/usr/include/fcl/collision_data.h is in libfcl-dev 0.5.0-5.
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* Software License Agreement (BSD License)
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* Copyright (c) 2011-2014, Willow Garage, Inc.
* Copyright (c) 2014-2016, Open Source Robotics Foundation
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/** \author Jia Pan */
#ifndef FCL_COLLISION_DATA_H
#define FCL_COLLISION_DATA_H
#include "fcl/collision_object.h"
#include "fcl/learning/classifier.h"
#include "fcl/math/vec_3f.h"
#include <vector>
#include <set>
#include <limits>
#include <functional>
namespace fcl
{
/// @brief Type of narrow phase GJK solver
enum GJKSolverType {GST_LIBCCD, GST_INDEP};
/// @brief Minimal contact information returned by collision
struct ContactPoint
{
/// @brief Contact normal, pointing from o1 to o2
Vec3f normal;
/// @brief Contact position, in world space
Vec3f pos;
/// @brief Penetration depth
FCL_REAL penetration_depth;
/// @brief Constructor
ContactPoint() : normal(Vec3f()), pos(Vec3f()), penetration_depth(0.0) {}
/// @brief Constructor
ContactPoint(const Vec3f& n_, const Vec3f& p_, FCL_REAL d_) : normal(n_),
pos(p_),
penetration_depth(d_)
{}
};
/// @brief Return true if _cp1's penentration depth is less than _cp2's.
bool comparePenDepth(const ContactPoint& _cp1, const ContactPoint& _cp2);
/// @brief Contact information returned by collision
struct Contact
{
/// @brief collision object 1
const CollisionGeometry* o1;
/// @brief collision object 2
const CollisionGeometry* o2;
/// @brief contact primitive in object 1
/// if object 1 is mesh or point cloud, it is the triangle or point id
/// if object 1 is geometry shape, it is NONE (-1),
/// if object 1 is octree, it is the id of the cell
int b1;
/// @brief contact primitive in object 2
/// if object 2 is mesh or point cloud, it is the triangle or point id
/// if object 2 is geometry shape, it is NONE (-1),
/// if object 2 is octree, it is the id of the cell
int b2;
/// @brief contact normal, pointing from o1 to o2
Vec3f normal;
/// @brief contact position, in world space
Vec3f pos;
/// @brief penetration depth
FCL_REAL penetration_depth;
/// @brief invalid contact primitive information
static const int NONE = -1;
Contact() : o1(NULL),
o2(NULL),
b1(NONE),
b2(NONE)
{}
Contact(const CollisionGeometry* o1_, const CollisionGeometry* o2_, int b1_, int b2_) : o1(o1_),
o2(o2_),
b1(b1_),
b2(b2_)
{}
Contact(const CollisionGeometry* o1_, const CollisionGeometry* o2_, int b1_, int b2_,
const Vec3f& pos_, const Vec3f& normal_, FCL_REAL depth_) : o1(o1_),
o2(o2_),
b1(b1_),
b2(b2_),
normal(normal_),
pos(pos_),
penetration_depth(depth_)
{}
bool operator < (const Contact& other) const
{
if(b1 == other.b1)
return b2 < other.b2;
return b1 < other.b1;
}
};
/// @brief Cost source describes an area with a cost. The area is described by an AABB region.
