unsigned int PhysicsEngine::addUserVehicle(const osg::Vec3f& pos, const osg::Vec3f& sizes, const osg::Quat& orient, float mass) { assert(OpenThreads::Thread::CurrentThread() == m_physicsThread); if (! m_vehicleShape) m_vehicleShape = new btBoxShape(btVector3(sizes.x() / 2, sizes.y() / 2, sizes.z() / 2)); //m_collisionShapes.push_back(m_vehicleShape); btTransform startTransform; startTransform.setIdentity(); startTransform.setRotation(btQuaternion(orient.x(), orient.y(), orient.z(), orient.w())); startTransform.setOrigin(btVector3(pos.x(), pos.y(), pos.z())); VehicleMotionState* motionState = new VehicleMotionState(this, m_nextUsedId, startTransform); btVector3 inertia; m_vehicleShape->calculateLocalInertia(mass, inertia); btRigidBody* body = new btRigidBody(mass, motionState, m_vehicleShape, inertia); m_vehicles[m_nextUsedId] = body; ++m_nextUsedId; body->setDamping(0.5f, 0.7f); m_physicsWorld->addRigidBody(body, COLLISION_SHIPGROUP, COLLISION_SHIPGROUP | COLLISION_ASTEROIDGROUP); return m_nextUsedId - 1; }
void ActorTracer::findGround(const Actor* actor, const osg::Vec3f& start, const osg::Vec3f& end, const btCollisionWorld* world) { const btVector3 btstart(start.x(), start.y(), start.z()); const btVector3 btend(end.x(), end.y(), end.z()); const btTransform &trans = actor->getCollisionObject()->getWorldTransform(); btTransform from(trans.getBasis(), btstart); btTransform to(trans.getBasis(), btend); ClosestNotMeConvexResultCallback newTraceCallback(actor->getCollisionObject(), btstart-btend, btScalar(0.0)); // Inherit the actor's collision group and mask newTraceCallback.m_collisionFilterGroup = actor->getCollisionObject()->getBroadphaseHandle()->m_collisionFilterGroup; newTraceCallback.m_collisionFilterMask = actor->getCollisionObject()->getBroadphaseHandle()->m_collisionFilterMask; newTraceCallback.m_collisionFilterMask &= ~CollisionType_Actor; world->convexSweepTest(actor->getConvexShape(), from, to, newTraceCallback); if(newTraceCallback.hasHit()) { const btVector3& tracehitnormal = newTraceCallback.m_hitNormalWorld; mFraction = newTraceCallback.m_closestHitFraction; mPlaneNormal = osg::Vec3f(tracehitnormal.x(), tracehitnormal.y(), tracehitnormal.z()); mEndPos = (end-start)*mFraction + start; } else { mEndPos = end; mPlaneNormal = osg::Vec3f(0.0f, 0.0f, 1.0f); mFraction = 1.0f; } }
osg::Vec4f Raytracer::renderPixel(int x, int y, const osg::Vec3f& eye, const osg::Vec3f& dir) { osg::Vec3f lightPos(-338.572, 0, 400); RTCRay ray; ray.primID = RTC_INVALID_GEOMETRY_ID; ray.geomID = RTC_INVALID_GEOMETRY_ID; ray.instID = RTC_INVALID_GEOMETRY_ID; ray.tnear = 0.0f; ray.tfar = 100000.0f; ray.org[0] = eye.x(); ray.org[1] = eye.y(); ray.org[2] = eye.z(); ray.dir[0]= dir.x(); ray.dir[1] = dir.y(); ray.dir[2] = dir.z(); rtcIntersect(_scene, ray); if(ray.primID != -1) { osg::Vec3f pos = eye + dir*ray.tfar; osg::Vec4f diffuse = getSurfaceColor(ray.geomID, ray.primID,ray.u,ray.v); osg::Vec3 normal = getNormal(ray.geomID,ray.primID,ray.u,ray.v); osg::Vec3f lightDir = lightPos - pos; lightDir.normalize(); float NdotL = std::max(normal * lightDir,0.0f); return diffuse * NdotL; } return _backgroundColor; }
//*********************************************************** //FUNCTION: void CPickNode::__drawCoordinateLine(const osg::Vec3f& vOrigin, float vLength, osg::ref_ptr<osg::Geode>& vLineNode) { osg::ref_ptr<osg::Geometry> CoordGeometry = new osg::Geometry(); osg::ref_ptr<osg::Vec3Array> CoordVertex = new osg::Vec3Array(); CoordVertex->push_back(vOrigin); CoordVertex->push_back(osg::Vec3(vOrigin.x()+vLength, vOrigin.y(), vOrigin.z())); CoordVertex->push_back(vOrigin); CoordVertex->push_back(osg::Vec3(vOrigin.x(), vOrigin.y()+vLength, vOrigin.z())); CoordVertex->push_back(vOrigin); CoordVertex->push_back(osg::Vec3(vOrigin.x(), vOrigin.y(), vOrigin.z()+vLength)); CoordGeometry->setVertexArray(CoordVertex.get()); CoordGeometry->addPrimitiveSet(new osg::DrawArrays(osg::PrimitiveSet::LINES, 0, 6)); osg::ref_ptr<osg::Vec4Array> VertColor = new osg::Vec4Array(); VertColor->push_back(osg::Vec4(1.0, 0.0, 0.0, 1.0)); VertColor->push_back(osg::Vec4(1.0, 0.0, 0.0, 1.0)); VertColor->push_back(osg::Vec4(0.0, 1.0, 0.0, 1.0)); VertColor->push_back(osg::Vec4(0.0, 1.0, 0.0, 1.0)); VertColor->push_back(osg::Vec4(0.0, 0.0, 1.0, 1.0)); VertColor->push_back(osg::Vec4(0.0, 0.0, 1.0, 1.0)); CoordGeometry->setColorArray(VertColor.get()); CoordGeometry->setColorBinding(osg::Geometry::BIND_PER_VERTEX); osg::ref_ptr<osg::LineWidth> LineSize = new osg::LineWidth(); LineSize->setWidth(5); vLineNode->getOrCreateStateSet()->setAttributeAndModes(LineSize.get(), osg::StateAttribute::ON); vLineNode->addDrawable(CoordGeometry.get()); }
