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git-svn-id: https://reactphysics3d.googlecode.com/svn/trunk@177 92aac97c-a6ce-11dd-a772-7fcde58d38e6

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chappuis.daniel 2009-07-21 20:29:37 +00:00
parent 83d82b7699
commit 951725a401
8 changed files with 538 additions and 11 deletions
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2
sources/reactphysics3d/collision/BroadPhaseAlgorithm.h
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@ -46,7 +46,7 @@ class BroadPhaseAlgorithm {
BroadPhaseAlgorithm(); // Constructor
virtual ~BroadPhaseAlgorithm(); // Destructor
virtual bool testCollisionPair(const BoundingVolume& boundingVolume1, const BoundingVolume& boundingVolume2)=0; // Return true if the two bounding volume can collide
virtual bool testCollisionPair(const BoundingVolume* const boundingVolume1, const BoundingVolume* const boundingVolume2)=0; // Return true if the two bounding volume can collide
};
} // End of reactphysics3d namespace

45
sources/reactphysics3d/collision/CollisionDetection.cpp
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@ -21,6 +21,9 @@
#include "CollisionDetection.h"
#include "SeparatingAxisAABB.h"
#include "SeparatingAxisOBB.h"
#include "../body/OBB.h"
#include "../body/RigidBody.h"
#include <cassert>
// We want to use the ReactPhysics3D namespace
using namespace reactphysics3d;
@ -50,7 +53,43 @@ void CollisionDetection::computeCollisionContacts() {
// TODO : Implement this method
}
// Compute the collision detection
void CollisionDetection::computeCollisionDetection(CollisionWorld& collisionWorld) {
// TODO : Implement this method
// Compute the collision detection for the time interval [0, timeMax]
// The method returns true if a collision occurs in the time interval [0, timeMax]
bool CollisionDetection::computeCollisionDetection(CollisionWorld* collisionWorld, const Time& timeMax, Time& timeFirst, Time& timeLast) {
bool existsCollision = false; // True if a collision is found in the time interval [0, timeMax]
// For each pair of bodies in the collisionWorld
for(std::vector<Body*>::const_iterator it1 = collisionWorld->getBodyListStartIterator(); it1 != collisionWorld->getBodyListEndIterator(); ++it1) {
for(std::vector<Body*>::const_iterator it2 = it1; it2 != collisionWorld->getBodyListEndIterator(); ++it2) {
// If both bodies are RigidBody and are different
RigidBody* rigidBody1 = dynamic_cast<RigidBody*>(*it1);
RigidBody* rigidBody2 = dynamic_cast<RigidBody*>(*it2);
if(rigidBody1 && rigidBody2 && rigidBody1 != rigidBody2) {
// Get the oriented bounding boxes of the two bodies
OBB obb1 = rigidBody1->getOBB();
OBB obb2 = rigidBody2->getOBB();
// Use the broad-phase algorithm to decide if the two bodies can collide
if(broadPhaseAlgorithm->testCollisionPair(&obb1, &obb2)) {
Contact* contact = 0;
// Get the velocities of both bodies
Vector3D velocity1 = rigidBody1->getInterpolatedState().getLinearVelocity();
Vector3D velocity2 = rigidBody2->getInterpolatedState().getLinearVelocity();
// Use the narrow-phase algorithm to check if the two bodies really collide
if(narrowPhaseAlgorithm->testCollision(&obb1, &obb2, &contact, velocity1, velocity2, timeMax, timeFirst, timeLast)) {
assert(contact != 0);
existsCollision = true;
// Add the new collision contact into the collision world
collisionWorld->addConstraint(contact);
}
}
}
}
}
return existsCollision;
}

2
sources/reactphysics3d/collision/CollisionDetection.h
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@ -53,7 +53,7 @@ class CollisionDetection {
CollisionDetection(); // Constructor
~CollisionDetection(); // Destructor
void computeCollisionDetection(CollisionWorld& collisionWorld); // Compute the collision detection
bool computeCollisionDetection(CollisionWorld* collisionWorld, const Time& timeMax, Time& timeFirst, Time& timeLast); // Compute the collision detection
};
// Add a possible collision pair of bodies in the possibleCollisionPairList

5
sources/reactphysics3d/collision/NarrowPhaseAlgorithm.h
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@ -41,7 +41,10 @@ class NarrowPhaseAlgorithm {
