bullet3/examples/SharedMemory/PhysicsClientC_API.cpp

#include "PhysicsClientC_API.h"
#include "PhysicsClientSharedMemory.h"
#include "Bullet3Common/b3Scalar.h"
#include "Bullet3Common/b3Vector3.h"
#include "Bullet3Common/b3Matrix3x3.h"

#include <string.h>
#include "SharedMemoryCommands.h"


b3SharedMemoryCommandHandle	b3LoadSdfCommandInit(b3PhysicsClientHandle physClient, const char* sdfFileName)
{
	PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    
	struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
	command->m_type = CMD_LOAD_SDF;
	int len = strlen(sdfFileName);
	if (len<MAX_SDF_FILENAME_LENGTH)
	{
		strcpy(command->m_sdfArguments.m_sdfFileName,sdfFileName);
	} else
	{
		command->m_sdfArguments.m_sdfFileName[0] = 0;
	}
	command->m_updateFlags = SDF_ARGS_FILE_NAME;
	
	return (b3SharedMemoryCommandHandle) command;
}

b3SharedMemoryCommandHandle	b3SaveWorldCommandInit(b3PhysicsClientHandle physClient, const char* sdfFileName)
{
	PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    
	struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
	command->m_type = CMD_SAVE_WORLD;
	int len = strlen(sdfFileName);
	if (len<MAX_SDF_FILENAME_LENGTH)
	{
		strcpy(command->m_sdfArguments.m_sdfFileName,sdfFileName);
	} else
	{
		command->m_sdfArguments.m_sdfFileName[0] = 0;
	}
	command->m_updateFlags = SDF_ARGS_FILE_NAME;
	
	return (b3SharedMemoryCommandHandle) command;
}

b3SharedMemoryCommandHandle	b3LoadUrdfCommandInit(b3PhysicsClientHandle physClient, const char* urdfFileName)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    
	if (cl->canSubmitCommand())
	{
		struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
		b3Assert(command);
		command->m_type = CMD_LOAD_URDF;
		int len = strlen(urdfFileName);
		if (len < MAX_URDF_FILENAME_LENGTH)
		{
			strcpy(command->m_urdfArguments.m_urdfFileName, urdfFileName);
		}
		else
		{
			command->m_urdfArguments.m_urdfFileName[0] = 0;
		}
		command->m_updateFlags = URDF_ARGS_FILE_NAME;

		return (b3SharedMemoryCommandHandle)command;
	}
	return 0;
}

b3SharedMemoryCommandHandle	b3LoadBunnyCommandInit(b3PhysicsClientHandle physClient)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    command->m_type = CMD_LOAD_BUNNY;
    command->m_updateFlags = 0;
    
    return (b3SharedMemoryCommandHandle) command;
}

int b3LoadBunnySetScale(b3SharedMemoryCommandHandle commandHandle, double scale)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command->m_type == CMD_LOAD_BUNNY);
    command->m_loadBunnyArguments.m_scale = scale;
    command->m_updateFlags |= LOAD_BUNNY_UPDATE_SCALE;
    return 0;
}

int b3LoadBunnySetMass(b3SharedMemoryCommandHandle commandHandle, double mass)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command->m_type == CMD_LOAD_BUNNY);
    command->m_loadBunnyArguments.m_mass = mass;
    command->m_updateFlags |= LOAD_BUNNY_UPDATE_MASS;
    return 0;
}

int b3LoadBunnySetCollisionMargin(b3SharedMemoryCommandHandle commandHandle, double collisionMargin)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command->m_type == CMD_LOAD_BUNNY);
    command->m_loadBunnyArguments.m_collisionMargin = collisionMargin;
    command->m_updateFlags |= LOAD_BUNNY_UPDATE_COLLISION_MARGIN;
    return 0;
}

int	b3LoadUrdfCommandSetUseMultiBody(b3SharedMemoryCommandHandle commandHandle, int useMultiBody)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_LOAD_URDF);
    command->m_updateFlags |=URDF_ARGS_USE_MULTIBODY;
    command->m_urdfArguments.m_useMultiBody = useMultiBody;
    
    return 0;
}

int	b3LoadSdfCommandSetUseMultiBody(b3SharedMemoryCommandHandle commandHandle, int useMultiBody)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_LOAD_SDF);
    command->m_updateFlags |=URDF_ARGS_USE_MULTIBODY;
    command->m_sdfArguments.m_useMultiBody = useMultiBody;
    
    return 0;
}

int	b3LoadUrdfCommandSetUseFixedBase(b3SharedMemoryCommandHandle commandHandle, int useFixedBase)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_LOAD_URDF);
	if (command && (command->m_type == CMD_LOAD_URDF))
	{
		command->m_updateFlags |= URDF_ARGS_USE_FIXED_BASE;
		command->m_urdfArguments.m_useFixedBase = useFixedBase;
		return 0;
	}
	return -1;
}

int	b3LoadUrdfCommandSetStartPosition(b3SharedMemoryCommandHandle commandHandle, double startPosX,double startPosY,double startPosZ)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
	b3Assert(command);
	if (command)
	{
		b3Assert(command->m_type == CMD_LOAD_URDF);
		if (command->m_type == CMD_LOAD_URDF)
		{
			command->m_urdfArguments.m_initialPosition[0] = startPosX;
			command->m_urdfArguments.m_initialPosition[1] = startPosY;
			command->m_urdfArguments.m_initialPosition[2] = startPosZ;
			command->m_updateFlags |= URDF_ARGS_INITIAL_POSITION;
		}
		return 0;
	}
	return -1;
}

int	b3LoadUrdfCommandSetStartOrientation(b3SharedMemoryCommandHandle commandHandle, double startOrnX,double startOrnY,double startOrnZ, double startOrnW)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
	b3Assert(command);
	if (command)
	{
		b3Assert(command->m_type == CMD_LOAD_URDF);
		if (command->m_type == CMD_LOAD_URDF)
		{
			command->m_urdfArguments.m_initialOrientation[0] = startOrnX;
			command->m_urdfArguments.m_initialOrientation[1] = startOrnY;
			command->m_urdfArguments.m_initialOrientation[2] = startOrnZ;
			command->m_urdfArguments.m_initialOrientation[3] = startOrnW;
			command->m_updateFlags |= URDF_ARGS_INITIAL_ORIENTATION;
		}
		return 0;
	}
	return -1;
}

b3SharedMemoryCommandHandle     b3InitPhysicsParamCommand(b3PhysicsClientHandle physClient)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
	b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
	command->m_type = CMD_SEND_PHYSICS_SIMULATION_PARAMETERS;
	command->m_updateFlags = 0;

    return (b3SharedMemoryCommandHandle) command;
}
int     b3PhysicsParamSetGravity(b3SharedMemoryCommandHandle commandHandle, double gravx,double gravy, double gravz)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
	b3Assert(command->m_type == CMD_SEND_PHYSICS_SIMULATION_PARAMETERS);
	command->m_physSimParamArgs.m_gravityAcceleration[0] = gravx;
	command->m_physSimParamArgs.m_gravityAcceleration[1] = gravy;
	command->m_physSimParamArgs.m_gravityAcceleration[2] = gravz; 
	command->m_updateFlags |= SIM_PARAM_UPDATE_GRAVITY;
	return 0;
}

int     b3PhysicsParamSetRealTimeSimulation(b3SharedMemoryCommandHandle commandHandle, int enableRealTimeSimulation)
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
	b3Assert(command->m_type == CMD_SEND_PHYSICS_SIMULATION_PARAMETERS);
	command->m_physSimParamArgs.m_allowRealTimeSimulation = (enableRealTimeSimulation!=0);
	command->m_updateFlags |= SIM_PARAM_UPDATE_REAL_TIME_SIMULATION;
	return 0;
}

int     b3PhysicsParamSetInternalSimFlags(b3SharedMemoryCommandHandle commandHandle, int flags)
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
	b3Assert(command->m_type == CMD_SEND_PHYSICS_SIMULATION_PARAMETERS);
	command->m_physSimParamArgs.m_internalSimFlags = flags;
	command->m_updateFlags |= SIM_PARAM_UPDATE_INTERNAL_SIMULATION_FLAGS;
	return 0;
}

int b3PhysicsParamSetNumSolverIterations(b3SharedMemoryCommandHandle commandHandle, int numSolverIterations)
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
	b3Assert(command->m_type == CMD_SEND_PHYSICS_SIMULATION_PARAMETERS);
	command->m_physSimParamArgs.m_numSolverIterations = numSolverIterations;
	command->m_updateFlags |= SIM_PARAM_UPDATE_NUM_SOLVER_ITERATIONS;
	return 0;
}