//*********************************************************** //FUNCTION: void CPickNode::__drawCoordinateMask(const osg::Vec3f& vOrigin, float vLength, osg::ref_ptr<osg::Geode>& vMaskNode) { osg::ref_ptr<osg::Geometry> MakGeom = new osg::Geometry(); osg::ref_ptr<osg::Vec3Array> MaskVert = new osg::Vec3Array(); for (unsigned int i=1; i<=10; i++) { float Offfset = vLength / 10.0 * i; MaskVert->push_back(osg::Vec3(vOrigin.x()+Offfset, vOrigin.y(), vOrigin.z())); MaskVert->push_back(osg::Vec3(vOrigin.x(), vOrigin.y()+Offfset, vOrigin.z())); MaskVert->push_back(osg::Vec3(vOrigin.x(), vOrigin.y(), vOrigin.z()+Offfset)); } osg::ref_ptr<osg::Vec4Array> ColorArray = new osg::Vec4Array; ColorArray->push_back(osg::Vec4(1.0, 1.0, 1.0, 1.0)); MakGeom->setVertexArray(MaskVert.get()); MakGeom->setColorArray(ColorArray); MakGeom->setColorBinding(osg::Geometry::BIND_OVERALL); MakGeom->addPrimitiveSet(new osg::DrawArrays(osg::PrimitiveSet::POINTS, 0, 30)); vMaskNode->addDrawable(MakGeom.get()); osg::ref_ptr<osg::Point> PointSize = new osg::Point(5.0); osg::ref_ptr<osg::StateSet> PointStateSet = vMaskNode->getOrCreateStateSet(); PointStateSet->setAttribute(PointSize); }
bool ShapeVisitor_RestrictedPositionGetter::insideCube( const osg::Vec3f& center, const osg::Vec3f& surfaceX, const osg::Vec3f& surfaceY, const osg::Vec3f& surfaceZ, osg::Vec3f& point ) { float distanceX = fabsf( ( center - surfaceX ).x() ); float distanceY = fabsf( ( center - surfaceY ).y() ); float distanceZ = fabsf( ( center - surfaceZ ).z() ); return ( point.x() > center.x() - distanceX && point.x() < center.x() + distanceX && point.y() > center.y() - distanceY && point.y() < center.y() + distanceY && point.z() > center.z() - distanceZ && point.z() < center.z() + distanceZ ); }
const osg::Vec3f Stars::sRgbColor(const osg::Vec3f xyzTristimulus) { // (The Colors of the Stars - Olson - 1998) - sRGB matrix - feel free to use other matrices here... const float r = 3.24 * xyzTristimulus.x() -1.537 * xyzTristimulus.y() -0.499 * xyzTristimulus.z(); const float g = -0.969 * xyzTristimulus.x() +1.876 * xyzTristimulus.y() +0.042 * xyzTristimulus.z(); const float b = 0.056 * xyzTristimulus.x() -0.204 * xyzTristimulus.y() +1.057 * xyzTristimulus.z(); return osg::Vec3f(r, g, b); }
osg::Vec3f ShapeVisitor_RestrictedPositionGetter::toCube( const osg::Vec3f& center, const osg::Vec3f& surfaceX, const osg::Vec3f& surfaceY, const osg::Vec3f& surfaceZ, const osg::Vec3f& point ) { float distanceX = std::fabs( ( center - surfaceX ).x() ); float distanceY = std::fabs( ( center - surfaceY ).y() ); float distanceZ = std::fabs( ( center - surfaceZ ).z() ); // nearest_point_on_box(x, y, z, box_min_x, box_min_y, box_min_z, box_max_x, box_max_y, box_max_z) float x = /*point.x() -*/ median( point.x(), center.x() - distanceX, center.x() + distanceX ); float y = /*point.y() -*/ median( point.y(), center.y() - distanceY, center.y() + distanceY ); float z = /*point.z() -*/ median( point.z(), center.z() - distanceZ, center.z() + distanceZ ); return osg::Vec3f( x,y,z ); }
GameInstanceServer::ChunkCoordinates GameInstanceServer::positionToChunk(const osg::Vec3f& pos) { return ChunkCoordinates( std::floor(pos.x() / chunksize), std::floor(pos.y() / chunksize), std::floor(pos.z() / chunksize)); }
void Storage::fixNormal (osg::Vec3f& normal, int cellX, int cellY, int col, int row) { while (col >= ESM::Land::LAND_SIZE-1) { ++cellY; col -= ESM::Land::LAND_SIZE-1; } while (row >= ESM::Land::LAND_SIZE-1) { ++cellX; row -= ESM::Land::LAND_SIZE-1; } while (col < 0) { --cellY; col += ESM::Land::LAND_SIZE-1; } while (row < 0) { --cellX; row += ESM::Land::LAND_SIZE-1; } ESM::Land* land = getLand(cellX, cellY); if (land && land->mDataTypes&ESM::Land::DATA_VNML) { normal.x() = land->mLandData->mNormals[col*ESM::Land::LAND_SIZE*3+row*3]; normal.y() = land->mLandData->mNormals[col*ESM::Land::LAND_SIZE*3+row*3+1]; normal.z() = land->mLandData->mNormals[col*ESM::Land::LAND_SIZE*3+row*3+2]; normal.normalize(); } else normal = osg::Vec3f(0,0,1); }