public :
NarrowPhaseAlgorithm(); // Constructor
virtual ~NarrowPhaseAlgorithm(); // Destructor
virtual bool testCollision(const BoundingVolume& boundingVolume1, const BoundingVolume& boundingVolume2, Contact* const contact)=0; // Return true and compute a collision contact if the two bounding volume collide
virtual bool testCollision(const BoundingVolume* const boundingVolume1, const BoundingVolume* const boundingVolume2,
Contact** contact, const Vector3D& velocity1, const Vector3D& velocity2,
const Time& timeMax, Time& timeFirst, Time& timeLast)=0; // Return true and compute a collision contact and collision time if the two bounding volume collide
};
} // End of reactphysics3d namespace

5
sources/reactphysics3d/collision/SeparatingAxisAABB.cpp
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@ -34,7 +34,10 @@ SeparatingAxisAABB::~SeparatingAxisAABB() {
}
// Return true if the two AABB of the bodies intersect
bool SeparatingAxisAABB::testCollisionPair(const BoundingVolume& boundingVolume1, const BoundingVolume& boundingVolume2) {
bool SeparatingAxisAABB::testCollisionPair(const BoundingVolume* const boundingVolume1, const BoundingVolume* const boundingVolume2) {
// TODO : Implement this method
// At this time this method returns true to indicate that all body pairs can collide
return true;
}

10
sources/reactphysics3d/collision/SeparatingAxisAABB.h
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@ -27,6 +27,14 @@
// ReactPhysics3D namespace
namespace reactphysics3d {
/* -------------------------------------------------------------------
Class SeparatingAxisAABB :
This class implements a broad-phase collision detection
algorithm. This algorithm is uses a separating axis technique
with axis aligned bounding box (AABB) to check if two bounding
volumes can colide or not.
-------------------------------------------------------------------
*/
class SeparatingAxisAABB : public BroadPhaseAlgorithm {
private :
@ -34,7 +42,7 @@ class SeparatingAxisAABB : public BroadPhaseAlgorithm {
SeparatingAxisAABB(); // Constructor
~SeparatingAxisAABB(); // Destructor
virtual bool testCollisionPair(const BoundingVolume& boundingVolume1, const BoundingVolume& boundingVolume2); // Return true if the two AABB of the bodies intersect
virtual bool testCollisionPair(const BoundingVolume* const boundingVolume1, const BoundingVolume* const boundingVolume2); // Return true if the two AABB of the bodies intersect
};
} // End of the ReactPhysics3D namespace

456
sources/reactphysics3d/collision/SeparatingAxisOBB.cpp
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@ -20,6 +20,10 @@
// Libraries
#include "SeparatingAxisOBB.h"
#include "../body/OBB.h"
#include "../constraint/Contact.h"
#include <cfloat>
#include <iostream> // TODO : Delete this
#include <cassert>
// We want to use the ReactPhysics3D namespace
using namespace reactphysics3d;
@ -36,6 +40,454 @@ SeparatingAxisOBB::~SeparatingAxisOBB() {
// Return true and compute a collision contact if the two bounding volume collide.
// The method returns false if there is no collision between the two bounding volumes.
bool SeparatingAxisOBB::testCollision(const BoundingVolume& boundingVolume1, const BoundingVolume& boundingVolume2, Contact* const contact) {
// TODO : Implement this method
bool SeparatingAxisOBB::testCollision(const BoundingVolume* const boundingVolume1, const BoundingVolume* const boundingVolume2, Contact** contact,
const Vector3D& velocity1, const Vector3D& velocity2, const Time& timeMax, Time& timeFirst, Time& timeLast) {
assert(boundingVolume1 != boundingVolume2);
// If the two bounding volumes are OBB
const OBB* const obb1 = dynamic_cast<const OBB* const>(boundingVolume1);
const OBB* const obb2 = dynamic_cast<const OBB* const>(boundingVolume2);
// If the two bounding volumes are OBB
if (obb1 && obb2) {
// Compute the collision test between two OBB
return computeCollisionTest(obb1, obb2, contact, velocity1, velocity2, timeMax, timeFirst, timeLast);
}
else {
return false;
}
}
// Return true and compute a collision contact if the two OBB collide.
