEBUG
broad_phase_self_distance_test<double>(200, 512);
broad_phase_self_distance_test<double>(200, 1000);
broad_phase_self_distance_test<double>(200, 5000);
#else
broad_phase_self_distance_test<double>(200, 256);
broad_phase_self_distance_test<double>(200, 500);
broad_phase_self_distance_test<double>(200, 2500);
#endif
}
/// check broad phase distance
GTEST_TEST(FCL_BROADPHASE, test_core_mesh_bf_broad_phase_distance_mesh)
{
#ifdef NDEBUG
broad_phase_distance_test<double>(200, 100, 100, true);
broad_phase_distance_test<double>(200, 1000, 100, true);
broad_phase_distance_test<double>(2000, 100, 100, true);
broad_phase_distance_test<double>(2000, 1000, 100, true);
#else
broad_phase_distance_test<double>(200, 2, 2, true);
broad_phase_distance_test<double>(200, 4, 2, true);
broad_phase_distance_test<double>(2000, 2, 2, true);
broad_phase_distance_test<double>(2000, 4, 2, true);
#endif
}
/// check broad phase self distance
GTEST_TEST(FCL_BROADPHASE, test_core_mesh_bf_broad_phase_self_distance_mesh)
{
#ifdef NDEBUG
broad_phase_self_distance_test<double>(200, 512, true);
broad_phase_self_distance_test<double>(200, 1000, true);
broad_phase_self_distance_test<double>(200, 5000, true);
#else
broad_phase_self_distance_test<double>(200, 128, true);
broad_phase_self_distance_test<double>(200, 250, true);
broad_phase_self_distance_test<double>(200, 1250, true);
#endif
}
template <typename S>
void generateSelfDistanceEnvironments(std::vector<CollisionObject<S>*>& env, S env_scale, std::size_t n)
{
unsigned int n_edge = std::floor(std::pow(n, 1/3.0));
S step_size = env_scale * 2 / n_edge;
S delta_size = step_size * 0.05;
S single_size = step_size - 2 * delta_size;
unsigned int i = 0;
for(; i < n_edge * n_edge * n_edge / 4; ++i)
{
int x = i % (n_edge * n_edge);
int y = (i - n_edge * n_edge * x) % n_edge;
int z = i - n_edge * n_edge * x - n_edge * y;
Box<S>* box = new Box<S>(single_size, single_size, single_size);
env.push_back(new CollisionObject<S>(std::shared_ptr<CollisionGeometry<S>>(box),
Transform3<S>(Translation3<S>(Vector3<S>(x * step_size + delta_size + 0.5 * single_size - env_scale,
y * step_size + delta_size + 0.5 * single_size - env_scale,
z * step_size + delta_size + 0.5 * single_size - env_scale)))));
}
for(; i < n_edge * n_edge * n_edge / 4; ++i)
{
int x = i % (n_edge * n_edge);
int y = (i - n_edge * n_edge * x) % n_edge;
int z = i - n_edge * n_edge * x - n_edge * y;
Sphere<S>* sphere = new Sphere<S>(single_size / 2);
env.push_back(new CollisionObject<S>(std::shared_ptr<CollisionGeometry<S>>(sphere),
Transform3<S>(Translation3<S>(Vector3<S>(x * step_size + delta_size + 0.5 * single_size - env_scale,
y * step_size + delta_size + 0.5 * single_size - env_scale,
z * step_size + delta_size + 0.5 * single_size - env_scale)))));
}
for(; i < n_edge * n_edge * n_edge / 4; ++i)
{
int x = i % (n_edge * n_edge);
int y = (i - n_edge * n_edge * x) % n_edge;
int z = i - n_edge * n_edge * x - n_edge * y;
Ellipsoid<S>* ellipsoid = new Ellipsoid<S>(single_size / 2, single_size / 2, single_size / 2);
env.push_back(new CollisionObject<S>(std::shared_ptr<CollisionGeometry<S>>(ellipsoid),
Transform3<S>(Translation3<S>(Vector3<S>(x * step_size + delta_size + 0.5 * single_size - env_scale,
y * step_size + delta_size + 0.5 * single_size - env_scale,
z * step_size + delta_size + 0.5 * single_size - env_scale)))));
}
for(; i < n_edge * n_edge * n_edge / 4; ++i)
{
int x = i % (n_edge * n_edge);
