reactphysics3d/test/tests/collision/TestRaycast.h
2018-01-26 17:34:26 +01:00

2053 lines
99 KiB
C++

/********************************************************************************
* ReactPhysics3D physics library, http://www.reactphysics3d.com *
* Copyright (c) 2010-2016 Daniel Chappuis *
*********************************************************************************
* *
* This software is provided 'as-is', without any express or implied warranty. *
* In no event will the authors be held liable for any damages arising from the *
* use of this software. *
* *
* Permission is granted to anyone to use this software for any purpose, *
* including commercial applications, and to alter it and redistribute it *
* freely, subject to the following restrictions: *
* *
* 1. The origin of this software must not be misrepresented; you must not claim *
* that you wrote the original software. If you use this software in a *
* product, an acknowledgment in the product documentation would be *
* appreciated but is not required. *
* *
* 2. Altered source versions must be plainly marked as such, and must not be *
* misrepresented as being the original software. *
* *
* 3. This notice may not be removed or altered from any source distribution. *
* *
********************************************************************************/
#ifndef TEST_RAYCAST_H
#define TEST_RAYCAST_H
// Libraries
#include "Test.h"
#include "engine/CollisionWorld.h"
#include "body/CollisionBody.h"
#include "collision/shapes/BoxShape.h"
#include "collision/shapes/SphereShape.h"
#include "collision/shapes/CapsuleShape.h"
#include "collision/shapes/ConvexMeshShape.h"
#include "collision/shapes/TriangleShape.h"
#include "collision/shapes/ConcaveMeshShape.h"
#include "collision/shapes/HeightFieldShape.h"
/// Reactphysics3D namespace
namespace reactphysics3d {
// Enumeration for categories
enum Category {
CATEGORY1 = 0x0001,
CATEGORY2 = 0x0002
};
/// Class WorldRaycastCallback
class WorldRaycastCallback : public RaycastCallback {
public:
RaycastInfo raycastInfo;
ProxyShape* shapeToTest;
bool isHit;
WorldRaycastCallback() {
isHit = false;
shapeToTest = nullptr;
}
virtual decimal notifyRaycastHit(const RaycastInfo& info) override {
if (shapeToTest->getBody()->getID() == info.body->getID()) {
raycastInfo.body = info.body;
raycastInfo.hitFraction = info.hitFraction;
raycastInfo.proxyShape = info.proxyShape;
raycastInfo.worldNormal = info.worldNormal;
raycastInfo.worldPoint = info.worldPoint;
isHit = true;
}
// Return a fraction of 1.0 because we need to gather all hits
return decimal(1.0);
}
void reset() {
raycastInfo.body = nullptr;
raycastInfo.hitFraction = decimal(0.0);
raycastInfo.proxyShape = nullptr;
raycastInfo.worldNormal.setToZero();
raycastInfo.worldPoint.setToZero();
isHit = false;
}
};
// Class TestPointInside
/**
* Unit test for the CollisionBody::testPointInside() method.
*/
class TestRaycast : public Test {
private :
// ---------- Atributes ---------- //
// Raycast callback class
WorldRaycastCallback mCallback;
DefaultAllocator mAllocator;
// Epsilon
decimal epsilon;
// Physics world
CollisionWorld* mWorld;
// Bodies
CollisionBody* mBoxBody;
CollisionBody* mSphereBody;
CollisionBody* mCapsuleBody;
CollisionBody* mConvexMeshBody;
CollisionBody* mCylinderBody;
CollisionBody* mCompoundBody;
CollisionBody* mTriangleBody;
CollisionBody* mConcaveMeshBody;
CollisionBody* mHeightFieldBody;
// Transform
Transform mBodyTransform;
Transform mShapeTransform;
Transform mLocalShapeToWorld;
Transform mLocalShape2ToWorld;
// Collision shapes
BoxShape* mBoxShape;
SphereShape* mSphereShape;
CapsuleShape* mCapsuleShape;
ConvexMeshShape* mConvexMeshShape;
TriangleShape* mTriangleShape;
ConcaveShape* mConcaveMeshShape;
HeightFieldShape* mHeightFieldShape;
// Proxy Shapes
ProxyShape* mBoxProxyShape;
ProxyShape* mSphereProxyShape;
ProxyShape* mCapsuleProxyShape;
ProxyShape* mConvexMeshProxyShape;
ProxyShape* mCompoundSphereProxyShape;
ProxyShape* mCompoundCapsuleProxyShape;
ProxyShape* mTriangleProxyShape;
ProxyShape* mConcaveMeshProxyShape;
ProxyShape* mHeightFieldProxyShape;
// Triangle meshes
TriangleMesh mConcaveTriangleMesh;
std::vector<Vector3> mConcaveMeshVertices;
std::vector<uint> mConcaveMeshIndices;
TriangleVertexArray* mConcaveMeshVertexArray;
float mHeightFieldData[100];
PolygonVertexArray::PolygonFace mPolygonFaces[6];
PolygonVertexArray* mPolygonVertexArray;
PolyhedronMesh* mPolyhedronMesh;
Vector3 mPolyhedronVertices[8];
int mPolyhedronIndices[4 * 6];
public :
// ---------- Methods ---------- //
/// Constructor
TestRaycast(const std::string& name) : Test(name) {
epsilon = decimal(0.0001);
// Create the world
mWorld = new CollisionWorld();
// Body transform
Vector3 position(-3, 2, 7);
Quaternion orientation = Quaternion::fromEulerAngles(PI / 5, PI / 6, PI / 7);
mBodyTransform = Transform(position, orientation);
// Create the bodies
mBoxBody = mWorld->createCollisionBody(mBodyTransform);
mSphereBody = mWorld->createCollisionBody(mBodyTransform);
mCapsuleBody = mWorld->createCollisionBody(mBodyTransform);
mConvexMeshBody = mWorld->createCollisionBody(mBodyTransform);
mCylinderBody = mWorld->createCollisionBody(mBodyTransform);
mCompoundBody = mWorld->createCollisionBody(mBodyTransform);
mTriangleBody = mWorld->createCollisionBody(mBodyTransform);
mConcaveMeshBody = mWorld->createCollisionBody(mBodyTransform);
mHeightFieldBody = mWorld->createCollisionBody(mBodyTransform);
// Collision shape transform
Vector3 shapePosition(1, -4, -3);
Quaternion shapeOrientation = Quaternion::fromEulerAngles(3 * PI / 6 , -PI / 8, PI / 3);
mShapeTransform = Transform(shapePosition, shapeOrientation);
// Compute the the transform from a local shape point to world-space
mLocalShapeToWorld = mBodyTransform * mShapeTransform;
// Create collision shapes
mBoxShape = new BoxShape(Vector3(2, 3, 4));
mBoxProxyShape = mBoxBody->addCollisionShape(mBoxShape, mShapeTransform);
mSphereShape = new SphereShape(3);
mSphereProxyShape = mSphereBody->addCollisionShape(mSphereShape, mShapeTransform);
Vector3 triangleVertices[3];
triangleVertices[0] = Vector3(100, 100, 0);
triangleVertices[1] = Vector3(105, 100, 0);
triangleVertices[2] = Vector3(100, 103, 0);
Vector3 triangleVerticesNormals[3] = {Vector3(0, 0, 1), Vector3(0, 0, 1), Vector3(0, 0, 1)};
mTriangleShape = new TriangleShape(triangleVertices, triangleVerticesNormals, 0, mAllocator);
mTriangleProxyShape = mTriangleBody->addCollisionShape(mTriangleShape, mShapeTransform);
mCapsuleShape = new CapsuleShape(2, 5);
mCapsuleProxyShape = mCapsuleBody->addCollisionShape(mCapsuleShape, mShapeTransform);
mPolyhedronVertices[0] = Vector3(-2, -3, 4);
mPolyhedronVertices[1] = Vector3(2, -3, 4);
mPolyhedronVertices[2] = Vector3(2, 3, 4);
mPolyhedronVertices[3] = Vector3(-2, 3, 4);
mPolyhedronVertices[4] = Vector3(2, -3, -4);
mPolyhedronVertices[5] = Vector3(2, 3, -4);
mPolyhedronVertices[6] = Vector3(-2, 3, -4);
mPolyhedronVertices[7] = Vector3(-2, -3, -4);
mPolyhedronIndices[0] = 0; mPolyhedronIndices[1] = 1; mPolyhedronIndices[2] = 2; mPolyhedronIndices[3] = 3;
mPolyhedronIndices[4] = 1; mPolyhedronIndices[5] = 4; mPolyhedronIndices[6] = 5; mPolyhedronIndices[7] = 2;
mPolyhedronIndices[8] = 4; mPolyhedronIndices[9] = 7; mPolyhedronIndices[10] = 6; mPolyhedronIndices[11] = 5;
mPolyhedronIndices[12] = 0; mPolyhedronIndices[13] = 3; mPolyhedronIndices[14] = 6; mPolyhedronIndices[15] = 7;
mPolyhedronIndices[16] = 2; mPolyhedronIndices[17] = 5; mPolyhedronIndices[18] = 6; mPolyhedronIndices[19] = 3;
mPolyhedronIndices[20] = 1; mPolyhedronIndices[21] = 0; mPolyhedronIndices[22] = 7; mPolyhedronIndices[23] = 4;
// Polygon faces descriptions for the polyhedron
for (int f=0; f < 8; f++) {
PolygonVertexArray::PolygonFace& face = mPolygonFaces[f];
face.indexBase = f * 4;
face.nbVertices = 4;
}
// Create the polygon vertex array
mPolygonVertexArray = new PolygonVertexArray(8, mPolyhedronVertices, sizeof(Vector3),
mPolyhedronIndices, sizeof(int), 6, mPolygonFaces,
PolygonVertexArray::VertexDataType::VERTEX_FLOAT_TYPE,
PolygonVertexArray::IndexDataType::INDEX_INTEGER_TYPE);
mPolyhedronMesh = new PolyhedronMesh(mPolygonVertexArray);
mConvexMeshShape = new ConvexMeshShape(mPolyhedronMesh);
mConvexMeshProxyShape = mConvexMeshBody->addCollisionShape(mConvexMeshShape, mShapeTransform);
// Compound shape is a cylinder and a sphere
Vector3 positionShape2(Vector3(4, 2, -3));
Quaternion orientationShape2 = Quaternion::fromEulerAngles(-3 *PI / 8, 1.5 * PI/ 3, PI / 13);
Transform shapeTransform2(positionShape2, orientationShape2);
mLocalShape2ToWorld = mBodyTransform * shapeTransform2;
mCompoundCapsuleProxyShape = mCompoundBody->addCollisionShape(mCapsuleShape, mShapeTransform);
mCompoundSphereProxyShape = mCompoundBody->addCollisionShape(mSphereShape, shapeTransform2);
// Concave Mesh shape
mConcaveMeshVertices.push_back(Vector3(-2, -3, -4));
mConcaveMeshVertices.push_back(Vector3(2, -3, -4));
mConcaveMeshVertices.push_back(Vector3(2, -3, 4));
mConcaveMeshVertices.push_back(Vector3(-2, -3, 4));
mConcaveMeshVertices.push_back(Vector3(-2, 3, -4));
mConcaveMeshVertices.push_back(Vector3(2, 3, -4));
mConcaveMeshVertices.push_back(Vector3(2, 3, 4));
mConcaveMeshVertices.push_back(Vector3(-2, 3, 4));
mConcaveMeshIndices.push_back(0); mConcaveMeshIndices.push_back(1); mConcaveMeshIndices.push_back(2);
mConcaveMeshIndices.push_back(0); mConcaveMeshIndices.push_back(2); mConcaveMeshIndices.push_back(3);
mConcaveMeshIndices.push_back(1); mConcaveMeshIndices.push_back(5); mConcaveMeshIndices.push_back(2);
mConcaveMeshIndices.push_back(2); mConcaveMeshIndices.push_back(5); mConcaveMeshIndices.push_back(6);
mConcaveMeshIndices.push_back(2); mConcaveMeshIndices.push_back(7); mConcaveMeshIndices.push_back(3);
mConcaveMeshIndices.push_back(2); mConcaveMeshIndices.push_back(6); mConcaveMeshIndices.push_back(7);
mConcaveMeshIndices.push_back(0); mConcaveMeshIndices.push_back(3); mConcaveMeshIndices.push_back(4);
mConcaveMeshIndices.push_back(3); mConcaveMeshIndices.push_back(7); mConcaveMeshIndices.push_back(4);