int	b3PhysicsParamSetTimeStep(b3SharedMemoryCommandHandle commandHandle, double timeStep)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
	b3Assert(command->m_type == CMD_SEND_PHYSICS_SIMULATION_PARAMETERS);
	command->m_updateFlags |= SIM_PARAM_UPDATE_DELTA_TIME;	
	command->m_physSimParamArgs.m_deltaTime = timeStep;
	return 0;
}

int	b3PhysicsParamSetNumSubSteps(b3SharedMemoryCommandHandle commandHandle, int numSubSteps)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command->m_type == CMD_SEND_PHYSICS_SIMULATION_PARAMETERS);
    command->m_updateFlags |= SIM_PARAM_UPDATE_NUM_SIMULATION_SUB_STEPS;
    command->m_physSimParamArgs.m_numSimulationSubSteps = numSubSteps;
    return 0;
}


int	b3PhysicsParamSetDefaultContactERP(b3SharedMemoryCommandHandle commandHandle, double defaultContactERP)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command->m_type == CMD_SEND_PHYSICS_SIMULATION_PARAMETERS);
    command->m_updateFlags |= SIM_PARAM_UPDATE_DEFAULT_CONTACT_ERP;
    command->m_physSimParamArgs.m_defaultContactERP = defaultContactERP;
    return 0;
}


int	b3PhysicsParamSetDefaultContactERP(b3SharedMemoryCommandHandle commandHandle, double defaultContactERP);

b3SharedMemoryCommandHandle	b3InitStepSimulationCommand(b3PhysicsClientHandle physClient)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
	command->m_type = CMD_STEP_FORWARD_SIMULATION;
	command->m_updateFlags = 0;
	 return (b3SharedMemoryCommandHandle) command;
}

b3SharedMemoryCommandHandle     b3InitResetSimulationCommand(b3PhysicsClientHandle physClient)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    command->m_type = CMD_RESET_SIMULATION;
    command->m_updateFlags = 0;

     return (b3SharedMemoryCommandHandle) command;

}


b3SharedMemoryCommandHandle  b3JointControlCommandInit(b3PhysicsClientHandle physClient, int controlMode)
{
    return b3JointControlCommandInit2(physClient,0,controlMode);
}

b3SharedMemoryCommandHandle b3JointControlCommandInit2( b3PhysicsClientHandle physClient, int bodyUniqueId, int controlMode)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
	command->m_type = CMD_SEND_DESIRED_STATE;
    command->m_sendDesiredStateCommandArgument.m_controlMode = controlMode;
	command->m_sendDesiredStateCommandArgument.m_bodyUniqueId = bodyUniqueId;
	command->m_updateFlags = 0;
    for (int i=0;i<MAX_DEGREE_OF_FREEDOM;i++)
    {
        command->m_sendDesiredStateCommandArgument.m_hasDesiredStateFlags[i] = 0;
    }
    return (b3SharedMemoryCommandHandle) command;
}

int b3JointControlSetDesiredPosition(b3SharedMemoryCommandHandle commandHandle, int qIndex, double value)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    command->m_sendDesiredStateCommandArgument.m_desiredStateQ[qIndex] = value;
	command->m_updateFlags |= SIM_DESIRED_STATE_HAS_Q;
    command->m_sendDesiredStateCommandArgument.m_hasDesiredStateFlags[qIndex] |= SIM_DESIRED_STATE_HAS_Q;

    return 0;
}

int b3JointControlSetKp(b3SharedMemoryCommandHandle commandHandle, int dofIndex, double value)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    command->m_sendDesiredStateCommandArgument.m_Kp[dofIndex] = value;
	command->m_updateFlags |= SIM_DESIRED_STATE_HAS_KP;
    command->m_sendDesiredStateCommandArgument.m_hasDesiredStateFlags[dofIndex] |= SIM_DESIRED_STATE_HAS_KP;

    return 0;
}

int b3JointControlSetKd(b3SharedMemoryCommandHandle commandHandle, int dofIndex, double value)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    command->m_sendDesiredStateCommandArgument.m_Kd[dofIndex] = value;
	command->m_updateFlags |= SIM_DESIRED_STATE_HAS_KD;
    command->m_sendDesiredStateCommandArgument.m_hasDesiredStateFlags[dofIndex] |= SIM_DESIRED_STATE_HAS_KD;

    return 0;
}

int b3JointControlSetDesiredVelocity(b3SharedMemoryCommandHandle commandHandle, int dofIndex, double value)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    command->m_sendDesiredStateCommandArgument.m_desiredStateQdot[dofIndex] = value;
	command->m_updateFlags |= SIM_DESIRED_STATE_HAS_QDOT;
    command->m_sendDesiredStateCommandArgument.m_hasDesiredStateFlags[dofIndex] |= SIM_DESIRED_STATE_HAS_QDOT;

    return 0;
}


int b3JointControlSetMaximumForce(b3SharedMemoryCommandHandle commandHandle, int dofIndex,  double value)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    command->m_sendDesiredStateCommandArgument.m_desiredStateForceTorque[dofIndex] = value;
	command->m_updateFlags |= SIM_DESIRED_STATE_HAS_MAX_FORCE;
    command->m_sendDesiredStateCommandArgument.m_hasDesiredStateFlags[dofIndex] |= SIM_DESIRED_STATE_HAS_MAX_FORCE;

    return 0;
}

int b3JointControlSetDesiredForceTorque(b3SharedMemoryCommandHandle commandHandle, int  dofIndex, double value)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    command->m_sendDesiredStateCommandArgument.m_desiredStateForceTorque[dofIndex] = value;
    command->m_updateFlags |= SIM_DESIRED_STATE_HAS_MAX_FORCE;
    command->m_sendDesiredStateCommandArgument.m_hasDesiredStateFlags[dofIndex] |= SIM_DESIRED_STATE_HAS_MAX_FORCE;

    return 0;
}


b3SharedMemoryCommandHandle b3RequestActualStateCommandInit(b3PhysicsClientHandle physClient, int bodyUniqueId)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    command->m_type =CMD_REQUEST_ACTUAL_STATE;
	command->m_requestActualStateInformationCommandArgument.m_bodyUniqueId = bodyUniqueId;
    return (b3SharedMemoryCommandHandle) command;
}

void b3GetJointState(b3PhysicsClientHandle physClient, b3SharedMemoryStatusHandle statusHandle, int jointIndex, b3JointSensorState *state)
{
  const SharedMemoryStatus* status = (const SharedMemoryStatus* ) statusHandle;
  b3Assert(status);
  int bodyIndex = status->m_sendActualStateArgs.m_bodyUniqueId;
  b3Assert(bodyIndex>=0);
  if (bodyIndex>=0)
  {
	  b3JointInfo info;
	  b3GetJointInfo(physClient, bodyIndex,jointIndex, &info);
	  state->m_jointPosition = status->m_sendActualStateArgs.m_actualStateQ[info.m_qIndex];
	  state->m_jointVelocity = status->m_sendActualStateArgs.m_actualStateQdot[info.m_uIndex];
	  for (int ii(0); ii < 6; ++ii) {
		state->m_jointForceTorque[ii] = status->m_sendActualStateArgs.m_jointReactionForces[6 * jointIndex + ii];
	  }
      state->m_jointMotorTorque = status->m_sendActualStateArgs.m_jointMotorForce[jointIndex];
  }
}

void b3GetLinkState(b3PhysicsClientHandle physClient, b3SharedMemoryStatusHandle statusHandle, int linkIndex, b3LinkState *state)
{
  const SharedMemoryStatus* status = (const SharedMemoryStatus* ) statusHandle;
  b3Assert(status);
  int bodyIndex = status->m_sendActualStateArgs.m_bodyUniqueId;
  b3Assert(bodyIndex>=0);
  if (bodyIndex>=0)
  {
    for (int i = 0; i < 3; ++i) 
    {
      state->m_worldPosition[i] = status->m_sendActualStateArgs.m_linkState[7 * linkIndex + i];
      state->m_localInertialPosition[i] = status->m_sendActualStateArgs.m_linkLocalInertialFrames[7 * linkIndex + i];
    }
    for (int i = 0; i < 4; ++i) 
    {
      state->m_worldOrientation[i] = status->m_sendActualStateArgs.m_linkState[7 * linkIndex + 3 + i];
      state->m_localInertialOrientation[i] = status->m_sendActualStateArgs.m_linkLocalInertialFrames[7 * linkIndex + 3 + i];
    }
  }
}

