コード例 #1
0
ファイル: Draw.cpp プロジェクト: StanEpp/Rendering
void drawVector(RenderingContext & rc, const Geometry::Vec3 & from, const Geometry::Vec3 & to) {
	static Util::Reference<Mesh> mesh;
	if (mesh.isNull()) {
		VertexDescription vertexDescription;
		vertexDescription.appendPosition3D();
		mesh = new Mesh(vertexDescription, 2, 2);
		mesh->setDrawMode(Mesh::DRAW_LINES);

		MeshIndexData & id = mesh->openIndexData();
		uint32_t * indices = id.data();
		indices[0] = 0;
		indices[1] = 1;
		id.updateIndexRange();
		id.markAsChanged();
		mesh->setDataStrategy(SimpleMeshDataStrategy::getPureLocalStrategy());
	}

	MeshVertexData & vd = mesh->openVertexData();
	float * vertices = reinterpret_cast<float *> (vd.data());
	*vertices++ = from.getX(); // From
	*vertices++ = from.getY();
	*vertices++ = from.getZ();
	*vertices++ = to.getX(); // To
	*vertices++ = to.getY();
	*vertices++ = to.getZ();
	vd.updateBoundingBox();
	vd.markAsChanged();

	rc.displayMesh(mesh.get());
}
コード例 #2
0
ファイル: Draw.cpp プロジェクト: StanEpp/Rendering
void drawTriangle(RenderingContext & rc, const Geometry::Vec3f & vertexA, const Geometry::Vec3f & vertexB, const Geometry::Vec3f & vertexC) {
	static Util::Reference<Mesh> mesh;
	if (mesh.isNull()) {
		VertexDescription vertexDescription;
		vertexDescription.appendPosition3D();
		mesh = new Mesh(vertexDescription, 3, 3);

		MeshIndexData & id = mesh->openIndexData();
		uint32_t * indices = id.data();
		indices[0] = 0;
		indices[1] = 1;
		indices[2] = 2;
		id.updateIndexRange();
		id.markAsChanged();
	}

	MeshVertexData & vd = mesh->openVertexData();
	float * vertices = reinterpret_cast<float *>(vd.data());
	// First vertex
	*vertices++ = vertexA.getX();
	*vertices++ = vertexA.getY();
	*vertices++ = vertexA.getZ();
	// Second vertex
	*vertices++ = vertexB.getX();
	*vertices++ = vertexB.getY();
	*vertices++ = vertexB.getZ();
	// Third vertex
	*vertices++ = vertexC.getX();
	*vertices++ = vertexC.getY();
	*vertices++ = vertexC.getZ();
	vd.updateBoundingBox();
	vd.markAsChanged();

	rc.displayMesh(mesh.get());
}
コード例 #3
0
ファイル: Draw.cpp プロジェクト: StanEpp/Rendering
void drawWireframeBox(RenderingContext & rc, const Geometry::Box & box) {
	static Util::Reference<Mesh> mesh;
	if (mesh.isNull()) {
		VertexDescription vertexDescription;
		vertexDescription.appendPosition3D();
		mesh = new Mesh(vertexDescription, 8, 16);
		mesh->setDataStrategy(SimpleMeshDataStrategy::getPureLocalStrategy());
		mesh->setDrawMode(Mesh::DRAW_LINE_STRIP);

		MeshIndexData & id = mesh->openIndexData();
		uint32_t * indices = id.data();
		/*
		 *  Corners:
		 *     6---------7
		 *    /|        /|
		 *   / |       / |
		 *  2---------3  |
		 *  |  |      |  |
		 *  |  4------|--5
		 *  | /       | /
		 *  |/        |/
		 *  0---------1
		 */
		indices[0] = 0;
		indices[1] = 2;
		indices[2] = 3;
		indices[3] = 1;
		indices[4] = 5;
		indices[5] = 7;
		indices[6] = 6;
		indices[7] = 4;
		indices[8] = 0;
		indices[9] = 1;
		indices[10] = 3;
		indices[11] = 7;
		indices[12] = 5;
		indices[13] = 4;
		indices[14] = 6;
		indices[15] = 2;
		id.updateIndexRange();
		id.markAsChanged();
	}

	MeshVertexData & vd = mesh->openVertexData();
	float * vertices = reinterpret_cast<float *>(vd.data());
	for (uint_fast8_t c = 0; c < 8; ++c) {
		const Geometry::Vec3 & corner = box.getCorner(static_cast<Geometry::corner_t> (c));
		*vertices++ = corner.getX();
		*vertices++ = corner.getY();
		*vertices++ = corner.getZ();
	}
	vd._setBoundingBox(box);
	vd.markAsChanged();

	rc.displayMesh(mesh.get());
}
コード例 #4
0
void drawGrid(RenderingContext & rc, float scale) {
	static Util::Reference<Mesh> mesh;
	if (mesh.isNull()) {
		VertexDescription vertexDescription;
		vertexDescription.appendPosition3D();
		mesh = new Mesh(vertexDescription, 4 * 101, 4 * 101);
		mesh->setDrawMode(Mesh::DRAW_LINES);
		
