bullet3/examples/Importers/ImportURDFDemo/ImportURDFSetup.cpp

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#include "ImportURDFSetup.h"
#include "BulletDynamics/ConstraintSolver/btGeneric6DofSpring2Constraint.h"
#include "BulletDynamics/Featherstone/btMultiBodyLinkCollider.h"
#include "Bullet3Common/b3FileUtils.h"
#include "BulletDynamics/Featherstone/btMultiBodyJointMotor.h"
#include "BulletDynamics/Featherstone/btMultiBodyDynamicsWorld.h"
#include "../CommonInterfaces/CommonParameterInterface.h"
#include "../../Utils/b3ResourcePath.h"
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#include "BulletUrdfImporter.h"
#include "URDF2Bullet.h"
//#include "urdf_samples.h"
#include "../CommonInterfaces/CommonMultiBodyBase.h"
#include "MyMultiBodyCreator.h"
class ImportUrdfSetup : public CommonMultiBodyBase
{
char m_fileName[1024];
struct ImportUrdfInternalData* m_data;
bool m_useMultiBody;
btAlignedObjectArray<std::string* > m_nameMemory;
public:
ImportUrdfSetup(struct GUIHelperInterface* helper, int option, const char* fileName);
virtual ~ImportUrdfSetup();
virtual void initPhysics();
virtual void stepSimulation(float deltaTime);
void setFileName(const char* urdfFileName);
virtual void resetCamera()
{
float dist = 3.5;
float pitch = -136;
float yaw = 28;
float targetPos[3]={0.47,0,-0.64};
m_guiHelper->resetCamera(dist,pitch,yaw,targetPos[0],targetPos[1],targetPos[2]);
}
};
btAlignedObjectArray<std::string> gFileNameArray;
#define MAX_NUM_MOTORS 1024
struct ImportUrdfInternalData
{
ImportUrdfInternalData()
:m_numMotors(0)
{
for (int i=0;i<MAX_NUM_MOTORS;i++)
{
m_jointMotors[i] = 0;
m_generic6DofJointMotors[i] = 0;
}
}
btScalar m_motorTargetVelocities[MAX_NUM_MOTORS];
btMultiBodyJointMotor* m_jointMotors [MAX_NUM_MOTORS];
btGeneric6DofSpring2Constraint* m_generic6DofJointMotors [MAX_NUM_MOTORS];
int m_numMotors;
};
ImportUrdfSetup::ImportUrdfSetup(struct GUIHelperInterface* helper, int option, const char* fileName)
:CommonMultiBodyBase(helper)
{
m_data = new ImportUrdfInternalData;
if (option==1)
{
m_useMultiBody = true;
} else
{
m_useMultiBody = false;
}
static int count = 0;
if (fileName)
{
setFileName(fileName);
} else
{
gFileNameArray.clear();
//load additional urdf file names from file
FILE* f = fopen("urdf_files.txt","r");
if (f)
{
int result;
//warning: we don't avoid string buffer overflow in this basic example in fscanf
char fileName[1024];
do
{
result = fscanf(f,"%s",fileName);
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b3Printf("urdf_files.txt entry %s",fileName);
if (result==1)
{
gFileNameArray.push_back(fileName);
}
} while (result==1);
fclose(f);
}
if (gFileNameArray.size()==0)
{
gFileNameArray.push_back("r2d2.urdf");
}
int numFileNames = gFileNameArray.size();
if (count>=numFileNames)
{
count=0;
}
sprintf(m_fileName,"%s",gFileNameArray[count++].c_str());
}
}
ImportUrdfSetup::~ImportUrdfSetup()
{
for (int i=0;i<m_nameMemory.size();i++)
{
delete m_nameMemory[i];
}
m_nameMemory.clear();
delete m_data;
}
static btVector4 colors[4] =
{
btVector4(1,0,0,1),
btVector4(0,1,0,1),
btVector4(0,1,1,1),
btVector4(1,1,0,1),
};
static btVector3 selectColor()
{
static int curColor = 0;
btVector4 color = colors[curColor];
curColor++;
curColor&=3;
return color;
}
void ImportUrdfSetup::setFileName(const char* urdfFileName)
{
memcpy(m_fileName,urdfFileName,strlen(urdfFileName)+1);
}