// This method implements the separating algorithm between two OBB. The goal of this method is to compute the
// time (in the interval [0, timeMax] at wich the two bodies will collide if they will collide. If they will
// collide we report a collision contact. "velocity1" and "velocity2" are the velocity vectors of the two bodies.
// If they collide, timeFirst will contain the first collision time of the two bodies and timeLast will contain
// the time when the two bodies separate after the collision. The separation axis that have to be tested for two
// OBB are the six face normals (3 for each OBB) and the nine vectors V = Ai x Bj where Ai is the ith face normal
// vector of OBB 1 and Bj is the jth face normal vector of OBB 2. We will use the notation Ai for the ith face
// normal of OBB 1 and Bj for the jth face normal of OBB 2.
bool SeparatingAxisOBB::computeCollisionTest(const OBB* const obb1, const OBB* const obb2, Contact** contact,
const Vector3D& velocity1, const Vector3D& velocity2, const Time& timeMax,
Time& timeFirst, Time& timeLast) {
double center; // Center
double speed; // Relavtive speed of the projection intervals (dotProduct(SeparatingAxis, deltaVelocity))
double radius1; // Radius of projection interval [min1, max1]
double radius2; // Radius of projection interval [min2, max2]
double min1; // Minimum of interval 1
double max1; // Maximum of interval 1
double min2; // Minimm of interval 2
double max2; // Maximum of interval 2
const double cutoff = 0.999999; // Cutoff for cosine of angles between box axes
bool existsParallelPair = false; // True if there exists two face normals that are parallel.
// This is used because if a parallel pair exists, it is sufficient
// to test only the face normals of the OBBs for separation. Two nearly
// parallel faces can lead to all face normal tests reporting no separation
// along those directions. The cross product directions are tested next, but
// Ai x Bj is nearly the zero vector and can cause a report that the two OBBs
// are not intersecting when in fact they are.
double c[3][3]; // c[i][j] = DotProduct(obb1.Ai, obb2.Bj)
double absC[3][3]; // absC[i][j] = abs(DotProduct(obb1.Ai, obb2.Bj))
double udc1[3]; // DotProduct(obb1.Ai, obb2.center - obb1.center)
double udv1[3]; // DotProduct(obb1.Ai, velocity2 - velocity1)
double udc2[3]; // DotProduct(obb2.Ai, obb2.center - obb1.center)
double udv2[3]; // DotProduct(obb2.Ai, velocity2 - velocity1)
Vector3D deltaVelocity = velocity2-velocity1; // Difference of box center velocities
Vector3D boxDistance = obb2->getCenter() - obb1->getCenter(); // Distance between the centers of the OBBs
timeFirst.setValue(0.0); // timeFirst = 0
timeLast.setValue(DBL_MAX); // timeLast = infinity
// Axis A0
for (int i=0; i<3; ++i) {
c[0][i] = obb1->getAxis(0).scalarProduct(obb2->getAxis(i));
absC[0][i] = fabs(c[0][i]);
if (absC[0][i] > cutoff) {
existsParallelPair = true;
}
}
udc1[0] = obb1->getAxis(0).scalarProduct(boxDistance);
udv1[0] = obb1->getAxis(0).scalarProduct(deltaVelocity);
center = udc1[0];
speed = udv1[0];
radius1 = obb1->getExtent(0);
radius2 = obb2->getExtent(0)*absC[0][0] + obb2->getExtent(1)*absC[0][1] + obb2->getExtent(2) * absC[0][2];
min1 = -radius1;
max1 = radius1;
min2 = center - radius2;
max2 = center + radius2;
std::cout << "Speed : " << speed << std::endl;
std::cout << "min1 : " << min1 << std::endl;
std::cout << "max1 : " << max1 << std::endl;
