/************************************************************************* * * * Open Dynamics Engine, Copyright (C) 2001,2002 Russell L. Smith. * * All rights reserved. Email: russ@q12.org Web: www.q12.org * * * * This library is free software; you can redistribute it and/or * * modify it under the terms of EITHER: * * (1) The GNU Lesser General Public License as published by the Free * * Software Foundation; either version 2.1 of the License, or (at * * your option) any later version. The text of the GNU Lesser * * General Public License is included with this library in the * * file LICENSE.TXT. * * (2) The BSD-style license that is included with this library in * * the file LICENSE-BSD.TXT. * * * * This library is distributed in the hope that it will be useful, * * but WITHOUT ANY WARRANTY; without even the implied warranty of * * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the files * * LICENSE.TXT and LICENSE-BSD.TXT for more details. * * * *************************************************************************/ //234567890123456789012345678901234567890123456789012345678901234567890123456789 // 1 2 3 4 5 6 7 //////////////////////////////////////////////////////////////////////////////// // This file create unit test for some of the functions found in: // ode/src/joinst/pu.cpp // // //////////////////////////////////////////////////////////////////////////////// #include #include #include "../../ode/src/config.h" #include "../../ode/src/joints/pu.h" SUITE (TestdxJointPU) { // The 2 bodies are positionned at (0, 0, 0), and (0, 0, 0) // The second body has a rotation of 27deg around X axis. // The joint is a PU Joint // Axis is along the X axis // Anchor at (0, 0, 0) struct Fixture_dxJointPU_B1_and_B2_At_Zero_Axis_Along_X { Fixture_dxJointPU_B1_and_B2_At_Zero_Axis_Along_X() { wId = dWorldCreate(); bId1 = dBodyCreate (wId); dBodySetPosition (bId1, 0, 0, 0); bId2 = dBodyCreate (wId); dBodySetPosition (bId2, 0, 0, 0); dMatrix3 R; dRFromAxisAndAngle (R, 1, 0, 0, REAL(0.47123)); // 27deg dBodySetRotation (bId2, R); jId = dJointCreatePU (wId, 0); joint = (dxJointPU*) jId; dJointAttach (jId, bId1, bId2); } ~Fixture_dxJointPU_B1_and_B2_At_Zero_Axis_Along_X() { dWorldDestroy (wId); } dWorldID wId; dBodyID bId1; dBodyID bId2; dJointID jId; dxJointPU* joint; }; // Test is dJointSetPUAxis and dJointGetPUAxis return same value TEST_FIXTURE (Fixture_dxJointPU_B1_and_B2_At_Zero_Axis_Along_X, test_dJointSetGetPUAxis) { dVector3 axisOrig, axis; dJointGetPUAxis1 (jId, axisOrig); dJointGetPUAxis1 (jId, axis); dJointSetPUAxis1 (jId, axis[0], axis[1], axis[2]); dJointGetPUAxis1 (jId, axis); CHECK_CLOSE (axis[0], axisOrig[0] , 1e-4); CHECK_CLOSE (axis[1], axisOrig[1] , 1e-4); CHECK_CLOSE (axis[2], axisOrig[2] , 1e-4); dJointGetPUAxis2 (jId, axisOrig); dJointGetPUAxis2(jId, axis); dJointSetPUAxis2 (jId, axis[0], axis[1], axis[2]); dJointGetPUAxis2 (jId, axis); CHECK_CLOSE (axis[0], axisOrig[0] , 1e-4); CHECK_CLOSE (axis[1], axisOrig[1] , 1e-4); CHECK_CLOSE (axis[2], axisOrig[2] , 1e-4); dJointGetPUAxis3 (jId, axisOrig); dJointGetPUAxis3(jId, axis); dJointSetPUAxis3 (jId, axis[0], axis[1], axis[2]); dJointGetPUAxis3 (jId, axis); CHECK_CLOSE (axis[0], axisOrig[0] , 1e-4); CHECK_CLOSE (axis[1], axisOrig[1] , 1e-4); CHECK_CLOSE (axis[2], axisOrig[2] , 1e-4); } // The joint is a PU Joint // Default joint value // The two bodies at at (0, 0, 0) struct Fixture_dxJointPU_B1_and_B2_At_Zero { Fixture_dxJointPU_B1_and_B2_At_Zero() { wId = dWorldCreate(); bId1 = dBodyCreate (wId); dBodySetPosition (bId1, 0, 0, 0); bId2 = dBodyCreate (wId); dBodySetPosition (bId2, 0, 0, 0); jId = dJointCreatePU (wId, 0); joint = (dxJointPU*) jId; dJointAttach (jId, bId1, bId2); } ~Fixture_dxJointPU_B1_and_B2_At_Zero() { dWorldDestroy (wId); } dWorldID wId; dBodyID bId1; dBodyID bId2; dJointID jId; dxJointPU* joint; static const dReal offset; }; const dReal Fixture_dxJointPU_B1_and_B2_At_Zero::offset = REAL (3.1); // Move 1st body offset unit in the X direction // // X-------> X---------> Axis --> // B1 => B1 // B2 B2 // // Start with a Offset of offset unit // // X-------> X---------> Axis --> // B1 => B1 // B2 B2 TEST_FIXTURE (Fixture_dxJointPU_B1_and_B2_At_Zero, test_dJointSetPUAxisOffset_B1_3Unit) { CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId1, offset, 0, 0); CHECK_CLOSE (offset, dJointGetPUPosition (jId), 1e-4); dVector3 axis; dJointGetPUAxisP (jId, axis); dJointSetPUAnchorOffset (jId, 0, 0, 0, offset*axis[0],offset*axis[1],offset*axis[2]); CHECK_CLOSE (offset, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId1, 0, 0, 0); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); } // Move 1st body offset unit in the opposite X direction // // X-------> X---------> Axis --> // B1 => B1 // B2 B2 // // Start with a Offset of -offset unit // // X-------> X---------> Axis --> // B1 => B1 // B2 B2 TEST_FIXTURE (Fixture_dxJointPU_B1_and_B2_At_Zero, test_dJointSetPUAxisOffset_B1_Minus_3Unit) { CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId1, -offset, 0, 0); CHECK_CLOSE (-offset, dJointGetPUPosition (jId), 1e-4); dVector3 axis; dJointGetPUAxisP (jId, axis); dJointSetPUAnchorOffset (jId, 0, 0, 0, -offset*axis[0],-offset*axis[1],-offset*axis[2]); CHECK_CLOSE (-offset, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId1, 0, 0, 0); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); } // Move 2nd body offset unit in the X direction // // X-------> X---------> Axis --> // B1 => B1 // B2 B2 // // Start with a Offset of offset unit // // X-------> X---------> Axis --> // B1 => B1 // B2 B2 TEST_FIXTURE (Fixture_dxJointPU_B1_and_B2_At_Zero, test_dJointSetPUAxisOffset_B2_3Unit) { CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId2, offset, 0, 0); CHECK_CLOSE (-offset, dJointGetPUPosition (jId), 1e-4); dVector3 axis; dJointGetPUAxisP (jId, axis); dJointSetPUAnchorOffset (jId, 0, 0, 0, -offset*axis[0],-offset*axis[1],-offset*axis[2]); CHECK_CLOSE (-offset, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId2, 0, 0, 0); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); } // Move 2nd body offset unit in the opposite X direction // // X-------> X---------> Axis --> // B1 => B1 // B2 B2 // // Start with a Offset of -offset unit // // X-------> X---------> Axis --> // B1 => B1 // B2 B2 TEST_FIXTURE (Fixture_dxJointPU_B1_and_B2_At_Zero, test_dJointSetPUAxisOffset_B2_Minus_3Unit) { CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId2, -offset, 