		MeshVertexData & vd = mesh->openVertexData();
		float * vertices = reinterpret_cast<float *> (vd.data());
		MeshIndexData & id = mesh->openIndexData();
		uint32_t * indices = id.data();
		uint32_t nextIndex = 0;
		const float step = 1.0f / 100.0f;
		for (uint_fast8_t line = 0; line < 101; ++line) {
			const float pos = -0.5f + static_cast<float> (line) * step;

			*vertices++ = -0.5f;
			*vertices++ = 0.0f;
			*vertices++ = pos;

			*vertices++ = 0.5f;
			*vertices++ = 0.0f;
			*vertices++ = pos;

			*indices++ = nextIndex++;
			*indices++ = nextIndex++;

			*vertices++ = pos;
			*vertices++ = 0.0f;
			*vertices++ = -0.5f;

			*vertices++ = pos;
			*vertices++ = 0.0f;
			*vertices++ = 0.5f;

			*indices++ = nextIndex++;
			*indices++ = nextIndex++;

		}
		vd.updateBoundingBox();
		vd.markAsChanged();
		id.updateIndexRange();
		id.markAsChanged();
	}

	Geometry::Matrix4x4 matrix;
	matrix.scale(scale);
	rc.pushMatrix_modelToCamera();
	rc.multMatrix_modelToCamera(matrix);
	rc.displayMesh(mesh.get());
	rc.popMatrix_modelToCamera();
}
コード例 #5
0
void drawFrustum(RenderingContext & rc, const Geometry::Frustum & frustum, const Util::Color4f & color, float lineWidth) {
	static Util::Reference<Mesh> mesh;
	if (mesh.isNull()) {
		VertexDescription vertexDescription;
		vertexDescription.appendPosition3D();
		mesh = new Mesh(vertexDescription, 8, 16);
		mesh->setDrawMode(Mesh::DRAW_LINE_STRIP);

		MeshIndexData & id = mesh->openIndexData();
		uint32_t * indices = id.data();
		indices[0] = 0;
		indices[1] = 2;
		indices[2] = 3;
		indices[3] = 1;
		indices[4] = 5;
		indices[5] = 7;
		indices[6] = 6;
		indices[7] = 4;
		indices[8] = 0;
		indices[9] = 1;
		indices[10] = 3;
		indices[11] = 7;
		indices[12] = 5;
		indices[13] = 4;
		indices[14] = 6;
		indices[15] = 2;
		id.updateIndexRange();
	}

	MeshVertexData & vd = mesh->openVertexData();
	float * vertices = reinterpret_cast<float *>(vd.data());
	for (uint_fast8_t c = 0; c < 8; ++c) {
		const Geometry::Vec3 & corner = frustum[static_cast<Geometry::corner_t> (c)];
		*vertices++ = corner.getX();
		*vertices++ = corner.getY();
		*vertices++ = corner.getZ();
	}
	vd.updateBoundingBox();
	vd.markAsChanged();

	rc.pushAndSetLine(lineWidth);
	rc.pushAndSetLighting(LightingParameters(false));
	rc.pushAndSetColorMaterial(color);
	rc.displayMesh(mesh.get());
	rc.popMaterial();
	rc.popLighting();
	rc.popLine();
}
コード例 #6
0
ファイル: Draw.cpp プロジェクト: StanEpp/Rendering
void drawRect(RenderingContext & rc, const Geometry::Rect & rect) {
	static Util::Reference<Mesh> mesh;
	if (mesh.isNull()) {
		VertexDescription vertexDescription;
		vertexDescription.appendPosition2D();
		mesh = new Mesh(vertexDescription, 4, 6);
		mesh->setDrawMode(Mesh::DRAW_TRIANGLES);

		MeshVertexData & vd = mesh->openVertexData();
		float * vertices = reinterpret_cast<float *> (vd.data());
		*vertices++ = 0.0f; // Bottom left
		*vertices++ = 0.0f;
		*vertices++ = 1.0f; // Bottom right
		*vertices++ = 0.0f;
		*vertices++ = 1.0f; // Top right
		*vertices++ = 1.0f;
		*vertices++ = 0.0f; // Top left
		*vertices++ = 1.0f;
		vd.updateBoundingBox();
		vd.markAsChanged();

		MeshIndexData & id = mesh->openIndexData();
		uint32_t * indices = id.data();
		indices[0] = 0;
		indices[1] = 2;
		indices[2] = 1;
		indices[3] = 0;
		indices[4] = 3;
		indices[5] = 2;
		id.updateIndexRange();
		id.markAsChanged();
	}

	Geometry::Matrix4x4 matrix;
	matrix.translate(rect.getX(), rect.getY(), 0.0f);
	matrix.scale(rect.getWidth(), rect.getHeight(), 1.0f);
	rc.pushMatrix_modelToCamera();
	rc.multMatrix_modelToCamera(matrix);
	rc.displayMesh(mesh.get());
	rc.popMatrix_modelToCamera();
}
コード例 #7
0
void ParticlePointRenderer::operator()(ParticleSystemNode* psys, FrameContext & context, const RenderParam & rp /* = 0 */) {
	if ( (rp.getFlag(NO_GEOMETRY)) )
		return;