std::cout << "min2 : " << min2 << std::endl;
std::cout << "max2 : " << max2 << std::endl;
if(!computeIntervalsIntersectionTime(timeMax, speed, min1, max1, min2, max2, timeFirst, timeLast)) {
// We have found a separation axis, therefore the two OBBs don't collide
return false;
}
// Axis A1
for (int i=0; i<3; ++i) {
c[1][i] = obb1->getAxis(1).scalarProduct(obb2->getAxis(i));
absC[1][i] = fabs(c[1][i]);
if (absC[1][i] > cutoff) {
existsParallelPair = true;
}
}
udc1[1] = obb1->getAxis(1).scalarProduct(boxDistance);
udv1[1] = obb1->getAxis(1).scalarProduct(deltaVelocity);
center = udc1[1];
std::cout << "Axis - X : " << obb1->getAxis(1).getX() << "Y : " << obb1->getAxis(1).getY() << "Z : " << obb1->getAxis(1).getZ() << std::endl;
std::cout << "Distance - X : " << boxDistance.getX() << "Y : " << boxDistance.getY() << "Z : " << boxDistance.getZ() << std::endl;
std::cout << "Center : " << center << std::endl;
speed = udv1[1];
radius1 = obb1->getExtent(1);
radius2 = obb2->getExtent(0)*absC[1][0] + obb2->getExtent(1)*absC[1][1] + obb2->getExtent(2) * absC[1][2];
min1 = -radius1;
max1 = radius1;
min2 = center - radius2;
max2 = center + radius2;
std::cout << "Speed : " << speed << std::endl;
std::cout << "min1 : " << min1 << std::endl;
std::cout << "max1 : " << max1 << std::endl;
std::cout << "min2 : " << min2 << std::endl;
std::cout << "max2 : " << max2 << std::endl;
if(!computeIntervalsIntersectionTime(timeMax, speed, min1, max1, min2, max2, timeFirst, timeLast)) {
// We have found a separation axis, therefore the two OBBs don't collide
return false;
}
// Axis A2
for (int i=0; i<3; ++i) {
c[2][i] = obb1->getAxis(2).scalarProduct(obb2->getAxis(i));
absC[2][i] = fabs(c[2][i]);
if (absC[2][i] > cutoff) {
existsParallelPair = true;
}
}
udc1[2] = obb1->getAxis(2).scalarProduct(boxDistance);
udv1[2] = obb1->getAxis(2).scalarProduct(deltaVelocity);
center = udc1[2];
speed = udv1[2];
radius1 = obb1->getExtent(2);
radius2 = obb2->getExtent(0)*absC[2][0] + obb2->getExtent(1)*absC[2][1] + obb2->getExtent(2) * absC[2][2];
min1 = -radius1;
max1 = radius1;
min2 = center - radius2;
max2 = center + radius2;
std::cout << "Speed : " << speed << std::endl;
std::cout << "min1 : " << min1 << std::endl;
std::cout << "max1 : " << max1 << std::endl;
std::cout << "min2 : " << min2 << std::endl;
std::cout << "max2 : " << max2 << std::endl;
if(!computeIntervalsIntersectionTime(timeMax, speed, min1, max1, min2, max2, timeFirst, timeLast)) {
// We have found a separation axis, therefore the two OBBs don't collide
return false;
}
// Axis B0
udc2[0] = obb2->getAxis(0).scalarProduct(boxDistance);
udv2[0] = obb2->getAxis(0).scalarProduct(deltaVelocity);
center = udc2[0];
speed = udv2[0];
radius1 = obb1->getExtent(0)*absC[0][0] + obb1->getExtent(1)*absC[1][0] + obb1->getExtent(2) * absC[1][0];
radius2 = obb2->getExtent(0);
min1 = center - radius1;
max1 = center + radius1;
min2 = -radius2;
max2 = radius2;
if(!computeIntervalsIntersectionTime(timeMax, speed, min1, max1, min2, max2, timeFirst, timeLast)) {
// We have found a separation axis, therefore the two OBBs don't collide
return false;
}
// Axis B1
udc2[1] = obb2->getAxis(1).scalarProduct(boxDistance);
udv2[1] = obb2->getAxis(1).scalarProduct(deltaVelocity);
center = udc2[1];
speed = udv2[1];
radius1 = obb1->getExtent(0)*absC[0][1] + obb1->getExtent(1)*absC[1][1] + obb1->getExtent(2) * absC[1][1];
radius2 = obb2->getExtent(1);
min1 = center - radius1;
max1 = center + radius1;