mConcaveMeshIndices.push_back(0); mConcaveMeshIndices.push_back(4); mConcaveMeshIndices.push_back(1);
mConcaveMeshIndices.push_back(1); mConcaveMeshIndices.push_back(4); mConcaveMeshIndices.push_back(5);
mConcaveMeshIndices.push_back(5); mConcaveMeshIndices.push_back(7); mConcaveMeshIndices.push_back(6);
mConcaveMeshIndices.push_back(4); mConcaveMeshIndices.push_back(7); mConcaveMeshIndices.push_back(5);
TriangleVertexArray::VertexDataType vertexType = sizeof(decimal) == 4 ? TriangleVertexArray::VertexDataType::VERTEX_FLOAT_TYPE :
TriangleVertexArray::VertexDataType::VERTEX_DOUBLE_TYPE;
mConcaveMeshVertexArray =
new TriangleVertexArray(8, &(mConcaveMeshVertices[0]), sizeof(Vector3),
12, &(mConcaveMeshIndices[0]), 3 * sizeof(uint),
vertexType, TriangleVertexArray::IndexDataType::INDEX_INTEGER_TYPE);
// Add the triangle vertex array of the subpart to the triangle mesh
mConcaveTriangleMesh.addSubpart(mConcaveMeshVertexArray);
mConcaveMeshShape = new ConcaveMeshShape(&mConcaveTriangleMesh);
mConcaveMeshProxyShape = mConcaveMeshBody->addCollisionShape(mConcaveMeshShape, mShapeTransform);
// Heightfield shape (plane height field at height=4)
for (int i=0; i<100; i++) mHeightFieldData[i] = 4;
mHeightFieldShape = new HeightFieldShape(10, 10, 0, 4, mHeightFieldData, HeightFieldShape::HeightDataType::HEIGHT_FLOAT_TYPE);
mHeightFieldProxyShape = mHeightFieldBody->addCollisionShape(mHeightFieldShape, mShapeTransform);
// Assign proxy shapes to the different categories
mBoxProxyShape->setCollisionCategoryBits(CATEGORY1);
mSphereProxyShape->setCollisionCategoryBits(CATEGORY1);
mCapsuleProxyShape->setCollisionCategoryBits(CATEGORY1);
mConvexMeshProxyShape->setCollisionCategoryBits(CATEGORY2);
mCompoundSphereProxyShape->setCollisionCategoryBits(CATEGORY2);
mCompoundCapsuleProxyShape->setCollisionCategoryBits(CATEGORY2);
mTriangleProxyShape->setCollisionCategoryBits(CATEGORY1);
mConcaveMeshProxyShape->setCollisionCategoryBits(CATEGORY2);
mHeightFieldProxyShape->setCollisionCategoryBits(CATEGORY2);
}
/// Destructor
virtual ~TestRaycast() {
delete mBoxShape;
delete mSphereShape;
delete mCapsuleShape;
delete mConvexMeshShape;
delete mTriangleShape;
delete mConcaveMeshShape;
delete mHeightFieldShape;
delete mConcaveMeshVertexArray;
delete mPolygonVertexArray;
delete mPolyhedronMesh;
}
/// Run the tests
void run() {
testBox();
testSphere();
testCapsule();
testConvexMesh();
testCompound();
testTriangle();
testConcaveMesh();
testHeightField();
}
/// Test the ProxyBoxShape::raycast(), CollisionBody::raycast() and
/// CollisionWorld::raycast() methods.
void testBox() {
// ----- Test feedback data ----- //
Vector3 point1 = mLocalShapeToWorld * Vector3(1 , 2, 10);
Vector3 point2 = mLocalShapeToWorld * Vector3(1, 2, -20);
Ray ray(point1, point2);
Vector3 hitPoint = mLocalShapeToWorld * Vector3(1, 2, 4);
mCallback.shapeToTest = mBoxProxyShape;
// CollisionWorld::raycast()
mCallback.reset();
mWorld->raycast(ray, &mCallback);
test(mCallback.isHit);
test(mCallback.raycastInfo.body == mBoxBody);
test(mCallback.raycastInfo.proxyShape == mBoxProxyShape);
test(approxEqual(mCallback.raycastInfo.hitFraction, decimal(0.2), epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.z, hitPoint.z, epsilon));
// Correct category filter mask
mCallback.reset();
mWorld->raycast(ray, &mCallback, CATEGORY1);
test(mCallback.isHit);
// Wrong category filter mask
mCallback.reset();
mWorld->raycast(ray, &mCallback, CATEGORY2);
test(!mCallback.isHit);
// CollisionBody::raycast()
RaycastInfo raycastInfo2;
test(mBoxBody->raycast(ray, raycastInfo2));
test(raycastInfo2.body == mBoxBody);
test(raycastInfo2.proxyShape == mBoxProxyShape);
test(approxEqual(raycastInfo2.hitFraction, decimal(0.2), epsilon));
test(approxEqual(raycastInfo2.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo2.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo2.worldPoint.z, hitPoint.z, epsilon));
// ProxyCollisionShape::raycast()
RaycastInfo raycastInfo3;
test(mBoxProxyShape->raycast(ray, raycastInfo3));
test(raycastInfo3.body == mBoxBody);
test(raycastInfo3.proxyShape == mBoxProxyShape);
test(approxEqual(raycastInfo3.hitFraction, decimal(0.2), epsilon));
test(approxEqual(raycastInfo3.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo3.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo3.worldPoint.z, hitPoint.z, epsilon));
Ray ray1(mLocalShapeToWorld * Vector3(0, 0, 0), mLocalShapeToWorld * Vector3(5, 7, -1));
Ray ray2(mLocalShapeToWorld * Vector3(5, 11, 7), mLocalShapeToWorld * Vector3(17, 29, 28));
Ray ray3(mLocalShapeToWorld * Vector3(1, 2, 3), mLocalShapeToWorld * Vector3(-11, 2, 24));
Ray ray4(mLocalShapeToWorld * Vector3(10, 10, 10), mLocalShapeToWorld * Vector3(22, 28, 31));
Ray ray5(mLocalShapeToWorld * Vector3(3, 1, -5), mLocalShapeToWorld * Vector3(-30, 1, -5));
Ray ray6(mLocalShapeToWorld * Vector3(4, 4, 1), mLocalShapeToWorld * Vector3(4, -20, 1));
Ray ray7(mLocalShapeToWorld * Vector3(1, -4, 5), mLocalShapeToWorld * Vector3(1, -4, -20));
Ray ray8(mLocalShapeToWorld * Vector3(-4, 4, 0), mLocalShapeToWorld * Vector3(20, 4, 0));
Ray ray9(mLocalShapeToWorld * Vector3(0, -4, -7), mLocalShapeToWorld * Vector3(0, 50, -7));
Ray ray10(mLocalShapeToWorld * Vector3(-3, 0, -6), mLocalShapeToWorld * Vector3(-3, 0, 20));
Ray ray11(mLocalShapeToWorld * Vector3(3, 1, 2), mLocalShapeToWorld * Vector3(-20, 1, 2));
Ray ray12(mLocalShapeToWorld * Vector3(1, 4, -1), mLocalShapeToWorld * Vector3(1, -20, -1));
Ray ray13(mLocalShapeToWorld * Vector3(-1, 2, 5), mLocalShapeToWorld * Vector3(-1, 2, -20));
Ray ray14(mLocalShapeToWorld * Vector3(-3, 2, -2), mLocalShapeToWorld * Vector3(20, 2, -2));
Ray ray15(mLocalShapeToWorld * Vector3(0, -4, 1), mLocalShapeToWorld * Vector3(0, 20, 1));
Ray ray16(mLocalShapeToWorld * Vector3(-1, 2, -5), mLocalShapeToWorld * Vector3(-1, 2, 20));
// ----- Test raycast miss ----- //
test(!mBoxBody->raycast(ray1, raycastInfo3));
test(!mBoxProxyShape->raycast(ray1, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray1, &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray1.point1, ray1.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray1.point1, ray1.point2, decimal(100.0)), &mCallback);
test(!mCallback.isHit);
test(!mBoxBody->raycast(ray2, raycastInfo3));
test(!mBoxProxyShape->raycast(ray2, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray2, &mCallback);
test(!mCallback.isHit);
test(!mBoxBody->raycast(ray3, raycastInfo3));
test(!mBoxProxyShape->raycast(ray3, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray3, &mCallback);
test(!mCallback.isHit);
test(!mBoxBody->raycast(ray4, raycastInfo3));
test(!mBoxProxyShape->raycast(ray4, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray4, &mCallback);
test(!mCallback.isHit);
test(!mBoxBody->raycast(ray5, raycastInfo3));
test(!mBoxProxyShape->raycast(ray5, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray5, &mCallback);
test(!mCallback.isHit);
test(!mBoxBody->raycast(ray6, raycastInfo3));
test(!mBoxProxyShape->raycast(ray6, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray6, &mCallback);
test(!mCallback.isHit);
test(!mBoxBody->raycast(ray7, raycastInfo3));
test(!mBoxProxyShape->raycast(ray7, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray7, &mCallback);
test(!mCallback.isHit);
test(!mBoxBody->raycast(ray8, raycastInfo3));
test(!mBoxProxyShape->raycast(ray8, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray8, &mCallback);
test(!mCallback.isHit);
test(!mBoxBody->raycast(ray9, raycastInfo3));
test(!mBoxProxyShape->raycast(ray9, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray9, &mCallback);
test(!mCallback.isHit);
test(!mBoxBody->raycast(ray10, raycastInfo3));
test(!mBoxProxyShape->raycast(ray10, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray10, &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray11.point1, ray11.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray12.point1, ray12.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray13.point1, ray13.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray14.point1, ray14.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray15.point1, ray15.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray16.point1, ray16.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
// ----- Test raycast hits ----- //
test(mBoxBody->raycast(ray11, raycastInfo3));
test(mBoxProxyShape->raycast(ray11, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray11, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray11.point1, ray11.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mBoxBody->raycast(ray12, raycastInfo3));
test(mBoxProxyShape->raycast(ray12, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray12, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray12.point1, ray12.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mBoxBody->raycast(ray13, raycastInfo3));
test(mBoxProxyShape->raycast(ray13, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray13, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray13.point1, ray13.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mBoxBody->raycast(ray14, raycastInfo3));
test(mBoxProxyShape->raycast(ray14, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray14, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray14.point1, ray14.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mBoxBody->raycast(ray15, raycastInfo3));
test(mBoxProxyShape->raycast(ray15, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray15, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray15.point1, ray15.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mBoxBody->raycast(ray16, raycastInfo3));
test(mBoxProxyShape->raycast(ray16, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray16, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray16.point1, ray16.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
}
/// Test the ProxySphereShape::raycast(), CollisionBody::raycast() and
/// CollisionWorld::raycast() methods.