unsigned int PhysicsEngine::addCollisionSphere(osg::Vec3f pos, float radius, float mass) { assert(OpenThreads::Thread::CurrentThread() == m_physicsThread); btSphereShape* newShape = new btSphereShape(radius); m_collisionShapes.push_back(newShape); btTransform initialTransform; initialTransform.setIdentity(); initialTransform.setOrigin(btVector3(pos.x(), pos.y(), pos.z())); //btMotionState* motionState = new btDefaultMotionState(initialTransform); //btVector3 inertia; //newShape->calculateLocalInertia(0.0, inertia); // TODO: upgrade to the rigid body status? btCollisionObject* newBody = new btCollisionObject; newBody->setCollisionShape(newShape); newBody->setWorldTransform(initialTransform); m_collisionObjects.insert(std::make_pair(m_nextUsedId, newBody)); ++m_nextUsedId; m_physicsWorld->addCollisionObject(newBody, COLLISION_ASTEROIDGROUP, COLLISION_SHIPGROUP); return m_nextUsedId - 1; }
std::string toString(const osg::Vec3f &value) { std::stringstream str; str << value.x() << " " << value.y() << " " << value.z(); return str.str(); }
osg::Vec3f CoordinateConverter::toLocalVec3(const osg::Vec3f& point) { return osg::Vec3f( point.x() - static_cast<float>(mCellX), point.y() - static_cast<float>(mCellY), point.z() ); }
void RippleSimulation::emitRipple(const osg::Vec3f &pos) { if (std::abs(pos.z() - mParticleNode->getPosition().z()) < 20) { osgParticle::Particle* p = mParticleSystem->createParticle(NULL); p->setPosition(osg::Vec3f(pos.x(), pos.y(), 0.f)); p->setAngle(osg::Vec3f(0,0, Misc::Rng::rollProbability() * osg::PI * 2 - osg::PI)); } }
/* Linearly interpolate the position where an isosurface cuts an edge between two vertices, each with their own scalar value */ osg::Vec3f VertexInterp(double isolevel, osg::Vec3f p1, osg::Vec3f p2, double valp1, double valp2) { double mu; osg::Vec3f p; if (ABS(isolevel-valp1) < 0.00001) return p1; if (ABS(isolevel-valp2) < 0.00001) return p2; if (ABS(valp1-valp2) < 0.00001) return p1; mu = (isolevel - valp1) / (valp2 - valp1); p.set(p1.x() + mu * (p2.x() - p1.x()), p1.y() + mu * (p2.y() - p1.y()), p1.z() + mu * (p2.z() - p1.z())); return p; }
void Scene::playerMoved(const osg::Vec3f &pos) { if (!mCurrentCell || !mCurrentCell->isExterior()) return; // figure out the center of the current cell grid (*not* necessarily mCurrentCell, which is the cell the player is in) int cellX, cellY; getGridCenter(cellX, cellY); float centerX, centerY; MWBase::Environment::get().getWorld()->indexToPosition(cellX, cellY, centerX, centerY, true); const float maxDistance = 8192/2 + 1024; // 1/2 cell size + threshold float distance = std::max(std::abs(centerX-pos.x()), std::abs(centerY-pos.y())); if (distance > maxDistance) { int newX, newY; MWBase::Environment::get().getWorld()->positionToIndex(pos.x(), pos.y(), newX, newY); changeCellGrid(newX, newY); //mRendering.updateTerrain(); } }
inline void update(void) { _pat.setPosition(osg::Vec3f(_eye.x(), _eye.y(), _pat.getPosition().z())); }
//------------------------------------------------------------------------------ osg::ref_ptr<osg::Node> setupScene( osg::ref_ptr<osg::Geometry> geom, osg::Vec3f bbmin, osg::Vec3f bbmax ) { osg::ref_ptr<osg::Group> scene = new osg::Group; ////////////////////////////// // CREATE PARTICLE GEOMETRY // ////////////////////////////// osg::ref_ptr<osg::Geode> geode = new osg::Geode; geode->addDrawable( geom.get() ); osg::ref_ptr<osg::Program> computation = new osg::Program; const std::string vtxShader= "uniform vec2 pixelsize; \n" " \n" "void main(void) \n" "{ \n" " vec4 worldPos = vec4(gl_Vertex.x,gl_Vertex.y,gl_Vertex.z,1.0); \n" " vec4 projPos = gl_ModelViewProjectionMatrix * worldPos; \n" " \n" " float dist = projPos.z / projPos.w; \n" " float distAlpha = (dist+1.0)/2.0; \n" " gl_PointSize = pixelsize.y - distAlpha * (pixelsize.y - pixelsize.x); \n" " \n" " gl_Position = projPos; \n" "} \n"; computation->addShader( new osg::Shader(osg::Shader::VERTEX, vtxShader ) ); const std::string frgShader= "void main (void) \n" "{ \n" " vec4 