min2 = -radius2;
max2 = radius2;
if(!computeIntervalsIntersectionTime(timeMax, speed, min1, max1, min2, max2, timeFirst, timeLast)) {
// We have found a separation axis, therefore the two OBBs don't collide
return false;
}
// Axis B2
udc2[2] = obb2->getAxis(2).scalarProduct(boxDistance);
udv2[2] = obb2->getAxis(2).scalarProduct(deltaVelocity);
center = udc2[2];
speed = udv2[2];
radius1 = obb1->getExtent(0)*absC[0][2] + obb1->getExtent(1)*absC[1][2] + obb1->getExtent(2) * absC[1][2];
radius2 = obb2->getExtent(2);
min1 = center - radius1;
max1 = center + radius1;
min2 = -radius2;
max2 = radius2;
if(!computeIntervalsIntersectionTime(timeMax, speed, min1, max1, min2, max2, timeFirst, timeLast)) {
// We have found a separation axis, therefore the two OBBs don't collide
return false;
}
// If there exists a parallel pair of face normals
if (existsParallelPair) {
// There exists a parallel pair of face normals and we have already checked all the face
// normals for separation. Therefore the OBBs must intersect
// TODO : Delete this
(*contact) = new Contact(obb1->getBodyPointer(), obb2->getBodyPointer(), Vector3D(1,0,0));
std::cout << "Contact : " << contact << std::endl;
return true;
}
// Axis A0 x B0
center = udc1[2] * c[1][0] - udc1[1] * c[2][0];
speed = udv1[2] * c[1][0] - udv1[1] * c[2][0];
radius1 = obb1->getExtent(1) * absC[2][0] + obb1->getExtent(2) * absC[1][0];
radius2 = obb2->getExtent(1) * absC[0][2] + obb2->getExtent(2) * absC[0][1];
min1 = -radius1;
max1 = radius1;
min2 = center - radius2;
max2 = center + radius2;
if(!computeIntervalsIntersectionTime(timeMax, speed, min1, max1, min2, max2, timeFirst, timeLast)) {
// We have found a separation axis, therefore the two OBBs don't collide
return false;
}
// Axis A0 x B1
center = udc1[2] * c[1][1] - udc1[1] * c[2][1];
speed = udv1[2] * c[1][1] - udv1[1] * c[2][1];
radius1 = obb1->getExtent(1) * absC[2][1] + obb1->getExtent(2) * absC[1][1];
radius2 = obb2->getExtent(0) * absC[0][2] + obb2->getExtent(2) * absC[0][0];
min1 = -radius1;
max1 = radius1;
min2 = center - radius2;
max2 = center + radius2;
if(!computeIntervalsIntersectionTime(timeMax, speed, min1, max1, min2, max2, timeFirst, timeLast)) {
// We have found a separation axis, therefore the two OBBs don't collide
return false;
}
// Axis A0 x B2
center = udc1[2] * c[1][2] - udc1[1] * c[2][2];
speed = udv1[2] * c[1][2] - udv1[1] * c[2][2];
radius1 = obb1->getExtent(1) * absC[2][2] + obb1->getExtent(2) * absC[1][2];
radius2 = obb2->getExtent(0) * absC[0][1] + obb2->getExtent(1) * absC[0][0];
min1 = -radius1;
max1 = radius1;
min2 = center - radius2;
max2 = center + radius2;
if(!computeIntervalsIntersectionTime(timeMax, speed, min1, max1, min2, max2, timeFirst, timeLast)) {
// We have found a separation axis, therefore the two OBBs don't collide
return false;
}
// Axis A1 x B0
center = udc1[0] * c[2][0] - udc1[2] * c[0][0];
speed = udv1[0] * c[2][0] - udv1[2] * c[0][0];
radius1 = obb1->getExtent(0) * absC[2][0] + obb1->getExtent(2) * absC[0][0];
radius2 = obb2->getExtent(1) * absC[1][2] + obb2->getExtent(2) * absC[1][1];
min1 = -radius1;
max1 = radius1;
min2 = center - radius2;
max2 = center + radius2;
if(!computeIntervalsIntersectionTime(timeMax, speed, min1, max1, min2, max2, timeFirst, timeLast)) {
// We have found a separation axis, therefore the two OBBs don't collide
return false;
}
// Axis A1 x B1
center = udc1[0] * c[2][1] - udc1[2] * c[0][1];