void testSphere() {
// ----- Test feedback data ----- //
Vector3 point1 = mLocalShapeToWorld * Vector3(-5 , 0, 0);
Vector3 point2 = mLocalShapeToWorld * Vector3(5, 0, 0);
Ray ray(point1, point2);
Vector3 hitPoint = mLocalShapeToWorld * Vector3(-3, 0, 0);
mCallback.shapeToTest = mSphereProxyShape;
// CollisionWorld::raycast()
mCallback.reset();
mWorld->raycast(ray, &mCallback);
test(mCallback.isHit);
test(mCallback.raycastInfo.body == mSphereBody);
test(mCallback.raycastInfo.proxyShape == mSphereProxyShape);
test(approxEqual(mCallback.raycastInfo.hitFraction, 0.2, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.z, hitPoint.z, epsilon));
// Correct category filter mask
mCallback.reset();
mWorld->raycast(ray, &mCallback, CATEGORY1);
test(mCallback.isHit);
// Wrong category filter mask
mCallback.reset();
mWorld->raycast(ray, &mCallback, CATEGORY2);
test(!mCallback.isHit);
// CollisionBody::raycast()
RaycastInfo raycastInfo2;
test(mSphereBody->raycast(ray, raycastInfo2));
test(raycastInfo2.body == mSphereBody);
test(raycastInfo2.proxyShape == mSphereProxyShape);
test(approxEqual(raycastInfo2.hitFraction, 0.2, epsilon));
test(approxEqual(raycastInfo2.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo2.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo2.worldPoint.z, hitPoint.z, epsilon));
// ProxyCollisionShape::raycast()
RaycastInfo raycastInfo3;
test(mSphereProxyShape->raycast(ray, raycastInfo3));
test(raycastInfo3.body == mSphereBody);
test(raycastInfo3.proxyShape == mSphereProxyShape);
test(approxEqual(raycastInfo3.hitFraction, 0.2, epsilon));
test(approxEqual(raycastInfo3.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo3.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo3.worldPoint.z, hitPoint.z, epsilon));
Ray ray1(mLocalShapeToWorld * Vector3(0, 0, 0), mLocalShapeToWorld * Vector3(5, 7, -1));
Ray ray2(mLocalShapeToWorld * Vector3(5, 11, 7), mLocalShapeToWorld * Vector3(4, 6, 7));
Ray ray3(mLocalShapeToWorld * Vector3(1, 2, 2), mLocalShapeToWorld * Vector3(-4, 0, 7));
Ray ray4(mLocalShapeToWorld * Vector3(10, 10, 10), mLocalShapeToWorld * Vector3(4, 6, 7));
Ray ray5(mLocalShapeToWorld * Vector3(4, 1, -5), mLocalShapeToWorld * Vector3(-30, 1, -5));
Ray ray6(mLocalShapeToWorld * Vector3(4, 4, 1), mLocalShapeToWorld * Vector3(4, -30, 1));
Ray ray7(mLocalShapeToWorld * Vector3(1, -4, 5), mLocalShapeToWorld * Vector3(1, -4, -30));
Ray ray8(mLocalShapeToWorld * Vector3(-4, 4, 0), mLocalShapeToWorld * Vector3(30, 4, 0));
Ray ray9(mLocalShapeToWorld * Vector3(0, -4, -4), mLocalShapeToWorld * Vector3(0, 30, -4));
Ray ray10(mLocalShapeToWorld * Vector3(-4, 0, -6), mLocalShapeToWorld * Vector3(-4, 0, 30));
Ray ray11(mLocalShapeToWorld * Vector3(4, 1, 2), mLocalShapeToWorld * Vector3(-30, 1, 2));
Ray ray12(mLocalShapeToWorld * Vector3(1, 4, -1), mLocalShapeToWorld * Vector3(1, -30, -1));
Ray ray13(mLocalShapeToWorld * Vector3(-1, 2, 5), mLocalShapeToWorld * Vector3(-1, 2, -30));
Ray ray14(mLocalShapeToWorld * Vector3(-5, 2, -2), mLocalShapeToWorld * Vector3(30, 2, -2));
Ray ray15(mLocalShapeToWorld * Vector3(0, -4, 1), mLocalShapeToWorld * Vector3(0, 30, 1));
Ray ray16(mLocalShapeToWorld * Vector3(-1, 2, -11), mLocalShapeToWorld * Vector3(-1, 2, 30));
// ----- Test raycast miss ----- //
test(!mSphereBody->raycast(ray1, raycastInfo3));
test(!mSphereProxyShape->raycast(ray1, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray1, &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray1.point1, ray1.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray1.point1, ray1.point2, decimal(100.0)), &mCallback);
test(!mCallback.isHit);
test(!mSphereBody->raycast(ray2, raycastInfo3));
test(!mSphereProxyShape->raycast(ray2, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray2, &mCallback);
test(!mCallback.isHit);
test(!mSphereBody->raycast(ray3, raycastInfo3));
test(!mSphereProxyShape->raycast(ray3, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray3, &mCallback);
test(!mCallback.isHit);
test(!mSphereBody->raycast(ray4, raycastInfo3));
test(!mSphereProxyShape->raycast(ray4, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray4, &mCallback);
test(!mCallback.isHit);
test(!mSphereBody->raycast(ray5, raycastInfo3));
test(!mSphereProxyShape->raycast(ray5, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray5, &mCallback);
test(!mCallback.isHit);
test(!mSphereBody->raycast(ray6, raycastInfo3));
test(!mSphereProxyShape->raycast(ray6, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray6, &mCallback);
test(!mCallback.isHit);
test(!mSphereBody->raycast(ray7, raycastInfo3));
test(!mSphereProxyShape->raycast(ray7, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray7, &mCallback);
test(!mCallback.isHit);
test(!mSphereBody->raycast(ray8, raycastInfo3));
test(!mSphereProxyShape->raycast(ray8, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray8, &mCallback);
test(!mCallback.isHit);
test(!mSphereBody->raycast(ray9, raycastInfo3));
test(!mSphereProxyShape->raycast(ray9, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray9, &mCallback);
test(!mCallback.isHit);
test(!mSphereBody->raycast(ray10, raycastInfo3));
test(!mSphereProxyShape->raycast(ray10, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray10, &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray11.point1, ray11.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray12.point1, ray12.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray13.point1, ray13.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray14.point1, ray14.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray15.point1, ray15.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray16.point1, ray16.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
// ----- Test raycast hits ----- //
test(mSphereBody->raycast(ray11, raycastInfo3));
test(mSphereProxyShape->raycast(ray11, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray11, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray11.point1, ray11.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mSphereBody->raycast(ray12, raycastInfo3));
test(mSphereProxyShape->raycast(ray12, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray12, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray12.point1, ray12.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mSphereBody->raycast(ray13, raycastInfo3));
test(mSphereProxyShape->raycast(ray13, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray13, &mCallback);
mCallback.reset();
mWorld->raycast(Ray(ray13.point1, ray13.point2, decimal(0.8)), &mCallback);
test(mSphereBody->raycast(ray14, raycastInfo3));
test(mSphereProxyShape->raycast(ray14, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray14, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray14.point1, ray14.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mSphereBody->raycast(ray15, raycastInfo3));
test(mSphereProxyShape->raycast(ray15, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray15, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray15.point1, ray15.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mSphereBody->raycast(ray16, raycastInfo3));
test(mSphereProxyShape->raycast(ray16, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray16, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray16.point1, ray16.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
}
/// Test the ProxyCapsuleShape::raycast(), CollisionBody::raycast() and
/// CollisionWorld::raycast() methods.