0, 0); CHECK_CLOSE (offset, dJointGetPUPosition (jId), 1e-4); dVector3 axis; dJointGetPUAxisP (jId, axis); dJointSetPUAnchorOffset (jId, 0, 0, 0, offset*axis[0],offset*axis[1],offset*axis[2]); CHECK_CLOSE (offset, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId2, 0, 0, 0); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); } // Attach only one body at position 1 to the joint dJointAttach (jId, bId, 0) // Move 1st body offset unit in the X direction // // X-------> X---------> Axis --> // B1 => B1 // // Start with a Offset of offset unit // // X-------> X---------> Axis --> // B1 => B1 TEST_FIXTURE (Fixture_dxJointPU_B1_and_B2_At_Zero, test_dJointSetPUAxisOffset_B1_OffsetUnit) { dJointAttach (jId, bId1, 0); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId1, offset, 0, 0); CHECK_CLOSE (offset, dJointGetPUPosition (jId), 1e-4); dVector3 axis; dJointGetPUAxisP (jId, axis); dJointSetPUAnchorOffset (jId, 0, 0, 0, offset*axis[0],offset*axis[1],offset*axis[2]); CHECK_CLOSE (offset, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId1, 0, 0, 0); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); } // Attache only one body at position 1 to the joint dJointAttach (jId, bId, 0) // Move 1st body offset unit in the opposite X direction // // X-------> X---------> Axis --> // B1 => B1 // // Start with a Offset of -offset unit // // X-------> X---------> Axis --> // B1 => B1 TEST_FIXTURE (Fixture_dxJointPU_B1_and_B2_At_Zero, test_dJointSetPUAxisOffset_B1_Minus_OffsetUnit) { dJointAttach (jId, bId1, 0); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId1, -offset, 0, 0); CHECK_CLOSE (-offset, dJointGetPUPosition (jId), 1e-4); dVector3 axis; dJointGetPUAxisP (jId, axis); dJointSetPUAnchorOffset (jId, 0, 0, 0, -offset*axis[0],-offset*axis[1],-offset*axis[2]); CHECK_CLOSE (-offset, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId1, 0, 0, 0); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); } // Attache only one body at position 2 to the joint dJointAttach (jId, 0, bId) // Move 1st body offset unit in the X direction // // X-------> X---------> Axis --> // B2 => B2 // // Start with a Offset of offset unit // // X-------> X---------> Axis --> // B2 => B2 TEST_FIXTURE (Fixture_dxJointPU_B1_and_B2_At_Zero, test_dJointSetPUAxisOffset_B2_OffsetUnit) { dJointAttach (jId, 0, bId2); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId2, offset, 0, 0); CHECK_CLOSE (-offset, dJointGetPUPosition (jId), 1e-4); dVector3 axis; dJointGetPUAxisP (jId, axis); dJointSetPUAnchorOffset (jId, 0, 0, 0, -offset*axis[0], -offset*axis[1], -offset*axis[2]); CHECK_CLOSE (-offset, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId2, 0, 0, 0); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); } // Attache only one body at position 2 to the joint dJointAttach (jId, 0, bId) // Move 1st body offset unit in the opposite X direction // // X-------> X---------> Axis --> // B2 => B2 // // Start with a Offset of -offset unit // // X-------> X---------> Axis --> // B2 => B2 TEST_FIXTURE (Fixture_dxJointPU_B1_and_B2_At_Zero, test_dJointSetPUAxisOffset_B2_Minus_OffsetUnit) { dJointAttach (jId, 0, bId2); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId2, -offset, 0, 0); CHECK_CLOSE (offset, dJointGetPUPosition (jId), 1e-4); dVector3 axis; dJointGetPUAxisP (jId, axis); dJointSetPUAnchorOffset (jId, 0, 0, 0, offset*axis[0], offset*axis[1], offset*axis[2]); CHECK_CLOSE (offset, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId2, 0, 0, 0); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); } // Only one body // The body are positionned at (0, 0, 0), with no rotation // The joint is a PU Joint // Axis is in the oppsite X axis // Anchor at (0, 0, 0) // N.B. By default the body is attached at position 1 on the joint // dJointAttach (jId, bId, 0); struct Fixture_dxJointPU_One_Body_At_Zero_Axis_Inverse_of_X { Fixture_dxJointPU_One_Body_At_Zero_Axis_Inverse_of_X() { wId = dWorldCreate(); bId = dBodyCreate (wId); dBodySetPosition (bId, 0, 0, 0); jId = dJointCreatePU (wId, 0); joint = (dxJointPU*) jId; dJointAttach (jId, bId, NULL); dJointSetPUAxisP (jId, axis[0], axis[1], axis[2]); } ~Fixture_dxJointPU_One_Body_At_Zero_Axis_Inverse_of_X() { dWorldDestroy (wId); } dWorldID wId; dBodyID bId; dJointID jId; dxJointPU* joint; static const dVector3 axis; static const dReal offset; }; const dVector3 Fixture_dxJointPU_One_Body_At_Zero_Axis_Inverse_of_X::axis = { -1, 0, 0 }; const dReal Fixture_dxJointPU_One_Body_At_Zero_Axis_Inverse_of_X::offset = REAL (3.1); // Move 1st body offset unit in the X direction // // X-------> X---------> <--- Axis // B1 => B1 // // Start with a Offset of offset unit // // X-------> X---------> <--- Axis // B1 => B1 TEST_FIXTURE (Fixture_dxJointPU_One_Body_At_Zero_Axis_Inverse_of_X, test_dJointSetPUAxisOffset_B1_At_Position_1_OffsetUnit) { CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId, offset, 0, 0); CHECK_CLOSE (-offset, dJointGetPUPosition (jId), 1e-4); dJointSetPUAnchorOffset (jId, 0, 0, 0, -offset*axis[0],-offset*axis[1],-offset*axis[2]); CHECK_CLOSE (-offset, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId, 0, 0, 0); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); } // Move 1st body offset unit in the opposite X direction // // X-------> X---------> <--- Axis // B1 => B1 // // Start with a Offset of -offset unit // // X-------> X---------> <--- Axis // B1 => B1 TEST_FIXTURE (Fixture_dxJointPU_One_Body_At_Zero_Axis_Inverse_of_X, test_dJointSetPUAxisOffset_B1_Minus_OffsetUnit) { CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId, -offset, 0, 0); CHECK_CLOSE (offset, dJointGetPUPosition (jId), 1e-4); dJointSetPUAnchorOffset (jId, 0, 0, 0, offset*axis[0],offset*axis[1],offset*axis[2]); CHECK_CLOSE (offset, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId, 0, 0, 0); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); } // Move 1st body offset unit in the X direction // // X-------> X---------> <--- Axis // B2 => B2 // // Start with a Offset of offset unit // // X-------> X---------> <--- Axis // B2 => B2 TEST_FIXTURE (Fixture_dxJointPU_One_Body_At_Zero_Axis_Inverse_of_X, test_dJointSetPUAxisOffset_B2_OffsetUnit) { // By default it is attached to position 1 // Now attach the body at positiojn 2 dJointAttach(jId, 0, bId); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId, offset, 