int y = (i - n_edge * n_edge * x) % n_edge;
int z = i - n_edge * n_edge * x - n_edge * y;
Cylinder<S>* cylinder = new Cylinder<S>(single_size / 2, single_size);
env.push_back(new CollisionObject<S>(std::shared_ptr<CollisionGeometry<S>>(cylinder),
Transform3<S>(Translation3<S>(Vector3<S>(x * step_size + delta_size + 0.5 * single_size - env_scale,
y * step_size + delta_size + 0.5 * single_size - env_scale,
z * step_size + delta_size + 0.5 * single_size - env_scale)))));
}
for(; i < n_edge * n_edge * n_edge / 4; ++i)
{
int x = i % (n_edge * n_edge);
int y = (i - n_edge * n_edge * x) % n_edge;
int z = i - n_edge * n_edge * x - n_edge * y;
Cone<S>* cone = new Cone<S>(single_size / 2, single_size);
env.push_back(new CollisionObject<S>(std::shared_ptr<CollisionGeometry<S>>(cone),
Transform3<S>(Translation3<S>(Vector3<S>(x * step_size + delta_size + 0.5 * single_size - env_scale,
y * step_size + delta_size + 0.5 * single_size - env_scale,
z * step_size + delta_size + 0.5 * single_size - env_scale)))));
}
}
template <typename S>
void generateSelfDistanceEnvironmentsMesh(std::vector<CollisionObject<S>*>& env, S env_scale, std::size_t n)
{
unsigned int n_edge = std::floor(std::pow(n, 1/3.0));
S step_size = env_scale * 2 / n_edge;
S delta_size = step_size * 0.05;
S single_size = step_size - 2 * delta_size;
std::size_t i = 0;
for(; i < n_edge * n_edge * n_edge / 4; ++i)
{
int x = i % (n_edge * n_edge);
int y = (i - n_edge * n_edge * x) % n_edge;
int z = i - n_edge * n_edge * x - n_edge * y;
Box<S> box(single_size, single_size, single_size);
BVHModel<OBBRSS<S>>* model = new BVHModel<OBBRSS<S>>();
generateBVHModel(*model, box, Transform3<S>::Identity());
env.push_back(new CollisionObject<S>(std::shared_ptr<CollisionGeometry<S>>(model),
Transform3<S>(Translation3<S>(Vector3<S>(x * step_size + delta_size + 0.5 * single_size - env_scale,
y * step_size + delta_size + 0.5 * single_size - env_scale,
z * step_size + delta_size + 0.5 * single_size - env_scale)))));
}
for(; i < n_edge * n_edge * n_edge / 4; ++i)
{
int x = i % (n_edge * n_edge);
int y = (i - n_edge * n_edge * x) % n_edge;
int z = i - n_edge * n_edge * x - n_edge * y;
Sphere<S> sphere(single_size / 2);
BVHModel<OBBRSS<S>>* model = new BVHModel<OBBRSS<S>>();
generateBVHModel(*model, sphere, Transform3<S>::Identity(), 16, 16);
env.push_back(new CollisionObject<S>(std::shared_ptr<CollisionGeometry<S>>(model),
Transform3<S>(Translation3<S>(Vector3<S>(x * step_size + delta_size + 0.5 * single_size - env_scale,
y * step_size + delta_size + 0.5 * single_size - env_scale,
z * step_size + delta_size + 0.5 * single_size - env_scale)))));
}
for(; i < n_edge * n_edge * n_edge / 4; ++i)
{
int x = i % (n_edge * n_edge);
int y = (i - n_edge * n_edge * x) % n_edge;
int z = i - n_edge * n_edge * x - n_edge * y;
Ellipsoid<S> ellipsoid(single_size / 2, single_size / 2, single_size / 2);
BVHModel<OBBRSS<S>>* model = new BVHModel<OBBRSS<S>>();
generateBVHModel(*model, ellipsoid, Transform3<S>::Identity(), 16, 16);
env.push_back(new CollisionObject<S>(std::shared_ptr<CollisionGeometry<S>>(model),
Transform3<S>(Translation3<S>(Vector3<S>(x * step_size + delta_size + 0.5 * single_size - env_scale,
y * step_size + delta_size + 0.5 * single_size - env_scale,
z * step_size + delta_size + 0.5 * single_size - env_scale)))));
}
for(; i < n_edge * n_edge * n_edge / 4; ++i)
{
int x = i % (n_edge * n_edge);
int y = (i - n_edge * n_edge * x) % n_edge;
int z = i - n_edge * n_edge * x - n_edge * y;