void ImportUrdfSetup::initPhysics()
{
int upAxis = 2;
m_guiHelper->setUpAxis(upAxis);
this->createEmptyDynamicsWorld();
//m_dynamicsWorld->getSolverInfo().m_numIterations = 100;
m_guiHelper->createPhysicsDebugDrawer(m_dynamicsWorld);
m_dynamicsWorld->getDebugDrawer()->setDebugMode(
btIDebugDraw::DBG_DrawConstraints
+btIDebugDraw::DBG_DrawContactPoints
+btIDebugDraw::DBG_DrawAabb
);//+btIDebugDraw::DBG_DrawConstraintLimits);
btVector3 gravity(0,0,0);
gravity[upAxis]=-9.8;
m_dynamicsWorld->setGravity(gravity);
//now print the tree using the new interface
URDFImporterInterface* bla=0;
static bool newURDF = true;
if (newURDF)
{
b3Printf("using new URDF\n");
bla = new BulletURDFImporter(m_guiHelper);
}
URDFImporterInterface& u2b = *bla;
bool loadOk = u2b.loadURDF(m_fileName);
#ifdef TEST_MULTIBODY_SERIALIZATION
//test to serialize a multibody to disk or shared memory, with base, link and joint names
btSerializer* s = new btDefaultSerializer;
#endif //TEST_MULTIBODY_SERIALIZATION
if (loadOk)
{
//printTree(u2b,u2b.getRootLinkIndex());
//u2b.printTree();
btTransform identityTrans;
identityTrans.setIdentity();
{
btMultiBody* mb = 0;
//todo: move these internal API called inside the 'ConvertURDF2Bullet' call, hidden from the user
int rootLinkIndex = u2b.getRootLinkIndex();
b3Printf("urdf root link index = %d\n",rootLinkIndex);
MyMultiBodyCreator creation(m_guiHelper);
ConvertURDF2Bullet(u2b,creation, identityTrans,m_dynamicsWorld,m_useMultiBody,u2b.getPathPrefix());
mb = creation.getBulletMultiBody();
if (m_useMultiBody && mb )
{
std::string* name = new std::string(u2b.getLinkName(u2b.getRootLinkIndex()));
m_nameMemory.push_back(name);
#ifdef TEST_MULTIBODY_SERIALIZATION
s->registerNameForPointer(name->c_str(),name->c_str());
#endif//TEST_MULTIBODY_SERIALIZATION
mb->setBaseName(name->c_str());
//create motors for each btMultiBody joint
int numLinks = mb->getNumLinks();
for (int i=0;i<numLinks;i++)
{
int mbLinkIndex = i;
int urdfLinkIndex = creation.m_mb2urdfLink[mbLinkIndex];
std::string* jointName = new std::string(u2b.getJointName(urdfLinkIndex));
std::string* linkName = new std::string(u2b.getLinkName(urdfLinkIndex).c_str());
#ifdef TEST_MULTIBODY_SERIALIZATION
s->registerNameForPointer(jointName->c_str(),jointName->c_str());
s->registerNameForPointer(linkName->c_str(),linkName->c_str());
#endif//TEST_MULTIBODY_SERIALIZATION
m_nameMemory.push_back(jointName);
m_nameMemory.push_back(linkName);
mb->getLink(i).m_linkName = linkName->c_str();
mb->getLink(i).m_jointName = jointName->c_str();
if (mb->getLink(mbLinkIndex).m_jointType==btMultibodyLink::eRevolute
||mb->getLink(mbLinkIndex).m_jointType==btMultibodyLink::ePrismatic
)
{
if (m_data->m_numMotors<MAX_NUM_MOTORS)
{
char motorName[1024];
sprintf(motorName,"%s q'", jointName->c_str());
btScalar* motorVel = &m_data->m_motorTargetVelocities[m_data->m_numMotors];
*motorVel = 0.f;
SliderParams slider(motorName,motorVel);
slider.m_minVal=-4;
slider.m_maxVal=4;
m_guiHelper->getParameterInterface()->registerSliderFloatParameter(slider);
float maxMotorImpulse = 10.1f;
btMultiBodyJointMotor* motor = new btMultiBodyJointMotor(mb,mbLinkIndex,0,0,maxMotorImpulse);
//motor->setMaxAppliedImpulse(0);
m_data->m_jointMotors[m_data->m_numMotors]=motor;
m_dynamicsWorld->addMultiBodyConstraint(motor);
m_data->m_numMotors++;
}
}
}
} else
{
if (1)
{
//create motors for each generic joint