b3SharedMemoryCommandHandle b3CreateBoxShapeCommandInit(b3PhysicsClientHandle physClient)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    command->m_type = CMD_CREATE_BOX_COLLISION_SHAPE;
    command->m_updateFlags =0;
    return (b3SharedMemoryCommandHandle) command;
}

int	b3CreateBoxCommandSetStartPosition(b3SharedMemoryCommandHandle commandHandle, double startPosX,double startPosY,double startPosZ)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_CREATE_BOX_COLLISION_SHAPE);
    command->m_updateFlags |=BOX_SHAPE_HAS_INITIAL_POSITION;
    
    command->m_createBoxShapeArguments.m_initialPosition[0] = startPosX;
    command->m_createBoxShapeArguments.m_initialPosition[1] = startPosY;
    command->m_createBoxShapeArguments.m_initialPosition[2] = startPosZ;
    return 0;
}


int	b3CreateBoxCommandSetHalfExtents(b3SharedMemoryCommandHandle commandHandle, double halfExtentsX,double halfExtentsY,double halfExtentsZ)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_CREATE_BOX_COLLISION_SHAPE);
    command->m_updateFlags |=BOX_SHAPE_HAS_HALF_EXTENTS;
    
    command->m_createBoxShapeArguments.m_halfExtentsX = halfExtentsX;
    command->m_createBoxShapeArguments.m_halfExtentsY = halfExtentsY;
    command->m_createBoxShapeArguments.m_halfExtentsZ = halfExtentsZ;

    return 0;
}


int	b3CreateBoxCommandSetMass(b3SharedMemoryCommandHandle commandHandle, double mass)
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_CREATE_BOX_COLLISION_SHAPE);
	command->m_updateFlags |=BOX_SHAPE_HAS_MASS;
	command->m_createBoxShapeArguments.m_mass = mass;
	return 0;
}


int	b3CreateBoxCommandSetCollisionShapeType(b3SharedMemoryCommandHandle commandHandle, int collisionShapeType)
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_CREATE_BOX_COLLISION_SHAPE);
	command->m_updateFlags |=BOX_SHAPE_HAS_COLLISION_SHAPE_TYPE;
	command->m_createBoxShapeArguments.m_collisionShapeType = collisionShapeType;

	return 0;
}

int	b3CreateBoxCommandSetColorRGBA(b3SharedMemoryCommandHandle commandHandle, double red,double green,double blue, double alpha)
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_CREATE_BOX_COLLISION_SHAPE);
	command->m_updateFlags |=BOX_SHAPE_HAS_COLOR;
	command->m_createBoxShapeArguments.m_colorRGBA[0] = red;
	command->m_createBoxShapeArguments.m_colorRGBA[1] = green;
	command->m_createBoxShapeArguments.m_colorRGBA[2] = blue;
	command->m_createBoxShapeArguments.m_colorRGBA[3] = alpha;
	return 0;
}

int	b3CreateBoxCommandSetStartOrientation(b3SharedMemoryCommandHandle commandHandle, double startOrnX,double startOrnY,double startOrnZ, double startOrnW)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_CREATE_BOX_COLLISION_SHAPE);
    command->m_updateFlags |=BOX_SHAPE_HAS_INITIAL_ORIENTATION;
    
    command->m_createBoxShapeArguments.m_initialOrientation[0] = startOrnX;
    command->m_createBoxShapeArguments.m_initialOrientation[1] = startOrnY;
    command->m_createBoxShapeArguments.m_initialOrientation[2] = startOrnZ;
    command->m_createBoxShapeArguments.m_initialOrientation[3] = startOrnW;
    return 0;
}

b3SharedMemoryCommandHandle b3CreatePoseCommandInit(b3PhysicsClientHandle physClient, int bodyIndex)
{
    
	PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    command->m_type = CMD_INIT_POSE;
    command->m_updateFlags =0;
	command->m_initPoseArgs.m_bodyUniqueId = bodyIndex;
	//a bit slow, initialing the full range to zero...
	for (int i=0;i<MAX_DEGREE_OF_FREEDOM;i++)
    {
        command->m_initPoseArgs.m_hasInitialStateQ[i] = 0;
    }
    return (b3SharedMemoryCommandHandle) command;
}

int	b3CreatePoseCommandSetBasePosition(b3SharedMemoryCommandHandle commandHandle, double startPosX,double startPosY,double startPosZ)
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_INIT_POSE);
    command->m_updateFlags |=INIT_POSE_HAS_INITIAL_POSITION;
	command->m_initPoseArgs.m_initialStateQ[0] = startPosX;
	command->m_initPoseArgs.m_initialStateQ[1] = startPosY;
	command->m_initPoseArgs.m_initialStateQ[2] = startPosZ;
	
	command->m_initPoseArgs.m_hasInitialStateQ[0] = 1;
	command->m_initPoseArgs.m_hasInitialStateQ[1] = 1;
	command->m_initPoseArgs.m_hasInitialStateQ[2] = 1;
	
	return 0;
}

int	b3CreatePoseCommandSetBaseOrientation(b3SharedMemoryCommandHandle commandHandle, double startOrnX,double startOrnY,double startOrnZ, double startOrnW)
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_INIT_POSE);
    command->m_updateFlags |=INIT_POSE_HAS_INITIAL_ORIENTATION;
	command->m_initPoseArgs.m_initialStateQ[3] = startOrnX;
	command->m_initPoseArgs.m_initialStateQ[4] = startOrnY;
	command->m_initPoseArgs.m_initialStateQ[5] = startOrnZ;
	command->m_initPoseArgs.m_initialStateQ[6] = startOrnW;
	
	command->m_initPoseArgs.m_hasInitialStateQ[3] = 1;
	command->m_initPoseArgs.m_hasInitialStateQ[4] = 1;
	command->m_initPoseArgs.m_hasInitialStateQ[5] = 1;
	command->m_initPoseArgs.m_hasInitialStateQ[6] = 1;
	
	return 0;
}

int	b3CreatePoseCommandSetJointPositions(b3SharedMemoryCommandHandle commandHandle, int numJointPositions, const double* jointPositions)
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_INIT_POSE);
    command->m_updateFlags |=INIT_POSE_HAS_JOINT_STATE;
	for (int i=0;i<numJointPositions;i++)
	{
		command->m_initPoseArgs.m_initialStateQ[i+7] = jointPositions[i];
		command->m_initPoseArgs.m_hasInitialStateQ[i+7] = 1;
	}
	return 0;
}

int	b3CreatePoseCommandSetJointPosition(b3PhysicsClientHandle physClient, b3SharedMemoryCommandHandle commandHandle, int jointIndex, double jointPosition)
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
	b3Assert(command);
	b3Assert(command->m_type == CMD_INIT_POSE);
	command->m_updateFlags |=INIT_POSE_HAS_JOINT_STATE;
	b3JointInfo info;
	b3GetJointInfo(physClient, command->m_initPoseArgs.m_bodyUniqueId,jointIndex, &info);
	btAssert((info.m_flags & JOINT_HAS_MOTORIZED_POWER) && info.m_qIndex >=0);
	if ((info.m_flags & JOINT_HAS_MOTORIZED_POWER) && info.m_qIndex >=0)
	{  
		command->m_initPoseArgs.m_initialStateQ[info.m_qIndex] = jointPosition;
		command->m_initPoseArgs.m_hasInitialStateQ[info.m_qIndex] = 1;
	}
	return 0;
}




b3SharedMemoryCommandHandle b3CreateSensorCommandInit(b3PhysicsClientHandle physClient, int bodyUniqueId)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    
    command->m_type = CMD_CREATE_SENSOR;
    command->m_updateFlags = 0;
    command->m_createSensorArguments.m_numJointSensorChanges = 0;
	command->m_createSensorArguments.m_bodyUniqueId = bodyUniqueId;
    return (b3SharedMemoryCommandHandle) command;
    