Cylinder<S> cylinder(single_size / 2, single_size);
BVHModel<OBBRSS<S>>* model = new BVHModel<OBBRSS<S>>();
generateBVHModel(*model, cylinder, Transform3<S>::Identity(), 16, 16);
env.push_back(new CollisionObject<S>(std::shared_ptr<CollisionGeometry<S>>(model),
Transform3<S>(Translation3<S>(Vector3<S>(x * step_size + delta_size + 0.5 * single_size - env_scale,
y * step_size + delta_size + 0.5 * single_size - env_scale,
z * step_size + delta_size + 0.5 * single_size - env_scale)))));
}
for(; i < n_edge * n_edge * n_edge / 4; ++i)
{
int x = i % (n_edge * n_edge);
int y = (i - n_edge * n_edge * x) % n_edge;
int z = i - n_edge * n_edge * x - n_edge * y;
Cone<S> cone(single_size / 2, single_size);
BVHModel<OBBRSS<S>>* model = new BVHModel<OBBRSS<S>>();
generateBVHModel(*model, cone, Transform3<S>::Identity(), 16, 16);
env.push_back(new CollisionObject<S>(std::shared_ptr<CollisionGeometry<S>>(model),
Transform3<S>(Translation3<S>(Vector3<S>(x * step_size + delta_size + 0.5 * single_size - env_scale,
y * step_size + delta_size + 0.5 * single_size - env_scale,
z * step_size + delta_size + 0.5 * single_size - env_scale)))));
}
}
template <typename S>
void broad_phase_self_distance_test(S env_scale, std::size_t env_size, bool use_mesh)
{
std::vector<test::TStruct> ts;
std::vector<test::Timer> timers;
std::vector<CollisionObject<S>*> env;
if(use_mesh)
generateSelfDistanceEnvironmentsMesh(env, env_scale, env_size);
else
generateSelfDistanceEnvironments(env, env_scale, env_size);
std::vector<BroadPhaseCollisionManager<S>*> managers;
managers.push_back(new NaiveCollisionManager<S>());
managers.push_back(new SSaPCollisionManager<S>());
managers.push_back(new SaPCollisionManager<S>());
managers.push_back(new IntervalTreeCollisionManager<S>());
Vector3<S> lower_limit, upper_limit;
SpatialHashingCollisionManager<S>::computeBound(env, lower_limit, upper_limit);
S cell_size = std::min(std::min((upper_limit[0] - lower_limit[0]) / 5, (upper_limit[1] - lower_limit[1]) / 5), (upper_limit[2] - lower_limit[2]) / 5);
// managers.push_back(new SpatialHashingCollisionManager<S>(cell_size, lower_limit, upper_limit));
managers.push_back(new SpatialHashingCollisionManager<S, detail::SparseHashTable<AABB<S>, CollisionObject<S>*, detail::SpatialHash<S>> >(cell_size, lower_limit, upper_limit));
#if USE_GOOGLEHASH
managers.push_back(new SpatialHashingCollisionManager<S, detail::SparseHashTable<AABB<S>, CollisionObject<S>*, detail::SpatialHash<S>, GoogleSparseHashTable> >(cell_size, lower_limit, upper_limit));
managers.push_back(new SpatialHashingCollisionManager<S, detail::SparseHashTable<AABB<S>, CollisionObject<S>*, detail::SpatialHash<S>, GoogleDenseHashTable> >(cell_size, lower_limit, upper_limit));
#endif
managers.push_back(new DynamicAABBTreeCollisionManager<S>());
managers.push_back(new DynamicAABBTreeCollisionManager_Array<S>());
{
DynamicAABBTreeCollisionManager<S>* m = new DynamicAABBTreeCollisionManager<S>();
m->tree_init_level = 2;
managers.push_back(m);
}
{
DynamicAABBTreeCollisionManager_Array<S>* m = new DynamicAABBTreeCollisionManager_Array<S>();
m->tree_init_level = 2;
managers.push_back(m);
}
ts.resize(managers.size());
timers.resize(managers.size());
for(size_t i = 0; i < managers.size(); ++i)
{
timers[i].start();
managers[i]->registerObjects(env);
timers[i].stop();
ts[i].push_back(timers[i].getElapsedTime());
}
for(size_t i = 0; i < managers.size(); ++i)
{
timers[i].start();