void testCapsule() {
// ----- Test feedback data ----- //
Vector3 point1A = mLocalShapeToWorld * Vector3(4 , 1, 0);
Vector3 point1B = mLocalShapeToWorld * Vector3(-6, 1, 0);
Ray ray(point1A, point1B);
Vector3 hitPoint = mLocalShapeToWorld * Vector3(2, 1, 0);
Vector3 point2A = mLocalShapeToWorld * Vector3(0 , 6.5, 0);
Vector3 point2B = mLocalShapeToWorld * Vector3(0, -3.5, 0);
Ray rayTop(point2A, point2B);
Vector3 hitPointTop = mLocalShapeToWorld * Vector3(0, decimal(4.5), 0);
Vector3 point3A = mLocalShapeToWorld * Vector3(0 , -6.5, 0);
Vector3 point3B = mLocalShapeToWorld * Vector3(0, 3.5, 0);
Ray rayBottom(point3A, point3B);
Vector3 hitPointBottom = mLocalShapeToWorld * Vector3(0, decimal(-4.5), 0);
mCallback.shapeToTest = mCapsuleProxyShape;
// CollisionWorld::raycast()
mCallback.reset();
mWorld->raycast(ray, &mCallback);
test(mCallback.isHit);
test(mCallback.raycastInfo.body == mCapsuleBody);
test(mCallback.raycastInfo.proxyShape == mCapsuleProxyShape);
test(approxEqual(mCallback.raycastInfo.hitFraction, decimal(0.2), epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.z, hitPoint.z, epsilon));
// Correct category filter mask
mCallback.reset();
mWorld->raycast(ray, &mCallback, CATEGORY1);
test(mCallback.isHit);
// Wrong category filter mask
mCallback.reset();
mWorld->raycast(ray, &mCallback, CATEGORY2);
test(!mCallback.isHit);
// CollisionBody::raycast()
RaycastInfo raycastInfo2;
test(mCapsuleBody->raycast(ray, raycastInfo2));
test(raycastInfo2.body == mCapsuleBody);
test(raycastInfo2.proxyShape == mCapsuleProxyShape);
test(approxEqual(raycastInfo2.hitFraction, decimal(0.2), epsilon));
test(approxEqual(raycastInfo2.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo2.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo2.worldPoint.z, hitPoint.z, epsilon));
// ProxyCollisionShape::raycast()
RaycastInfo raycastInfo3;
test(mCapsuleProxyShape->raycast(ray, raycastInfo3));
test(raycastInfo3.body == mCapsuleBody);
test(raycastInfo3.proxyShape == mCapsuleProxyShape);
test(approxEqual(raycastInfo3.hitFraction, decimal(0.2), epsilon));
test(approxEqual(raycastInfo3.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo3.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo3.worldPoint.z, hitPoint.z, epsilon));
RaycastInfo raycastInfo4;
test(mCapsuleProxyShape->raycast(rayTop, raycastInfo4));
test(raycastInfo4.body == mCapsuleBody);
test(raycastInfo4.proxyShape == mCapsuleProxyShape);
test(approxEqual(raycastInfo4.hitFraction, decimal(0.2), epsilon));
test(approxEqual(raycastInfo4.worldPoint.x, hitPointTop.x, epsilon));
test(approxEqual(raycastInfo4.worldPoint.y, hitPointTop.y, epsilon));
test(approxEqual(raycastInfo4.worldPoint.z, hitPointTop.z, epsilon));
// ProxyCollisionShape::raycast()
RaycastInfo raycastInfo5;
test(mCapsuleProxyShape->raycast(rayBottom, raycastInfo5));
test(raycastInfo5.body == mCapsuleBody);
test(raycastInfo5.proxyShape == mCapsuleProxyShape);
test(approxEqual(raycastInfo5.hitFraction, decimal(0.2), epsilon));
test(approxEqual(raycastInfo5.worldPoint.x, hitPointBottom.x, epsilon));
test(approxEqual(raycastInfo5.worldPoint.y, hitPointBottom.y, epsilon));
test(approxEqual(raycastInfo5.worldPoint.z, hitPointBottom.z, epsilon));
Ray ray1(mLocalShapeToWorld * Vector3(0, 0, 0), mLocalShapeToWorld * Vector3(5, 7, -1));
Ray ray2(mLocalShapeToWorld * Vector3(5, 11, 7), mLocalShapeToWorld * Vector3(9, 17, 14));
Ray ray3(mLocalShapeToWorld * Vector3(1, 3, -1), mLocalShapeToWorld * Vector3(-3, 3, 6));
Ray ray4(mLocalShapeToWorld * Vector3(10, 10, 10), mLocalShapeToWorld * Vector3(14, 16, 17));
Ray ray5(mLocalShapeToWorld * Vector3(4, 1, -5), mLocalShapeToWorld * Vector3(1, 1, -5));
Ray ray6(mLocalShapeToWorld * Vector3(4, 9, 1), mLocalShapeToWorld * Vector3(4, 7, 1));
Ray ray7(mLocalShapeToWorld * Vector3(1, -9, 5), mLocalShapeToWorld * Vector3(1, -9, 3));
Ray ray8(mLocalShapeToWorld * Vector3(-4, 9, 0), mLocalShapeToWorld * Vector3(-3, 9, 0));
Ray ray9(mLocalShapeToWorld * Vector3(0, -9, -4), mLocalShapeToWorld * Vector3(0, -4, -4));
Ray ray10(mLocalShapeToWorld * Vector3(-4, 0, -6), mLocalShapeToWorld * Vector3(-4, 0, 2));
Ray ray11(mLocalShapeToWorld * Vector3(4, 1, 1.5), mLocalShapeToWorld * Vector3(-30, 1, 1.5));
Ray ray12(mLocalShapeToWorld * Vector3(1, 9, -1), mLocalShapeToWorld * Vector3(1, -30, -1));
Ray ray13(mLocalShapeToWorld * Vector3(-1, 2, 3), mLocalShapeToWorld * Vector3(-1, 2, -30));
Ray ray14(mLocalShapeToWorld * Vector3(-3, 2, -1.7), mLocalShapeToWorld * Vector3(30, 2, -1.7));
Ray ray15(mLocalShapeToWorld * Vector3(0, -9, 1), mLocalShapeToWorld * Vector3(0, 30, 1));
Ray ray16(mLocalShapeToWorld * Vector3(-1, 2, -7), mLocalShapeToWorld * Vector3(-1, 2, 30));
// ----- Test raycast miss ----- //
test(!mCapsuleBody->raycast(ray1, raycastInfo3));
test(!mCapsuleProxyShape->raycast(ray1, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray1, &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray1.point1, ray1.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray1.point1, ray1.point2, decimal(100.0)), &mCallback);
test(!mCallback.isHit);
test(!mCapsuleBody->raycast(ray2, raycastInfo3));
test(!mCapsuleProxyShape->raycast(ray2, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray2, &mCallback);
test(!mCallback.isHit);
test(!mCapsuleBody->raycast(ray3, raycastInfo3));
test(!mCapsuleProxyShape->raycast(ray3, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray3, &mCallback);
test(!mCallback.isHit);
test(!mCapsuleBody->raycast(ray4, raycastInfo3));
test(!mCapsuleProxyShape->raycast(ray4, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray4, &mCallback);
test(!mCallback.isHit);
test(!mCapsuleBody->raycast(ray5, raycastInfo3));
test(!mCapsuleProxyShape->raycast(ray5, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray5, &mCallback);
test(!mCallback.isHit);
test(!mCapsuleBody->raycast(ray6, raycastInfo3));
test(!mCapsuleProxyShape->raycast(ray6, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray6, &mCallback);
test(!mCallback.isHit);
test(!mCapsuleBody->raycast(ray7, raycastInfo3));
test(!mCapsuleProxyShape->raycast(ray7, raycastInfo3));
mWorld->raycast(ray7, &mCallback);
test(!mCallback.isHit);
test(!mCapsuleBody->raycast(ray8, raycastInfo3));
test(!mCapsuleProxyShape->raycast(ray8, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray8, &mCallback);
test(!mCallback.isHit);
test(!mCapsuleBody->raycast(ray9, raycastInfo3));
test(!mCapsuleProxyShape->raycast(ray9, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray9, &mCallback);
test(!mCallback.isHit);
test(!mCapsuleBody->raycast(ray10, raycastInfo3));
test(!mCapsuleProxyShape->raycast(ray10, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray10, &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray11.point1, ray11.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray12.point1, ray12.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray13.point1, ray13.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray14.point1, ray14.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray15.point1, ray15.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray16.point1, ray16.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
// ----- Test raycast hits ----- //
test(mCapsuleBody->raycast(ray11, raycastInfo3));
test(mCapsuleProxyShape->raycast(ray11, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray11, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray11.point1, ray11.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mCapsuleBody->raycast(ray12, raycastInfo3));
test(mCapsuleProxyShape->raycast(ray12, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray12, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray12.point1, ray12.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mCapsuleBody->raycast(ray13, raycastInfo3));
test(mCapsuleProxyShape->raycast(ray13, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray13, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray13.point1, ray13.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mCapsuleBody->raycast(ray14, raycastInfo3));
test(mCapsuleProxyShape->raycast(ray14, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray14, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray14.point1, ray14.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mCapsuleBody->raycast(ray15, raycastInfo3));
test(mCapsuleProxyShape->raycast(ray15, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray15, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray15.point1, ray15.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mCapsuleBody->raycast(ray16, raycastInfo3));
test(mCapsuleProxyShape->raycast(ray16, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray16, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray16.point1, ray16.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
}
/// Test the ProxySphereShape::raycast(), CollisionBody::raycast() and
/// CollisionWorld::raycast() methods.