0, 0); CHECK_CLOSE (offset, dJointGetPUPosition (jId), 1e-4); dJointSetPUAnchorOffset (jId, 0, 0, 0, offset*axis[0], offset*axis[1], offset*axis[2]); CHECK_CLOSE (offset, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId, 0, 0, 0); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); } // Move 1st body offset unit in the opposite X direction // // X-------> X---------> <--- Axis // B2 => B2 // // Start with a Offset of -offset unit // // X-------> X---------> <--- Axis // B2 => B2 TEST_FIXTURE (Fixture_dxJointPU_One_Body_At_Zero_Axis_Inverse_of_X, test_dJointSetPUAxisOffset_B2_Minus_OffsetUnit) { // By default it is attached to position 1 // Now attach the body at positiojn 2 dJointAttach(jId, 0, bId); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId, -offset, 0, 0); CHECK_CLOSE (-offset, dJointGetPUPosition (jId), 1e-4); dJointSetPUAnchorOffset (jId, 0, 0, 0, -offset*axis[0], -offset*axis[1], -offset*axis[2]); CHECK_CLOSE (-offset, dJointGetPUPosition (jId), 1e-4); dBodySetPosition (bId, 0, 0, 0); CHECK_CLOSE (0.0, dJointGetPUPosition (jId), 1e-4); } // Compare only one body to 2 bodies with one fixed. // // The body are positionned at (0, 0, 0), with no rotation // The joint is a PU Joint with default values struct Fixture_dxJointPU_Compare_One_Body_To_Two_Bodies_At_Zero { Fixture_dxJointPU_Compare_One_Body_To_Two_Bodies_At_Zero() { wId = dWorldCreate(); bId1_12 = dBodyCreate (wId); dBodySetPosition (bId1_12, 0, 0, 0); bId2_12 = dBodyCreate (wId); dBodySetPosition (bId2_12, 0, 0, 0); // The force will be added in the function since it is not // always on the same body jId_12 = dJointCreatePU (wId, 0); dJointAttach(jId_12, bId1_12, bId2_12); fixed = dJointCreateFixed (wId, 0); jId = dJointCreatePU (wId, 0); bId = dBodyCreate (wId); dBodySetPosition (bId, 0, 0, 0); // Linear velocity along the prismatic axis; dVector3 axis; dJointGetPUAxisP(jId_12, axis); dJointSetPUAxisP(jId, axis[0], axis[1], axis[2]); dBodySetLinearVel (bId, magnitude*axis[0], magnitude*axis[1], magnitude*axis[2]); } ~Fixture_dxJointPU_Compare_One_Body_To_Two_Bodies_At_Zero() { dWorldDestroy (wId); } dWorldID wId; dBodyID bId1_12; dBodyID bId2_12; dJointID jId_12; // Joint with 2 bodies dJointID fixed; dBodyID bId; dJointID jId; // Joint with one body static const dReal magnitude; }; const dReal Fixture_dxJointPU_Compare_One_Body_To_Two_Bodies_At_Zero::magnitude = REAL (4.27); TEST_FIXTURE (Fixture_dxJointPU_Compare_One_Body_To_Two_Bodies_At_Zero, test_dJointSetPUPositionRate_Only_B1) { // Linear velocity along the prismatic axis; dVector3 axis; dJointGetPUAxisP(jId_12, axis); dBodySetLinearVel (bId1_12, magnitude*axis[0], magnitude*axis[1], magnitude*axis[2]); dJointAttach(jId_12, bId1_12, bId2_12); dJointAttach(fixed, 0, bId2_12); dJointSetFixed(fixed); dJointAttach(jId, bId, 0); CHECK_CLOSE(dJointGetPUPositionRate(jId_12), dJointGetPUPositionRate(jId), 1e-2); } TEST_FIXTURE (Fixture_dxJointPU_Compare_One_Body_To_Two_Bodies_At_Zero, test_dJointSetPUPositionRate_Only_B2) { // Linear velocity along the prismatic axis; dVector3 axis; dJointGetPUAxisP(jId_12, axis); dBodySetLinearVel (bId2_12, magnitude*axis[0], magnitude*axis[1], magnitude*axis[2]); dJointAttach(jId_12, bId1_12, bId2_12); dJointAttach(fixed, bId1_12, 0); dJointSetFixed(fixed); dJointAttach(jId, 0, bId); CHECK_CLOSE(dJointGetPUPositionRate(jId_12), dJointGetPUPositionRate(jId), 1e-2); } // This test compare the result of a pu joint with 2 bodies where body body 2 is // fixed to the world to a pu joint with only one body at position 1. // // Test the limits [-1, 0.25] when only one body at is attached to the joint // using dJointAttache(jId, bId, 0); // TEST_FIXTURE(Fixture_dxJointPU_Compare_One_Body_To_Two_Bodies_At_Zero, test_Limit_minus1_025_One_Body_on_left) { dVector3 axis; dJointGetPUAxisP(jId_12, axis); dJointSetPUAxisP(jId, axis[0], axis[1], axis[2]); dBodySetLinearVel (bId1_12, magnitude*axis[0], magnitude*axis[1], magnitude*axis[2]); dJointAttach(jId_12, bId1_12, bId2_12); dJointSetPUParam(jId_12, dParamLoStop3, -1); dJointSetPUParam(jId_12, dParamHiStop3, 0.25); dJointAttach(fixed, 0, bId2_12); dJointSetFixed(fixed); dJointAttach(jId, bId, 0); dJointSetPUParam(jId, dParamLoStop3, -1); dJointSetPUParam(jId, dParamHiStop3, 0.25); for (int i=0; i<50; ++i) dWorldStep(wId, 1.0); const dReal *pos1_12 = dBodyGetPosition(bId1_12); const dReal *pos = dBodyGetPosition(bId); CHECK_CLOSE (pos1_12[0], pos[0], 1e-2); CHECK_CLOSE (pos1_12[1], pos[1], 1e-2); CHECK_CLOSE (pos1_12[2], pos[2], 1e-2); const dReal *q1_12 = dBodyGetQuaternion(bId1_12); const dReal *q = dBodyGetQuaternion(bId); CHECK_CLOSE (q1_12[0], q[0], 1e-4); CHECK_CLOSE (q1_12[1], q[1], 1e-4); CHECK_CLOSE (q1_12[2], q[2], 1e-4); CHECK_CLOSE (q1_12[3], q[3], 1e-4); // Should be different than zero CHECK( dJointGetPUPosition(jId_12) ); CHECK( dJointGetPUPosition(jId) ); CHECK( dJointGetPUPositionRate(jId_12) ); CHECK( dJointGetPUPositionRate(jId) ); } // This test compare the result of a pu joint with 2 bodies where body body 1 is // fixed to the world to a pu joint with only one body at position 2. // // Test the limits [-1, 0.25] when only one body at is attached to the joint // using dJointAttache(jId, 0, bId); // TEST_FIXTURE(Fixture_dxJointPU_Compare_One_Body_To_Two_Bodies_At_Zero, test_Limit_minus1_025_One_Body_on_right) { dVector3 axis; dJointGetPUAxisP(jId_12, axis); dJointSetPUAxisP(jId, axis[0], axis[1], axis[2]); dBodySetLinearVel (bId2_12, magnitude*axis[0], magnitude*axis[1], magnitude*axis[2]); dJointAttach(jId_12, bId1_12, bId2_12); dJointSetPUParam(jId_12, dParamLoStop3, -1); dJointSetPUParam(jId_12, dParamHiStop3, 0.25); dJointAttach(fixed, bId1_12, 0); dJointSetFixed(fixed); dJointAttach(jId, 0, bId); dJointSetPUParam(jId, dParamLoStop3, -1); dJointSetPUParam(jId, dParamHiStop3, 0.25); for (int i=0; i<50; ++i) dWorldStep(wId, 1.0); const dReal *pos2_12 = dBodyGetPosition(bId2_12); const dReal *pos = dBodyGetPosition(bId); CHECK_CLOSE (pos2_12[0], pos[0], 1e-2); CHECK_CLOSE (pos2_12[1], pos[1], 1e-2); CHECK_CLOSE (pos2_12[2], pos[2], 1e-2); const dReal *q2_12 = dBodyGetQuaternion(bId2_12); const dReal *q = dBodyGetQuaternion(bId); CHECK_CLOSE (q2_12[0], q[0], 1e-4); CHECK_CLOSE (q2_12[1], q[1], 1e-4); CHECK_CLOSE (q2_12[2], q[2], 1e-4); CHECK_CLOSE (q2_12[3], q[3], 1e-4); // Should be different than zero