#include "RobotControlExample.h" #if 0 #include "../CommonInterfaces/CommonParameterInterface.h" #include "PhysicsServer.h" #include "PhysicsClient.h" #include "SharedMemoryCommon.h" #include "../Utils/b3Clock.h" #include "PhysicsClientC_API.h" #include "../Utils/b3ResourcePath.h" #include //const char* blaatnaam = "basename"; struct MyMotorInfo { std::string m_jointName; btScalar m_velTarget; btScalar m_posTarget; btScalar m_kp; btScalar m_kd; btScalar m_maxForce; int m_uIndex; int m_posIndex; int m_jointIndex; btScalar m_measuredJointPosition; btScalar m_measuredJointVelocity; btVector3 m_measuredJointForce; btVector3 m_measuredJointTorque; }; #define MAX_NUM_MOTORS 128 class RobotControlExample : public SharedMemoryCommon { PhysicsServerSharedMemory m_physicsServer; PhysicsClientSharedMemory m_physicsClient; b3Clock m_realtimeClock; int m_sequenceNumberGenerator; bool m_wantsShutdown; btAlignedObjectArray m_userCommandRequests; void createButton(const char* name, int id, bool isTrigger ); public: //@todo, add accessor methods MyMotorInfo m_motorTargetState[MAX_NUM_MOTORS]; int m_numMotors; int m_option; bool m_verboseOutput; RobotControlExample(GUIHelperInterface* helper, int option); virtual ~RobotControlExample(); virtual void initPhysics(); virtual void stepSimulation(float deltaTime); void prepareControlCommand(SharedMemoryCommand& cmd); void enqueueCommand(const SharedMemoryCommand& orgCommand) { m_userCommandRequests.push_back(orgCommand); SharedMemoryCommand& cmd = m_userCommandRequests[m_userCommandRequests.size()-1]; cmd.m_sequenceNumber = m_sequenceNumberGenerator++; cmd.m_timeStamp = m_realtimeClock.getTimeMicroseconds(); if (m_verboseOutput) { b3Printf("User put command request %d on queue (queue length = %d)\n",cmd.m_type, m_userCommandRequests.size()); } } virtual void resetCamera() { float dist = 5; float pitch = 50; float yaw = 35; float targetPos[3]={0,0,0};//-3,2.8,-2.5}; m_guiHelper->resetCamera(dist,pitch,yaw,targetPos[0],targetPos[1],targetPos[2]); } virtual bool wantsTermination(); virtual bool isConnected(); virtual void renderScene() { m_physicsServer.renderScene(); } virtual void exitPhysics(){} virtual void physicsDebugDraw(int debugFlags) { m_physicsServer.physicsDebugDraw(debugFlags); } virtual bool mouseMoveCallback(float x,float y){return false;}; virtual bool mouseButtonCallback(int button, int state, float x, float y){return false;} virtual bool keyboardCallback(int key, int state){return false;} virtual void setSharedMemoryKey(int key) { m_physicsServer.setSharedMemoryKey(key); m_physicsClient.setSharedMemoryKey(key); } }; bool RobotControlExample::isConnected() { return m_physicsClient.isConnected(); } void MyCallback2(int buttonId, bool buttonState, void* userPtr) { RobotControlExample* cl = (RobotControlExample*) userPtr; SharedMemoryCommand command; switch (buttonId) { case CMD_LOAD_URDF: { command.m_type =CMD_LOAD_URDF; command.m_updateFlags = URDF_ARGS_FILE_NAME|URDF_ARGS_INITIAL_POSITION|URDF_ARGS_INITIAL_ORIENTATION; sprintf(command.m_urdfArguments.m_urdfFileName,"r2d2.urdf");//kuka_lwr/kuka.urdf");//r2d2.urdf"); command.m_urdfArguments.m_initialPosition[0] = 0.0; command.m_urdfArguments.m_initialPosition[1] = 0.0; command.m_urdfArguments.m_initialPosition[2] = 0.0; command.m_urdfArguments.m_initialOrientation[0] = 0.0; command.m_urdfArguments.m_initialOrientation[1] = 0.0; command.m_urdfArguments.m_initialOrientation[2] = 0.0; command.m_urdfArguments.m_initialOrientation[3] = 1.0; command.m_urdfArguments.m_useFixedBase = false; command.m_urdfArguments.m_useMultiBody = true; cl->enqueueCommand(command); break; } case CMD_SEND_PHYSICS_SIMULATION_PARAMETERS: { //#ifdef USE_C_API b3InitPhysicsParamCommand(&command); b3PhysicsParamSetGravity(&command, 1,1,-10); // #else // // command.m_type = CMD_SEND_PHYSICS_SIMULATION_PARAMETERS; // command.m_physSimParamArgs.m_gravityAcceleration[0] = 0; // command.m_physSimParamArgs.m_gravityAcceleration[1] = 