struct CostSource
{
/// @brief aabb lower bound
Vec3f aabb_min;
/// @brief aabb upper bound
Vec3f aabb_max;
/// @brief cost density in the AABB region
FCL_REAL cost_density;
FCL_REAL total_cost;
CostSource(const Vec3f& aabb_min_, const Vec3f& aabb_max_, FCL_REAL cost_density_) : aabb_min(aabb_min_),
aabb_max(aabb_max_),
cost_density(cost_density_)
{
total_cost = cost_density * (aabb_max[0] - aabb_min[0]) * (aabb_max[1] - aabb_min[1]) * (aabb_max[2] - aabb_min[2]);
}
CostSource(const AABB& aabb, FCL_REAL cost_density_) : aabb_min(aabb.min_),
aabb_max(aabb.max_),
cost_density(cost_density_)
{
total_cost = cost_density * (aabb_max[0] - aabb_min[0]) * (aabb_max[1] - aabb_min[1]) * (aabb_max[2] - aabb_min[2]);
}
CostSource() {}
bool operator < (const CostSource& other) const
{
if(total_cost < other.total_cost)
return false;
if(total_cost > other.total_cost)
return true;
if(cost_density < other.cost_density)
return false;
if(cost_density > other.cost_density)
return true;
for(size_t i = 0; i < 3; ++i)
if(aabb_min[i] != other.aabb_min[i])
return aabb_min[i] < other.aabb_min[i];
return false;
}
};
struct CollisionResult;
/// @brief request to the collision algorithm
struct CollisionRequest
{
/// @brief The maximum number of contacts will return
size_t num_max_contacts;
/// @brief whether the contact information (normal, penetration depth and contact position) will return
bool enable_contact;
/// @brief The maximum number of cost sources will return
size_t num_max_cost_sources;
/// @brief whether the cost sources will be computed
bool enable_cost;
/// @brief whether the cost computation is approximated
bool use_approximate_cost;
/// @brief narrow phase solver
GJKSolverType gjk_solver_type;
/// @brief whether enable gjk intial guess
bool enable_cached_gjk_guess;
/// @brief the gjk intial guess set by user
Vec3f cached_gjk_guess;
CollisionRequest(size_t num_max_contacts_ = 1,
bool enable_contact_ = false,
size_t num_max_cost_sources_ = 1,
bool enable_cost_ = false,
bool use_approximate_cost_ = true,
GJKSolverType gjk_solver_type_ = GST_LIBCCD) : num_max_contacts(num_max_contacts_),
enable_contact(enable_contact_),
num_max_cost_sources(num_max_cost_sources_),
enable_cost(enable_cost_),
use_approximate_cost(use_approximate_cost_),
gjk_solver_type(gjk_solver_type_)
{
enable_cached_gjk_guess = false;
cached_gjk_guess = Vec3f(1, 0, 0);
}
bool isSatisfied(const CollisionResult& result) const;
};
/// @brief collision result
struct CollisionResult
{
private:
/// @brief contact information
std::vector<Contact> contacts;
/// @brief cost sources
std::set<CostSource> cost_sources;
public:
Vec3f cached_gjk_guess;
public:
CollisionResult()
{
}
/// @brief add one contact into result structure
inline void addContact(const Contact& c)
{
contacts.push_back(c);
}
/// @brief add one cost source into result structure
inline void addCostSource(const CostSource& c, std::size_t num_max_cost_sources)
{
cost_sources.insert(c);
while (cost_sources.size() > num_max_cost_sources)
cost_sources.erase(--cost_sources.end());
}
/// @brief return binary collision result
bool isCollision() const
{
return contacts.size() > 0;
}
/// @brief number of contacts found
size_t numContacts() const
{
return contacts.size();
}
/// @brief number of cost sources found
size_t numCostSources() const
{
return cost_sources.size();
}
/// @brief get the i-th contact calculated
const Contact& getContact(size_t i) const
{
if(i < contacts.size())
return contacts[i];
else
return contacts.back();
}
/// @brief get all the contacts
void getContacts(std::vector<Contact>& contacts_)
{
contacts_.resize(contacts.size());
std::copy(contacts.begin(), contacts.end(), contacts_.begin());
}
/// @brief get all the cost sources
void getCostSources(std::vector<CostSource>& cost_sources_)
{
cost_sources_.resize(cost_sources.size());
std::copy(cost_sources.begin(), cost_sources.end(), cost_sources_.begin());
}
/// @brief clear the results obtained
void clear()
{
contacts.clear();
cost_sources.clear();
}
};
struct DistanceResult;
/// @brief request to the distance computation
struct DistanceRequest
{
/// @brief whether to return the nearest points
bool enable_nearest_points;
/// @brief error threshold for approximate distance
FCL_REAL rel_err; // relative error, between 0 and 1
FCL_REAL abs_err; // absoluate error
/// @brief narrow phase solver type
GJKSolverType gjk_solver_type;
DistanceRequest(bool enable_nearest_points_ = false,
FCL_REAL rel_err_ = 0.0,
FCL_REAL abs_err_ = 0.0,
GJKSolverType gjk_solver_type_ = GST_LIBCCD) : enable_nearest_points(enable_nearest_points_),
rel_err(rel_err_),
abs_err(abs_err_),
gjk_solver_type(gjk_solver_type_)
{
}
bool isSatisfied(const DistanceResult& result) const;
};
/// @brief distance result
struct DistanceResult
{
public:
/// @brief minimum distance between two objects. if two objects are in collision, min_distance <= 0.
