/** * @file mass_properties.cpp * @author andrew@lindenlab.com * @date 2007-12-20 * @brief Tests for the LLPrimMassProperties and LLObjectMassProperties classes * * $LicenseInfo:firstyear=2007&license=internal$ * * Copyright (c) 2007-2009, Linden Research, Inc. * * The following source code is PROPRIETARY AND CONFIDENTIAL. Use of * this source code is governed by the Linden Lab Source Code Disclosure * Agreement ("Agreement") previously entered between you and Linden * Lab. By accessing, using, copying, modifying or distributing this * software, you acknowledge that you have been informed of your * obligations under the Agreement and agree to abide by those obligations. * * ALL LINDEN LAB SOURCE CODE IS PROVIDED "AS IS." LINDEN LAB MAKES NO * WARRANTIES, EXPRESS, IMPLIED OR OTHERWISE, REGARDING ITS ACCURACY, * COMPLETENESS OR PERFORMANCE. * $/LicenseInfo$ */ #include "linden_common.h" #include "lltut.h" #include #include #include #include #include #include #include #include const F32 SMALL_RELATIVE_ERROR = 0.001f; // 0.1% const F32 SQRT_THREE = 1.732050808f; const F32 SQRT_SIX = 2.449489743f; namespace tut { struct mass_properties_data { LLPrimMassProperties prim_properties; LLObjectMassProperties object_properties; }; typedef test_group mass_properties_group; typedef mass_properties_group::object mass_properties; tut::mass_properties_group mp_test_group("mass properties"); template<> template<> void mass_properties::test<1>() { // test SPHERE mass properties LLPrimMassProperties prim_sphere; prim_sphere.setUnitSphere(); F32 density = 1000.f; F32 radius = 5.f; F32 diameter = 2.f * radius; LLVector3 scale(diameter, diameter, diameter); LLObjectMassProperties obj_sphere(prim_sphere, scale, density); F32 computed_mass = obj_sphere.getMass(); //LLVector3 center_of_mass //obj_sphere.getCenterOfMass(center_of_mass); LLMatrix3 inertia; obj_sphere.getInertiaLocal(inertia); F32 computed_inertia_eigenvalue = inertia.mMatrix[0][0]; // volume is normalized for scale = <1,1,1> // V = 4/3 * PI * r^3 // inertia_eigenvalue = (2/5) * M * r^2 F32 volume = ( 4.f / 3.f ) * radius * radius * radius * F_PI; F32 expected_mass = density * volume; F32 expected_inertia_eigenvalue = ( 2.f / 5.f ) * expected_mass * radius * radius; F32 error = fabs(computed_mass - expected_mass) / expected_mass; ensure("expected sphere mass should match computed", error < SMALL_RELATIVE_ERROR); error = fabs(computed_inertia_eigenvalue - expected_inertia_eigenvalue) / expected_inertia_eigenvalue; ensure("expected sphere inertia should match computed", error < SMALL_RELATIVE_ERROR); } template<> template<> void mass_properties::test<2>() { // test LLInertiaTensorUtils // define a known inertia tensor in the center of mass frame // from the numerical example in this paper: // http://www.journaldatabase.org/articles/87064/Explicit_Exact_Formulas_f.html F32 known_mass = 1873.23f; LLVector3 known_center( 0.f, 0.f, 0.f ); LLMatrix3 known_inertia; known_inertia.mMatrix[0][0] = 43520.33257f; known_inertia.mMatrix[1][1] = 194711.28938f; known_inertia.mMatrix[2][2] = 191168.76173f; known_inertia.mMatrix[0][1] = -11996.20119f; known_inertia.mMatrix[1][0] = -11996.20119f; known_inertia.mMatrix[0][2] = 46343.16662f; known_inertia.mMatrix[2][0] = 46343.16662f; known_inertia.mMatrix[2][1] = -4417.66150f; known_inertia.mMatrix[1][2] = -4417.66150f; // the following two shifts should have null effect { LLVector3 first_shift(2.f, 3.f, 4.f); LLVector3 second_shift = - first_shift; LLMatrix3 