result; \n" " \n" " vec2 tex_coord = gl_TexCoord[0].xy; \n" " tex_coord.y = 1.0-tex_coord.y; \n" " float d = 2.0*distance(tex_coord.xy, vec2(0.5, 0.5)); \n" " result.a = step(d, 1.0); \n" " \n" " vec3 eye_vector = normalize(vec3(0.0, 0.0, 1.0)); \n" " vec3 light_vector = normalize(vec3(2.0, 2.0, 1.0)); \n" " vec3 surface_normal = normalize(vec3(2.0* \n" " (tex_coord.xy-vec2(0.5, 0.5)), sqrt(1.0-d))); \n" " vec3 half_vector = normalize(eye_vector+light_vector); \n" " \n" " float specular = dot(surface_normal, half_vector); \n" " float diffuse = dot(surface_normal, light_vector); \n" " \n" " vec4 lighting = vec4(0.75, max(diffuse, 0.0), pow(max(specular, 0.0), 40.0), 0.0); \n" " \n" " result.rgb = lighting.x*vec3(0.2, 0.8, 0.2)+lighting.y*vec3(0.6, 0.6, 0.6)+ \n" " lighting.z*vec3(0.25, 0.25, 0.25); \n" " \n" " gl_FragColor = result; \n" "} \n"; computation->addShader( new osg::Shader( osg::Shader::FRAGMENT, frgShader ) ); geode->getOrCreateStateSet()->setAttribute(computation); geode->getOrCreateStateSet()->setMode(GL_VERTEX_PROGRAM_POINT_SIZE, osg::StateAttribute::ON); geode->getOrCreateStateSet()->setTextureAttributeAndModes(0, new osg::PointSprite, osg::StateAttribute::ON); geode->getOrCreateStateSet()->setAttribute( new osg::AlphaFunc( osg::AlphaFunc::GREATER, 0.1f) ); geode->getOrCreateStateSet()->setMode( GL_ALPHA_TEST, GL_TRUE ); geode->getOrCreateStateSet()->addUniform( new osg::Uniform( "pixelsize", osg::Vec2(1.0f,50.0f) ) ); geode->setCullingActive( false ); scene->addChild( geode ); ///////////////////////// // CREATE BOUNDING BOX // ///////////////////////// osg::Geode* bbox = new osg::Geode; bbox->addDrawable(new osg::ShapeDrawable(new osg::Box((bbmin + bbmax) * 0.5f,bbmax.x() - bbmin.x(),bbmax.y() - bbmin.y(),bbmax.z() - bbmin.z()),new osg::TessellationHints())); bbox->getOrCreateStateSet()->setMode( GL_LIGHTING, osg::StateAttribute::OFF ); bbox->getOrCreateStateSet()->setAttribute( new osg::PolygonMode(osg::PolygonMode::FRONT_AND_BACK,osg::PolygonMode::LINE)); scene->addChild( bbox ); return scene; }
void VRPhysics::setGravity(OSG::Vec3f v) { Lock lock(mtx()); if (body) body->setGravity(btVector3 (v.x(),v.y(),v.z())); }
//////////////////////////////////////////////////////////// /// Set the sound position (take a 3D vector). /// The default position is (0, 0, 0) //////////////////////////////////////////////////////////// void Sound::SetPosition(const osg::Vec3f& Position) { SetPosition(Position.x(), Position.y(), Position.z()); }
Vector3::Vector3(osg::Vec3f const &vec) : m_x(vec.x()), m_y(vec.y()), m_z(vec.z()) {}
bool FFTOceanSurface::updateMipmaps( const osg::Vec3f& eye, unsigned int frame ) { static unsigned int count = 0; bool updated = false; _newNumVertices = 0; int tileSize = _tileResolution+1; int x_offset = 0; int y_offset = 0; if(_isEndless) { float xMin = _startPos.x(); float yMin = _startPos.y() - (float)((_tileResolution+1)*_numTiles); x_offset = (int) ( (eye.x()-xMin) / (float)_tileResolution ); y_offset = (int) ( (eye.y()-yMin) / (float)_tileResolution ); x_offset -= _numTiles/2; y_offset -= _numTiles/2; _startPos.x() += (float)(x_offset * tileSize); _startPos.y() += (float)(y_offset * tileSize); } for( unsigned int y = 0; y < _numTiles; ++y) { for( unsigned int x = 0; x < _numTiles; ++x) { osg::Vec3f newbound = getTile(x,y)->getBound().center(); newbound.x() += (float)(x_offset * tileSize); newbound.y() += (float)(y_offset * tileSize); osg::Vec3f distanceToTile = newbound - eye; unsigned int mipmapLevel = 0; for( unsigned int m = 0; m < _minDist.size(); ++m ) { if( distanceToTile.length2() > _minDist.at(m) ) mipmapLevel = m; } if( getTile(x,y)->getLevel() != mipmapLevel ) updated = true; getTile(x,y)->setLevel( mipmapLevel ); getTile(x,y)->setIdx( _newNumVertices ); unsigned int verts = 0; unsigned int size = getTile(x,y)->getResolution(); verts = size * size; if(x == _numTiles-1 ) verts += size; if(y == _numTiles-1 ) verts += size; if(x == _numTiles-1 && y == _numTiles-1) verts += 1; _newNumVertices += verts; } } return updated; }
void CoordinateConverter::toLocal(osg::Vec3f& point) { point.x() -= static_cast<float>(mCellX); point.y() -= static_cast<float>(mCellY); }