	// render particles
	std::vector<Particle> & particles = psys->getParticles();
	uint32_t count = psys->getParticleCount();

	Rendering::VertexDescription vertexDesc;
	const Rendering::VertexAttribute & posAttrib = vertexDesc.appendPosition3D();
	const Rendering::VertexAttribute & colorAttrib = vertexDesc.appendColorRGBAByte();
	// The usage of a cache for the mesh has been tested. Reusing a preallocated mesh is not faster.
	Util::Reference<Rendering::Mesh> mesh = new Rendering::Mesh(vertexDesc, count, count);
	mesh->setDataStrategy(Rendering::SimpleMeshDataStrategy::getPureLocalStrategy());
	mesh->setDrawMode(Rendering::Mesh::DRAW_POINTS);
//	mesh->setUseIndexData(false);
	Rendering::MeshIndexData & indexData = mesh->openIndexData();
	Rendering::MeshVertexData & vertexData = mesh->openVertexData();
	Util::Reference<Rendering::PositionAttributeAccessor> positionAccessor = Rendering::PositionAttributeAccessor::create(vertexData, posAttrib.getNameId());
	Util::Reference<Rendering::ColorAttributeAccessor> colorAccessor = Rendering::ColorAttributeAccessor::create(vertexData, colorAttrib.getNameId());
	uint32_t * indices = indexData.data();

	for(uint_fast32_t index = 0; index < count; ++index) {
		const Particle & p = particles[index];

		colorAccessor->setColor(index, p.color);
		positionAccessor->setPosition(index, p.position);

		*indices++ = index;
	}

	indexData.markAsChanged();
	indexData.updateIndexRange();
	vertexData.markAsChanged();
	vertexData.updateBoundingBox();
	context.displayMesh(mesh.get());
}
コード例 #8
0
void drawCoordSys(RenderingContext & rc, float scale) {
	static Util::Reference<Mesh> arrow;
	static Util::Reference<Mesh> sphere;
	static Util::Reference<Mesh> charX;
	static Util::Reference<Mesh> charY;
	static Util::Reference<Mesh> charZ;
	const float radius = 0.025f;
	if (arrow.isNull()) {
		std::deque<Mesh *> meshes;
		std::deque<Geometry::Matrix4x4> transformations;

		Geometry::Matrix4x4 transform;

		meshes.push_back(MeshUtils::MeshBuilder::createConicalFrustum(radius, radius, 0.7f, 16));
		transformations.push_back(transform);

		meshes.push_back(MeshUtils::MeshBuilder::createConicalFrustum(radius, 2.0f * radius, 0.01f, 16));
		transform.translate(0.7f, 0.0f, 0.0f);
		transformations.push_back(transform);

		meshes.push_back(MeshUtils::MeshBuilder::createCone(2.0f * radius, 0.29f, 16));
		transform.translate(0.01f, 0.0f, 0.0f);
		transformations.push_back(transform);

		arrow = MeshUtils::combineMeshes(meshes, transformations);
		MeshUtils::optimizeIndices(arrow.get());

		while (!meshes.empty()) {
			delete meshes.back();
			meshes.pop_back();
		}
	}
	if (sphere.isNull()) {
		Util::Reference<Mesh> icosahedron = MeshUtils::PlatonicSolids::createIcosahedron();
		sphere = MeshUtils::PlatonicSolids::createEdgeSubdivisionSphere(icosahedron.get(), 2);
		Geometry::Matrix4x4 transform;
		transform.scale(1.1f * radius);
		MeshUtils::transform(sphere.get()->openVertexData(), transform);
	}
	if(charX.isNull()) {
		std::deque<Mesh *> meshes;
		std::deque<Geometry::Matrix4x4> transformations;

		VertexDescription vertexDescription;
		vertexDescription.appendPosition3D();
		vertexDescription.appendNormalFloat();

		const Geometry::Box box(Geometry::Vec3f(0.0f, 0.0f, 0.0f), 0.02f, 0.2f, 0.05f);
		{
			meshes.push_back(MeshUtils::MeshBuilder::createBox(vertexDescription, box));
			Geometry::Matrix4x4 transform;
			transform.translate(1.2f, 0.0f, 0.0f);
			transform.rotate_deg(30.0f, 0.0f, 0.0f, -1.0f);
			transformations.push_back(transform);
		}
		{
			meshes.push_back(MeshUtils::MeshBuilder::createBox(vertexDescription, box));
			Geometry::Matrix4x4 transform;
			transform.translate(1.2f, 0.0f, 0.0f);
			transform.rotate_deg(-30.0f, 0.0f, 0.0f, -1.0f);
			transformations.push_back(transform);
		}
		charX = MeshUtils::combineMeshes(meshes, transformations);
		MeshUtils::optimizeIndices(charX.get());

		while(!meshes.empty()) {
			delete meshes.back();
			meshes.pop_back();
		}
	}
	if(charY.isNull()) {
		std::deque<Mesh *> meshes;
		std::deque<Geometry::Matrix4x4> transformations;