0; // command.m_physSimParamArgs.m_gravityAcceleration[2] = -10; // command.m_physSimParamArgs.m_updateFlags = SIM_PARAM_UPDATE_GRAVITY; // #endif // USE_C_API cl->enqueueCommand(command); break; }; case CMD_INIT_POSE: { ///@todo: implement this command.m_type = CMD_INIT_POSE; cl->enqueueCommand(command); break; } case CMD_CREATE_BOX_COLLISION_SHAPE: { command.m_type =CMD_CREATE_BOX_COLLISION_SHAPE; command.m_updateFlags = BOX_SHAPE_HAS_INITIAL_POSITION; command.m_createBoxShapeArguments.m_initialPosition[0] = 0; command.m_createBoxShapeArguments.m_initialPosition[1] = 0; command.m_createBoxShapeArguments.m_initialPosition[2] = -3; cl->enqueueCommand(command); break; } case CMD_REQUEST_ACTUAL_STATE: { command.m_type =CMD_REQUEST_ACTUAL_STATE; cl->enqueueCommand(command); break; }; case CMD_STEP_FORWARD_SIMULATION: { command.m_type =CMD_STEP_FORWARD_SIMULATION; cl->enqueueCommand(command); break; } case CMD_SEND_DESIRED_STATE: { command.m_type =CMD_SEND_DESIRED_STATE; cl->prepareControlCommand(command); cl->enqueueCommand(command); break; } case CMD_SEND_BULLET_DATA_STREAM: { command.m_type = buttonId; sprintf(command.m_dataStreamArguments.m_bulletFileName,"slope.bullet"); command.m_dataStreamArguments.m_streamChunkLength = 0; cl->enqueueCommand(command); break; } default: { b3Error("Unknown buttonId"); btAssert(0); } }; } void RobotControlExample::prepareControlCommand(SharedMemoryCommand& command) { for (int i=0;igetParameterInterface()->registerButtonParameter(button); } RobotControlExample::RobotControlExample(GUIHelperInterface* helper, int option) :SharedMemoryCommon(helper), m_wantsShutdown(false), m_sequenceNumberGenerator(0), m_numMotors(0), m_option(option), m_verboseOutput(false) { bool useServer = true; } RobotControlExample::~RobotControlExample() { bool deInitializeSharedMemory = true; m_physicsClient.disconnectSharedMemory(); m_physicsServer.disconnectSharedMemory(deInitializeSharedMemory); } void RobotControlExample::initPhysics() { ///for this testing we use Z-axis up int upAxis = 2; m_guiHelper->setUpAxis(upAxis); /* createEmptyDynamicsWorld(); //todo: create a special debug drawer that will cache the lines, so we can send the debug info over the wire m_guiHelper->createPhysicsDebugDrawer(m_dynamicsWorld); btVector3 grav(0,0,0); grav[upAxis] = 0;//-9.8; this->m_dynamicsWorld->setGravity(grav); */ m_physicsServer.connectSharedMemory( m_guiHelper); if (m_guiHelper && m_guiHelper->getParameterInterface()) { bool isTrigger = false; createButton("Load URDF",CMD_LOAD_URDF, isTrigger); createButton("Step Sim",CMD_STEP_FORWARD_SIMULATION, isTrigger); createButton("Send Bullet Stream",CMD_SEND_BULLET_DATA_STREAM, isTrigger); createButton("Get State",CMD_REQUEST_ACTUAL_STATE, isTrigger); createButton("Send Desired State",CMD_SEND_DESIRED_STATE, isTrigger); createButton("Create Box Collider",CMD_CREATE_BOX_COLLISION_SHAPE,isTrigger); createButton("Set Physics Params",CMD_SEND_PHYSICS_SIMULATION_PARAMETERS,isTrigger); createButton("Init Pose",CMD_INIT_POSE,isTrigger); } else { /* m_userCommandRequests.push_back(CMD_LOAD_URDF); m_userCommandRequests.push_back(CMD_REQUEST_ACTUAL_STATE); m_userCommandRequests.push_back(CMD_SEND_DESIRED_STATE); m_userCommandRequests.push_back(CMD_REQUEST_ACTUAL_STATE); //m_userCommandRequests.push_back(CMD_SET_JOINT_FEEDBACK); m_userCommandRequests.push_back(CMD_CREATE_BOX_COLLISION_SHAPE); //m_userCommandRequests.push_back(CMD_CREATE_RIGID_BODY); m_userCommandRequests.push_back(CMD_STEP_FORWARD_SIMULATION); m_userCommandRequests.push_back(CMD_REQUEST_ACTUAL_STATE); m_userCommandRequests.push_back(CMD_SHUTDOWN); */ } if (!m_physicsClient.connect()) { b3Warning("Cannot eonnect to physics client"); } } bool RobotControlExample::wantsTermination() { return m_wantsShutdown; } void RobotControlExample::stepSimulation(float deltaTime) { m_physicsServer.processClientCommands(); if (m_physicsClient.isConnected()) { SharedMemoryStatus status; bool hasStatus = m_physicsClient.processServerStatus(status); if ((m_option==ROBOT_PING_PONG_JOINT_FEEDBACK) && hasStatus && status.m_type == CMD_ACTUAL_STATE_UPDATE_COMPLETED) { //update sensor feedback: joint force/torque data and measured joint positions for (int i=0;i0.1) { m_motorTargetState[i].m_velTarget = -1.5; } else { m_motorTargetState[i].m_velTarget = 1.5; } b3Printf("Joint Force (Linear) [%s]=(%f,%f,%f)\n",m_motorTargetState[i].m_jointName.c_str(),m_motorTargetState[i].m_measuredJointForce.x(),m_motorTargetState[i].m_measuredJointForce.y(),m_motorTargetState[i].m_measuredJointForce.z()); b3Printf("Joint Torque (Angular) [%s]=(%f,%f,%f)\n",m_motorTargetState[i].m_jointName.c_str(),m_motorTargetState[i].m_measuredJointTorque.x(),m_motorTargetState[i].m_measuredJointTorque.y(),m_motorTargetState[i].m_measuredJointTorque.z()); } } if (hasStatus && status.m_type == CMD_URDF_LOADING_COMPLETED) { SharedMemoryCommand sensorCommand; sensorCommand.m_type = CMD_CREATE_SENSOR; sensorCommand.m_createSensorArguments.m_numJointSensorChanges = 0; for (int jointIndex=0;jointIndexm_jointName = info.m_jointName; motorInfo->m_velTarget = 0.f; motorInfo->m_posTarget = 0.f; motorInfo->m_uIndex = info.m_uIndex; SliderParams slider(motorName,&motorInfo->m_velTarget); slider.m_minVal=-4; slider.m_maxVal=4; m_guiHelper->getParameterInterface()->registerSliderFloatParameter(slider); m_numMotors++; break; } case ROBOT_PD_CONTROL: { char motorName[1024]; MyMotorInfo* motorInfo = &m_motorTargetState[m_numMotors]; motorInfo->m_jointName = info.m_jointName; motorInfo->m_velTarget = 0.f; motorInfo->m_posTarget = 0.f; motorInfo->m_uIndex = info.m_uIndex; motorInfo->m_posIndex = info.m_qIndex; motorInfo->m_kp = 1; motorInfo->m_kd = 0; { sprintf(motorName,"%s kp", info.m_jointName); SliderParams slider(motorName,&motorInfo->m_kp); slider.m_minVal=0; slider.m_maxVal=1; m_guiHelper->getParameterInterface()->registerSliderFloatParameter(slider); } { sprintf(motorName,"%s q", info.m_jointName); SliderParams slider(motorName,&motorInfo->m_posTarget); slider.m_minVal=-SIMD_PI; slider.m_maxVal=SIMD_PI; m_guiHelper->getParameterInterface()->registerSliderFloatParameter(slider); } { sprintf(motorName,"%s kd", info.m_jointName); SliderParams slider(motorName,&motorInfo->m_kd); slider.m_minVal=0; slider.m_maxVal=1; m_guiHelper->getParameterInterface()->registerSliderFloatParameter(slider); } { sprintf(motorName,"%s q'", info.m_jointName); SliderParams slider(motorName,&motorInfo->m_velTarget); slider.m_minVal=-10; slider.m_maxVal=10; m_guiHelper->getParameterInterface()->registerSliderFloatParameter(slider); } m_numMotors++; break; } case ROBOT_PING_PONG_JOINT_FEEDBACK: { if (info.m_flags & JOINT_HAS_MOTORIZED_POWER) { if (m_numMotorsm_jointName = info.m_jointName; motorInfo->m_velTarget = 0.f; motorInfo->m_posTarget = 0.f; motorInfo->m_uIndex = info.m_uIndex; motorInfo->m_posIndex = info.m_qIndex; motorInfo->m_jointIndex = jointIndex; sensorCommand.m_createSensorArguments.m_sensorType[sensorCommand.m_createSensorArguments.m_numJointSensorChanges] = SENSOR_FORCE_TORQUE; sensorCommand.m_createSensorArguments.m_jointIndex[sensorCommand.m_createSensorArguments.m_numJointSensorChanges] = jointIndex; sensorCommand.m_createSensorArguments.m_enableJointForceSensor[sensorCommand.m_createSensorArguments.m_numJointSensorChanges] = true; sensorCommand.m_createSensorArguments.m_numJointSensorChanges++; m_numMotors++; } } break; } default: { b3Warning("Unknown control mode in RobotControlExample::stepSimulation"); } }; } } } if (sensorCommand.m_createSensorArguments.m_numJointSensorChanges) { enqueueCommand(sensorCommand); } } if (m_physicsClient.canSubmitCommand()) { if (m_userCommandRequests.size()) { if (m_verboseOutput) { b3Printf("Outstanding user command requests: %d\n", m_userCommandRequests.size()); } SharedMemoryCommand cmd = m_userCommandRequests[0]; //a manual 'pop_front', we don't use 'remove' because it will re-order the commands for (int i=1;i=0) { example->setSharedMemoryKey(gSharedMemoryKey); } return example; } #endif