int num6Dof = creation.getNum6DofConstraints();
for (int i=0;i<num6Dof;i++)
{
btGeneric6DofSpring2Constraint* c = creation.get6DofConstraint(i);
if (c->getUserConstraintPtr())
{
GenericConstraintUserInfo* jointInfo = (GenericConstraintUserInfo*)c->getUserConstraintPtr();
if ((jointInfo->m_urdfJointType ==URDFRevoluteJoint) ||
(jointInfo->m_urdfJointType ==URDFPrismaticJoint) ||
(jointInfo->m_urdfJointType ==URDFContinuousJoint))
{
int urdfLinkIndex = jointInfo->m_urdfIndex;
std::string jointName = u2b.getJointName(urdfLinkIndex);
char motorName[1024];
sprintf(motorName,"%s q'", jointName.c_str());
btScalar* motorVel = &m_data->m_motorTargetVelocities[m_data->m_numMotors];
*motorVel = 0.f;
SliderParams slider(motorName,motorVel);
slider.m_minVal=-4;
slider.m_maxVal=4;
m_guiHelper->getParameterInterface()->registerSliderFloatParameter(slider);
m_data->m_generic6DofJointMotors[m_data->m_numMotors]=c;
bool motorOn = true;
c->enableMotor(jointInfo->m_jointAxisIndex,motorOn);
c->setMaxMotorForce(jointInfo->m_jointAxisIndex,10000);
c->setTargetVelocity(jointInfo->m_jointAxisIndex,0);
m_data->m_numMotors++;
}
}
}
}
}
}
//the btMultiBody support is work-in-progress :-)
for (int i=0;i<m_dynamicsWorld->getNumMultiBodyConstraints();i++)
{
m_dynamicsWorld->getMultiBodyConstraint(i)->finalizeMultiDof();
}
bool createGround=true;
if (createGround)
{
btVector3 groundHalfExtents(20,20,20);
groundHalfExtents[upAxis]=1.f;
btBoxShape* box = new btBoxShape(groundHalfExtents);
box->initializePolyhedralFeatures();
m_guiHelper->createCollisionShapeGraphicsObject(box);
btTransform start; start.setIdentity();
btVector3 groundOrigin(0,0,0);
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groundOrigin[upAxis]=-2.5;
start.setOrigin(groundOrigin);
btRigidBody* body = createRigidBody(0,start,box);
//m_dynamicsWorld->removeRigidBody(body);
// m_dynamicsWorld->addRigidBody(body,2,1);
btVector3 color(0.5,0.5,0.5);
m_guiHelper->createRigidBodyGraphicsObject(body,color);
}
///this extra stepSimulation call makes sure that all the btMultibody transforms are properly propagates.
m_dynamicsWorld->stepSimulation(1. / 240., 0);// 1., 10, 1. / 240.);
}
#ifdef TEST_MULTIBODY_SERIALIZATION
m_dynamicsWorld->serialize(s);
b3ResourcePath p;
char resourcePath[1024];
if (p.findResourcePath("r2d2_multibody.bullet",resourcePath,1024))
{
FILE* f = fopen(resourcePath,"wb");
fwrite(s->getBufferPointer(),s->getCurrentBufferSize(),1,f);
fclose(f);
}
#endif//TEST_MULTIBODY_SERIALIZATION
}
void ImportUrdfSetup::stepSimulation(float deltaTime)
{
if (m_dynamicsWorld)
{
for (int i=0;i<m_data->m_numMotors;i++)
{
if (m_data->m_jointMotors[i])
{
m_data->m_jointMotors[i]->setVelocityTarget(m_data->m_motorTargetVelocities[i]);
}
if (m_data->m_generic6DofJointMotors[i])
{
GenericConstraintUserInfo* jointInfo = (GenericConstraintUserInfo*)m_data->m_generic6DofJointMotors[i]->getUserConstraintPtr();
m_data->m_generic6DofJointMotors[i]->setTargetVelocity(jointInfo->m_jointAxisIndex,m_data->m_motorTargetVelocities[i]);
//jointInfo->
}
}
//the maximal coordinates/iterative MLCP solver requires a smallish timestep to converge
m_dynamicsWorld->stepSimulation(deltaTime,10,1./240.);
}
}
class CommonExampleInterface* ImportURDFCreateFunc(struct CommonExampleOptions& options)
{
return new ImportUrdfSetup(options.m_guiHelper, options.m_option,options.m_fileName);
}