managers[i]->setup();
timers[i].stop();
ts[i].push_back(timers[i].getElapsedTime());
}
std::vector<test::DistanceData<S>> self_data(managers.size());
for(size_t i = 0; i < self_data.size(); ++i)
{
timers[i].start();
managers[i]->distance(&self_data[i], test::defaultDistanceFunction);
timers[i].stop();
ts[i].push_back(timers[i].getElapsedTime());
// std::cout << self_data[i].result.min_distance << " ";
}
// std::cout << std::endl;
for(size_t i = 1; i < managers.size(); ++i)
EXPECT_TRUE(fabs(self_data[0].result.min_distance - self_data[i].result.min_distance) < getDELTA<S>() ||
fabs(self_data[0].result.min_distance - self_data[i].result.min_distance) / fabs(self_data[0].result.min_distance) < getDELTA<S>());
for(size_t i = 0; i < env.size(); ++i)
delete env[i];
for(size_t i = 0; i < managers.size(); ++i)
delete managers[i];
std::cout.setf(std::ios_base::left, std::ios_base::adjustfield);
size_t w = 7;
std::cout << "self distance timing summary" << std::endl;
std::cout << env.size() << " objs" << std::endl;
std::cout << "register time" << std::endl;
for(size_t i = 0; i < ts.size(); ++i)
std::cout << std::setw(w) << ts[i].records[0] << " ";
std::cout << std::endl;
std::cout << "setup time" << std::endl;
for(size_t i = 0; i < ts.size(); ++i)
std::cout << std::setw(w) << ts[i].records[1] << " ";
std::cout << std::endl;
std::cout << "self distance time" << std::endl;
for(size_t i = 0; i < ts.size(); ++i)
std::cout << std::setw(w) << ts[i].records[2] << " ";
std::cout << std::endl;
std::cout << "overall time" << std::endl;
for(size_t i = 0; i < ts.size(); ++i)
std::cout << std::setw(w) << ts[i].overall_time << " ";
std::cout << std::endl;
std::cout << std::endl;
}
template <typename S>
void broad_phase_distance_test(S env_scale, std::size_t env_size, std::size_t query_size, bool use_mesh)
{
std::vector<test::TStruct> ts;
std::vector<test::Timer> timers;
std::vector<CollisionObject<S>*> env;
if(use_mesh)
test::generateEnvironmentsMesh(env, env_scale, env_size);
else
test::generateEnvironments(env, env_scale, env_size);
std::vector<CollisionObject<S>*> query;
BroadPhaseCollisionManager<S>* manager = new NaiveCollisionManager<S>();
for(std::size_t i = 0; i < env.size(); ++i)
manager->registerObject(env[i]);
manager->setup();
while(1)
{
std::vector<CollisionObject<S>*> candidates;
if(use_mesh)
test::generateEnvironmentsMesh(candidates, env_scale, query_size);
else
test::generateEnvironments(candidates, env_scale, query_size);
for(std::size_t i = 0; i < candidates.size(); ++i)
{
test::CollisionData<S> query_data;
manager->collide(candidates[i], &query_data, test::defaultCollisionFunction);
if(query_data.result.numContacts() == 0)
query.push_back(candidates[i]);
else
delete candidates[i];
if(query.size() == query_size) break;
}
if(query.size() == query_size) break;
}
delete manager;
std::vector<BroadPhaseCollisionManager<S>*> managers;
managers.push_back(new NaiveCollisionManager<S>());
managers.push_back(new SSaPCollisionManager<S>());
managers.push_back(new SaPCollisionManager<S>());
managers.push_back(new IntervalTreeCollisionManager<S>());
Vector3<S> lower_limit, upper_limit;
SpatialHashingCollisionManager<S>::computeBound(env, lower_limit, upper_limit);
S cell_size = std::min(std::min((upper_limit[0] - lower_limit[0]) / 20, (upper_limit[1] - lower_limit[1]) / 20), (upper_limit[2] - lower_limit[2])/20);
// managers.push_back(new SpatialHashingCollisionManager<S>(cell_size, lower_limit, upper_limit));