void testTriangle() {
// ----- Test feedback data ----- //
Vector3 point1 = mLocalShapeToWorld * Vector3(101, 101, 400);
Vector3 point2 = mLocalShapeToWorld * Vector3(101, 101, -200);
Ray ray(point1, point2);
Ray rayBackward(point2, point1);
Vector3 hitPoint = mLocalShapeToWorld * Vector3(101, 101, 0);
Vector3 hitNormal = mLocalShapeToWorld.getOrientation() * Vector3(0, 0, 1);
hitNormal.normalize();
mCallback.shapeToTest = mTriangleProxyShape;
// CollisionWorld::raycast()
mCallback.reset();
mTriangleShape->setRaycastTestType(TriangleRaycastSide::FRONT);
mWorld->raycast(ray, &mCallback);
test(mCallback.isHit);
test(mCallback.raycastInfo.body == mTriangleBody);
test(mCallback.raycastInfo.proxyShape == mTriangleProxyShape);
test(approxEqual(mCallback.raycastInfo.hitFraction, 0.6666, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.z, hitPoint.z, epsilon));
test(approxEqual(mCallback.raycastInfo.worldNormal.x, hitNormal.x, epsilon));
test(approxEqual(mCallback.raycastInfo.worldNormal.y, hitNormal.y, epsilon));
test(approxEqual(mCallback.raycastInfo.worldNormal.z, hitNormal.z, epsilon));
mCallback.reset();
mTriangleShape->setRaycastTestType(TriangleRaycastSide::BACK);
mWorld->raycast(rayBackward, &mCallback);
test(mCallback.isHit);
test(mCallback.raycastInfo.body == mTriangleBody);
test(mCallback.raycastInfo.proxyShape == mTriangleProxyShape);
test(approxEqual(mCallback.raycastInfo.hitFraction, 0.3333, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.z, hitPoint.z, epsilon));
test(approxEqual(mCallback.raycastInfo.worldNormal.x, -hitNormal.x, epsilon));
test(approxEqual(mCallback.raycastInfo.worldNormal.y, -hitNormal.y, epsilon));
test(approxEqual(mCallback.raycastInfo.worldNormal.z, -hitNormal.z, epsilon));
mCallback.reset();
mTriangleShape->setRaycastTestType(TriangleRaycastSide::FRONT_AND_BACK);
mWorld->raycast(ray, &mCallback);
test(mCallback.isHit);
test(mCallback.raycastInfo.body == mTriangleBody);
test(mCallback.raycastInfo.proxyShape == mTriangleProxyShape);
test(approxEqual(mCallback.raycastInfo.hitFraction, 0.6666, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.z, hitPoint.z, epsilon));
test(approxEqual(mCallback.raycastInfo.worldNormal.x, hitNormal.x, epsilon));
test(approxEqual(mCallback.raycastInfo.worldNormal.y, hitNormal.y, epsilon));
test(approxEqual(mCallback.raycastInfo.worldNormal.z, hitNormal.z, epsilon));
mCallback.reset();
mTriangleShape->setRaycastTestType(TriangleRaycastSide::FRONT_AND_BACK);
mWorld->raycast(rayBackward, &mCallback);
test(mCallback.isHit);
test(mCallback.raycastInfo.body == mTriangleBody);
test(mCallback.raycastInfo.proxyShape == mTriangleProxyShape);
test(approxEqual(mCallback.raycastInfo.hitFraction, 0.3333, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.z, hitPoint.z, epsilon));
test(approxEqual(mCallback.raycastInfo.worldNormal.x, -hitNormal.x, epsilon));
test(approxEqual(mCallback.raycastInfo.worldNormal.y, -hitNormal.y, epsilon));
test(approxEqual(mCallback.raycastInfo.worldNormal.z, -hitNormal.z, epsilon));
mTriangleShape->setRaycastTestType(TriangleRaycastSide::FRONT);
// Correct category filter mask
mCallback.reset();
mWorld->raycast(ray, &mCallback, CATEGORY1);
test(mCallback.isHit);
// Wrong category filter mask
mCallback.reset();
mWorld->raycast(ray, &mCallback, CATEGORY2);
test(!mCallback.isHit);
// CollisionBody::raycast()
RaycastInfo raycastInfo2;
test(mTriangleBody->raycast(ray, raycastInfo2));
test(raycastInfo2.body == mTriangleBody);
test(raycastInfo2.proxyShape == mTriangleProxyShape);
test(approxEqual(raycastInfo2.hitFraction, 0.6666, epsilon));
test(approxEqual(raycastInfo2.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo2.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo2.worldPoint.z, hitPoint.z, epsilon));
// ProxyCollisionShape::raycast()
RaycastInfo raycastInfo3;
test(mTriangleProxyShape->raycast(ray, raycastInfo3));
test(raycastInfo3.body == mTriangleBody);
test(raycastInfo3.proxyShape == mTriangleProxyShape);
test(approxEqual(raycastInfo3.hitFraction, 0.6666, epsilon));
test(approxEqual(raycastInfo3.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo3.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo3.worldPoint.z, hitPoint.z, epsilon));
Ray ray1(mLocalShapeToWorld * Vector3(-10, 10, 4), mLocalShapeToWorld * Vector3(15, 6, -4));
Ray ray2(mLocalShapeToWorld * Vector3(102, 107, 5), mLocalShapeToWorld * Vector3(102, 107, -5));
Ray ray3(mLocalShapeToWorld * Vector3(106, 102, 6), mLocalShapeToWorld * Vector3(106, 102, -8));
Ray ray4(mLocalShapeToWorld * Vector3(100.2, 101, 5), mLocalShapeToWorld * Vector3(100.2, 101, -5));
Ray ray5(mLocalShapeToWorld * Vector3(100.5, 101.5, 4), mLocalShapeToWorld * Vector3(100.5, 101.5, -54));
Ray ray6(mLocalShapeToWorld * Vector3(102, 101, 1), mLocalShapeToWorld * Vector3(102, 102, -1));
Ray ray4Back(mLocalShapeToWorld * Vector3(100.2, 101, -5), mLocalShapeToWorld * Vector3(100.2, 101, 5));
Ray ray5Back(mLocalShapeToWorld * Vector3(100.5, 101.5, -54), mLocalShapeToWorld * Vector3(100.5, 101.5, 4));
Ray ray6Back(mLocalShapeToWorld * Vector3(102, 102, -1), mLocalShapeToWorld * Vector3(102, 101, 1));
// ----- Test raycast miss ----- //
test(!mTriangleBody->raycast(ray1, raycastInfo3));
test(!mTriangleProxyShape->raycast(ray1, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray1, &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray1.point1, ray1.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray1.point1, ray1.point2, decimal(100.0)), &mCallback);
test(!mCallback.isHit);
test(!mTriangleBody->raycast(ray2, raycastInfo3));
test(!mTriangleProxyShape->raycast(ray2, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray2, &mCallback);
test(!mCallback.isHit);
test(!mTriangleBody->raycast(ray3, raycastInfo3));
test(!mTriangleProxyShape->raycast(ray3, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray3, &mCallback);
test(!mCallback.isHit);
// Test backward ray against front triangles (not hit should occur)
mTriangleShape->setRaycastTestType(TriangleRaycastSide::FRONT);
test(!mTriangleBody->raycast(ray4Back, raycastInfo3));
test(!mTriangleProxyShape->raycast(ray4Back, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray4Back, &mCallback);
test(!mCallback.isHit);
test(!mTriangleBody->raycast(ray5Back, raycastInfo3));
test(!mTriangleProxyShape->raycast(ray5Back, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray5Back, &mCallback);
test(!mCallback.isHit);
test(!mTriangleBody->raycast(ray6Back, raycastInfo3));
test(!mTriangleProxyShape->raycast(ray6Back, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray6Back, &mCallback);
test(!mCallback.isHit);
// Test front ray against back triangles (not hit should occur)
mTriangleShape->setRaycastTestType(TriangleRaycastSide::BACK);
test(!mTriangleBody->raycast(ray4, raycastInfo3));
test(!mTriangleProxyShape->raycast(ray4, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray4, &mCallback);
test(!mCallback.isHit);
test(!mTriangleBody->raycast(ray5, raycastInfo3));
test(!mTriangleProxyShape->raycast(ray5, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray5, &mCallback);
test(!mCallback.isHit);
test(!mTriangleBody->raycast(ray6, raycastInfo3));
test(!mTriangleProxyShape->raycast(ray6, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray6, &mCallback);
test(!mCallback.isHit);
// ----- Test raycast hits ----- //
// Test front ray against front triangles
mTriangleShape->setRaycastTestType(TriangleRaycastSide::FRONT);
test(mTriangleBody->raycast(ray4, raycastInfo3));
test(mTriangleProxyShape->raycast(ray4, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray4, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray4.point1, ray4.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mTriangleBody->raycast(ray5, raycastInfo3));
test(mTriangleProxyShape->raycast(ray5, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray5, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray5.point1, ray5.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mTriangleBody->raycast(ray6, raycastInfo3));
test(mTriangleProxyShape->raycast(ray6, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray6, &mCallback);
mCallback.reset();
mWorld->raycast(Ray(ray6.point1, ray6.point2, decimal(0.8)), &mCallback);
// Test back ray against back triangles
mTriangleShape->setRaycastTestType(TriangleRaycastSide::BACK);
test(mTriangleBody->raycast(ray4Back, raycastInfo3));
test(mTriangleProxyShape->raycast(ray4Back, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray4Back, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray4Back.point1, ray4Back.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mTriangleBody->raycast(ray5Back, raycastInfo3));
test(mTriangleProxyShape->raycast(ray5Back, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray5Back, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray5Back.point1, ray5Back.point2, decimal(1.0)), &mCallback);
test(mCallback.isHit);
test(mTriangleBody->raycast(ray6Back, raycastInfo3));
test(mTriangleProxyShape->raycast(ray6Back, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray6Back, &mCallback);
mCallback.reset();
mWorld->raycast(Ray(ray6Back.point1, ray6Back.point2, decimal(0.8)), &mCallback);
// Test front ray against front-back triangles
mTriangleShape->setRaycastTestType(TriangleRaycastSide::FRONT_AND_BACK);
test(mTriangleBody->raycast(ray4, raycastInfo3));
test(mTriangleProxyShape->raycast(ray4, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray4, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray4.point1, ray4.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mTriangleBody->raycast(ray5, raycastInfo3));
test(mTriangleProxyShape->raycast(ray5, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray5, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray5.point1, ray5.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mTriangleBody->raycast(ray6, raycastInfo3));
test(mTriangleProxyShape->raycast(ray6, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray6, &mCallback);
mCallback.reset();
mWorld->raycast(Ray(ray6.point1, ray6.point2, decimal(0.8)), &mCallback);
// Test back ray against front-back triangles
mTriangleShape->setRaycastTestType(TriangleRaycastSide::FRONT_AND_BACK);
test(mTriangleBody->raycast(ray4Back, raycastInfo3));
test(mTriangleProxyShape->raycast(ray4Back, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray4Back, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray4Back.point1, ray4Back.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mTriangleBody->raycast(ray5Back, raycastInfo3));
test(mTriangleProxyShape->raycast(ray5Back, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray5Back, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray5Back.point1, ray5Back.point2, decimal(1.0)), &mCallback);
test(mCallback.isHit);
test(mTriangleBody->raycast(ray6Back, raycastInfo3));
test(mTriangleProxyShape->raycast(ray6Back, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray6Back, &mCallback);
mCallback.reset();
mWorld->raycast(Ray(ray6Back.point1, ray6Back.point2, decimal(0.8)), &mCallback);
}
/// Test the ProxyConvexMeshShape::raycast(), CollisionBody::raycast() and
/// CollisionWorld::raycast() methods.