inertia = known_inertia; LLInertiaTensorUtils::shiftCenteredInertiaTensor(inertia, first_shift, known_mass); LLInertiaTensorUtils::centerInertiaTensor(inertia, second_shift, known_mass); // we should now have the same inertia with which we started for (S32 i=0; i<3; ++i) { for (S32 j=0; j<3; ++j) { F32 error = fabs(1.f - inertia.mMatrix[i][j] / known_inertia.mMatrix[i][j]); ensure("LLInertiaTensorUtils shift+sclae-shift-scale should be no-op", error < SMALL_RELATIVE_ERROR); } } } // the following series operations should have null effect { LLVector3 first_shift(1.f, 5.f, 10.f); LLVector3 second_scale(2.f, 3.f, 4.f); LLVector3 third_shift; LLVector3 fourth_scale; for (S32 i = 0; i < 3; ++i) { third_shift.mV[i] = -first_shift.mV[i] * second_scale.mV[i]; fourth_scale.mV[i] = 1.f / second_scale.mV[i]; } F32 mass = known_mass; LLVector3 center = known_center; LLMatrix3 inertia = known_inertia; // first LLInertiaTensorUtils::shiftCenteredInertiaTensor(inertia, first_shift, mass); center += first_shift; // second LLInertiaTensorUtils::scaleInertiaTensor(inertia, second_scale); mass *= second_scale.mV[VX] * second_scale.mV[VY] * second_scale.mV[VZ]; for (S32 i = 0; i < 3; ++i) { center.mV[i] *= second_scale.mV[i]; } // third LLInertiaTensorUtils::centerInertiaTensor(inertia, third_shift, mass); center -= third_shift; // foruth LLInertiaTensorUtils::scaleInertiaTensor(inertia, fourth_scale); // we should now have the same inertia with which we started for (S32 i=0; i<3; ++i) { for (S32 j=0; j<3; ++j) { F32 error = fabs(1.f - inertia.mMatrix[i][j] / known_inertia.mMatrix[i][j]); ensure("LLInertiaTensorUtils shift+sclae-shift-scale should be no-op", error < SMALL_RELATIVE_ERROR); } } } } template<> template<> void mass_properties::test<3>() { // test tetrahedral decomposition of unit tetrahedron centered on origin std::vector< LLVector3 > points; points.push_back( LLVector3( 0.f, 0.f, 0.f ) ); points.push_back( LLVector3( 1.f, 0.f, 0.f ) ); points.push_back( LLVector3( 0.5f, 0.5f * SQRT_THREE, 0.f) ); points.push_back( LLVector3( 0.5f, SQRT_THREE / 6.f, SQRT_SIX / 3.f) ); // compute the center LLVector3 center; for (S32 i = 0; i < (S32)points.size(); ++i) { center += points[i]; } center *= ( 1.f / F32(points.size()) ); // shift all points to center of mass frame for (S32 i = 0; i < (S32)points.size(); ++i) { points[i] -= center; } LLPrimMassProperties tetrahedron; tetrahedron.addSignedTetrahedron(1.0, points[0], points[1], points[2], points[3]); // we must manually center the inertia tensor here // since addSignedTetrahedron() does not do it automatically tetrahedron.centerInertiaTensor(); F32 density = 1.0f; LLVector3 scale(1.f, 1.f, 1.f); LLMatrix3 analytic_inertia; tetrahedron.getScaledInertiaTensor(analytic_inertia, scale, density); // compute the mesh std::vector< S32 > triangle_indices; triangle_indices.push_back(0); triangle_indices.push_back(2); triangle_indices.push_back(1); triangle_indices.push_back(0); triangle_indices.push_back(1); triangle_indices.push_back(3); triangle_indices.push_back(0); triangle_indices.push_back(3); triangle_indices.push_back(2); triangle_indices.push_back(1); triangle_indices.push_back(2); triangle_indices.push_back(3); // compute the same inertia using a mesh { LLPrimMassProperties mesh; mesh.setUnitMesh(points, triangle_indices); // the two properties should agree F32 error = ( tetrahedron.getVolume() - mesh.getVolume() ) / tetrahedron.getVolume(); ensure("tetrahedron and mesh