void OsgDrawableCullCallback::SetParams (bool wms_active, int cx, int cy, osg::Vec3f &_eye, osg::Vec3f &_center, osg::Vec3f &_up, osg::Vec3f &_punto_mira, bool _resetWMS, double msec, const unsigned char &_blending) { // guardamos los parámetros eye = _eye; // posición de la cámara punto_mira = _punto_mira; // punto de corte con la escena width2 = cx; // mitad del ancho de la imagen, en pixels height2 = cy; // mitad del alto de la imagen, en pixels // calculamos los 3 ejes del sistema de referencia de la cámara vx = _up.x(); vy = _up.y(); vz = _up.z(); wx = _center.x() - _eye.x(); wy = _center.y() - _eye.y(); wz = _center.z() - _eye.z(); ux = wy*vz - wz*vy; uy = wz*vx - wx*vz; uz = wx*vy - wy*vx; // calculamos la distancia focal (mirar perspectiva.tex) // tendría que usar la función UTMToSceneCoords, pero no sé como hacerlo desde aquí //cpw::Point3d<float> P1 = cpw::ApplicationScene::GetInstance()->GetScene()->UTMToSceneCoords(cpw::Point3d<float>(punto_mira.x(), punto_mira.y(), punto_mira.z())); cpw::Point3d<double> out = ((OsgScene *)cpw::ApplicationScene::GetInstance()->GetScene())->UTMToSceneCoords( cpw::Point3d<double>(punto_mira.x() - traslation.x(), punto_mira.y() - traslation.y(), punto_mira.z() - traslation.z())); double x1=out.x, y1=out.y, z1=out.z; /* ahora convertimos a utm con la llamada de David double x1 = punto_mira.x() - traslation.x(); double y1 = punto_mira.y() - traslation.y() - 3e6; double z1 = punto_mira.z() - traslation.z(); */ double num = x1*wx + y1*wy + z1*wz - eye.x()*wx - eye.y()*wy - eye.z()*wz; double den = x1*vx + y1*vy + z1*vz - eye.x()*vx - eye.y()*vy - eye.z()*vz; D = - height2 / 3.0 * num / den; // si alquien picó en el tree layer, _resetWMS está a true, y pasamos al estado 3 if (_resetWMS) { switch (estadoWMS) { case 1: CancelPetitions(); resetWMS = true; break; case 2: estadoWMS = 3; CancelPetitions(); // según si quedan capas o no, pasamos al estado 3 o seguimos en el estado 2 if (wms_active) { estadoWMS=1; //resetWMS = true; } else { estadoWMS=3; } break; case 3: CancelPetitions(); break; } } // colocamos el estado WMS actual (ver grafo libreta y algoritmoWMS.doc) if (wms_active) { if (estadoWMS == 0) estadoWMS = 1; //if (pets.empty()) ComputeNextPetition(); ComputeNextPetition(); } else { switch (estadoWMS) { case 1: estadoWMS = 0; CancelPetitions(); resetWMS = true; break; case 2: estadoWMS = 3; CancelPetitions(); break; } } // si hay peticiones pendientes, miramos si han llegado if (!pets.empty() && estadoWMS>0 && estadoWMS<3) { // si alguna textura no la reclamo nadie, las descartamos for (int i=(int)pets.size()-1; i>=0; i--) { if (pets[i].TextureWMS.get()) { pets.erase (pets.begin()+i); printf ("hubo una textura que no reclamó nadie. Quedan %d pendientes", pets.size()); } } // si se quedó vacía reiniciamos el flag //if (pets.empty()) PET_PEND = false; //instead of getting and releasing the mutex in every "IsPetitionAttended" call, //better call this function to get it only once petman->GainSafeAccess(); // miramos si alguna petición pendiente ha llegado for (unsigned int i=0; i<pets.size(); i++) { bool result = petman->IsPetitionAttended (pets[i].id_wms, pets[i].TextureWMS); if (!result) printf ("hubo una petición errónea"); } petman->ReleaseSafeAccess(); //release mutex } // calculamos el nuevo factor de blending if (last_blending != _blending) { // si han movido el slider, cogemos el nuevo valor last_blending = blending = _blending; } else { // si no, lo hacemos en función del tiempo switch (estadoWMS) { case 0: blending = 0; break; case 2: if (blending < _blending) { int inc = msec * 255 / BLENDING_DELAY; if (inc==0) inc = 1; int bl_i = (int) blending + inc; blending = (bl_i > _blending)? _blending : (unsigned char) bl_i; } break; case 3: if (blending > 0) { int inc = msec * 255 / BLENDING_DELAY; if (inc==0) inc = 1; int bl_i = (int) blending - inc; blending = (bl_i < 0)? 0 : (unsigned char) bl_i; } // si llegamos a cero cambiamos de estado y reseteamos texturas if (blending == 0) { resetWMS = true; if (wms_active) estadoWMS=1; else { estadoWMS=0; CancelPetitions(); } } break; } } // si no hay peticiones pendientes, actualizamos el cronometro if (pets.empty()) { t0_wms = osg::Timer::instance()->tick(); } else { // si hace tiempo que no llegan texturas, reseteamos la cola de peticiones if (estadoWMS==2 && GetWaitedTimeWMS()>1000*MAX_TIME_OUT) { printf ("¡¡¡¡¡¡¡¡¡¡¡¡¡TIME_OUT!!!!!!!!!!!!!!!!"); CancelPetitions(); t0_wms = osg::Timer::instance()->tick(); resetPetPend = true; } } }