		VertexDescription vertexDescription;
		vertexDescription.appendPosition3D();
		vertexDescription.appendNormalFloat();

		const Geometry::Box box(Geometry::Vec3f(0.0f, 0.0f, 0.0f), 0.02f, 0.1f, 0.05f);
		{
			meshes.push_back(MeshUtils::MeshBuilder::createBox(vertexDescription, box));
			Geometry::Matrix4x4 transform;
			transform.translate(0.025f, 0.045f, 0.0f);
			transform.rotate_deg(30.0f, 0.0f, 0.0f, -1.0f);
			transformations.push_back(transform);
		}
		{
			meshes.push_back(MeshUtils::MeshBuilder::createBox(vertexDescription, box));
			Geometry::Matrix4x4 transform;
			transform.translate(-0.025f, 0.045f, 0.0f);
			transform.rotate_deg(-30.0f, 0.0f, 0.0f, -1.0f);
			transformations.push_back(transform);
		}
		{
			meshes.push_back(MeshUtils::MeshBuilder::createBox(vertexDescription, box));
			Geometry::Matrix4x4 transform;
			transform.translate(0.0f, -0.045f, 0.0f);
			transformations.push_back(transform);
		}
		charY = MeshUtils::combineMeshes(meshes, transformations);
		Geometry::Matrix4x4 transform;
		transform.translate(1.2f, 0.0f, 0.0f);
		transform.rotate_deg(90.0f, 0.0f, 0.0f, -1.0f);
		MeshUtils::transform(charY->openVertexData(), transform);
		MeshUtils::optimizeIndices(charY.get());

		while(!meshes.empty()) {
			delete meshes.back();
			meshes.pop_back();
		}
	}
	if(charZ.isNull()) {
		std::deque<Mesh *> meshes;
		std::deque<Geometry::Matrix4x4> transformations;

		VertexDescription vertexDescription;
		vertexDescription.appendPosition3D();
		vertexDescription.appendNormalFloat();

		const Geometry::Box box(Geometry::Vec3f(0.0f, 0.0f, 0.0f), 0.02f, 0.1f, 0.05f);
		{
			meshes.push_back(MeshUtils::MeshBuilder::createBox(vertexDescription, box));
			Geometry::Matrix4x4 transform;
			transform.translate(1.2f, 0.075f, 0.0f);
			transform.rotate_deg(90.0f, 0.0f, 0.0f, -1.0f);
			transformations.push_back(transform);
		}
		{
			meshes.push_back(MeshUtils::MeshBuilder::createBox(vertexDescription, box));
			Geometry::Matrix4x4 transform;
			transform.translate(1.2f, 0.0f, 0.0f);
			transform.rotate_deg(-30.0f, 0.0f, 0.0f, -1.0f);
			transform.scale(1.0f, 1.6f, 1.0f);
			transformations.push_back(transform);
		}
		{
			meshes.push_back(MeshUtils::MeshBuilder::createBox(vertexDescription, box));
			Geometry::Matrix4x4 transform;
			transform.translate(1.2f, -0.075f, 0.0f);
			transform.rotate_deg(-90.0f, 0.0f, 0.0f, -1.0f);
			transformations.push_back(transform);
		}
		charZ = MeshUtils::combineMeshes(meshes, transformations);
		MeshUtils::optimizeIndices(charZ.get());

		while(!meshes.empty()) {
			delete meshes.back();
			meshes.pop_back();
		}
	}
	// Origin
	rc.pushAndSetColorMaterial(Util::ColorLibrary::WHITE);
	rc.displayMesh(sphere.get());
	rc.popMaterial();

	// X axis
	Geometry::Matrix4x4 transform;
	transform.scale(scale, 1.0f, 1.0f);
	rc.pushMatrix_modelToCamera();
	rc.multMatrix_modelToCamera(transform);
	rc.pushAndSetColorMaterial(Util::ColorLibrary::RED);
	rc.displayMesh(arrow.get());
	rc.displayMesh(charX.get());
	rc.popMaterial();
	rc.popMatrix_modelToCamera();
	// Y axis
	transform.setIdentity();
	transform.scale(1.0f, scale, 1.0f);
	transform.rotate_deg(90.0f, 0.0f, 0.0f, 1.0f);
	rc.pushMatrix_modelToCamera();
	rc.multMatrix_modelToCamera(transform);
	rc.pushAndSetColorMaterial(Util::ColorLibrary::GREEN);
	rc.displayMesh(arrow.get());
	rc.displayMesh(charY.get());
	rc.popMaterial();
	rc.popMatrix_modelToCamera();
	// Z axis
	transform.setIdentity();
	transform.scale(1.0f, 1.0f, scale);
	transform.rotate_deg(90.0f, 0.0f, -1.0f, 0.0f);
	rc.pushMatrix_modelToCamera();
	rc.multMatrix_modelToCamera(transform);
	rc.pushAndSetColorMaterial(Util::ColorLibrary::BLUE);
	rc.displayMesh(arrow.get());
	rc.displayMesh(charZ.get());
	rc.popMaterial();
	rc.popMatrix_modelToCamera();
}
コード例 #9
0
int test_spherical_sampling_serialization() {
#ifdef MINSG_EXT_SVS
	std::cout << "Test serialization of SVS objects ... ";
	Util::Timer timer;
	timer.reset();