CHECK( dJointGetPUPosition(jId_12) ); CHECK( dJointGetPUPosition(jId) ); CHECK( dJointGetPUPositionRate(jId_12) ); CHECK( dJointGetPUPositionRate(jId) ); } // This test compare the result of a pu joint with 2 bodies where body 2 is // fixed to the world to a pu joint with only one body at position 1. // // Test the limits [0, 0] when only one body at is attached to the joint // using dJointAttache(jId, bId, 0); // // The body should not move since their is no room between the two limits // TEST_FIXTURE(Fixture_dxJointPU_Compare_One_Body_To_Two_Bodies_At_Zero, test_Limit_0_0_One_Body_on_left) { dVector3 axis; dJointGetPUAxisP(jId_12, axis); dJointSetPUAxisP(jId, axis[0], axis[1], axis[2]); dBodySetLinearVel (bId1_12, magnitude*axis[0], magnitude*axis[1], magnitude*axis[2]); dJointAttach(jId_12, bId1_12, bId2_12); dJointSetPUParam(jId_12, dParamLoStop3, 0); dJointSetPUParam(jId_12, dParamHiStop3, 0); dJointAttach(fixed, 0, bId2_12); dJointSetFixed(fixed); dJointAttach(jId, bId, 0); dJointSetPUParam(jId, dParamLoStop3, 0); dJointSetPUParam(jId, dParamHiStop3, 0); for (int i=0; i<500; ++i) dWorldStep(wId, 1.0); const dReal *pos1_12 = dBodyGetPosition(bId1_12); const dReal *pos = dBodyGetPosition(bId); CHECK_CLOSE (pos1_12[0], pos[0], 1e-4); CHECK_CLOSE (pos1_12[1], pos[1], 1e-4); CHECK_CLOSE (pos1_12[2], pos[2], 1e-4); CHECK_CLOSE (0, pos[0], 1e-4); CHECK_CLOSE (0, pos[1], 1e-4); CHECK_CLOSE (0, pos[2], 1e-4); const dReal *q1_12 = dBodyGetQuaternion(bId1_12); const dReal *q = dBodyGetQuaternion(bId); CHECK_CLOSE (q1_12[0], q[0], 1e-4); CHECK_CLOSE (q1_12[1], q[1], 1e-4); CHECK_CLOSE (q1_12[2], q[2], 1e-4); CHECK_CLOSE (q1_12[3], q[3], 1e-4); } // This test compare the result of a pu joint with 2 bodies where body body 1 is // fixed to the world to a pu joint with only one body at position 2. // // Test the limits [0, 0] when only one body at is attached to the joint // using dJointAttache(jId, 0, bId); // // The body should not move since their is no room between the two limits // TEST_FIXTURE(Fixture_dxJointPU_Compare_One_Body_To_Two_Bodies_At_Zero, test_Limit_0_0_One_Body_on_right) { dVector3 axis; dJointGetPUAxisP(jId_12, axis); dJointSetPUAxisP(jId, axis[0], axis[1], axis[2]); dBodySetLinearVel (bId2_12, magnitude*axis[0], magnitude*axis[1], magnitude*axis[2]); dJointAttach(jId_12, bId1_12, bId2_12); dJointSetPUParam(jId_12, dParamLoStop3, 0); dJointSetPUParam(jId_12, dParamHiStop3, 0); dJointAttach(fixed, bId1_12, 0); dJointSetFixed(fixed); dJointAttach(jId, 0, bId); dJointSetPUParam(jId, dParamLoStop3, 0); dJointSetPUParam(jId, dParamHiStop3, 0); for (int i=0; i<500; ++i) dWorldStep(wId, 1.0); const dReal *pos2_12 = dBodyGetPosition(bId2_12); const dReal *pos = dBodyGetPosition(bId); CHECK_CLOSE (pos2_12[0], pos[0], 1e-4); CHECK_CLOSE (pos2_12[1], pos[1], 1e-4); CHECK_CLOSE (pos2_12[2], pos[2], 1e-4); CHECK_CLOSE (0, pos[0], 1e-4); CHECK_CLOSE (0, pos[1], 1e-4); CHECK_CLOSE (0, pos[2], 1e-4); const dReal *q2_12 = dBodyGetQuaternion(bId2_12); const dReal *q = dBodyGetQuaternion(bId); CHECK_CLOSE (q2_12[0], q[0], 1e-4); CHECK_CLOSE (q2_12[1], q[1], 1e-4); CHECK_CLOSE (q2_12[2], q[2], 1e-4); CHECK_CLOSE (q2_12[3], q[3], 1e-4); } } // End of SUITE TestdxJointPU