volume should match", error < SMALL_RELATIVE_ERROR); error = ( tetrahedron.getCenterOfMass() - mesh.getCenterOfMass() ).length(); ensure("tetrahedron and mesh centers should match", error < SMALL_RELATIVE_ERROR); LLMatrix3 mesh_inertia; mesh.getScaledInertiaTensor(mesh_inertia, scale, density); for (S32 i=0; i<3; ++i) { for (S32 j=0; j<3; ++j) { // only verify the non-small elements if (analytic_inertia.mMatrix[i][j] > SMALL_RELATIVE_ERROR) { error = fabs(1.f - mesh_inertia.mMatrix[i][j] / analytic_inertia.mMatrix[i][j]); ensure("LLPrimMassProperties::setUnitMesh() inertia ", error < SMALL_RELATIVE_ERROR); } } } } // shift the whole tetrahedron away from the center of mass and recompute the mesh { LLVector3 shift(11.f, 7.f, 3.f); for (S32 i = 0; i < (S32)points.size(); ++i) { points[i] += shift; } LLPrimMassProperties mesh; mesh.setUnitMesh(points, triangle_indices); // the two properties should agree F32 error = ( tetrahedron.getVolume() - mesh.getVolume() ) / tetrahedron.getVolume(); ensure("tetrahedron and mesh volume should match", error < SMALL_RELATIVE_ERROR); LLMatrix3 mesh_inertia; mesh.getScaledInertiaTensor(mesh_inertia, scale, density); for (S32 i=0; i<3; ++i) { for (S32 j=0; j<3; ++j) { // only verify the non-small elements if (analytic_inertia.mMatrix[i][j] > SMALL_RELATIVE_ERROR) { error = fabs(1.f - mesh_inertia.mMatrix[i][j] / analytic_inertia.mMatrix[i][j]); ensure("LLPrimMassProperties::setUnitMesh() inertia ", error < SMALL_RELATIVE_ERROR); } } } } } template<> template<> void mass_properties::test<4>() { // test tetrahedron utilities // from the paper described here: // from the numerical example in this paper: // http://www.journaldatabase.org/articles/87064/Explicit_Exact_Formulas_f.html // initialize info about the tetrahedron std::vector< LLVector3 > points; points.push_back( LLVector3( 8.33220f, -11.86875f, 0.93355f) ); points.push_back( LLVector3( 0.75523f, 5.00000f, 16.37072f) ); points.push_back( LLVector3( 52.61236f, 5.00000f, - 5.38580f) ); points.push_back( LLVector3( 2.00000f, 5.00000f, 3.00000f) ); LLVector3 expected_center( 15.92492f, 0.78281f, 3.732962f); LLMatrix3 expected_inertia; expected_inertia.mMatrix[0][0] = 43520.33257f; expected_inertia.mMatrix[1][1] = 194711.28938f; expected_inertia.mMatrix[2][2] = 191168.76173f; expected_inertia.mMatrix[0][1] = -11996.20119f; expected_inertia.mMatrix[1][0] = -11996.20119f; expected_inertia.mMatrix[0][2] = 46343.16662f; expected_inertia.mMatrix[2][0] = 46343.16662f; expected_inertia.mMatrix[2][1] = -4417.66150f; expected_inertia.mMatrix[1][2] = -4417.66150f; // measure tetrahedron bounding box max dimension // for relative error estimates LLVector3 box_min(FLT_MAX, FLT_MAX, FLT_MAX); LLVector3 box_max(-FLT_MAX, -FLT_MAX, -FLT_MAX); for (S32 point_index = 0; point_index < (S32)points.size(); ++point_index) { for (S32 i = 0; i < 3; ++i) { if (points[point_index].mV[i] < box_min.mV[i]) { box_min.mV[i] = points[point_index].mV[i]; } if (points[point_index].mV[i] > box_max.mV[i]) { box_max.mV[i] = points[point_index].mV[i]; } } } F32 tetrahedron_max_dimension = (box_max - box_min).length(); // test LLPrimMassProperties::addSignedTetrahedron() { LLPrimMassProperties tetrahedron; tetrahedron.addSignedTetrahedron(1.f, points[0], points[1], points[2], points[3]); // we must manually center the inertia tensor here // since addSignedTetrahedron() does not do it automatically tetrahedron.centerInertiaTensor(); // check the center of mass LLVector3 center = tetrahedron.getCenterOfMass(); F32 error = (center - expected_center).length() / tetrahedron_max_dimension; ensure("LLPrimMassProperties::addSignedTetrahedron() center of mass ", error < SMALL_RELATIVE_ERROR); // check the inertia tensor LLMatrix3 computed_inertia; LLVector3 scale(1.f, 1.f, 1.f); F32 density = 1.f; tetrahedron.getScaledInertiaTensor(computed_inertia, scale, density); for (S32 i=0; i<3; ++i) { for (S32 j=0; j<3; ++j) { error = fabs(1.f - computed_inertia.mMatrix[i][j] / expected_inertia.mMatrix[i][j]); ensure("LLPrimMassProperties::addSignedTetrahedron inertia ", error < SMALL_RELATIVE_ERROR); } } } // test LLPrimMassProperties::addUnitMesh() { std::vector< S32 > triangle_indices; triangle_indices.push_back(0); triangle_indices.push_back(2); triangle_indices.push_back(1); triangle_indices.push_back(1); triangle_indices.push_back(3); triangle_indices.push_back(0); triangle_indices.push_back(2); triangle_indices.push_back(0); triangle_indices.push_back(3); triangle_indices.push_back(3); triangle_indices.push_back(1); triangle_indices.push_back(2); LLPrimMassProperties mesh; mesh.setUnitMesh(points, triangle_indices); // check the center of mass LLVector3 center = mesh.getCenterOfMass(); F32 error = (center - expected_center).length() / tetrahedron_max_dimension; ensure("LLPrimMassProperties::setUnitMesh() center of mass ", error < SMALL_RELATIVE_ERROR); // check the inertia tensor LLMatrix3 computed_inertia; LLVector3 scale(1.f, 1.f, 1.f); F32 density = 1.f; mesh.getScaledInertiaTensor(computed_inertia, scale, density); for (S32 i=0; i<3; ++i) { for (S32 j=0; j<3; ++j) { error = fabs(1.f - computed_inertia.mMatrix[i][j] / expected_inertia.mMatrix[i][j]); ensure("LLPrimMassProperties::setUnitMesh() inertia diagonal elements mismatch", error < SMALL_RELATIVE_ERROR); } } } } template<> template<> void mass_properties::test<5>() { // test LLPrimMassProperties // unit shape box LLPrimMassProperties box; box.setUnitBox(); // unit shape mesh -- box // // 4-----------0 // z /| /| // | / | / | // | / | / | // | 6-----------2 | // | | | | | // | | 5-------|---1 // | | / | / // | | / | / // | y |/ |/ // |/ 7-----------3 // +------------------------ x std::vector< LLVector3 > points; points.push_back( LLVector3( 0.5f, 0.5f, 0.5f) ); points.push_back( LLVector3( 0.5f, 0.5f, -0.5f) ); points.push_back( LLVector3( 0.5f, -0.5f, 0.5f) ); points.push_back( LLVector3( 0.5f, -0.5f, -0.5f) ); points.push_back( LLVector3(-0.5f, 0.5f, 0.5f) ); points.push_back( LLVector3(-0.5f, 0.5f, -0.5f) ); points.push_back( LLVector3(-0.5f, -0.5f, 0.5f) ); points.push_back( LLVector3(-0.5f, -0.5f, -0.5f) ); std::vector< S32 > triangle_indices; // +x triangle_indices.push_back(1); triangle_indices.push_back(0); triangle_indices.push_back(2); triangle_indices.push_back(1); triangle_indices.push_back(2); triangle_indices.push_back(3); // -y triangle_indices.push_back(3); triangle_indices.push_back(2); triangle_indices.push_back(7); triangle_indices.push_back(7); triangle_indices.push_back(2); triangle_indices.push_back(6); // -x triangle_indices.push_back(7); triangle_indices.push_back(6); triangle_indices.push_back(4); triangle_indices.push_back(7); triangle_indices.push_back(4); triangle_indices.push_back(5); // +y triangle_indices.push_back(5); triangle_indices.push_back(4); triangle_indices.push_back(1); triangle_indices.push_back(1); triangle_indices.push_back(4); triangle_indices.push_back(0); // +z