	using namespace MinSG::SVS;
	MinSG::SceneManagement::SceneManager sceneManager;

	const uint32_t count = 10;
	std::array<Util::Reference<MinSG::GeometryNode>, count> nodes;
	for(uint_fast32_t i = 0; i < count; ++i) {
		nodes[i] = new MinSG::GeometryNode;
		sceneManager.registerNode(std::string("Node") + Util::StringUtils::toString(i), nodes[i].get());
	}
	MinSG::VisibilitySubdivision::VisibilityVector vv;
	for(uint_fast32_t i = 0; i < count; ++i) {
		vv.setNode(nodes[i].get(), i);
	}

	std::vector<SamplePoint> samples;
	{
		using namespace Rendering::MeshUtils::PlatonicSolids;
		Util::Reference<Rendering::Mesh> mesh = createEdgeSubdivisionSphere(createIcosahedron(), 4);
		auto accessor = Rendering::PositionAttributeAccessor::create(mesh->openVertexData(), Rendering::VertexAttributeIds::POSITION);
		for(std::size_t i = 0; accessor->checkRange(i); ++i) {
			samples.emplace_back(accessor->getPosition(i));
		}
	}
	{
		std::stringstream stream;
		stream.precision(std::numeric_limits<long double>::digits10);
		// Serialize
		for(const auto & sample : samples) {
			stream << sample.getPosition() << ' ';
			sample.getValue().serialize(stream, sceneManager);
			stream << ' ';
		}
		// Unserialize
		std::vector<SamplePoint> newSamples;
		for(std::size_t s = 0; s < samples.size(); ++s) {
			Geometry::Vec3f pos;
			stream >> pos;
			SamplePoint sample(pos);
			sample.setValue(MinSG::VisibilitySubdivision::VisibilityVector::unserialize(stream, sceneManager));
			newSamples.push_back(sample);
		}
		for(std::size_t s = 0; s < samples.size(); ++s) {
			const SamplePoint & oldSample = samples[s];
			const SamplePoint & newSample = newSamples[s];
			if(oldSample.getPosition().distance(newSample.getPosition()) > std::numeric_limits<float>::epsilon()) {
				std::cout << "Serialization/unserialization failed." << std::endl;
				return EXIT_FAILURE;
			}
			const auto & oldVV = oldSample.getValue();
			const auto & newVV = newSample.getValue();
			for(uint_fast32_t n = 0; n < count; ++n) {
				if(oldVV.getBenefits(nodes[n].get()) != newVV.getBenefits(nodes[n].get())) {
					std::cout << "Serialization/unserialization failed." << std::endl;
					return EXIT_FAILURE;
				}
			}
		}
	}
	VisibilitySphere visibilitySphere(Geometry::Sphere_f(Geometry::Vec3f(1.0f, 2.0f, 3.0f), 17.0f), samples);
	{
		std::stringstream stream;
		stream.precision(std::numeric_limits<long double>::digits10);
		// Serialize
		stream << visibilitySphere.getSphere() << ' ' << samples.size();
		for(const auto & sample : samples) {
			stream << ' ' << sample.getPosition() << ' ';
			sample.getValue().serialize(stream, sceneManager);
			stream << ' ';
		}
		
		// Unserialize
		Geometry::Sphere_f sphere;
		stream >> sphere;
		std::size_t sampleCount;
		stream >> sampleCount;
		std::vector<SamplePoint> newSamples;
		for(std::size_t s = 0; s < sampleCount; ++s) {
			Geometry::Vec3f pos;
			stream >> pos;
			SamplePoint sample(pos);
			sample.setValue(MinSG::VisibilitySubdivision::VisibilityVector::unserialize(stream, sceneManager));
			newSamples.push_back(sample);
		}
		
		VisibilitySphere newVisibilitySphere(sphere, newSamples);
		if(!(visibilitySphere.getSphere() == newVisibilitySphere.getSphere())) {
			std::cout << "Serialization/unserialization failed." << std::endl;
			return EXIT_FAILURE;
		}
		for(std::size_t s = 0; s < samples.size(); ++s) {
			const SamplePoint & oldSample = visibilitySphere.getSamples()[s];
			const SamplePoint & newSample = newVisibilitySphere.getSamples()[s];
			if(oldSample.getPosition().distance(newSample.getPosition()) > std::numeric_limits<float>::epsilon()) {
				std::cout << "Serialization/unserialization failed." << std::endl;
				return EXIT_FAILURE;
			}
			const auto & oldVV = oldSample.getValue();
			const auto & newVV = newSample.getValue();
			for(uint_fast32_t n = 0; n < count; ++n) {
				if(oldVV.getBenefits(nodes[n].get()) != newVV.getBenefits(nodes[n].get())) {
					std::cout << "Serialization/unserialization failed." << std::endl;
					return EXIT_FAILURE;
				}
			}
		}
	}