}

int b3CreateSensorEnable6DofJointForceTorqueSensor(b3SharedMemoryCommandHandle commandHandle, int jointIndex, int enable)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_CREATE_SENSOR);
    int curIndex = command->m_createSensorArguments.m_numJointSensorChanges;
    command->m_createSensorArguments.m_sensorType[curIndex] = SENSOR_FORCE_TORQUE;
    
    command->m_createSensorArguments.m_jointIndex[curIndex] = jointIndex;
    command->m_createSensorArguments.m_enableJointForceSensor[curIndex] = enable;
    command->m_createSensorArguments.m_numJointSensorChanges++;
    return 0;
}

int b3CreateSensorEnableIMUForLink(b3SharedMemoryCommandHandle commandHandle, int linkIndex, int enable)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_CREATE_SENSOR);
    int curIndex = command->m_createSensorArguments.m_numJointSensorChanges;
    command->m_createSensorArguments.m_sensorType[curIndex] = SENSOR_IMU;
    command->m_createSensorArguments.m_linkIndex[curIndex] = linkIndex;
    command->m_createSensorArguments.m_enableSensor[curIndex] = enable;
    command->m_createSensorArguments.m_numJointSensorChanges++;
	return 0;    
}



void	b3DisconnectSharedMemory(b3PhysicsClientHandle physClient)
{
	PhysicsClient* cl = (PhysicsClient* ) physClient;
	cl->disconnectSharedMemory();
	delete cl;
}

b3SharedMemoryStatusHandle b3ProcessServerStatus(b3PhysicsClientHandle physClient)
{
	PhysicsClient* cl = (PhysicsClient* ) physClient;
	if (cl && cl->isConnected())
	{
		const SharedMemoryStatus* stat = cl->processServerStatus();
		return (b3SharedMemoryStatusHandle) stat;
	}
	return 0;
}




int b3GetStatusType(b3SharedMemoryStatusHandle statusHandle)
{
    const SharedMemoryStatus* status = (const SharedMemoryStatus* ) statusHandle;
    b3Assert(status);
    if (status)
    {
        return status->m_type;
    }
    return CMD_INVALID_STATUS;
}

int b3GetStatusBodyIndices(b3SharedMemoryStatusHandle statusHandle, int* bodyIndicesOut, int bodyIndicesCapacity)
{
    int numBodies = 0;
    const SharedMemoryStatus* status = (const SharedMemoryStatus* ) statusHandle;
    b3Assert(status);
	
	if (status)
	{
			switch (status->m_type)
			{
				case CMD_SDF_LOADING_COMPLETED:
				{
				    int i,maxBodies;
				    numBodies = status->m_sdfLoadedArgs.m_numBodies;
				    maxBodies = btMin(bodyIndicesCapacity, numBodies);
				    for (i=0;i<maxBodies;i++)
				    {
                            bodyIndicesOut[i] = status->m_sdfLoadedArgs.m_bodyUniqueIds[i];
				    }
					break;
				}
			}
	}
	
	return numBodies;
}

int b3GetStatusBodyIndex(b3SharedMemoryStatusHandle statusHandle)
{
	const SharedMemoryStatus* status = (const SharedMemoryStatus* ) statusHandle;
    b3Assert(status);
	int bodyId = -1;

	if (status)
	{
			switch (status->m_type)
			{
				case CMD_URDF_LOADING_COMPLETED:
				{
					bodyId = status->m_dataStreamArguments.m_bodyUniqueId;
					break;
				}
				case CMD_RIGID_BODY_CREATION_COMPLETED:
				{
					bodyId = status->m_rigidBodyCreateArgs.m_bodyUniqueId;
					break;
				}
				default:
				{
					b3Assert(0);
				}
			};
	}
	return bodyId;
}


int b3GetStatusActualState(b3SharedMemoryStatusHandle statusHandle,
                           int* bodyUniqueId,
                           int* numDegreeOfFreedomQ,
                           int* numDegreeOfFreedomU,
                           const double* rootLocalInertialFrame[],
                           const double* actualStateQ[],
                           const double* actualStateQdot[],
                           const double* jointReactionForces[]) {
    const SharedMemoryStatus* status = (const SharedMemoryStatus* ) statusHandle;
    const SendActualStateArgs &args = status->m_sendActualStateArgs;
    btAssert(status->m_type == CMD_ACTUAL_STATE_UPDATE_COMPLETED);
    if (status->m_type != CMD_ACTUAL_STATE_UPDATE_COMPLETED)
        return false;
    
    if (bodyUniqueId) {
        *bodyUniqueId = args.m_bodyUniqueId;
    }
    if (numDegreeOfFreedomQ) {
        *numDegreeOfFreedomQ = args.m_numDegreeOfFreedomQ;
    }
    if (numDegreeOfFreedomU) {
        *numDegreeOfFreedomU = args.m_numDegreeOfFreedomU;
    }
    if (rootLocalInertialFrame) {
        *rootLocalInertialFrame = args.m_rootLocalInertialFrame;
    }
    if (actualStateQ) {
        *actualStateQ = args.m_actualStateQ;
    }
    if (actualStateQdot) {
        *actualStateQdot = args.m_actualStateQdot;
    }
    if (jointReactionForces) {
        *jointReactionForces = args.m_jointReactionForces;
    }
    return true;
}

int	b3CanSubmitCommand(b3PhysicsClientHandle physClient)
{
	PhysicsClient* cl = (PhysicsClient* ) physClient;
	if (cl)
	{
		return (int)cl->canSubmitCommand();
	}
	return false;
}

int	b3SubmitClientCommand(b3PhysicsClientHandle physClient, const b3SharedMemoryCommandHandle commandHandle)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    PhysicsClient* cl = (PhysicsClient* ) physClient;
	b3Assert(command);
	b3Assert(cl);
	if (command && cl)
	{
		return (int)cl->submitClientCommand(*command);
	}
	return -1;

}

b3SharedMemoryStatusHandle b3SubmitClientCommandAndWaitStatus(b3PhysicsClientHandle physClient, const b3SharedMemoryCommandHandle commandHandle)
{
	int timeout = 1024 * 1024 * 1024;
	b3SharedMemoryStatusHandle statusHandle = 0;
	b3Assert(commandHandle);
	b3Assert(physClient);
	if (physClient && commandHandle)
	{
		b3SubmitClientCommand(physClient, commandHandle);

		while ((statusHandle == 0) && (timeout-- > 0))
		{
			statusHandle = b3ProcessServerStatus(physClient);
		}
		return (b3SharedMemoryStatusHandle)statusHandle;
	}

	return 0;
}


///return the total number of bodies in the simulation
int	b3GetNumBodies(b3PhysicsClientHandle physClient)
{
	PhysicsClient* cl = (PhysicsClient* ) physClient;
	return cl->getNumBodies();
}

/// return the body unique id, given the index in range [0 , b3GetNumBodies() )
int b3GetBodyUniqueId(b3PhysicsClientHandle physClient, int serialIndex)
{
	PhysicsClient* cl = (PhysicsClient* ) physClient;
	return cl->getBodyUniqueId(serialIndex);
}

///given a body unique id, return the body information. See b3BodyInfo in SharedMemoryPublic.h
int b3GetBodyInfo(b3PhysicsClientHandle physClient, int bodyUniqueId, struct b3BodyInfo* info)
{
	PhysicsClient* cl = (PhysicsClient* ) physClient;
	return cl->getBodyInfo(bodyUniqueId,*info);
}



int	b3GetNumJoints(b3PhysicsClientHandle physClient, int bodyId)
{
	PhysicsClient* cl = (PhysicsClient* ) physClient;
	return cl->getNumJoints(bodyId);
}


int	b3GetJointInfo(b3PhysicsClientHandle physClient, int bodyIndex, int jointIndex, struct b3JointInfo* info)
{
	PhysicsClient* cl = (PhysicsClient* ) physClient;
	return cl->getJointInfo(bodyIndex, jointIndex, *info);
}

b3SharedMemoryCommandHandle b3CreateJoint(b3PhysicsClientHandle physClient, int parentBodyIndex, int parentJointIndex, int childBodyIndex, int childJointIndex, struct b3JointInfo* info)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    
    command->m_type = CMD_CREATE_JOINT;
    command->m_createJointArguments.m_parentBodyIndex = parentBodyIndex;
    command->m_createJointArguments.m_parentJointIndex = parentJointIndex;
    command->m_createJointArguments.m_childBodyIndex = childBodyIndex;
    command->m_createJointArguments.m_childJointIndex = childJointIndex;
    for (int i = 0; i < 7; ++i) {
        command->m_createJointArguments.m_parentFrame[i] = info->m_parentFrame[i];
        command->m_createJointArguments.m_childFrame[i] = info->m_childFrame[i];
    }
    for (int i = 0; i < 3; ++i) {
        command->m_createJointArguments.m_jointAxis[i] = info->m_jointAxis[i];
    }
    command->m_createJointArguments.m_jointType = info->m_jointType;
    return (b3SharedMemoryCommandHandle)command;
}