triangle_indices.push_back(0); triangle_indices.push_back(4); triangle_indices.push_back(6); triangle_indices.push_back(0); triangle_indices.push_back(6); triangle_indices.push_back(2); // -z triangle_indices.push_back(7); triangle_indices.push_back(5); triangle_indices.push_back(3); triangle_indices.push_back(3); triangle_indices.push_back(5); triangle_indices.push_back(1); LLPrimMassProperties mesh; mesh.setUnitMesh(points, triangle_indices); // the unit box and unit mesh mass properties should be nearly the same // volume should agree F32 error = fabs(box.getVolume() - mesh.getVolume()) / box.getVolume(); ensure("UnitBox and UnitMesh(box) should have same volume", error < SMALL_RELATIVE_ERROR); // center of mass should agree LLVector3 box_center = box.getCenterOfMass(); LLVector3 mesh_center = mesh.getCenterOfMass(); error = fabs( (box_center - mesh_center).length() ); ensure("UnitBox and UnitMesh(box) centers of mass should agree", error < SMALL_RELATIVE_ERROR ); LLVector3 scale(1.f, 1.f, 1.f); F32 density = 1.f; LLMatrix3 box_inertia, mesh_inertia; box.getScaledInertiaTensor(box_inertia, scale, density); mesh.getScaledInertiaTensor(mesh_inertia, scale, density); // mesh eigenvalues should be uniform for (S32 i = 0; i < 2; ++i) { error = fabs(mesh_inertia.mMatrix[i][i] - mesh_inertia.mMatrix[i+1][i+1]) / mesh_inertia.mMatrix[i][i]; ensure("UnitMesh(box) should have uniform eigenvalues", error < SMALL_RELATIVE_ERROR); } // inertias should agree for (S32 i = 0; i < 3; ++i) { for (S32 j = 0; j < 3; ++j) { error = fabs(box_inertia.mMatrix[i][j] - mesh_inertia.mMatrix[i][j]); if (error > 0.f && box_inertia.mMatrix[i][j] != 0.f) { error /= box_inertia.mMatrix[i][j]; } ensure("UnitBox and UnitMesh(box) should have same inertia", error < SMALL_RELATIVE_ERROR); } } // Here we test the boundary of the LLPrimLinkInfo::canLink() method // between semi-random middle-sized objects. } template<> template<> void mass_properties::test<6>() { // test LLObjectMassProperties // we make a large single-prim box, then a similarly shaped object // that is multiple prims, and compare their mass properties LLPrimMassProperties box; box.setUnitBox(); F32 density = 3.7f; LLVector3 big_scale(1.f, 2.f, 3.f); LLObjectMassProperties big_box(box, big_scale, density); LLObjectMassProperties multiple_box; LLVector3 position; LLQuaternion rotation; rotation.loadIdentity(); F32 small_box_size = 0.5f; LLVector3 small_scale( small_box_size, small_box_size, small_box_size); S32 num_boxes_x = S32(big_scale.mV[VX] / small_box_size); S32 num_boxes_y = S32(big_scale.mV[VY] / small_box_size); S32 num_boxes_z = S32(big_scale.mV[VZ] / small_box_size); LLVector3 start_pos = 0.5f * (small_scale - big_scale); for (S32 x = 0; x < num_boxes_x; ++x) { for (S32 y = 0; y < num_boxes_y; ++y) { for (S32 z = 0; z < num_boxes_z; ++z) { position.set( F32(x) * small_box_size, F32(y) * small_box_size, F32(z) * small_box_size ); position += start_pos; multiple_box.add(box, small_scale, density, position, rotation); } } } // the mass properties of the two boxes should match // mass F32 big_mass = big_box.getMass(); F32 multiple_mass = multiple_box.getMass(); F32 error = (big_mass - multiple_mass) / big_mass; ensure("Big box and equivalent multi-prim box should have same mass", error < SMALL_RELATIVE_ERROR); // center of mass LLVector3 big_center, multiple_center; big_box.getCenterOfMass(big_center); multiple_box.getCenterOfMass(multiple_center); error = (big_center - multiple_center).length(); ensure("Big box