	timer.stop();
	std::cout << "done (duration: " << timer.getSeconds() << " s).\n";
#endif /* MINSG_EXT_SVS */
	return EXIT_SUCCESS;
}
コード例 #10
0
ファイル: Draw.cpp プロジェクト: StanEpp/Rendering
void drawQuad(RenderingContext & rc, const Geometry::Vec3 & lowerLeft, const Geometry::Vec3 & lowerRight, const Geometry::Vec3 & upperRight,
				const Geometry::Vec3 & upperLeft) {
	static Util::Reference<Mesh> mesh;
	if (mesh.isNull()) {
		VertexDescription vertexDescription;
		vertexDescription.appendPosition3D();
		vertexDescription.appendNormalFloat();
		vertexDescription.appendTexCoord();
		mesh = new Mesh(vertexDescription, 4, 6);

		MeshIndexData & id = mesh->openIndexData();
		uint32_t * indices = id.data();
		indices[0] = 0;
		indices[1] = 1;
		indices[2] = 2;
		indices[3] = 0;
		indices[4] = 2;
		indices[5] = 3;
		id.updateIndexRange();
		id.markAsChanged();
	}
	const Geometry::Vec3 edgeA = lowerRight - lowerLeft;
	const Geometry::Vec3 edgeB = upperLeft - lowerLeft;
	Geometry::Vec3 normal = edgeA.cross(edgeB);
	normal.normalize();

	MeshVertexData & vd = mesh->openVertexData();
	float * vertices = reinterpret_cast<float *> (vd.data());
	// Lower left
	*vertices++ = lowerLeft.getX();
	*vertices++ = lowerLeft.getY();
	*vertices++ = lowerLeft.getZ();
	*vertices++ = normal.getX();
	*vertices++ = normal.getY();
	*vertices++ = normal.getZ();
	*vertices++ = 0.0f;
	*vertices++ = 0.0f;
	// Lower right
	*vertices++ = lowerRight.getX();
	*vertices++ = lowerRight.getY();
	*vertices++ = lowerRight.getZ();
	*vertices++ = normal.getX();
	*vertices++ = normal.getY();
	*vertices++ = normal.getZ();
	*vertices++ = 1.0f;
	*vertices++ = 0.0f;
	// Upper right
	*vertices++ = upperRight.getX();
	*vertices++ = upperRight.getY();
	*vertices++ = upperRight.getZ();
	*vertices++ = normal.getX();
	*vertices++ = normal.getY();
	*vertices++ = normal.getZ();
	*vertices++ = 1.0f;
	*vertices++ = 1.0f;
	// Upper left
	*vertices++ = upperLeft.getX();
	*vertices++ = upperLeft.getY();
	*vertices++ = upperLeft.getZ();
	*vertices++ = normal.getX();
	*vertices++ = normal.getY();
	*vertices++ = normal.getZ();
	*vertices++ = 0.0f;
	*vertices++ = 1.0f;
	vd.updateBoundingBox();
	vd.markAsChanged();

	rc.displayMesh(mesh.get());
}
コード例 #11
0
void ParticleBillboardRenderer::operator()(ParticleSystemNode * psys, FrameContext & context, const RenderParam & rp) {
	if(rp.getFlag(NO_GEOMETRY)) {
		return;
	}

	const auto & worldToCamera = context.getRenderingContext().getMatrix_worldToCamera();
	const auto cameraToWorld = worldToCamera.inverse();

	const auto halfRight = cameraToWorld.transformDirection(context.getWorldRightVector() * 0.5f);
	const auto halfUp = cameraToWorld.transformDirection(context.getWorldUpVector() * 0.5f);

	// 2. just update position for each particle and render
	// render particles
	const uint32_t count = psys->getParticleCount();

	Rendering::VertexDescription vertexDesc;
	const Rendering::VertexAttribute & posAttrib = vertexDesc.appendPosition3D();
	const Rendering::VertexAttribute & colorAttrib = vertexDesc.appendColorRGBAByte();
	const Rendering::VertexAttribute & texCoordAttrib = vertexDesc.appendTexCoord();
	// The usage of a cache for the mesh has been tested. Reusing a preallocated mesh is not faster.
	Util::Reference<Rendering::Mesh> mesh = new Rendering::Mesh(vertexDesc, 4 * count, 6 * count);
	mesh->setDataStrategy(Rendering::SimpleMeshDataStrategy::getPureLocalStrategy());
	Rendering::MeshIndexData & indexData = mesh->openIndexData();
	Rendering::MeshVertexData & vertexData = mesh->openVertexData();
	Util::Reference<Rendering::PositionAttributeAccessor> positionAccessor = Rendering::PositionAttributeAccessor::create(vertexData, posAttrib.getNameId());
	Util::Reference<Rendering::ColorAttributeAccessor> colorAccessor = Rendering::ColorAttributeAccessor::create(vertexData, colorAttrib.getNameId());
	Util::Reference<Rendering::TexCoordAttributeAccessor> texCoordAccessor = Rendering::TexCoordAttributeAccessor::create(vertexData, texCoordAttrib.getNameId());
	uint32_t * indices = indexData.data();