b3SharedMemoryCommandHandle b3PickBody(b3PhysicsClientHandle physClient, double rayFromWorldX,
                                       double rayFromWorldY, double rayFromWorldZ,
                                       double rayToWorldX, double rayToWorldY, double rayToWorldZ)
{
    PhysicsClient *cl = (PhysicsClient *)physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand *command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    command->m_type = CMD_PICK_BODY;
    command->m_pickBodyArguments.m_rayFromWorld[0] = rayFromWorldX;
    command->m_pickBodyArguments.m_rayFromWorld[1] = rayFromWorldY;
    command->m_pickBodyArguments.m_rayFromWorld[2] = rayFromWorldZ;
    command->m_pickBodyArguments.m_rayToWorld[0] = rayToWorldX;
    command->m_pickBodyArguments.m_rayToWorld[1] = rayToWorldY;
    command->m_pickBodyArguments.m_rayToWorld[2] = rayToWorldZ;
    return (b3SharedMemoryCommandHandle)command;
}

b3SharedMemoryCommandHandle b3MovePickedBody(b3PhysicsClientHandle physClient, double rayFromWorldX,
                                             double rayFromWorldY, double rayFromWorldZ,
                                             double rayToWorldX, double rayToWorldY,
                                             double rayToWorldZ)
{
    PhysicsClient *cl = (PhysicsClient *)physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand *command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    command->m_type = CMD_MOVE_PICKED_BODY;
    command->m_pickBodyArguments.m_rayFromWorld[0] = rayFromWorldX;
    command->m_pickBodyArguments.m_rayFromWorld[1] = rayFromWorldY;
    command->m_pickBodyArguments.m_rayFromWorld[2] = rayFromWorldZ;
    command->m_pickBodyArguments.m_rayToWorld[0] = rayToWorldX;
    command->m_pickBodyArguments.m_rayToWorld[1] = rayToWorldY;
    command->m_pickBodyArguments.m_rayToWorld[2] = rayToWorldZ;
    return (b3SharedMemoryCommandHandle)command;
}

b3SharedMemoryCommandHandle b3RemovePickingConstraint(b3PhysicsClientHandle physClient)
{
    PhysicsClient *cl = (PhysicsClient *)physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand *command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    command->m_type = CMD_REMOVE_PICKING_CONSTRAINT_BODY;
    return (b3SharedMemoryCommandHandle)command;
}

b3SharedMemoryCommandHandle b3InitRequestDebugLinesCommand(b3PhysicsClientHandle physClient, int debugMode)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    
    command->m_type =CMD_REQUEST_DEBUG_LINES;
    command->m_requestDebugLinesArguments.m_debugMode = debugMode;
    command->m_requestDebugLinesArguments.m_startingLineIndex = 0;
    return (b3SharedMemoryCommandHandle) command;
}
void    b3GetDebugLines(b3PhysicsClientHandle physClient, struct b3DebugLines* lines)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;

    b3Assert(lines);
    if (lines)
    {
        lines->m_numDebugLines = cl->getNumDebugLines();
        lines->m_linesFrom = cl->getDebugLinesFrom();
        lines->m_linesTo = cl->getDebugLinesTo();
        lines->m_linesColor = cl->getDebugLinesColor();
        
    }
    
}

///request an image from a simulated camera, using a software renderer.
b3SharedMemoryCommandHandle b3InitRequestCameraImage(b3PhysicsClientHandle physClient)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    command->m_type =CMD_REQUEST_CAMERA_IMAGE_DATA;
	command->m_requestPixelDataArguments.m_startPixelIndex = 0;
    command->m_updateFlags = 0;//REQUEST_PIXEL_ARGS_USE_HARDWARE_OPENGL;
    return (b3SharedMemoryCommandHandle) command;
}

void b3RequestCameraImageSelectRenderer(b3SharedMemoryCommandHandle commandHandle, int renderer)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_REQUEST_CAMERA_IMAGE_DATA);
    b3Assert(renderer>(1<<15));
    command->m_updateFlags |= renderer;
}

void b3RequestCameraImageSetCameraMatrices(b3SharedMemoryCommandHandle commandHandle, float viewMatrix[16], float projectionMatrix[16])
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_REQUEST_CAMERA_IMAGE_DATA);
	for (int i=0;i<16;i++)
	{
		command->m_requestPixelDataArguments.m_projectionMatrix[i] = projectionMatrix[i];
		command->m_requestPixelDataArguments.m_viewMatrix[i] = viewMatrix[i];
	}
	command->m_updateFlags |= REQUEST_PIXEL_ARGS_HAS_CAMERA_MATRICES;
}

void b3RequestCameraImageSetViewMatrix2(b3SharedMemoryCommandHandle commandHandle, const float cameraTargetPosition[3], float distance, float yaw, float pitch, float roll, int upAxis)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_REQUEST_CAMERA_IMAGE_DATA);
    b3Vector3 camUpVector;
    b3Vector3 camForward;
    b3Vector3 camPos;
    b3Vector3 camTargetPos = b3MakeVector3(cameraTargetPosition[0],cameraTargetPosition[1],cameraTargetPosition[2]);
    b3Vector3 eyePos = b3MakeVector3(0,0,0);
        
	int forwardAxis(-1);
	
	{
	
	switch (upAxis)
	{
	    
        case 1:
            {
                
            
            forwardAxis = 0;
            eyePos[forwardAxis] = -distance;
            camForward = b3MakeVector3(eyePos[0],eyePos[1],eyePos[2]);
            if (camForward.length2() < B3_EPSILON)
            {
                camForward.setValue(1.f,0.f,0.f);
            } else
            {
                camForward.normalize();
            }
              b3Scalar rollRad = roll * b3Scalar(0.01745329251994329547);
            b3Quaternion rollRot(camForward,rollRad);
            
            camUpVector = b3QuatRotate(rollRot,b3MakeVector3(0,1,0));
            //gLightPos = b3MakeVector3(-50.f,100,30);
            break;
            }
        case 2:
            {
                
            
            forwardAxis = 1;
            eyePos[forwardAxis] = -distance;
            camForward = b3MakeVector3(eyePos[0],eyePos[1],eyePos[2]);
            if (camForward.length2() < B3_EPSILON)
            {
                camForward.setValue(1.f,0.f,0.f);
            } else
            {
                camForward.normalize();
            }
            
            b3Scalar rollRad = roll * b3Scalar(0.01745329251994329547);
            b3Quaternion rollRot(camForward,rollRad);
            
            camUpVector = b3QuatRotate(rollRot,b3MakeVector3(0,0,1));
            //gLightPos = b3MakeVector3(-50.f,30,100);
            break;
            }
        default:
            {
                //b3Assert(0);
                return;
            }
        };
	}
	

	b3Scalar yawRad = yaw * b3Scalar(0.01745329251994329547);// rads per deg
	b3Scalar pitchRad = pitch * b3Scalar(0.01745329251994329547);// rads per deg

	b3Quaternion pitchRot(camUpVector,pitchRad);
	
	b3Vector3 right = camUpVector.cross(camForward);
	b3Quaternion yawRot(right,-yawRad);
	
	

	eyePos = b3Matrix3x3(pitchRot) * b3Matrix3x3(yawRot) * eyePos;
	camPos = eyePos;
	camPos += camTargetPos;
	
    float camPosf[4] = {camPos[0],camPos[1],camPos[2],0};
    float camPosTargetf[4] = {camTargetPos[0],camTargetPos[1],camTargetPos[2],0};
    float camUpf[4] = {camUpVector[0],camUpVector[1],camUpVector[2],0};
    
    b3RequestCameraImageSetViewMatrix(commandHandle,camPosf,camPosTargetf,camUpf);
    
}
void b3RequestCameraImageSetViewMatrix(b3SharedMemoryCommandHandle commandHandle, const float cameraPosition[3], const float cameraTargetPosition[3], const float cameraUp[3])
{
    b3Vector3 eye = b3MakeVector3(cameraPosition[0], cameraPosition[1], cameraPosition[2]);
    b3Vector3 center = b3MakeVector3(cameraTargetPosition[0], cameraTargetPosition[1], cameraTargetPosition[2]);
    b3Vector3 up = b3MakeVector3(cameraUp[0], cameraUp[1], cameraUp[2]);
    b3Vector3 f = (center - eye).normalized();
    b3Vector3 u = up.normalized();
    b3Vector3 s = (f.cross(u)).normalized();
    u = s.cross(f);
    
    float viewMatrix[16];
    
    viewMatrix[0*4+0] = s.x;
    viewMatrix[1*4+0] = s.y;
    viewMatrix[2*4+0] = s.z;
    
    viewMatrix[0*4+1] = u.x;
    viewMatrix[1*4+1] = u.y;
    viewMatrix[2*4+1] = u.z;
    
    viewMatrix[0*4+2] =-f.x;
    viewMatrix[1*4+2] =-f.y;
    viewMatrix[2*4+2] =-f.z;
    
    viewMatrix[0*4+3] = 0.f;
    viewMatrix[1*4+3] = 0.f;
    viewMatrix[2*4+3] = 0.f;
    
    viewMatrix[3*4+0] = -s.dot(eye);
    viewMatrix[3*4+1] = -u.dot(eye);
    viewMatrix[3*4+2] = f.dot(eye);
    viewMatrix[3*4+3] = 1.f;
    