and equivalent multi-prim box should have same center", error < SMALL_RELATIVE_ERROR); // inertia LLMatrix3 big_inertia, multiple_inertia; big_box.getInertiaLocal(big_inertia); multiple_box.getInertiaLocal(multiple_inertia); for (S32 i = 0; i < 3; ++i) { for (S32 j = 0; j < 3; ++j) { error = fabs(big_inertia.mMatrix[i][j] - multiple_inertia.mMatrix[i][j]); if (error > 0.f && big_inertia.mMatrix[i][j] != 0.f) { error /= big_inertia.mMatrix[i][j]; } ensure("UnitBox and UnitMesh(box) should have same inertia", error < SMALL_RELATIVE_ERROR); } } } template<> template<> void mass_properties::test<7>() { // test LLObjectMassProperties with rotations // we make a large single-prim box via mesh, then a similarly shaped // object that is multiple prims (implicit boxes), and compare their // mass properties // // 4-----------0 // z /| /| // | / | / | // | / | / | // | 6-----------2 | // | | | | | // | | 5-------|---1 // | | / | / // | | / | / // | y |/ |/ // |/ 7-----------3 // +------------------------ x std::vector< LLVector3 > points; points.push_back( LLVector3( 0.5f, 0.5f, 0.5f) ); points.push_back( LLVector3( 0.5f, 0.5f, -0.5f) ); points.push_back( LLVector3( 0.5f, -0.5f, 0.5f) ); points.push_back( LLVector3( 0.5f, -0.5f, -0.5f) ); points.push_back( LLVector3(-0.5f, 0.5f, 0.5f) ); points.push_back( LLVector3(-0.5f, 0.5f, -0.5f) ); points.push_back( LLVector3(-0.5f, -0.5f, 0.5f) ); points.push_back( LLVector3(-0.5f, -0.5f, -0.5f) ); std::vector< S32 > triangle_indices; // +x triangle_indices.push_back(1); triangle_indices.push_back(0); triangle_indices.push_back(2); triangle_indices.push_back(1); triangle_indices.push_back(2); triangle_indices.push_back(3); // -y triangle_indices.push_back(3); triangle_indices.push_back(2); triangle_indices.push_back(7); triangle_indices.push_back(7); triangle_indices.push_back(2); triangle_indices.push_back(6); // -x triangle_indices.push_back(7); triangle_indices.push_back(6); triangle_indices.push_back(4); triangle_indices.push_back(7); triangle_indices.push_back(4); triangle_indices.push_back(5); // +y triangle_indices.push_back(5); triangle_indices.push_back(4); triangle_indices.push_back(1); triangle_indices.push_back(1); triangle_indices.push_back(4); triangle_indices.push_back(0); // +z triangle_indices.push_back(0); triangle_indices.push_back(4); triangle_indices.push_back(6); triangle_indices.push_back(0); triangle_indices.push_back(6); triangle_indices.push_back(2); // -z triangle_indices.push_back(7); triangle_indices.push_back(5); triangle_indices.push_back(3); triangle_indices.push_back(3); triangle_indices.push_back(5); triangle_indices.push_back(1); F32 angle_step = F_PI / (2.f * 3.f); for (F32 angle = 0.f; angle < 0.51f * F_PI; angle += angle_step) { // scale and rotate mesh points LLVector3 axis(0.f, 0.f, angle); LLQuaternion mesh_rotation(angle, axis); LLVector3 big_scale(3.f, 5.f, 7.f); std::vector< LLVector3 > new_points; for (S32 p = 0; p < (S32)points.size(); ++p) { LLVector3 new_point = points[p]; for (S32 i = 0; i < 3; ++i) { new_point.mV[i] *= big_scale.mV[i]; } new_points.push_back( new_point * mesh_rotation ); } // build the big mesh box LLPrimMassProperties mesh_box; mesh_box.setUnitMesh(new_points, triangle_indices); F32 density = 3.7f; LLVector3 unit_scale(1.f, 1.f, 1.f); LLObjectMassProperties big_box(mesh_box, unit_scale, density); // build the multiple_box LLPrimMassProperties box; box.setUnitBox(); LLObjectMassProperties multiple_box; LLVector3 position; F32 