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bullet3/examples/RoboticsLearning/R2D2GraspExample.cpp
Erwin Coumans ecd814c9c5 export contact friction/damping through URDF and API 
convert from contact friction/damping to cfm/erp
btCollisionObject::setContactFrictionAndDamping
2016-09-02 16:40:56 -07:00

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#include "R2D2GraspExample.h"
#include "../CommonInterfaces/CommonGraphicsAppInterface.h"
#include "Bullet3Common/b3Quaternion.h"
#include "Bullet3Common/b3AlignedObjectArray.h"
#include "../CommonInterfaces/CommonRenderInterface.h"
#include "../CommonInterfaces/CommonExampleInterface.h"
#include "../CommonInterfaces/CommonGUIHelperInterface.h"
#include "../SharedMemory/PhysicsServerSharedMemory.h"
#include "../SharedMemory/PhysicsClientC_API.h"
#include <string>
#include "b3RobotSimAPI.h"
#include "../Utils/b3Clock.h"
///quick demo showing the right-handed coordinate system and positive rotations around each axis
class R2D2GraspExample : public CommonExampleInterface
{
CommonGraphicsApp* m_app;
GUIHelperInterface* m_guiHelper;
b3RobotSimAPI m_robotSim;
int m_options;
int m_r2d2Index;
float m_x;
float m_y;
float m_z;
b3AlignedObjectArray<int> m_movingInstances;
enum
{
numCubesX = 20,
numCubesY = 20
};
public:
R2D2GraspExample(GUIHelperInterface* helper, int options)
:m_app(helper->getAppInterface()),
m_guiHelper(helper),
m_options(options),
m_r2d2Index(-1),
m_x(0),
m_y(0),
m_z(0)
{
m_app->setUpAxis(2);
}
virtual ~R2D2GraspExample()
{
m_app->m_renderer->enableBlend(false);
}
virtual void physicsDebugDraw(int debugDrawMode)
{
}
virtual void initPhysics()
{
bool connected = m_robotSim.connect(m_guiHelper);
b3Printf("robotSim connected = %d",connected);
if ((m_options & eROBOTIC_LEARN_GRASP)!=0)
{
{
b3RobotSimLoadFileArgs args("");
args.m_fileName = "r2d2.urdf";
args.m_startPosition.setValue(0,0,.5);
b3RobotSimLoadFileResults results;
if (m_robotSim.loadFile(args, results) && results.m_uniqueObjectIds.size()==1)
{
int m_r2d2Index = results.m_uniqueObjectIds[0];
int numJoints = m_robotSim.getNumJoints(m_r2d2Index);
b3Printf("numJoints = %d",numJoints);
for (int i=0;i<numJoints;i++)
{
b3JointInfo jointInfo;
m_robotSim.getJointInfo(m_r2d2Index,i,&jointInfo);
b3Printf("joint[%d].m_jointName=%s",i,jointInfo.m_jointName);
}
int wheelJointIndices[4]={2,3,6,7};
int wheelTargetVelocities[4]={-10,-10,-10,-10};
for (int i=0;i<4;i++)
{
b3JointMotorArgs controlArgs(CONTROL_MODE_VELOCITY);
controlArgs.m_targetVelocity = wheelTargetVelocities[i];
controlArgs.m_maxTorqueValue = 1e30;
m_robotSim.setJointMotorControl(m_r2d2Index,wheelJointIndices[i],controlArgs);
}
}
}
{
b3RobotSimLoadFileArgs args("");
args.m_fileName = "kiva_shelf/model.sdf";
args.m_forceOverrideFixedBase = true;
args.m_fileType = B3_SDF_FILE;
args.m_startOrientation = b3Quaternion(0,0,0,1);
b3RobotSimLoadFileResults results;
m_robotSim.loadFile(args,results);
}
{
b3RobotSimLoadFileArgs args("");
args.m_fileName = "plane.urdf";
args.m_startPosition.setValue(0,0,0);
args.m_forceOverrideFixedBase = true;
b3RobotSimLoadFileResults results;
m_robotSim.loadFile(args,results);
m_robotSim.setGravity(b3MakeVector3(0,0,-10));
}
}
if ((m_options & eROBOTIC_LEARN_COMPLIANT_CONTACT)!=0)
{
b3RobotSimLoadFileArgs args("");
b3RobotSimLoadFileResults results;
{
args.m_fileName = "cube_soft.urdf";
args.m_startPosition.setValue(0,0,2.5);
args.m_startOrientation.setEulerZYX(0,0.2,0);
m_robotSim.loadFile(args,results);
}
{
args.m_fileName = "cube_no_friction.urdf";
args.m_startPosition.setValue(0,2,2.5);
args.m_startOrientation.setEulerZYX(0,0.2,0);
m_robotSim.loadFile(args,results);
}
{
b3RobotSimLoadFileArgs args("");
args.m_fileName = "plane.urdf";
args.m_startPosition.setValue(0,0,0);
args.m_startOrientation.setEulerZYX(0,0.2,0);
args.m_forceOverrideFixedBase = true;
b3RobotSimLoadFileResults results;
m_robotSim.loadFile(args,results);
m_robotSim.setGravity(b3MakeVector3(0,0,-10));
}
}
if ((m_options & eROBOTIC_LEARN_ROLLING_FRICTION)!=0)
{
b3RobotSimLoadFileArgs args("");
b3RobotSimLoadFileResults results;
{
args.m_fileName = "sphere2_rolling_friction.urdf";
args.m_startPosition.setValue(0,0,2.5);
args.m_startOrientation.setEulerZYX(0,0,0);
args.m_useMultiBody = true;
m_robotSim.loadFile(args,results);
}
{
args.m_fileName = "sphere2.urdf";
args.m_startPosition.setValue(0,2,2.5);
args.m_startOrientation.setEulerZYX(0,0,0);
args.m_useMultiBody = true;
m_robotSim.loadFile(args,results);
}
{
b3RobotSimLoadFileArgs args("");
args.m_fileName = "plane.urdf";
args.m_startPosition.setValue(0,0,0);
args.m_startOrientation.setEulerZYX(0,0.2,0);
args.m_useMultiBody = true;
args.m_forceOverrideFixedBase = true;
b3RobotSimLoadFileResults results;
m_robotSim.loadFile(args,results);
m_robotSim.setGravity(b3MakeVector3(0,0,-10));
}
}
}
virtual void exitPhysics()
{
m_robotSim.disconnect();
}
virtual void stepSimulation(float deltaTime)
{
m_robotSim.stepSimulation();
}
virtual void renderScene()
{
m_robotSim.renderScene();
//m_app->m_renderer->renderScene();
}
virtual void physicsDebugDraw()
{
}
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 resetCamera()
{
float dist = 3;
float pitch = -75;
float yaw = 30;
float targetPos[3]={-0.2,0.8,0.3};
if (m_app->m_renderer && m_app->m_renderer->getActiveCamera())
{
m_app->m_renderer->getActiveCamera()->setCameraDistance(dist);
m_app->m_renderer->getActiveCamera()->setCameraPitch(pitch);
m_app->m_renderer->getActiveCamera()->setCameraYaw(yaw);
m_app->m_renderer->getActiveCamera()->setCameraTargetPosition(targetPos[0],targetPos[1],targetPos[2]);
}
}
};
class CommonExampleInterface* R2D2GraspExampleCreateFunc(struct CommonExampleOptions& options)
{
return new R2D2GraspExample(options.m_guiHelper, options.m_option);
}
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