FCL_REAL min_distance;
/// @brief nearest points
Vec3f nearest_points[2];
/// @brief collision object 1
const CollisionGeometry* o1;
/// @brief collision object 2
const CollisionGeometry* o2;
/// @brief information about the nearest point in object 1
/// if object 1 is mesh or point cloud, it is the triangle or point id
/// if object 1 is geometry shape, it is NONE (-1),
/// if object 1 is octree, it is the id of the cell
int b1;
/// @brief information about the nearest point in object 2
/// if object 2 is mesh or point cloud, it is the triangle or point id
/// if object 2 is geometry shape, it is NONE (-1),
/// if object 2 is octree, it is the id of the cell
int b2;
/// @brief invalid contact primitive information
static const int NONE = -1;
DistanceResult(FCL_REAL min_distance_ = std::numeric_limits<FCL_REAL>::max()) : min_distance(min_distance_),
o1(NULL),
o2(NULL),
b1(NONE),
b2(NONE)
{
}
/// @brief add distance information into the result
void update(FCL_REAL distance, const CollisionGeometry* o1_, const CollisionGeometry* o2_, int b1_, int b2_)
{
if(min_distance > distance)
{
min_distance = distance;
o1 = o1_;
o2 = o2_;
b1 = b1_;
b2 = b2_;
}
}
/// @brief add distance information into the result
void update(FCL_REAL distance, const CollisionGeometry* o1_, const CollisionGeometry* o2_, int b1_, int b2_, const Vec3f& p1, const Vec3f& p2)
{
if(min_distance > distance)
{
min_distance = distance;
o1 = o1_;
o2 = o2_;
b1 = b1_;
b2 = b2_;
nearest_points[0] = p1;
nearest_points[1] = p2;
}
}
/// @brief add distance information into the result
void update(const DistanceResult& other_result)
{
if(min_distance > other_result.min_distance)
{
min_distance = other_result.min_distance;
o1 = other_result.o1;
o2 = other_result.o2;
b1 = other_result.b1;
b2 = other_result.b2;
nearest_points[0] = other_result.nearest_points[0];
nearest_points[1] = other_result.nearest_points[1];
}
}
/// @brief clear the result
void clear()
{
min_distance = std::numeric_limits<FCL_REAL>::max();
o1 = NULL;
o2 = NULL;
b1 = NONE;
b2 = NONE;
}
};
enum CCDMotionType {CCDM_TRANS, CCDM_LINEAR, CCDM_SCREW, CCDM_SPLINE};
enum CCDSolverType {CCDC_NAIVE, CCDC_CONSERVATIVE_ADVANCEMENT, CCDC_RAY_SHOOTING, CCDC_POLYNOMIAL_SOLVER};
struct ContinuousCollisionRequest
{
/// @brief maximum num of iterations
std::size_t num_max_iterations;
/// @brief error in first contact time
FCL_REAL toc_err;
/// @brief ccd motion type
CCDMotionType ccd_motion_type;
/// @brief gjk solver type
GJKSolverType gjk_solver_type;
/// @brief ccd solver type
CCDSolverType ccd_solver_type;
ContinuousCollisionRequest(std::size_t num_max_iterations_ = 10,
FCL_REAL toc_err_ = 0.0001,
CCDMotionType ccd_motion_type_ = CCDM_TRANS,
GJKSolverType gjk_solver_type_ = GST_LIBCCD,
CCDSolverType ccd_solver_type_ = CCDC_NAIVE) : num_max_iterations(num_max_iterations_),
toc_err(toc_err_),
ccd_motion_type(ccd_motion_type_),
gjk_solver_type(gjk_solver_type_),
ccd_solver_type(ccd_solver_type_)
{
}
};
/// @brief continuous collision result
struct ContinuousCollisionResult
{
/// @brief collision or not
bool is_collide;
/// @brief time of contact in [0, 1]
FCL_REAL time_of_contact;
Transform3f contact_tf1, contact_tf2;
ContinuousCollisionResult() : is_collide(false), time_of_contact(1.0)
{
}
};
enum PenetrationDepthType {PDT_TRANSLATIONAL, PDT_GENERAL_EULER, PDT_GENERAL_QUAT, PDT_GENERAL_EULER_BALL, PDT_GENERAL_QUAT_BALL};
struct PenetrationDepthRequest
{
void* classifier;
/// @brief PD algorithm type
PenetrationDepthType pd_type;
/// @brief gjk solver type
GJKSolverType gjk_solver_type;
std::vector<Transform3f> contact_vectors;
PenetrationDepthRequest(void* classifier_,
PenetrationDepthType pd_type_ = PDT_TRANSLATIONAL,
GJKSolverType gjk_solver_type_ = GST_LIBCCD) : classifier(classifier_),
pd_type(pd_type_),
gjk_solver_type(gjk_solver_type_)
{
}
};
struct PenetrationDepthResult
{
/// @brief penetration depth value
FCL_REAL pd_value;
/// @brief the transform where the collision is resolved
Transform3f resolved_tf;
};
}
#endif
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