small_box_size = 0.5f; LLVector3 small_scale( small_box_size, small_box_size, small_box_size); S32 num_boxes_x = S32(big_scale.mV[VX] / small_box_size); S32 num_boxes_y = S32(big_scale.mV[VY] / small_box_size); S32 num_boxes_z = S32(big_scale.mV[VZ] / small_box_size); LLVector3 start_pos = (0.5f * (small_scale - big_scale)) * mesh_rotation; for (S32 x = 0; x < num_boxes_x; ++x) { for (S32 y = 0; y < num_boxes_y; ++y) { for (S32 z = 0; z < num_boxes_z; ++z) { position.set( F32(x) * small_box_size, F32(y) * small_box_size, F32(z) * small_box_size ); position *= mesh_rotation; position += start_pos; multiple_box.add(box, small_scale, density, position, mesh_rotation); } } } // the mass properties of the two boxes should match // mass F32 big_mass = big_box.getMass(); F32 multiple_mass = multiple_box.getMass(); F32 error = (big_mass - multiple_mass) / big_mass; ensure("Big box and equivalent multi-prim box should have same mass", error < SMALL_RELATIVE_ERROR); // center of mass LLVector3 big_center, multiple_center; big_box.getCenterOfMass(big_center); multiple_box.getCenterOfMass(multiple_center); error = (big_center - multiple_center).length(); ensure("Big box and equivalent multi-prim box should have same center", error < SMALL_RELATIVE_ERROR); LLMatrix3 big_inertia, multiple_inertia; big_box.getInertiaLocal(big_inertia); multiple_box.getInertiaLocal(multiple_inertia); for (S32 i = 0; i < 3; ++i) { for (S32 j = 0; j < 3; ++j) { error = fabs(big_inertia.mMatrix[i][j] - multiple_inertia.mMatrix[i][j]); if (error > 0.f && big_inertia.mMatrix[i][j] > SMALL_RELATIVE_ERROR) { error /= big_inertia.mMatrix[i][j]; } ensure("UnitBox and UnitMesh(box) should have same inertia", error < SMALL_RELATIVE_ERROR); } } } } template<> template<> void mass_properties::test<8>() { // test LLPhysicsVolumeManager // we make a large single-prim box, then a similarly shaped object // that is multiple prims, and compare their mass properties // first we make the single-prim giant // // 4-----------0 // z /| /| // | / | / | // | / | / | // | 6-----------2 | // | | | | | // | | 5-------|---1 // | | / | / // | | / | / // | y |/ |/ // |/ 7-----------3 // +------------------------ x std::vector< LLVector3 > points; points.push_back( LLVector3( 0.5f, 0.5f, 0.5f) ); points.push_back( LLVector3( 0.5f, 0.5f, -0.5f) ); points.push_back( LLVector3( 0.5f, -0.5f, 0.5f) ); points.push_back( LLVector3( 0.5f, -0.5f, -0.5f) ); points.push_back( LLVector3(-0.5f, 0.5f, 0.5f) ); points.push_back( LLVector3(-0.5f, 0.5f, -0.5f) ); points.push_back( LLVector3(-0.5f, -0.5f, 0.5f) ); points.push_back( LLVector3(-0.5f, -0.5f, -0.5f) ); std::vector< S32 > triangle_indices; // +x triangle_indices.push_back(1); triangle_indices.push_back(0); triangle_indices.push_back(2); triangle_indices.push_back(1); triangle_indices.push_back(2); triangle_indices.push_back(3); // -y triangle_indices.push_back(3); triangle_indices.push_back(2); triangle_indices.push_back(7); triangle_indices.push_back(7); triangle_indices.push_back(2); triangle_indices.push_back(6); // -x triangle_indices.push_back(7); triangle_indices.push_back(6); triangle_indices.push_back(4); triangle_indices.push_back(7); triangle_indices.push_back(4); triangle_indices.push_back(5); // +y triangle_indices.push_back(5); triangle_indices.push_back(4); triangle_indices.push_back(1); triangle_indices.push_back(1); triangle_indices.push_back(4); triangle_indices.push_back(0); // +z