void testConvexMesh() {
// ----- Test feedback data ----- //
Vector3 point1 = mLocalShapeToWorld * Vector3(1 , 2, 6);
Vector3 point2 = mLocalShapeToWorld * Vector3(1, 2, -4);
Ray ray(point1, point2);
Vector3 hitPoint = mLocalShapeToWorld * Vector3(1, 2, 4);
mCallback.shapeToTest = mConvexMeshProxyShape;
// CollisionWorld::raycast()
mCallback.reset();
mWorld->raycast(ray, &mCallback);
test(mCallback.isHit);
test(mCallback.raycastInfo.body == mConvexMeshBody);
test(mCallback.raycastInfo.proxyShape == mConvexMeshProxyShape);
test(approxEqual(mCallback.raycastInfo.hitFraction, decimal(0.2), epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.z, hitPoint.z, epsilon));
// Correct category filter mask
mCallback.reset();
mWorld->raycast(ray, &mCallback, CATEGORY2);
test(mCallback.isHit);
// Wrong category filter mask
mCallback.reset();
mWorld->raycast(ray, &mCallback, CATEGORY1);
test(!mCallback.isHit);
// CollisionBody::raycast()
RaycastInfo raycastInfo2;
test(mConvexMeshBody->raycast(ray, raycastInfo2));
test(raycastInfo2.body == mConvexMeshBody);
test(raycastInfo2.proxyShape == mConvexMeshProxyShape);
test(approxEqual(raycastInfo2.hitFraction, decimal(0.2), epsilon));
test(approxEqual(raycastInfo2.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo2.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo2.worldPoint.z, hitPoint.z, epsilon));
// ProxyCollisionShape::raycast()
RaycastInfo raycastInfo4;
test(mConvexMeshProxyShape->raycast(ray, raycastInfo4));
test(raycastInfo4.body == mConvexMeshBody);
test(raycastInfo4.proxyShape == mConvexMeshProxyShape);
test(approxEqual(raycastInfo4.hitFraction, decimal(0.2), epsilon));
test(approxEqual(raycastInfo4.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo4.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo4.worldPoint.z, hitPoint.z, epsilon));
Ray ray1(mLocalShapeToWorld * Vector3(0, 0, 0), mLocalShapeToWorld * Vector3(5, 7, -1));
Ray ray2(mLocalShapeToWorld * Vector3(5, 11, 7), mLocalShapeToWorld * Vector3(17, 29, 28));
Ray ray3(mLocalShapeToWorld * Vector3(1, 2, 3), mLocalShapeToWorld * Vector3(-11, 2, 24));
Ray ray4(mLocalShapeToWorld * Vector3(10, 10, 10), mLocalShapeToWorld * Vector3(22, 28, 31));
Ray ray5(mLocalShapeToWorld * Vector3(3, 1, -5), mLocalShapeToWorld * Vector3(-30, 1, -5));
Ray ray6(mLocalShapeToWorld * Vector3(4, 4, 1), mLocalShapeToWorld * Vector3(4, -30, 1));
Ray ray7(mLocalShapeToWorld * Vector3(1, -4, 5), mLocalShapeToWorld * Vector3(1, -4, -30));
Ray ray8(mLocalShapeToWorld * Vector3(-4, 4, 0), mLocalShapeToWorld * Vector3(30, 4, 0));
Ray ray9(mLocalShapeToWorld * Vector3(0, -4, -7), mLocalShapeToWorld * Vector3(0, 30, -7));
Ray ray10(mLocalShapeToWorld * Vector3(-3, 0, -6), mLocalShapeToWorld * Vector3(-3, 0, 30));
Ray ray11(mLocalShapeToWorld * Vector3(3, 1, 2), mLocalShapeToWorld * Vector3(-30, 0, -6));
Ray ray12(mLocalShapeToWorld * Vector3(1, 4, -1), mLocalShapeToWorld * Vector3(1, -30, -1));
Ray ray13(mLocalShapeToWorld * Vector3(-1, 2, 5), mLocalShapeToWorld * Vector3(-1, 2, -30));
Ray ray14(mLocalShapeToWorld * Vector3(-3, 2, -2), mLocalShapeToWorld * Vector3(30, 2, -2));
Ray ray15(mLocalShapeToWorld * Vector3(0, -4, 1), mLocalShapeToWorld * Vector3(0, 30, 1));
Ray ray16(mLocalShapeToWorld * Vector3(-1, 2, -7), mLocalShapeToWorld * Vector3(-1, 2, 30));
// ----- Test raycast miss ----- //
RaycastInfo raycastInfo3;
test(!mConvexMeshBody->raycast(ray1, raycastInfo3));
test(!mConvexMeshProxyShape->raycast(ray1, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray1, &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray1.point1, ray1.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray1.point1, ray1.point2, decimal(100.0)), &mCallback);
test(!mCallback.isHit);
test(!mConvexMeshBody->raycast(ray2, raycastInfo3));
test(!mConvexMeshProxyShape->raycast(ray2, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray2, &mCallback);
test(!mCallback.isHit);
test(!mConvexMeshBody->raycast(ray3, raycastInfo3));
test(!mConvexMeshProxyShape->raycast(ray3, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray3, &mCallback);
test(!mCallback.isHit);
test(!mConvexMeshBody->raycast(ray4, raycastInfo3));
test(!mConvexMeshProxyShape->raycast(ray4, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray4, &mCallback);
test(!mCallback.isHit);
test(!mConvexMeshBody->raycast(ray5, raycastInfo3));
test(!mConvexMeshProxyShape->raycast(ray5, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray5, &mCallback);
test(!mCallback.isHit);
test(!mConvexMeshBody->raycast(ray6, raycastInfo3));
test(!mConvexMeshProxyShape->raycast(ray6, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray6, &mCallback);
test(!mCallback.isHit);
test(!mConvexMeshBody->raycast(ray7, raycastInfo3));
test(!mConvexMeshProxyShape->raycast(ray7, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray7, &mCallback);
test(!mCallback.isHit);
test(!mConvexMeshBody->raycast(ray8, raycastInfo3));
test(!mConvexMeshProxyShape->raycast(ray8, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray8, &mCallback);
test(!mCallback.isHit);
test(!mConvexMeshBody->raycast(ray9, raycastInfo3));
test(!mConvexMeshProxyShape->raycast(ray9, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray9, &mCallback);
test(!mCallback.isHit);
test(!mConvexMeshBody->raycast(ray10, raycastInfo3));
test(!mConvexMeshProxyShape->raycast(ray10, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray10, &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray11.point1, ray11.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray12.point1, ray12.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray13.point1, ray13.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray14.point1, ray14.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray15.point1, ray15.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray16.point1, ray16.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
// ----- Test raycast hits ----- //
test(mConvexMeshBody->raycast(ray11, raycastInfo3));
test(mConvexMeshProxyShape->raycast(ray11, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray11, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray11.point1, ray11.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mConvexMeshBody->raycast(ray12, raycastInfo3));
test(mConvexMeshProxyShape->raycast(ray12, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray12, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray12.point1, ray12.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mConvexMeshBody->raycast(ray13, raycastInfo3));
test(mConvexMeshProxyShape->raycast(ray13, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray13, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray13.point1, ray13.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mConvexMeshBody->raycast(ray14, raycastInfo3));
test(mConvexMeshProxyShape->raycast(ray14, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray14, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray14.point1, ray14.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mConvexMeshBody->raycast(ray15, raycastInfo3));
test(mConvexMeshProxyShape->raycast(ray15, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray15, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray15.point1, ray15.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mConvexMeshBody->raycast(ray16, raycastInfo3));
test(mConvexMeshProxyShape->raycast(ray16, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray16, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray16.point1, ray16.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
}
/// Test the CollisionBody::raycast() and
/// CollisionWorld::raycast() methods.