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_REQUEST_CAMERA_IMAGE_DATA);
    for (int i=0;i<16;i++)
    {
        command->m_requestPixelDataArguments.m_viewMatrix[i] = viewMatrix[i];
    }
    command->m_updateFlags |= REQUEST_PIXEL_ARGS_HAS_CAMERA_MATRICES;

}

void b3RequestCameraImageSetProjectionMatrix(b3SharedMemoryCommandHandle commandHandle, float left, float  right, float bottom, float top, float nearVal, float farVal)
{
    float frustum[16];
    
    frustum[0*4+0] = (float(2) * nearVal) / (right - left);
    frustum[0*4+1] = float(0);
    frustum[0*4+2] = float(0);
    frustum[0*4+3] = float(0);
    
    frustum[1*4+0] = float(0);
    frustum[1*4+1] = (float(2) * nearVal) / (top - bottom);
    frustum[1*4+2] = float(0);
    frustum[1*4+3] = float(0);
    
    frustum[2*4+0] = (right + left) / (right - left);
    frustum[2*4+1] = (top + bottom) / (top - bottom);
    frustum[2*4+2] = -(farVal + nearVal) / (farVal - nearVal);
    frustum[2*4+3] = float(-1);
    
    frustum[3*4+0] = float(0);
    frustum[3*4+1] = float(0);
    frustum[3*4+2] = -(float(2) * farVal * nearVal) / (farVal - nearVal);
    frustum[3*4+3] = float(0);
    
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_REQUEST_CAMERA_IMAGE_DATA);
    for (int i=0;i<16;i++)
    {
        command->m_requestPixelDataArguments.m_projectionMatrix[i] = frustum[i];
    }
    command->m_updateFlags |= REQUEST_PIXEL_ARGS_HAS_CAMERA_MATRICES;
}

void b3RequestCameraImageSetFOVProjectionMatrix(b3SharedMemoryCommandHandle commandHandle, float fov, float aspect, float nearVal, float farVal)
{
  float yScale = 1.0 / tan((3.141592538 / 180.0) * fov / 2);
  float xScale = yScale / aspect;

  float frustum[16];

  frustum[0*4+0] = xScale;
  frustum[0*4+1] = float(0);
  frustum[0*4+2] = float(0);
  frustum[0*4+3] = float(0);

  frustum[1*4+0] = float(0);
  frustum[1*4+1] = yScale;
  frustum[1*4+2] = float(0);
  frustum[1*4+3] = float(0);

  frustum[2*4+0] = 0;
  frustum[2*4+1] = 0;
  frustum[2*4+2] = (nearVal + farVal) / (nearVal - farVal);
  frustum[2*4+3] = float(-1);

  frustum[3*4+0] = float(0);
  frustum[3*4+1] = float(0);
  frustum[3*4+2] = (float(2) * farVal * nearVal) / (nearVal - farVal);
  frustum[3*4+3] = float(0);

  struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
  b3Assert(command);
  b3Assert(command->m_type == CMD_REQUEST_CAMERA_IMAGE_DATA);
  for (int i=0;i<16;i++)
  {
    command->m_requestPixelDataArguments.m_projectionMatrix[i] = frustum[i];
  }
  command->m_updateFlags |= REQUEST_PIXEL_ARGS_HAS_CAMERA_MATRICES;
}

void b3RequestCameraImageSetPixelResolution(b3SharedMemoryCommandHandle commandHandle, int width, int height )
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
	b3Assert(command);
	b3Assert(command->m_type == CMD_REQUEST_CAMERA_IMAGE_DATA);
	command->m_requestPixelDataArguments.m_pixelWidth = width;
	command->m_requestPixelDataArguments.m_pixelHeight = height;
	command->m_updateFlags |= REQUEST_PIXEL_ARGS_SET_PIXEL_WIDTH_HEIGHT;	
}

void b3GetCameraImageData(b3PhysicsClientHandle physClient, struct b3CameraImageData* imageData)
{
	PhysicsClient* cl = (PhysicsClient* ) physClient;
	if (cl)
	{
		cl->getCachedCameraImage(imageData);
	}
}

///request an contact point information
b3SharedMemoryCommandHandle b3InitRequestContactPointInformation(b3PhysicsClientHandle physClient)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    command->m_type =CMD_REQUEST_CONTACT_POINT_INFORMATION;
	command->m_requestContactPointArguments.m_startingContactPointIndex = 0;
	command->m_requestContactPointArguments.m_objectAIndexFilter = -1;
	command->m_requestContactPointArguments.m_objectBIndexFilter = -1;
    command->m_updateFlags = 0;
    return (b3SharedMemoryCommandHandle) command;
}

void b3SetContactFilterBodyA(b3SharedMemoryCommandHandle commandHandle, int bodyUniqueIdA)
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_REQUEST_CONTACT_POINT_INFORMATION);
	command->m_requestContactPointArguments.m_objectAIndexFilter = bodyUniqueIdA;
}

void b3SetContactFilterBodyB(b3SharedMemoryCommandHandle commandHandle, int bodyUniqueIdB)
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_REQUEST_CONTACT_POINT_INFORMATION);
	command->m_requestContactPointArguments.m_objectBIndexFilter = bodyUniqueIdB;
}


///compute the closest points between two bodies
b3SharedMemoryCommandHandle b3InitClosestDistanceQuery(b3PhysicsClientHandle physClient)
{
	b3SharedMemoryCommandHandle commandHandle =b3InitRequestContactPointInformation(physClient);
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
	b3Assert(command);
	b3Assert(command->m_type == CMD_REQUEST_CONTACT_POINT_INFORMATION);
	command->m_updateFlags = CMD_REQUEST_CONTACT_POINT_HAS_QUERY_MODE;
	command->m_requestContactPointArguments.m_mode = CONTACT_QUERY_MODE_COMPUTE_CLOSEST_POINTS;
	return commandHandle;
}

void b3SetClosestDistanceFilterBodyA(b3SharedMemoryCommandHandle commandHandle, int bodyUniqueIdA)
{
	b3SetContactFilterBodyA(commandHandle,bodyUniqueIdA);
}

void b3SetClosestDistanceFilterBodyB(b3SharedMemoryCommandHandle commandHandle, int bodyUniqueIdB)
{
	b3SetContactFilterBodyB(commandHandle,bodyUniqueIdB);
}

void b3SetClosestDistanceThreshold(b3SharedMemoryCommandHandle commandHandle, double distance)
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
	b3Assert(command);
	b3Assert(command->m_type == CMD_REQUEST_CONTACT_POINT_INFORMATION);
	command->m_updateFlags += CMD_REQUEST_CONTACT_POINT_HAS_CLOSEST_DISTANCE_THRESHOLD;
	command->m_requestContactPointArguments.m_closestDistanceThreshold = distance;
}


///get all the bodies that touch a given axis aligned bounding box specified in world space (min and max coordinates)
b3SharedMemoryCommandHandle b3InitAABBOverlapQuery(b3PhysicsClientHandle physClient, const double aabbMin[3], const double aabbMax[3])
{
	b3SharedMemoryCommandHandle commandHandle = b3InitRequestContactPointInformation(physClient);
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
	b3Assert(command);
	b3Assert(command->m_type == CMD_REQUEST_CONTACT_POINT_INFORMATION);
	command->m_updateFlags = CMD_REQUEST_CONTACT_POINT_HAS_QUERY_MODE;
	command->m_requestContactPointArguments.m_mode = CONTACT_QUERY_MODE_AABB_OVERLAP;

	command->m_requestContactPointArguments.m_aabbQueryMin[0] = aabbMin[0];
	command->m_requestContactPointArguments.m_aabbQueryMin[1] = aabbMin[1];
	command->m_requestContactPointArguments.m_aabbQueryMin[2] = aabbMin[2];

	command->m_requestContactPointArguments.m_aabbQueryMax[0] = aabbMax[0];
	command->m_requestContactPointArguments.m_aabbQueryMax[1] = aabbMax[1];
	command->m_requestContactPointArguments.m_aabbQueryMax[2] = aabbMax[2];

	return commandHandle;
}

void b3GetAABBOverlapResults(b3PhysicsClientHandle physClient, struct b3AABBOverlapData* data)
{
	data->m_numOverlappingObjects = 0;
//	data->m_objectUniqueIds
}



void b3GetContactPointInformation(b3PhysicsClientHandle physClient, struct b3ContactInformation* contactPointData)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
	if (cl)
	{
	    cl->getCachedContactPointInformation(contactPointData);
	}
}

void b3GetClosestPointInformation(b3PhysicsClientHandle physClient, struct b3ContactInformation* contactPointInfo)
{
	b3GetContactPointInformation(physClient,contactPointInfo);
}