speed = udv1[0] * c[2][1] - udv1[2] * c[0][1];
radius1 = obb1->getExtent(0) * absC[2][1] + obb1->getExtent(2) * absC[0][1];
radius2 = obb2->getExtent(0) * absC[1][2] + obb2->getExtent(2) * absC[1][0];
min1 = -radius1;
max1 = radius1;
min2 = center - radius2;
max2 = center + radius2;
if(!computeIntervalsIntersectionTime(timeMax, speed, min1, max1, min2, max2, timeFirst, timeLast)) {
// We have found a separation axis, therefore the two OBBs don't collide
return false;
}
// Axis A1 x B2
center = udc1[0] * c[2][2] - udc1[2] * c[0][2];
speed = udv1[0] * c[2][2] - udv1[2] * c[0][2];
radius1 = obb1->getExtent(0) * absC[2][2] + obb1->getExtent(2) * absC[0][2];
radius2 = obb2->getExtent(0) * absC[1][1] + obb2->getExtent(1) * absC[1][0];
min1 = -radius1;
max1 = radius1;
min2 = center - radius2;
max2 = center + radius2;
if(!computeIntervalsIntersectionTime(timeMax, speed, min1, max1, min2, max2, timeFirst, timeLast)) {
// We have found a separation axis, therefore the two OBBs don't collide
return false;
}
// Axis A2 x B0
center = udc1[1] * c[0][0] - udc1[0] * c[1][0];
speed = udv1[1] * c[0][0] - udv1[0] * c[1][0];
radius1 = obb1->getExtent(0) * absC[1][0] + obb1->getExtent(1) * absC[0][0];
radius2 = obb2->getExtent(1) * absC[2][2] + obb2->getExtent(2) * absC[2][1];
min1 = -radius1;
max1 = radius1;
min2 = center - radius2;
max2 = center + radius2;
if(!computeIntervalsIntersectionTime(timeMax, speed, min1, max1, min2, max2, timeFirst, timeLast)) {
// We have found a separation axis, therefore the two OBBs don't collide
return false;
}
// Axis A2 x B1
center = udc1[1] * c[0][1] - udc1[0] * c[1][1];
speed = udv1[1] * c[0][1] - udv1[0] * c[1][1];
radius1 = obb1->getExtent(0) * absC[1][1] + obb1->getExtent(1) * absC[0][1];
radius2 = obb2->getExtent(0) * absC[2][2] + obb2->getExtent(2) * absC[2][0];
min1 = -radius1;
max1 = radius1;
min2 = center - radius2;
max2 = center + radius2;
if(!computeIntervalsIntersectionTime(timeMax, speed, min1, max1, min2, max2, timeFirst, timeLast)) {
// We have found a separation axis, therefore the two OBBs don't collide
return false;
}
// Axis A2 x B2
center = udc1[1] * c[0][2] - udc1[0] * c[1][2];
speed = udv1[1] * c[0][2] - udv1[0] * c[1][2];
radius1 = obb1->getExtent(0) * absC[1][2] + obb1->getExtent(1) * absC[0][2];
radius2 = obb2->getExtent(0) * absC[2][1] + obb2->getExtent(1) * absC[2][0];
min1 = -radius1;
max1 = radius1;
min2 = center - radius2;
max2 = center + radius2;
if(!computeIntervalsIntersectionTime(timeMax, speed, min1, max1, min2, max2, timeFirst, timeLast)) {
// We have found a separation axis, therefore the two OBBs don't collide
return false;
}
// TODO : Delete this
(*contact) = new Contact(obb1->getBodyPointer(), obb2->getBodyPointer(), Vector3D(1,0,0));
std::cout << "Contact2 : " << contact << std::endl;
// We have found no separation axis, therefore the two OBBs must collide
return true;
}
// This method computes the intersection time of two projection intervals.
// This method takes two projection intervals [min1, max1] and [min2, max2] and computes (if the
// two intervals intersect) in the time interval [0, timeMax] the time timeFirst where the two bodies
// enter in collision and the time timeLast where the two bodies separate themself from the collision.
// We consider that the interval 2 move at the speed "speed" and the interval 1 don't move.
// The method returns true if the two projection intervals intersect and false if they move appart.