void testCompound() {
// ----- Test feedback data ----- //
// Raycast hit against the sphere shape
Ray ray1(mLocalShape2ToWorld * Vector3(4, 1, 2), mLocalShape2ToWorld * Vector3(-30, 1, 2));
Ray ray2(mLocalShape2ToWorld * Vector3(1, 4, -1), mLocalShape2ToWorld * Vector3(1, -30, -1));
Ray ray3(mLocalShape2ToWorld * Vector3(-1, 2, 5), mLocalShape2ToWorld * Vector3(-1, 2, -30));
Ray ray4(mLocalShape2ToWorld * Vector3(-5, 2, -2), mLocalShape2ToWorld * Vector3(30, 2, -2));
Ray ray5(mLocalShape2ToWorld * Vector3(0, -4, 1), mLocalShape2ToWorld * Vector3(0, 30, 1));
Ray ray6(mLocalShape2ToWorld * Vector3(-1, 2, -11), mLocalShape2ToWorld * Vector3(-1, 2, 30));
mCallback.shapeToTest = mCompoundSphereProxyShape;
// Correct category filter mask
mCallback.reset();
mWorld->raycast(ray1, &mCallback, CATEGORY2);
test(mCallback.isHit);
// Wrong category filter mask
mCallback.reset();
mWorld->raycast(ray1, &mCallback, CATEGORY1);
test(!mCallback.isHit);
RaycastInfo raycastInfo;
test(mCompoundBody->raycast(ray1, raycastInfo));
mCallback.reset();
mWorld->raycast(ray1, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray1.point1, ray1.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mCompoundBody->raycast(ray2, raycastInfo));
mCallback.reset();
mWorld->raycast(ray2, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray2.point1, ray2.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mCompoundBody->raycast(ray3, raycastInfo));
mCallback.reset();
mWorld->raycast(ray3, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray3.point1, ray3.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mCompoundBody->raycast(ray4, raycastInfo));
mCallback.reset();
mWorld->raycast(ray4, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray4.point1, ray4.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mCompoundBody->raycast(ray5, raycastInfo));
mCallback.reset();
mWorld->raycast(ray5, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray5.point1, ray5.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mCompoundBody->raycast(ray6, raycastInfo));
mCallback.reset();
mWorld->raycast(ray6, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray6.point1, ray6.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
// Raycast hit agains the capsule shape
// TODO : Previous it was a cylinder, now it is a capsule shape, maybe those tests are wrong now
Ray ray11(mLocalShapeToWorld * Vector3(4, 1, 1.5), mLocalShapeToWorld * Vector3(-30, 1.5, 2));
Ray ray12(mLocalShapeToWorld * Vector3(1.5, 9, -1), mLocalShapeToWorld * Vector3(1.5, -30, -1));
Ray ray13(mLocalShapeToWorld * Vector3(-1, 2, 3), mLocalShapeToWorld * Vector3(-1, 2, -30));
Ray ray14(mLocalShapeToWorld * Vector3(-3, 2, -1.5), mLocalShapeToWorld * Vector3(30, 1, -1.5));
Ray ray15(mLocalShapeToWorld * Vector3(0, -9, 1), mLocalShapeToWorld * Vector3(0, 30, 1));
Ray ray16(mLocalShapeToWorld * Vector3(-1, 2, -7), mLocalShapeToWorld * Vector3(-1, 2, 30));
mCallback.shapeToTest = mCompoundCapsuleProxyShape;
test(mCompoundBody->raycast(ray11, raycastInfo));
mCallback.reset();
mWorld->raycast(ray11, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray11.point1, ray11.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mCompoundBody->raycast(ray12, raycastInfo));
mCallback.reset();
mWorld->raycast(ray12, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray12.point1, ray12.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mCompoundBody->raycast(ray13, raycastInfo));
mCallback.reset();
mWorld->raycast(ray13, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray13.point1, ray13.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mCompoundBody->raycast(ray14, raycastInfo));
mCallback.reset();
mWorld->raycast(ray14, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray14.point1, ray14.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mCompoundBody->raycast(ray15, raycastInfo));
mCallback.reset();
mWorld->raycast(ray15, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray15.point1, ray15.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mCompoundBody->raycast(ray16, raycastInfo));
mCallback.reset();
mWorld->raycast(ray16, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray16.point1, ray16.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
}
void testConcaveMesh() {
// ----- Test feedback data ----- //
Vector3 point1 = mLocalShapeToWorld * Vector3(1 , 2, 6);
Vector3 point2 = mLocalShapeToWorld * Vector3(1, 2, -4);
Ray ray(point1, point2);
Vector3 hitPoint = mLocalShapeToWorld * Vector3(1, 2, 4);
mCallback.shapeToTest = mConcaveMeshProxyShape;
// CollisionWorld::raycast()
mCallback.reset();
mWorld->raycast(ray, &mCallback);
test(mCallback.isHit);
test(mCallback.raycastInfo.body == mConcaveMeshBody);
test(mCallback.raycastInfo.proxyShape == mConcaveMeshProxyShape);
test(approxEqual(mCallback.raycastInfo.hitFraction, decimal(0.2), epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.z, hitPoint.z, epsilon));
// Correct category filter mask
mCallback.reset();
mWorld->raycast(ray, &mCallback, CATEGORY2);
test(mCallback.isHit);
// Wrong category filter mask
mCallback.reset();
mWorld->raycast(ray, &mCallback, CATEGORY1);
test(!mCallback.isHit);
// CollisionBody::raycast()
RaycastInfo raycastInfo2;
test(mConcaveMeshBody->raycast(ray, raycastInfo2));
test(raycastInfo2.body == mConcaveMeshBody);
test(raycastInfo2.proxyShape == mConcaveMeshProxyShape);
test(approxEqual(raycastInfo2.hitFraction, decimal(0.2), epsilon));
test(approxEqual(raycastInfo2.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo2.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo2.worldPoint.z, hitPoint.z, epsilon));
// ProxyCollisionShape::raycast()
RaycastInfo raycastInfo3;
test(mConcaveMeshBody->raycast(ray, raycastInfo3));
test(raycastInfo3.body == mConcaveMeshBody);
test(raycastInfo3.proxyShape == mConcaveMeshProxyShape);
test(approxEqual(raycastInfo3.hitFraction, decimal(0.2), epsilon));
test(approxEqual(raycastInfo3.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo3.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo3.worldPoint.z, hitPoint.z, epsilon));
// ProxyCollisionShape::raycast()
RaycastInfo raycastInfo4;
test(mConcaveMeshBody->raycast(ray, raycastInfo4));
test(raycastInfo4.body == mConcaveMeshBody);
test(raycastInfo4.proxyShape == mConcaveMeshProxyShape);
test(approxEqual(raycastInfo4.hitFraction, decimal(0.2), epsilon));
test(approxEqual(raycastInfo4.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo4.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo4.worldPoint.z, hitPoint.z, epsilon));
// ProxyCollisionShape::raycast()
RaycastInfo raycastInfo5;
test(mConcaveMeshBody->raycast(ray, raycastInfo5));
test(raycastInfo5.body == mConcaveMeshBody);
test(raycastInfo5.proxyShape == mConcaveMeshProxyShape);
test(approxEqual(raycastInfo5.hitFraction, decimal(0.2), epsilon));
test(approxEqual(raycastInfo5.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo5.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo5.worldPoint.z, hitPoint.z, epsilon));
Ray ray1(mLocalShapeToWorld * Vector3(0, 0, 0), mLocalShapeToWorld * Vector3(5, 7, -1));
Ray ray2(mLocalShapeToWorld * Vector3(5, 11, 7), mLocalShapeToWorld * Vector3(17, 29, 28));
Ray ray3(mLocalShapeToWorld * Vector3(1, 2, 3), mLocalShapeToWorld * Vector3(-11, 2, 24));
Ray ray4(mLocalShapeToWorld * Vector3(10, 10, 10), mLocalShapeToWorld * Vector3(22, 28, 31));
Ray ray5(mLocalShapeToWorld * Vector3(3, 1, -5), mLocalShapeToWorld * Vector3(-30, 1, -5));
Ray ray6(mLocalShapeToWorld * Vector3(4, 4, 1), mLocalShapeToWorld * Vector3(4, -30, 1));
Ray ray7(mLocalShapeToWorld * Vector3(1, -4, 5), mLocalShapeToWorld * Vector3(1, -4, -30));
Ray ray8(mLocalShapeToWorld * Vector3(-4, 4, 0), mLocalShapeToWorld * Vector3(30, 4, 0));
Ray ray9(mLocalShapeToWorld * Vector3(0, -4, -7), mLocalShapeToWorld * Vector3(0, 30, -7));
Ray ray10(mLocalShapeToWorld * Vector3(-3, 0, -6), mLocalShapeToWorld * Vector3(-3, 0, 30));
Ray ray11(mLocalShapeToWorld * Vector3(3, 1, 2), mLocalShapeToWorld * Vector3(-30, 0, -6));
Ray ray12(mLocalShapeToWorld * Vector3(1, 4, -1), mLocalShapeToWorld * Vector3(1, -30, -1));
Ray ray13(mLocalShapeToWorld * Vector3(-1, 2, 5), mLocalShapeToWorld * Vector3(-1, 2, -30));
Ray ray14(mLocalShapeToWorld * Vector3(-3, 2, -2), mLocalShapeToWorld * Vector3(30, 2, -2));
Ray ray15(mLocalShapeToWorld * Vector3(0, -4, 1), mLocalShapeToWorld * Vector3(0, 30, 1));
Ray ray16(mLocalShapeToWorld * Vector3(-1, 2, -7), mLocalShapeToWorld * Vector3(-1, 2, 30));
// ----- Test raycast miss ----- //
test(!mConcaveMeshBody->raycast(ray1, raycastInfo3));
//test(!mConvexMeshProxyShape->raycast(ray1, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray1, &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray1.point1, ray1.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray1.point1, ray1.point2, decimal(100.0)), &mCallback);
test(!mCallback.isHit);
test(!mConcaveMeshBody->raycast(ray2, raycastInfo3));
test(!mConcaveMeshProxyShape->raycast(ray2, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray2, &mCallback);
test(!mCallback.isHit);
test(!mConcaveMeshBody->raycast(ray3, raycastInfo3));
test(!mConcaveMeshProxyShape->raycast(ray3, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray3, &mCallback);
test(!mCallback.isHit);
test(!mConcaveMeshBody->raycast(ray4, raycastInfo3));
test(!mConcaveMeshProxyShape->raycast(ray4, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray4, &mCallback);
test(!mCallback.isHit);
test(!mConcaveMeshBody->raycast(ray5, raycastInfo3));
test(!mConcaveMeshProxyShape->raycast(ray5, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray5, &mCallback);
test(!mCallback.isHit);
test(!mConcaveMeshBody->raycast(ray6, raycastInfo3));
test(!mConcaveMeshProxyShape->raycast(ray6, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray6, &mCallback);