//request visual shape information
b3SharedMemoryCommandHandle b3InitRequestVisualShapeInformation(b3PhysicsClientHandle physClient, int bodyUniqueIdA)
{
	PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    command->m_type = CMD_REQUEST_VISUAL_SHAPE_INFO;
	command->m_requestVisualShapeDataArguments.m_bodyUniqueId = bodyUniqueIdA;
	command->m_requestVisualShapeDataArguments.m_startingVisualShapeIndex = 0;
	command->m_updateFlags = 0;
    return (b3SharedMemoryCommandHandle) command;
}

void b3GetVisualShapeInformation(b3PhysicsClientHandle physClient, struct b3VisualShapeInformation* visualShapeInfo)
{
	PhysicsClient* cl = (PhysicsClient*)physClient;
	if (cl)
	{
		cl->getCachedVisualShapeInformation(visualShapeInfo);
	}
}

b3SharedMemoryCommandHandle b3InitLoadTexture(b3PhysicsClientHandle physClient, const char* filename)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    command->m_type = CMD_LOAD_TEXTURE;
    int len = strlen(filename);
    if (len<MAX_FILENAME_LENGTH)
    {
        strcpy(command->m_loadTextureArguments.m_textureFileName,filename);
    } else
    {
        command->m_loadTextureArguments.m_textureFileName[0] = 0;
    }
    command->m_updateFlags = 0;
    return (b3SharedMemoryCommandHandle) command;
}

b3SharedMemoryCommandHandle b3InitUpdateVisualShape(b3PhysicsClientHandle physClient, int bodyUniqueId, int jointIndex, int shapeIndex, int textureUniqueId)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    command->m_type = CMD_UPDATE_VISUAL_SHAPE;
    command->m_updateVisualShapeDataArguments.m_bodyUniqueId = bodyUniqueId;
    command->m_updateVisualShapeDataArguments.m_jointIndex = jointIndex;
    command->m_updateVisualShapeDataArguments.m_shapeIndex = shapeIndex;
    command->m_updateVisualShapeDataArguments.m_textureUniqueId = textureUniqueId;
    command->m_updateFlags = 0;
    return (b3SharedMemoryCommandHandle) command;
}

b3SharedMemoryCommandHandle b3ApplyExternalForceCommandInit(b3PhysicsClientHandle physClient)
{
    PhysicsClient* cl = (PhysicsClient* ) physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    
    command->m_type = CMD_APPLY_EXTERNAL_FORCE;
    command->m_updateFlags = 0;
    command->m_externalForceArguments.m_numForcesAndTorques = 0;
    return (b3SharedMemoryCommandHandle) command;
}

void b3ApplyExternalForce(b3SharedMemoryCommandHandle commandHandle, int bodyUniqueId, int linkId, const double force[3], const double position[3], int flag)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_APPLY_EXTERNAL_FORCE);
    int index = command->m_externalForceArguments.m_numForcesAndTorques;
    command->m_externalForceArguments.m_bodyUniqueIds[index] = bodyUniqueId;
    command->m_externalForceArguments.m_linkIds[index] = linkId;
    command->m_externalForceArguments.m_forceFlags[index] = EF_FORCE+flag;
    for (int i = 0; i < 3; ++i) {
        command->m_externalForceArguments.m_forcesAndTorques[index+i] = force[i];
        command->m_externalForceArguments.m_positions[index+i] = position[i];
    }
    
    command->m_externalForceArguments.m_numForcesAndTorques++;
}

void b3ApplyExternalTorque(b3SharedMemoryCommandHandle commandHandle, int bodyUniqueId, int linkId, const double torque[3], int flag)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_APPLY_EXTERNAL_FORCE);
    int index = command->m_externalForceArguments.m_numForcesAndTorques;
    command->m_externalForceArguments.m_bodyUniqueIds[index] = bodyUniqueId;
    command->m_externalForceArguments.m_linkIds[index] = linkId;
    command->m_externalForceArguments.m_forceFlags[index] = EF_TORQUE+flag;

    for (int i = 0; i < 3; ++i) {
        command->m_externalForceArguments.m_forcesAndTorques[index+i] = torque[i];
    }
    command->m_externalForceArguments.m_numForcesAndTorques++;
}




///compute the forces to achieve an acceleration, given a state q and qdot using inverse dynamics
b3SharedMemoryCommandHandle	b3CalculateInverseDynamicsCommandInit(b3PhysicsClientHandle physClient, int bodyIndex,
	const double* jointPositionsQ, const double* jointVelocitiesQdot, const double* jointAccelerations)
{
	PhysicsClient* cl = (PhysicsClient*)physClient;
	b3Assert(cl);
	b3Assert(cl->canSubmitCommand());
	struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
	b3Assert(command);

	command->m_type = CMD_CALCULATE_INVERSE_DYNAMICS;
	command->m_updateFlags = 0;
	command->m_calculateInverseDynamicsArguments.m_bodyUniqueId = bodyIndex;
	int numJoints = cl->getNumJoints(bodyIndex);
	for (int i = 0; i < numJoints;i++)
	{
		command->m_calculateInverseDynamicsArguments.m_jointPositionsQ[i] = jointPositionsQ[i];
		command->m_calculateInverseDynamicsArguments.m_jointVelocitiesQdot[i] = jointVelocitiesQdot[i];
		command->m_calculateInverseDynamicsArguments.m_jointAccelerations[i] = jointAccelerations[i];
	}

	return (b3SharedMemoryCommandHandle)command;
}

int b3GetStatusInverseDynamicsJointForces(b3SharedMemoryStatusHandle statusHandle,
	int* bodyUniqueId,
	int* dofCount,
	double* jointForces)
{
	const SharedMemoryStatus* status = (const SharedMemoryStatus*)statusHandle;
	btAssert(status->m_type == CMD_CALCULATED_INVERSE_DYNAMICS_COMPLETED);
	if (status->m_type != CMD_CALCULATED_INVERSE_DYNAMICS_COMPLETED)
		return false;


	if (dofCount)
	{
		*dofCount = status->m_inverseDynamicsResultArgs.m_dofCount;
	}
	if (bodyUniqueId)
	{
		*bodyUniqueId = status->m_inverseDynamicsResultArgs.m_bodyUniqueId;
	}
	if (jointForces)
	{
		for (int i = 0; i < status->m_inverseDynamicsResultArgs.m_dofCount; i++)
		{
			jointForces[i] = status->m_inverseDynamicsResultArgs.m_jointForces[i];
		}
	}

	
	return true;
}

b3SharedMemoryCommandHandle	b3CalculateJacobianCommandInit(b3PhysicsClientHandle physClient, int bodyIndex, int linkIndex, const double* localPosition, const double* jointPositionsQ, const double* jointVelocitiesQdot, const double* jointAccelerations)
{
    PhysicsClient* cl = (PhysicsClient*)physClient;
    b3Assert(cl);
    b3Assert(cl->canSubmitCommand());
    struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
    b3Assert(command);
    
    command->m_type = CMD_CALCULATE_JACOBIAN;
    command->m_updateFlags = 0;
    command->m_calculateJacobianArguments.m_bodyUniqueId = bodyIndex;
    command->m_calculateJacobianArguments.m_linkIndex = linkIndex;
    command->m_calculateJacobianArguments.m_localPosition[0] = localPosition[0];
    command->m_calculateJacobianArguments.m_localPosition[1] = localPosition[1];
    command->m_calculateJacobianArguments.m_localPosition[2] = localPosition[2];
    int numJoints = cl->getNumJoints(bodyIndex);
    for (int i = 0; i < numJoints;i++)
    {
        command->m_calculateJacobianArguments.m_jointPositionsQ[i] = jointPositionsQ[i];
        command->m_calculateJacobianArguments.m_jointVelocitiesQdot[i] = jointVelocitiesQdot[i];
        command->m_calculateJacobianArguments.m_jointAccelerations[i] = jointAccelerations[i];
    }
    