bool SDCloudLayer::reposition( const osg::Vec3f& p, double dt ) { if (getCoverage() != SDCloudLayer::SD_CLOUD_CLEAR) { osg::Vec3 asl_offset( p ); asl_offset.normalize(); if ( p.y() <= layer_asl ) { asl_offset *= layer_asl; } else { asl_offset *= layer_asl + layer_thickness; } asl_offset += p; osg::Matrix T, LON, LAT; T.makeTranslate( asl_offset ); //LON.makeRotate(lon, osg::Vec3(0, 0, 1)); //LAT.makeRotate(90.0 * SD_DEGREES_TO_RADIANS - lat, osg::Vec3(0, 1, 0)); layer_transform->setMatrix( T ); group_bottom->getStateSet()->setRenderBinDetails(-(int)layer_asl, "RenderBin"); group_top->getStateSet()->setRenderBinDetails((int)layer_asl, "RenderBin"); if ( alt <= layer_asl ) { layer_root->setSingleChildOn(0); } else if ( alt >= layer_asl + layer_thickness ) { layer_root->setSingleChildOn(1); } else { layer_root->setAllChildrenOff(); } double sp_dist = speed * dt; if ( p.x() != last_x || p.y() != last_y || sp_dist != 0 ) { double ax = 0.0, ay = 0.0, bx = 0.0, by = 0.0; if (sp_dist > 0) { bx = cos((180.0-direction) * SD_DEGREES_TO_RADIANS) * sp_dist; by = sin((180.0-direction) * SD_DEGREES_TO_RADIANS) * sp_dist; } double xoff = (ax + bx) / (2 * scale); double yoff = (ay + by) / (2 * scale); const float layer_scale = layer_span / scale; base[0] += xoff; if ( base[0] > -10.0 && base[0] < 10.0 ) { base[0] -= (int)base[0]; } else { base[0] = 0.0; } base[1] += yoff; if ( base[1] > -10.0 && base[1] < 10.0 ) { base[1] -= (int)base[1]; } else { base[1] = 0.0; } setTextureOffset(base); last_pos = p; scale = layer_scale; } } //layer3D->reposition( p, up, lon, lat, dt, layer_asl, speed, direction); return true; }
void EnPlayerSound::updatePosition( const osg::Vec3f& pos ) { _soundPosition.x = pos.x(); _soundPosition.y = pos.y(); _soundPosition.z = pos.z(); }
float Storage::getHeightAt(const osg::Vec3f &worldPos) { int cellX = static_cast<int>(std::floor(worldPos.x() / 8192.f)); int cellY = static_cast<int>(std::floor(worldPos.y() / 8192.f)); ESM::Land* land = getLand(cellX, cellY); if (!land || !(land->mDataTypes&ESM::Land::DATA_VHGT)) return -2048; // Mostly lifted from Ogre::Terrain::getHeightAtTerrainPosition // Normalized position in the cell float nX = (worldPos.x() - (cellX * 8192))/8192.f; float nY = (worldPos.y() - (cellY * 8192))/8192.f; // get left / bottom points (rounded down) float factor = ESM::Land::LAND_SIZE - 1.0f; float invFactor = 1.0f / factor; int startX = static_cast<int>(nX * factor); int startY = static_cast<int>(nY * factor); int endX = startX + 1; int endY = startY + 1; endX = std::min(endX, ESM::Land::LAND_SIZE-1); endY = std::min(endY, ESM::Land::LAND_SIZE-1); // now get points in terrain space (effectively rounding them to boundaries) float startXTS = startX * invFactor; float startYTS = startY * invFactor; float endXTS = endX * invFactor; float endYTS = endY * invFactor; // get parametric from start coord to next point float xParam = (nX - startXTS) * factor; float yParam = (nY - startYTS) * factor; /* For even / odd tri strip rows, triangles are this shape: even odd 3---2 3---2 | / | | \ | 0---1 0---1 */ // Build all 4 positions in normalized cell space, using point-sampled height osg::Vec3f v0 (startXTS, startYTS, getVertexHeight(land, startX, startY) / 8192.f); osg::Vec3f v1 (endXTS, startYTS, getVertexHeight(land, endX, startY) / 8192.f); osg::Vec3f v2 (endXTS, endYTS, getVertexHeight(land, endX, endY) / 8192.f); osg::Vec3f v3 (startXTS, endYTS, getVertexHeight(land, startX, endY) / 8192.f); // define this plane in terrain space osg::Plane plane; // FIXME: deal with differing triangle alignment if (true) { // odd row bool secondTri = ((1.0 - yParam) > xParam); if (secondTri) plane = osg::Plane(v0, v1, v3); else plane = osg::Plane(v1, v2, v3); } /* else { // even row bool secondTri = (yParam > xParam); if (secondTri) plane.redefine(v0, v2, v3); else plane.redefine(v0, v1, v2); } */ // Solve plane equation for z return (-plane.getNormal().x() * nX -plane.getNormal().y() * nY - plane[3]) / plane.getNormal().z() * 8192; }