test(!mCallback.isHit);
test(!mConcaveMeshBody->raycast(ray7, raycastInfo3));
test(!mConcaveMeshProxyShape->raycast(ray7, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray7, &mCallback);
test(!mCallback.isHit);
test(!mConcaveMeshBody->raycast(ray8, raycastInfo3));
test(!mConcaveMeshProxyShape->raycast(ray8, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray8, &mCallback);
test(!mCallback.isHit);
test(!mConcaveMeshBody->raycast(ray9, raycastInfo3));
test(!mConcaveMeshProxyShape->raycast(ray9, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray9, &mCallback);
test(!mCallback.isHit);
test(!mConcaveMeshBody->raycast(ray10, raycastInfo3));
test(!mConcaveMeshProxyShape->raycast(ray10, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray10, &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray11.point1, ray11.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray12.point1, ray12.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray13.point1, ray13.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray14.point1, ray14.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray15.point1, ray15.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray16.point1, ray16.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
// ----- Test raycast hits ----- //
test(mConcaveMeshBody->raycast(ray11, raycastInfo3));
test(mConcaveMeshProxyShape->raycast(ray11, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray11, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray11.point1, ray11.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mConcaveMeshBody->raycast(ray12, raycastInfo3));
test(mConcaveMeshProxyShape->raycast(ray12, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray12, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray12.point1, ray12.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mConcaveMeshBody->raycast(ray13, raycastInfo3));
test(mConcaveMeshProxyShape->raycast(ray13, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray13, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray13.point1, ray13.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mConcaveMeshBody->raycast(ray14, raycastInfo3));
test(mConcaveMeshProxyShape->raycast(ray14, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray14, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray14.point1, ray14.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mConcaveMeshBody->raycast(ray15, raycastInfo3));
test(mConcaveMeshProxyShape->raycast(ray15, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray15, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray15.point1, ray15.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mConcaveMeshBody->raycast(ray16, raycastInfo3));
test(mConcaveMeshProxyShape->raycast(ray16, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray16, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray16.point1, ray16.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
}
void testHeightField() {
// ----- Test feedback data ----- //
Vector3 point1A = mLocalShapeToWorld * Vector3(0 , 10, 2);
Vector3 point1B = mLocalShapeToWorld * Vector3(0, -10, 2);
Ray ray(point1A, point1B);
Vector3 hitPoint = mLocalShapeToWorld * Vector3(0, 2, 2);
Vector3 point2A = mLocalShapeToWorld * Vector3(1 , 8, -4);
Vector3 point2B = mLocalShapeToWorld * Vector3(1, -8, -4);
Ray rayBottom(point2A, point2B);
Vector3 hitPoint2 = mLocalShapeToWorld * Vector3(1, 2, -4);
mCallback.shapeToTest = mHeightFieldProxyShape;
// CollisionWorld::raycast()
mCallback.reset();
mWorld->raycast(ray, &mCallback);
test(mCallback.isHit);
test(mCallback.raycastInfo.body == mHeightFieldBody);
test(mCallback.raycastInfo.proxyShape == mHeightFieldProxyShape);
test(approxEqual(mCallback.raycastInfo.hitFraction, decimal(0.4), epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.z, hitPoint.z, epsilon));
// Correct category filter mask
mCallback.reset();
mWorld->raycast(ray, &mCallback, CATEGORY2);
test(mCallback.isHit);
// Wrong category filter mask
mCallback.reset();
mWorld->raycast(ray, &mCallback, CATEGORY1);
test(!mCallback.isHit);
// CollisionBody::raycast()
RaycastInfo raycastInfo2;
test(mHeightFieldBody->raycast(ray, raycastInfo2));
test(raycastInfo2.body == mHeightFieldBody);
test(raycastInfo2.proxyShape == mHeightFieldProxyShape);
test(approxEqual(raycastInfo2.hitFraction, decimal(0.4), epsilon));
test(approxEqual(raycastInfo2.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo2.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo2.worldPoint.z, hitPoint.z, epsilon));
// ProxyCollisionShape::raycast()
RaycastInfo raycastInfo3;
test(mHeightFieldProxyShape->raycast(ray, raycastInfo3));
test(raycastInfo3.body == mHeightFieldBody);
test(raycastInfo3.proxyShape == mHeightFieldProxyShape);
test(approxEqual(raycastInfo3.hitFraction, decimal(0.4), epsilon));
test(approxEqual(raycastInfo3.worldPoint.x, hitPoint.x, epsilon));
test(approxEqual(raycastInfo3.worldPoint.y, hitPoint.y, epsilon));
test(approxEqual(raycastInfo3.worldPoint.z, hitPoint.z, epsilon));
mCallback.reset();
mWorld->raycast(rayBottom, &mCallback);
test(mCallback.isHit);
test(mCallback.raycastInfo.body == mHeightFieldBody);
test(mCallback.raycastInfo.proxyShape == mHeightFieldProxyShape);
test(approxEqual(mCallback.raycastInfo.hitFraction, decimal(0.375), epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.x, hitPoint2.x, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.y, hitPoint2.y, epsilon));
test(approxEqual(mCallback.raycastInfo.worldPoint.z, hitPoint2.z, epsilon));
// CollisionBody::raycast()
RaycastInfo raycastInfo5;
test(mHeightFieldBody->raycast(rayBottom, raycastInfo5));
test(raycastInfo5.body == mHeightFieldBody);
test(raycastInfo5.proxyShape == mHeightFieldProxyShape);
test(approxEqual(raycastInfo5.hitFraction, decimal(0.375), epsilon));
test(approxEqual(raycastInfo5.worldPoint.x, hitPoint2.x, epsilon));
test(approxEqual(raycastInfo5.worldPoint.y, hitPoint2.y, epsilon));
test(approxEqual(raycastInfo5.worldPoint.z, hitPoint2.z, epsilon));
// ProxyCollisionShape::raycast()
RaycastInfo raycastInfo6;
test(mHeightFieldProxyShape->raycast(rayBottom, raycastInfo6));
test(raycastInfo6.body == mHeightFieldBody);
test(raycastInfo6.proxyShape == mHeightFieldProxyShape);
test(approxEqual(raycastInfo6.hitFraction, decimal(0.375), epsilon));
test(approxEqual(raycastInfo6.worldPoint.x, hitPoint2.x, epsilon));
test(approxEqual(raycastInfo6.worldPoint.y, hitPoint2.y, epsilon));
test(approxEqual(raycastInfo6.worldPoint.z, hitPoint2.z, epsilon));
Ray ray1(mLocalShapeToWorld * Vector3(0, 5, 0), mLocalShapeToWorld * Vector3(5, 7, 5));
Ray ray2(mLocalShapeToWorld * Vector3(-4, -4, 7), mLocalShapeToWorld * Vector3(-4, 15, 7));
Ray ray3(mLocalShapeToWorld * Vector3(23, 7, 2), mLocalShapeToWorld * Vector3(23, 1, 2));
Ray ray4(mLocalShapeToWorld * Vector3(10, 3, 10), mLocalShapeToWorld * Vector3(22, 3, 31));
Ray ray5(mLocalShapeToWorld * Vector3(4, 10, -1), mLocalShapeToWorld * Vector3(4, 3, -1));
Ray ray11(mLocalShapeToWorld * Vector3(3, 15, 0.5), mLocalShapeToWorld * Vector3(3, 1, 0.5));
Ray ray12(mLocalShapeToWorld * Vector3(0, 45, 0), mLocalShapeToWorld * Vector3(0, -5, 0));
Ray ray13(mLocalShapeToWorld * Vector3(1, 23, 2), mLocalShapeToWorld * Vector3(1, -23, 2));
Ray ray14(mLocalShapeToWorld * Vector3(3, 8, 3), mLocalShapeToWorld * Vector3(3, 0, 3));
// ----- Test raycast miss ----- //
test(!mHeightFieldBody->raycast(ray1, raycastInfo3));
test(!mHeightFieldProxyShape->raycast(ray1, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray1, &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray1.point1, ray1.point2, decimal(0.01)), &mCallback);
test(!mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray1.point1, ray1.point2, decimal(100.0)), &mCallback);
test(!mCallback.isHit);
test(!mHeightFieldBody->raycast(ray2, raycastInfo3));
test(!mHeightFieldProxyShape->raycast(ray2, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray2, &mCallback);
test(!mCallback.isHit);
test(!mHeightFieldBody->raycast(ray3, raycastInfo3));
test(!mHeightFieldProxyShape->raycast(ray3, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray3, &mCallback);
test(!mCallback.isHit);
test(!mHeightFieldBody->raycast(ray4, raycastInfo3));
test(!mHeightFieldProxyShape->raycast(ray4, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray4, &mCallback);
test(!mCallback.isHit);
test(!mHeightFieldBody->raycast(ray5, raycastInfo3));
test(!mHeightFieldProxyShape->raycast(ray5, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray5, &mCallback);
test(!mCallback.isHit);
mCallback.reset();
// ----- Test raycast hits ----- //
test(mHeightFieldBody->raycast(ray11, raycastInfo3));
test(mHeightFieldProxyShape->raycast(ray11, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray11, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray11.point1, ray11.point2, decimal(0.95)), &mCallback);
test(mCallback.isHit);
test(mHeightFieldBody->raycast(ray12, raycastInfo3));
test(mHeightFieldProxyShape->raycast(ray12, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray12, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray12.point1, ray12.point2, decimal(0.87)), &mCallback);
test(mCallback.isHit);
test(mHeightFieldBody->raycast(ray13, raycastInfo3));
test(mHeightFieldProxyShape->raycast(ray13, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray13, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray13.point1, ray13.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
test(mHeightFieldBody->raycast(ray14, raycastInfo3));
test(mHeightFieldProxyShape->raycast(ray14, raycastInfo3));
mCallback.reset();
mWorld->raycast(ray14, &mCallback);
test(mCallback.isHit);
mCallback.reset();
mWorld->raycast(Ray(ray14.point1, ray14.point2, decimal(0.8)), &mCallback);
test(mCallback.isHit);
}
};
}
#endif