triangle_indices.push_back(0); triangle_indices.push_back(4); triangle_indices.push_back(6); triangle_indices.push_back(0); triangle_indices.push_back(6); triangle_indices.push_back(2); // -z triangle_indices.push_back(7); triangle_indices.push_back(5); triangle_indices.push_back(3); triangle_indices.push_back(3); triangle_indices.push_back(5); triangle_indices.push_back(1); // scale the mesh points LLVector3 big_scale(1.f, 2.f, 3.f); std::vector< LLVector3 > new_points; for (S32 p = 0; p < (S32)points.size(); ++p) { LLVector3 new_point = points[p]; for (S32 i = 0; i < 3; ++i) { new_point.mV[i] *= big_scale.mV[i]; } new_points.push_back( new_point ); } // build the big mesh box (primitive) LLPrimMassProperties mesh_box; mesh_box.setUnitMesh(new_points, triangle_indices); F32 density = DEFAULT_OBJECT_DENSITY; LLVector3 unit_scale(1.f, 1.f, 1.f); LLObjectMassProperties big_box(mesh_box, unit_scale, density); // build the multi-prim box (object) S32 TEST_VOLUME_DETAIL = 1; LLVolumeParams volume_params; volume_params.setCube(); LLObjectMassProperties multiple_box; F32 small_box_size = 0.5f; LLVector3 small_scale( small_box_size, small_box_size, small_box_size); { // hijack the volume manager used by LLPrimitive LLPhysicsVolumeManager* volume_manager = new LLPhysicsVolumeManager(); //volume_manager->setThreadSafe(false); LLPrimitive::setVolumeManager(volume_manager); std::vector< const LLPrimitive* > prim_list; F32 angle = 0.f; LLVector3 axis(0.f, 0.f, angle); LLVector3 position; LLQuaternion rotation(angle, axis); S32 num_boxes_x = S32(big_scale.mV[VX] / small_box_size); S32 num_boxes_y = S32(big_scale.mV[VY] / small_box_size); S32 num_boxes_z = S32(big_scale.mV[VZ] / small_box_size); for (S32 x = 0; x < num_boxes_x; ++x) { for (S32 y = 0; y < num_boxes_y; ++y) { for (S32 z = 0; z < num_boxes_z; ++z) { LLPrimitive* primp = new LLPrimitive(); primp->setVolume( volume_params, TEST_VOLUME_DETAIL); position.set( F32(x) * small_box_size, F32(y) * small_box_size, F32(z) * small_box_size ); position *= rotation; primp->setPosition(position); primp->setRotation(rotation); primp->setScale(small_scale); prim_list.push_back(primp); } } } volume_manager->getObjectMassProperties(multiple_box, prim_list); for (S32 i = 0; i < (S32)prim_list.size(); ++i) { delete prim_list[i]; prim_list[i] = NULL; } LLPrimitive::cleanupVolumeManager(); } // mass F32 big_mass = big_box.getMass(); F32 multiple_mass = multiple_box.getMass(); F32 error = (big_mass - multiple_mass) / big_mass; ensure("Big box and equivalent multi-prim box should have same mass", error < SMALL_RELATIVE_ERROR); // center of mass LLVector3 big_center, multiple_center; big_box.getCenterOfMass(big_center); multiple_box.getCenterOfMass(multiple_center); LLVector3 expected_shift = 0.5f * ( big_scale - small_scale ); error = ( big_center - (multiple_center - expected_shift) ).length(); ensure("Big box and equivalent multi-prim box should have same center", error < SMALL_RELATIVE_ERROR); // inertia LLMatrix3 big_inertia, multiple_inertia; big_box.getInertiaLocal(big_inertia); multiple_box.getInertiaLocal(multiple_inertia); for (S32 i = 0; i < 3; ++i) { for (S32 j = 0; j < 3; ++j) { error = fabs(big_inertia.mMatrix[i][j] - multiple_inertia.mMatrix[i][j]); if (error > 0.f && big_inertia.mMatrix[i][j] > SMALL_RELATIVE_ERROR) { error /= big_inertia.mMatrix[i][j]; } bool ok = error < SMALL_RELATIVE_ERROR || (i != j && error < SMALL_RELATIVE_ERROR); ensure("UnitBox and UnitMesh(box) should have same inertia", ok ); } } } }