bool FFTOceanSurfaceVBO::updateLevels(const osg::Vec3f& eye) { int x_offset = 0; int y_offset = 0; if(_isEndless) { float xMin = _startPos.x(); float yMin = _startPos.y()-(_tileResolution*_numTiles); x_offset = (int) ( (eye.x()-xMin) / _tileResolution ); y_offset = (int) ( (eye.y()-yMin) / _tileResolution ); x_offset -= ((int)_numTiles)/2; y_offset -= ((int)_numTiles)/2; // std::cerr << "Offset: " << x_offset << "," << y_offset << std::endl; // std::cerr << "Start: " << _startPos.x() << "," << _startPos.y() << std::endl; if(x_offset != 0 || y_offset != 0) { //std::cerr << "Surface Move." << std::endl; while ((x_offset != 0) || (y_offset != 0)) { if(x_offset < 0) { osg::Vec3f offset; _startPos.x() -= (int)_tileResolution; for(int r = 0; r < (int)_numTiles; ++r) { std::vector< osg::ref_ptr<osgOcean::MipmapGeometryVBO> >& row = _mipmapGeom.at(r); offset.x() = _startPos.x(); offset.y() = _startPos.y()-r*(int)_tileResolution; offset.z() = 0; row.insert( row.begin(), row.back() ); // insert the row.pop_back(); row.front()->setOffset( offset ); // change offset } ++x_offset; } else if (x_offset > 0) { osg::Vec3f offset; _startPos.x() += (int)_tileResolution; for(int r = 0; r < (int)_numTiles; ++r) { std::vector< osg::ref_ptr<osgOcean::MipmapGeometryVBO> >& row = _mipmapGeom.at(r); offset.x() = _startPos.x() + ( (_numTiles-1)*(int)_tileResolution ); offset.y() = _startPos.y()-r*(int)_tileResolution; offset.z() = 0; row.insert( row.end(), row.front() ); row.erase( row.begin() ); row.back()->setOffset( offset ); } --x_offset; } if(y_offset < 0) { _startPos.y() -= (int)_tileResolution; _mipmapGeom.insert( _mipmapGeom.end(), _mipmapGeom.front() ); _mipmapGeom.erase( _mipmapGeom.begin() ); osg::Vec3f offset; for(int c = 0; c < (int)_numTiles; c++ ) { offset.x() = _startPos.x() + c *(int) _tileResolution; offset.y() = _startPos.y()-( (_numTiles-1)*(int)_tileResolution ); offset.z() = 0; _mipmapGeom.back().at(c)->setOffset(offset); } ++y_offset; } else if(y_offset > 0) { _startPos.y() += (int)_tileResolution; _mipmapGeom.insert( _mipmapGeom.begin(), _mipmapGeom.back() ); _mipmapGeom.pop_back(); osg::Vec3f offset; for(int c = 0; c < (int)_numTiles; c++ ) { offset.x() = _startPos.x() + c * (int)_tileResolution; offset.y() = _startPos.y(); offset.z() = 0; _mipmapGeom.front().at(c)->setOffset(offset); } --y_offset; } } } } unsigned updates=0; for(int r = _numTiles-1; r>=0; --r ) { for(int c = _numTiles-1; c>=0; --c ) { osgOcean::MipmapGeometryVBO* curGeom = _mipmapGeom.at(r).at(c).get(); osg::Vec3f centre = curGeom->getBound().center(); float distanceToTile2 = (centre-eye).length2(); unsigned mipmapLevel = 0; unsigned rightLevel = 0; unsigned belowLevel = 0; for( unsigned int m = 0; m < _minDist.size(); ++m ) { if( distanceToTile2 > _minDist.at(m) ) mipmapLevel = m; } if( c != _numTiles-1 && r != _numTiles-1 ){ osgOcean::MipmapGeometryVBO* rightGeom = _mipmapGeom.at(r).at(c+1).get(); osgOcean::MipmapGeometryVBO* belowGeom = _mipmapGeom.at(r+1).at(c).get(); rightLevel = rightGeom->getLevel(); belowLevel = belowGeom->getLevel(); } else { if( c != _numTiles-1 ){ osgOcean::MipmapGeometryVBO* rightGeom = _mipmapGeom.at(r).at(c+1).get(); rightLevel = rightGeom->getLevel(); } else{ rightLevel = mipmapLevel; } if( r != _numTiles-1 ){ osgOcean::MipmapGeometryVBO* belowGeom = _mipmapGeom.at(r+1).at(c).get(); belowLevel = belowGeom->getLevel(); } else{ belowLevel = mipmapLevel; } } if( curGeom->updatePrimitives(mipmapLevel,rightLevel,belowLevel) ) updates++; } } #ifdef OSGOCEAN_MIPMAP if (updates > 0) { std::cerr << "Updates: " << updates << std::endl; for(int r = _numTiles-1; r>=0; --r ) { for(int c = _numTiles-1; c>=0; --c ) { fprintf(stderr, "%d", _mipmapGeom.at(r).at(c)->getLevel()); } fprintf(stderr, "\n"); } } #endif /*OSGOCEAN_MIPMAP*/ return updates > 0; }
void vecfFunc(osg::Vec3f vec) { std::cout << "Got the float vector " << vec.x() << "," << vec.y() << "," << vec.z() << std::endl; }