	uint_fast32_t index = 0;
	for(const auto & p : psys->getParticles()) {
		const Geometry::Vec3f upOffset = halfUp * p.size.getHeight();
		const Geometry::Vec3f rightOffset = halfRight * p.size.getWidth();

		colorAccessor->setColor(index + 0, p.color);
		texCoordAccessor->setCoordinate(index + 0, Geometry::Vec2f(0.0f, 0.0f));
		positionAccessor->setPosition(index + 0, p.position + upOffset - rightOffset);

		colorAccessor->setColor(index + 1, p.color);
		texCoordAccessor->setCoordinate(index + 1, Geometry::Vec2f(0.0f, 1.0f));
		positionAccessor->setPosition(index + 1, p.position - upOffset - rightOffset);

		colorAccessor->setColor(index + 2, p.color);
		texCoordAccessor->setCoordinate(index + 2, Geometry::Vec2f(1.0f, 1.0f));
		positionAccessor->setPosition(index + 2, p.position - upOffset + rightOffset);

		colorAccessor->setColor(index + 3, p.color);
		texCoordAccessor->setCoordinate(index + 3, Geometry::Vec2f(1.0f, 0.0f));
		positionAccessor->setPosition(index + 3, p.position + upOffset + rightOffset);

		*indices++ = index + 0;
		*indices++ = index + 1;
		*indices++ = index + 3;

		*indices++ = index + 1;
		*indices++ = index + 2;
		*indices++ = index + 3;

		index += 4;
	}

	indexData.markAsChanged();
	indexData.updateIndexRange();
	vertexData.markAsChanged();
	vertexData.updateBoundingBox();
	context.displayMesh(mesh.get());
}
コード例 #12
0
ファイル: test_OutOfCore.cpp プロジェクト: MeisterYeti/MinSG
int test_OutOfCore() {
#ifdef MINSG_EXT_OUTOFCORE
	const bool verbose = true;

	// Tests for MinSG::OutOfCore::CacheObjectPriority
	if(sizeof(MinSG::OutOfCore::CacheObjectPriority) != 8) {
		return EXIT_FAILURE;
	}
	if(!(MinSG::OutOfCore::CacheObjectPriority(1, 2, 3) == MinSG::OutOfCore::CacheObjectPriority(1, 2, 3))) {
		return EXIT_FAILURE;
	}
	if(!(MinSG::OutOfCore::CacheObjectPriority(1, 100, 100) < MinSG::OutOfCore::CacheObjectPriority(2, 0, 0))) {
		return EXIT_FAILURE;
	}
	if(!(MinSG::OutOfCore::CacheObjectPriority(2, 1, 100) < MinSG::OutOfCore::CacheObjectPriority(2, 2, 0))) {
		return EXIT_FAILURE;
	}
	if(!(MinSG::OutOfCore::CacheObjectPriority(2, 2, 1) < MinSG::OutOfCore::CacheObjectPriority(2, 2, 2))) {
		return EXIT_FAILURE;
	}

	std::default_random_engine engine;
	std::uniform_int_distribution<std::size_t> vertexCountDist(10, 1000);
	const uint32_t numMeshes = 30000;
	const Util::TemporaryDirectory tempDir("MinSGTest_OutOfCore");
	
	// Create empty meshes and save them into a subdirectory.
	{
		Rendering::VertexDescription vertexDesc;
		vertexDesc.appendPosition3D();
		
		for(uint_fast32_t i = 0; i < numMeshes; ++i) {
			Util::Reference<Rendering::Mesh> mesh = new Rendering::Mesh(vertexDesc, vertexCountDist(engine), 64);
			Rendering::MeshVertexData & vertexData = mesh->openVertexData();
			std::fill_n(vertexData.data(), vertexData.dataSize(), 0);
			vertexData.markAsChanged();
			Rendering::MeshIndexData & indexData = mesh->openIndexData();
			std::fill_n(indexData.data(), indexData.getIndexCount(), 0);
			indexData.markAsChanged();
			const std::string numberString = Util::StringUtils::toString<uint32_t>(i);
			Rendering::Serialization::saveMesh(mesh.get(), Util::FileName(tempDir.getPath().getDir() + numberString + ".mmf"));
		}
	}
	
	// Set up the OutOfCore system.
	MinSG::FrameContext frameContext;
	
	MinSG::OutOfCore::setUp(frameContext);

	MinSG::OutOfCore::CacheManager & manager = MinSG::OutOfCore::getCacheManager();
	manager.addCacheLevel(MinSG::OutOfCore::CacheLevelType::FILE_SYSTEM, 0);
	manager.addCacheLevel(MinSG::OutOfCore::CacheLevelType::FILES, 512 * kibibyte);
	manager.addCacheLevel(MinSG::OutOfCore::CacheLevelType::MAIN_MEMORY, 256 * kibibyte);
	
	Util::Timer addTimer;
	addTimer.reset();
	std::cout << "Adding meshes ..." << std::flush;
	