// This method will be called for each separation axis.
bool SeparatingAxisOBB::computeIntervalsIntersectionTime(const Time& timeMax, double speed, double min1, double max1,
double min2, double max2, Time& timeFirst, Time& timeLast) {
double speedInverse = 1.0/speed;
double t;
// If the interval [min0, max0] is on right of interval [min1, max1]
if (max2 < min1) {
// If the two intervals move apart they will not intersect
if (speed <= 0) {
return false;
}
// Compute the time t when the two intervals enter in contact
t = (min1-max2) * speedInverse;
// If we found a later collision time, we update the first collision time
if (t > timeFirst.getValue()) {
timeFirst.setValue(t);
}
// If the first collision time is outside of the time interval [0, timeMax]
if(timeFirst.getValue() > timeMax.getValue()) {
return false;
}
// Compute the time t when the two intervals separate from a contact
t = (max1 - min2) * speedInverse;
// If we found a earlier separated collision time, we update the last collision time
if (t < timeLast.getValue()) {
timeLast.setValue(t);
}
// If the first collision time occurs after the last collision time
if (timeFirst.getValue() > timeLast.getValue()) {
return false;
}
}
else if (max1 < min2) { // If the interval [min0, max0] is on left of interval [min1, max1]
// If the two intervals move apart they will not intersect
if (speed >= 0) {
return false;
}
// Compute the time t when the two intervals enter in contact
t = (max1 - min2) * speedInverse;
// If we found a later collision time
if (t > timeFirst.getValue()) {
timeFirst.setValue(t);
}
// If the first collision time is outside of the time interval [0, timeMax]
if(timeFirst.getValue() > timeMax.getValue()) {
return false;
}
// Compute the time t when the two intervals separate from a contact
t = (min1 - max2) * speedInverse;
// If we found a earlier separated collision time
if (t < timeLast.getValue()) {
timeLast.setValue(t);
}
// If the first collision time occurs after the last collision time
if (timeFirst.getValue() > timeLast.getValue()) {
return false;
}
}
else { // If the two intervals overlap
if (speed > 0) {
// Compute the time t when the two intervals separate from a contact
t = (max1 - min2) * speedInverse;
// If we found a earlier separated collision time
if (t < timeLast.getValue()) {
timeLast.setValue(t);
}
// If the first collision time occurs after the last collision time
if (timeFirst.getValue() > timeLast.getValue()) {
return false;
}
}
else if (speed < 0) {
// Compute the time t when the two intervals separate from a contact
t = (min1 - max2) * speedInverse;
// If we found a earlier separated collision time
if (t < timeLast.getValue()) {
timeLast.setValue(t);
}
// If the first collision time occurs after the last collision time
if (timeFirst.getValue() > timeLast.getValue()) {
return false;
}
}
}
return true;
}

24
sources/reactphysics3d/collision/SeparatingAxisOBB.h
View File

@ -23,18 +23,40 @@
// Libraries
#include "NarrowPhaseAlgorithm.h"
#include "../constraint/Contact.h"
#include "../body/OBB.h"
// ReactPhysics3D namespace
namespace reactphysics3d {
/* -------------------------------------------------------------------
Class SeparatingAxisOBB :
This class implements a narrow-phase algorithm. This algorithm
uses a separating axis technique with oriented bounding box
(OBB) to check if two bounding volumes collide or not. If the
two bounding volumes collide we have to create a contact object
to describe the collision contact. The idea is to check if there
exists an axis where, if we project the two bounding volumes on
this axis, the two projections are separated. If we find at
least an axis where the projections of the two bounding volumes
are separated then we know that the two bounding volumes don't
intersect.
-------------------------------------------------------------------
*/
class SeparatingAxisOBB : public NarrowPhaseAlgorithm {
private :
bool computeCollisionTest(const OBB* const obb1, const OBB* const obb2, Contact** contact,
const Vector3D& velocity1, const Vector3D& velocity2,
const Time& timeMax, Time& timeFirst, Time& timeLast); // Return true and compute a collision contact if the two OBB collide
bool computeIntervalsIntersectionTime(const Time& timeMax, double speed, double min0, double max0,
double min1, double max1, Time& timeFirst, Time& timeLast); // Compute the intersection time of two projection intervals
public :
SeparatingAxisOBB(); // Constructor
~SeparatingAxisOBB(); // Destructor
virtual bool testCollision(const BoundingVolume& boundingVolume1, const BoundingVolume& boundingVolume2, Contact* const contact); // Return true and compute a collision contact if the two bounding volume collide
virtual bool testCollision(const BoundingVolume* const boundingVolume1, const BoundingVolume* const boundingVolume2,
Contact** contact, const Vector3D& velocity1, const Vector3D& velocity2, const Time& timeMax,
Time& timeFirst, Time& timeLast); // Return true and compute a collision contact if the two bounding volume collide
};