    return (b3SharedMemoryCommandHandle)command;
}

int b3GetStatusJacobian(b3SharedMemoryStatusHandle statusHandle, double* linearJacobian, double* angularJacobian)
{
    const SharedMemoryStatus* status = (const SharedMemoryStatus*)statusHandle;
    btAssert(status->m_type == CMD_CALCULATED_JACOBIAN_COMPLETED);
    if (status->m_type != CMD_CALCULATED_JACOBIAN_COMPLETED)
        return false;
    
    if (linearJacobian)
    {
        for (int i = 0; i < status->m_jacobianResultArgs.m_dofCount*3; i++)
        {
            linearJacobian[i] = status->m_jacobianResultArgs.m_linearJacobian[i];
        }
    }
    if (angularJacobian)
    {
        for (int i = 0; i < status->m_jacobianResultArgs.m_dofCount*3; i++)
        {
            angularJacobian[i] = status->m_jacobianResultArgs.m_angularJacobian[i];
        }

    }
    
    return true;
}

///compute the joint positions to move the end effector to a desired target using inverse kinematics
b3SharedMemoryCommandHandle	b3CalculateInverseKinematicsCommandInit(b3PhysicsClientHandle physClient, int bodyIndex)
{
	PhysicsClient* cl = (PhysicsClient*)physClient;
	b3Assert(cl);
	b3Assert(cl->canSubmitCommand());
	struct SharedMemoryCommand* command = cl->getAvailableSharedMemoryCommand();
	b3Assert(command);

	command->m_type = CMD_CALCULATE_INVERSE_KINEMATICS;
	command->m_updateFlags = 0;
	command->m_calculateInverseKinematicsArguments.m_bodyUniqueId = bodyIndex;

	return (b3SharedMemoryCommandHandle)command;

}

void b3CalculateInverseKinematicsAddTargetPurePosition(b3SharedMemoryCommandHandle commandHandle, int endEffectorLinkIndex, const double targetPosition[3])
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_CALCULATE_INVERSE_KINEMATICS);
    command->m_updateFlags |= IK_HAS_TARGET_POSITION;
	command->m_calculateInverseKinematicsArguments.m_endEffectorLinkIndex = endEffectorLinkIndex;
	
	command->m_calculateInverseKinematicsArguments.m_targetPosition[0] = targetPosition[0];
	command->m_calculateInverseKinematicsArguments.m_targetPosition[1] = targetPosition[1];
	command->m_calculateInverseKinematicsArguments.m_targetPosition[2] = targetPosition[2];
   

}
void b3CalculateInverseKinematicsAddTargetPositionWithOrientation(b3SharedMemoryCommandHandle commandHandle, int endEffectorLinkIndex, const double targetPosition[3], const double targetOrientation[4])
{
	struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_CALCULATE_INVERSE_KINEMATICS);
    command->m_updateFlags |= IK_HAS_TARGET_POSITION+IK_HAS_TARGET_ORIENTATION;
	command->m_calculateInverseKinematicsArguments.m_endEffectorLinkIndex = endEffectorLinkIndex;

	command->m_calculateInverseKinematicsArguments.m_targetPosition[0] = targetPosition[0];
	command->m_calculateInverseKinematicsArguments.m_targetPosition[1] = targetPosition[1];
	command->m_calculateInverseKinematicsArguments.m_targetPosition[2] = targetPosition[2];
    
    command->m_calculateInverseKinematicsArguments.m_targetOrientation[0] = targetOrientation[0];
    command->m_calculateInverseKinematicsArguments.m_targetOrientation[1] = targetOrientation[1];
    command->m_calculateInverseKinematicsArguments.m_targetOrientation[2] = targetOrientation[2];
    command->m_calculateInverseKinematicsArguments.m_targetOrientation[3] = targetOrientation[3];

}

void b3CalculateInverseKinematicsPosWithNullSpaceVel(b3SharedMemoryCommandHandle commandHandle, int numDof, int endEffectorLinkIndex, const double targetPosition[3], const double* lowerLimit, const double* upperLimit, const double* jointRange, const double* restPose)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_CALCULATE_INVERSE_KINEMATICS);
    command->m_updateFlags |= IK_HAS_TARGET_POSITION+IK_HAS_NULL_SPACE_VELOCITY;
    command->m_calculateInverseKinematicsArguments.m_endEffectorLinkIndex = endEffectorLinkIndex;
    
    command->m_calculateInverseKinematicsArguments.m_targetPosition[0] = targetPosition[0];
    command->m_calculateInverseKinematicsArguments.m_targetPosition[1] = targetPosition[1];
    command->m_calculateInverseKinematicsArguments.m_targetPosition[2] = targetPosition[2];
    
    for (int i = 0; i < numDof; ++i)
    {
        command->m_calculateInverseKinematicsArguments.m_lowerLimit[i] = lowerLimit[i];
        command->m_calculateInverseKinematicsArguments.m_upperLimit[i] = upperLimit[i];
        command->m_calculateInverseKinematicsArguments.m_jointRange[i] = jointRange[i];
        command->m_calculateInverseKinematicsArguments.m_restPose[i] = restPose[i];
    }
}

void b3CalculateInverseKinematicsPosOrnWithNullSpaceVel(b3SharedMemoryCommandHandle commandHandle, int numDof, int endEffectorLinkIndex, const double targetPosition[3], const double targetOrientation[4], const double* lowerLimit, const double* upperLimit, const double* jointRange, const double* restPose)
{
    struct SharedMemoryCommand* command = (struct SharedMemoryCommand*) commandHandle;
    b3Assert(command);
    b3Assert(command->m_type == CMD_CALCULATE_INVERSE_KINEMATICS);
    command->m_updateFlags |= IK_HAS_TARGET_POSITION+IK_HAS_TARGET_ORIENTATION+IK_HAS_NULL_SPACE_VELOCITY;
    command->m_calculateInverseKinematicsArguments.m_endEffectorLinkIndex = endEffectorLinkIndex;
    
    command->m_calculateInverseKinematicsArguments.m_targetPosition[0] = targetPosition[0];
    command->m_calculateInverseKinematicsArguments.m_targetPosition[1] = targetPosition[1];
    command->m_calculateInverseKinematicsArguments.m_targetPosition[2] = targetPosition[2];
    
    command->m_calculateInverseKinematicsArguments.m_targetOrientation[0] = targetOrientation[0];
    command->m_calculateInverseKinematicsArguments.m_targetOrientation[1] = targetOrientation[1];
    command->m_calculateInverseKinematicsArguments.m_targetOrientation[2] = targetOrientation[2];
    command->m_calculateInverseKinematicsArguments.m_targetOrientation[3] = targetOrientation[3];
    
    for (int i = 0; i < numDof; ++i)
    {
        command->m_calculateInverseKinematicsArguments.m_lowerLimit[i] = lowerLimit[i];
        command->m_calculateInverseKinematicsArguments.m_upperLimit[i] = upperLimit[i];
        command->m_calculateInverseKinematicsArguments.m_jointRange[i] = jointRange[i];
        command->m_calculateInverseKinematicsArguments.m_restPose[i] = restPose[i];
    }

}

int b3GetStatusInverseKinematicsJointPositions(b3SharedMemoryStatusHandle statusHandle,
	int* bodyUniqueId,
	int* dofCount,
	double* jointPositions)
{
	const SharedMemoryStatus* status = (const SharedMemoryStatus*)statusHandle;
	btAssert(status->m_type == CMD_CALCULATE_INVERSE_KINEMATICS_COMPLETED);
	if (status->m_type != CMD_CALCULATE_INVERSE_KINEMATICS_COMPLETED)
		return false;


	if (dofCount)
	{
		*dofCount = status->m_inverseKinematicsResultArgs.m_dofCount;
	}
	if (bodyUniqueId)
	{
		*bodyUniqueId = status->m_inverseKinematicsResultArgs.m_bodyUniqueId;
	}
	if (jointPositions)
	{
		for (int i = 0; i < status->m_inverseKinematicsResultArgs.m_dofCount; i++)
		{
			jointPositions[i] = status->m_inverseKinematicsResultArgs.m_jointPositions[i];
		}
	}

	return true;
}