	// Add the meshes to the OutOfCore system.
	std::vector<Util::Reference<Rendering::Mesh> > meshes;
	meshes.reserve(numMeshes);
	static const Geometry::Box boundingBox(-1.0f, 1.0f, -1.0f, 1.0f, -1.0f, 1.0f);
	for(uint_fast32_t i = 0; i < numMeshes; ++i) {
		const std::string numberString = Util::StringUtils::toString<uint32_t>(i);
		meshes.push_back(MinSG::OutOfCore::addMesh(Util::FileName(tempDir.getPath().getDir() + numberString + ".mmf"), boundingBox));
	}
	
	manager.trigger();
	
	addTimer.stop();
	std::cout << " done (" << addTimer.getSeconds() << " s)" << std::endl;
	
	Util::Timer displayTimer;
	Util::Timer assureLocalTimer;
	Util::Timer overallTimer;
	overallTimer.reset();

	uint32_t frame = 0;

	{
		// Simulate frames to get the OutOfCore system working.
		std::uniform_int_distribution<std::size_t> indexDist(0, meshes.size() - 1);
		for(; frame < 10; ++frame) {
			std::cout << "Executing frame " << frame << " ..." << std::flush;
			frameContext.beginFrame();
			displayTimer.reset();
			// Simulate display of meshes to change the priorities of the system.
			for(uint32_t i = 0; i < meshes.size() / 2; ++i) {
				const uint32_t meshIndex = indexDist(engine);
				Rendering::Mesh * mesh = meshes[meshIndex].get();
				manager.meshDisplay(mesh);
			}
			manager.trigger();
			displayTimer.stop();
			assureLocalTimer.reset();
			for(uint32_t i = 0; i < 10; ++i) {
				const uint32_t meshIndex = indexDist(engine);
				
				Rendering::Mesh * mesh = meshes[meshIndex].get();
				const Rendering::MeshVertexData & vd = mesh->openVertexData();
				const Rendering::MeshIndexData & id = mesh->openIndexData();
				
				if (!vd.hasLocalData() || !id.hasLocalData()) {
					std::cout << "Error: Mesh has no local data." << std::endl;
					return EXIT_FAILURE;
				}
			}
			assureLocalTimer.stop();
			frameContext.endFrame();
			std::cout << " done (display: " << displayTimer.getSeconds() << " s, assureLocal: " << assureLocalTimer.getSeconds() << " s)" << std::endl;

			if(verbose) {
				outputCacheLevelInformation();
			}
		}
	}

	for(uint32_t round = 0; round < 10; ++round) {
		Util::Timer addAgainTimer;
		addAgainTimer.reset();
		std::cout << "Adding additional meshes ..." << std::flush;
		
		// Simulate loading a second scene by adding meshes again.
		meshes.reserve(meshes.size() + 3 * numMeshes);
		for(uint_fast32_t i = 0; i < numMeshes; ++i) {
			const std::string numberString = Util::StringUtils::toString<uint32_t>(i);
			meshes.push_back(MinSG::OutOfCore::addMesh(Util::FileName(tempDir.getPath().getDir() + numberString + ".mmf"), boundingBox));
			meshes.push_back(MinSG::OutOfCore::addMesh(Util::FileName(tempDir.getPath().getDir() + numberString + ".mmf"), boundingBox));
			meshes.push_back(MinSG::OutOfCore::addMesh(Util::FileName(tempDir.getPath().getDir() + numberString + ".mmf"), boundingBox));
		}
		
		manager.trigger();
		
		addAgainTimer.stop();
		std::cout << " done (" << addAgainTimer.getSeconds() << " s)" << std::endl;

		// Simulate frames to get the OutOfCore system working.
		std::normal_distribution<double> indexDist(meshes.size() / 2, std::sqrt(meshes.size() / 2));
		const auto untilFrame = frame + 5;
		for(; frame < untilFrame; ++frame) {
			std::cout << "Executing frame " << frame << " ..." << std::flush;
			frameContext.beginFrame();
			displayTimer.reset();
			// Simulate display of meshes to change the priorities of the system.
			for(uint32_t i = 0; i < meshes.size() / 10; ++i) {
				const std::size_t meshIndex = std::max(static_cast<std::size_t>(0), std::min(static_cast<std::size_t>(indexDist(engine)), meshes.size() - 1));
				Rendering::Mesh * mesh = meshes[meshIndex].get();
				manager.meshDisplay(mesh);
			}
			manager.trigger();
			displayTimer.stop();
			frameContext.endFrame();
			std::cout << " done (display: " << displayTimer.getSeconds() << " s)" << std::endl;

			if(verbose) {
				outputCacheLevelInformation();
			}
		}
	}

	overallTimer.stop();
	std::cout << "Overall duration: " << overallTimer.getSeconds() << " s" << std::endl;
	
	MinSG::OutOfCore::shutDown();
	
	return EXIT_SUCCESS;
#else /* MINSG_EXT_OUTOFCORE */
	return EXIT_FAILURE;
#endif /* MINSG_EXT_OUTOFCORE */
}