// constructor PrecipitationBase::PrecipitationBase(const char * szMaterialName, size_t nParticlesNumber, const osg::Vec3f & vBoxHalfSize, float fMeanLifeTime/* = 10.f*/) : m_bActive(false) , m_nParticlesNumber(nParticlesNumber) , m_vBoxHalf(vBoxHalfSize) , m_fIntensity(0.0f) , m_fWindSpeed(0.0f) { // base set up setUseDisplayList(false); setUseVertexBufferObjects(true); setDataVariance(osg::Object::STATIC); setComputeBoundingBoxCallback(new osg::Drawable::ComputeBoundingBoxCallback()); // // create state set // osg::StateSet * pCurStateSet = getOrCreateStateSet(); // setup shader defines (scroll scales and so on) avCore::Database::ShaderDefineVector cShaderDefines; // full box shader definition { const osg::Vec3f vBoxFull = m_vBoxHalf * 2.0f; std::ostringstream stream; stream << "vec3(" << vBoxFull.x() << ", " << vBoxFull.y() << ", " << vBoxFull.z() << ")"; cShaderDefines.push_back(avCore::Database::ShaderDefine("SCROLL_FULL", stream.str().c_str())); } // full-box rcp shader definition { const osg::Vec3f vBoxFullRcp = osg::Vec3f(0.5f / m_vBoxHalf.x(), 0.5f / m_vBoxHalf.y(), 0.5f / m_vBoxHalf.z()); std::ostringstream stream; stream << "vec3(" << vBoxFullRcp.x() << ", " << vBoxFullRcp.y() << ", " << vBoxFullRcp.z() << ")"; cShaderDefines.push_back(avCore::Database::ShaderDefine("SCROLL_RCP", stream.str().c_str())); } // setup shader osg::Program * pCurProgram = new osg::Program; pCurProgram->setName(szMaterialName); pCurProgram->addShader(avCore::GetDatabase()->LoadShader(std::string(szMaterialName).append(".vs").c_str(), &cShaderDefines, osg::Shader::VERTEX )); pCurProgram->addShader(avCore::GetDatabase()->LoadShader(std::string(szMaterialName).append(".gs").c_str(), NULL , osg::Shader::GEOMETRY)); pCurProgram->addShader(avCore::GetDatabase()->LoadShader(std::string(szMaterialName).append(".fs").c_str(), NULL , osg::Shader::FRAGMENT)); pCurProgram->setParameter(GL_GEOMETRY_VERTICES_OUT_EXT, 4); pCurProgram->setParameter(GL_GEOMETRY_INPUT_TYPE_EXT, GL_POINTS); pCurProgram->setParameter(GL_GEOMETRY_OUTPUT_TYPE_EXT, GL_TRIANGLE_STRIP); // bind shader pCurStateSet->setAttribute(pCurProgram); // setup texture for point quads pCurStateSet->setTextureAttribute(0, avCore::GetDatabase()->LoadTexture(std::string(szMaterialName).append(".dds").c_str(), osg::Texture::CLAMP_TO_EDGE)); // box position m_uniformScrollLBN = new osg::Uniform("ScrollLBN", osg::Vec3f()); pCurStateSet->addUniform(m_uniformScrollLBN.get()); // LTP box offset m_uniformWP2LTPBoxOffset = new osg::Uniform("LTPOffset", osg::Vec2f()); pCurStateSet->addUniform(m_uniformWP2LTPBoxOffset.get()); // wind vector m_uniformWindVec = new osg::Uniform("WindVector", osg::Vec3f()); pCurStateSet->addUniform(m_uniformWindVec.get()); // render data m_uniformRenderData = new osg::Uniform("RenderData", osg::Vec4f()); pCurStateSet->addUniform(m_uniformRenderData.get()); // // Construct geometry // // attach draw call command m_dipDrawArrays = new osg::DrawArrays(osg::PrimitiveSet::POINTS); addPrimitiveSet(m_dipDrawArrays.get()); // create vertex array Half4Array * aBoxPointsPos = new Half4Array(m_nParticlesNumber); // speed deviation factors osg::Vec4ubArray * aSpeedFactors = new osg::Vec4ubArray(m_nParticlesNumber); // fill every vertex point avCore::RandomNumber rndGen; for (size_t i = 0; i < m_nParticlesNumber; ++i) { // random lifetime float fLifeTime = rndGen.random_dev(fMeanLifeTime, 0.3f * fMeanLifeTime); // get random position osg::Vec3f vRandPos; vRandPos.x() = rndGen.random_unit_signed() * m_vBoxHalf.x(); vRandPos.y() = rndGen.random_unit_signed() * m_vBoxHalf.y(); vRandPos.z() = rndGen.random_unit_signed() * m_vBoxHalf.z(); // save it tagVertexData & curVertex = aBoxPointsPos->at(i); curVertex.x = vRandPos.x(); curVertex.y = vRandPos.y(); curVertex.z = vRandPos.z(); curVertex.t = fLifeTime; // speed deviation factors osg::Vec4ub & curSpeedFactors = aSpeedFactors->at(i); curSpeedFactors[0] = rndGen.random_8bit(); curSpeedFactors[1] = rndGen.random_8bit(); curSpeedFactors[2] = rndGen.random_8bit(); curSpeedFactors[3] = rndGen.random_8bit(); } // set vertex array aBoxPointsPos->setDataVariance(osg::Object::STATIC); setVertexArray(aBoxPointsPos); // set factors array static const size_t idxSpeedFactorsBinding = 5; aSpeedFactors->setDataVariance(osg::Object::STATIC); setVertexAttribBinding(idxSpeedFactorsBinding, osg::Geometry::BIND_PER_VERTEX); setVertexAttribNormalize(idxSpeedFactorsBinding, GL_TRUE); setVertexAttribArray(idxSpeedFactorsBinding, aSpeedFactors); // exit return; }