managers.push_back(new SpatialHashingCollisionManager<S, detail::SparseHashTable<AABB<S>, CollisionObject<S>*, detail::SpatialHash<S>> >(cell_size, lower_limit, upper_limit));
#if USE_GOOGLEHASH
managers.push_back(new SpatialHashingCollisionManager<S, detail::SparseHashTable<AABB<S>, CollisionObject<S>*, detail::SpatialHash<S>, GoogleSparseHashTable> >(cell_size, lower_limit, upper_limit));
managers.push_back(new SpatialHashingCollisionManager<S, detail::SparseHashTable<AABB<S>, CollisionObject<S>*, detail::SpatialHash<S>, GoogleDenseHashTable> >(cell_size, lower_limit, upper_limit));
#endif
managers.push_back(new DynamicAABBTreeCollisionManager<S>());
managers.push_back(new DynamicAABBTreeCollisionManager_Array<S>());
{
DynamicAABBTreeCollisionManager<S>* m = new DynamicAABBTreeCollisionManager<S>();
m->tree_init_level = 2;
managers.push_back(m);
}
{
DynamicAABBTreeCollisionManager_Array<S>* m = new DynamicAABBTreeCollisionManager_Array<S>();
m->tree_init_level = 2;
managers.push_back(m);
}
ts.resize(managers.size());
timers.resize(managers.size());
for(size_t i = 0; i < managers.size(); ++i)
{
timers[i].start();
managers[i]->registerObjects(env);
timers[i].stop();
ts[i].push_back(timers[i].getElapsedTime());
}
for(size_t i = 0; i < managers.size(); ++i)
{
timers[i].start();
managers[i]->setup();
timers[i].stop();
ts[i].push_back(timers[i].getElapsedTime());
}
for(size_t i = 0; i < query.size(); ++i)
{
std::vector<test::DistanceData<S>> query_data(managers.size());
for(size_t j = 0; j < managers.size(); ++j)
{
timers[j].start();
managers[j]->distance(query[i], &query_data[j], test::defaultDistanceFunction);
timers[j].stop();
ts[j].push_back(timers[j].getElapsedTime());
// std::cout << query_data[j].result.min_distance << " ";
}
// std::cout << std::endl;
for(size_t j = 1; j < managers.size(); ++j)
EXPECT_TRUE(fabs(query_data[0].result.min_distance - query_data[j].result.min_distance) < getDELTA<S>() ||
fabs(query_data[0].result.min_distance - query_data[j].result.min_distance) / fabs(query_data[0].result.min_distance) < getDELTA<S>());
}
for(std::size_t i = 0; i < env.size(); ++i)
delete env[i];
for(std::size_t i = 0; i < query.size(); ++i)
delete query[i];
for(size_t i = 0; i < managers.size(); ++i)
delete managers[i];
std::cout.setf(std::ios_base::left, std::ios_base::adjustfield);
size_t w = 7;
std::cout << "distance timing summary" << std::endl;
std::cout << env_size << " objs, " << query_size << " queries" << std::endl;
std::cout << "register time" << std::endl;
for(size_t i = 0; i < ts.size(); ++i)
std::cout << std::setw(w) << ts[i].records[0] << " ";
std::cout << std::endl;
std::cout << "setup time" << std::endl;
for(size_t i = 0; i < ts.size(); ++i)
std::cout << std::setw(w) << ts[i].records[1] << " ";
std::cout << std::endl;
std::cout << "distance time" << std::endl;
for(size_t i = 0; i < ts.size(); ++i)
{
S tmp = 0;
for(size_t j = 2; j < ts[i].records.size(); ++j)
tmp += ts[i].records[j];
std::cout << std::setw(w) << tmp << " ";
}
std::cout << std::endl;
std::cout << "overall time" << std::endl;
for(size_t i = 0; i < ts.size(); ++i)
std::cout << std::setw(w) << ts[i].overall_time << " ";
std::cout << std::endl;
std::cout << std::endl;
}
//==============================================================================
int main(int argc, char* argv[])
{
::testing::InitGoogleTest(&argc, argv);
return RUN_ALL_TESTS();
}
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