bullet3/examples/SharedMemory/grpc/ConvertGRPCBullet.cpp
2018-09-04 16:56:34 -07:00

1841 lines
67 KiB
C++

#include "ConvertGRPCBullet.h"
#include "PhysicsClientC_API.h"
#include "SharedMemoryCommands.h"
#include <memory>
#include <iostream>
#include <string>
#include <thread>
#include <grpc++/grpc++.h>
#include <grpc/support/log.h>
#include "pybullet.grpc.pb.h"
#include "LinearMath/btMinMax.h"
#define ALLOW_GRPC_COMMAND_CONVERSION
#define ALLOW_GRPC_STATUS_CONVERSION
using grpc::Server;
using grpc::ServerAsyncResponseWriter;
using grpc::ServerBuilder;
using grpc::ServerContext;
using grpc::ServerCompletionQueue;
using grpc::Status;
using pybullet_grpc::PyBulletCommand;
using pybullet_grpc::PyBulletStatus;
using pybullet_grpc::PyBulletAPI;
pybullet_grpc::PyBulletCommand* convertBulletToGRPCCommand(const struct SharedMemoryCommand& clientCmd, pybullet_grpc::PyBulletCommand& grpcCommand)
{
pybullet_grpc::PyBulletCommand* grpcCmdPtr = 0;
grpcCommand.set_commandtype(clientCmd.m_type);
switch (clientCmd.m_type)
{
case CMD_RESET_SIMULATION:
{
grpcCmdPtr = &grpcCommand;
break;
}
case CMD_REQUEST_KEYBOARD_EVENTS_DATA:
{
grpcCmdPtr = &grpcCommand;
break;
}
case CMD_USER_CONSTRAINT:
{
grpcCmdPtr = &grpcCommand;
::pybullet_grpc::UserConstraintCommand* con = grpcCommand.mutable_userconstraintcommand();
con->set_updateflags(clientCmd.m_updateFlags);
con->mutable_childframe()->mutable_origin()->set_x(clientCmd.m_userConstraintArguments.m_childFrame[0]);
con->mutable_childframe()->mutable_origin()->set_y(clientCmd.m_userConstraintArguments.m_childFrame[1]);
con->mutable_childframe()->mutable_origin()->set_z(clientCmd.m_userConstraintArguments.m_childFrame[2]);
con->mutable_childframe()->mutable_orientation()->set_x(clientCmd.m_userConstraintArguments.m_childFrame[3]);
con->mutable_childframe()->mutable_orientation()->set_y(clientCmd.m_userConstraintArguments.m_childFrame[4]);
con->mutable_childframe()->mutable_orientation()->set_z(clientCmd.m_userConstraintArguments.m_childFrame[5]);
con->mutable_childframe()->mutable_orientation()->set_w(clientCmd.m_userConstraintArguments.m_childFrame[6]);
con->mutable_parentframe()->mutable_origin()->set_x(clientCmd.m_userConstraintArguments.m_parentFrame[0]);
con->mutable_parentframe()->mutable_origin()->set_y(clientCmd.m_userConstraintArguments.m_parentFrame[1]);
con->mutable_parentframe()->mutable_origin()->set_z(clientCmd.m_userConstraintArguments.m_parentFrame[2]);
con->mutable_parentframe()->mutable_orientation()->set_x(clientCmd.m_userConstraintArguments.m_parentFrame[3]);
con->mutable_parentframe()->mutable_orientation()->set_y(clientCmd.m_userConstraintArguments.m_parentFrame[4]);
con->mutable_parentframe()->mutable_orientation()->set_z(clientCmd.m_userConstraintArguments.m_parentFrame[5]);
con->mutable_parentframe()->mutable_orientation()->set_w(clientCmd.m_userConstraintArguments.m_parentFrame[6]);
con->mutable_jointaxis()->set_x(clientCmd.m_userConstraintArguments.m_jointAxis[0]);
con->mutable_jointaxis()->set_y(clientCmd.m_userConstraintArguments.m_jointAxis[1]);
con->mutable_jointaxis()->set_z(clientCmd.m_userConstraintArguments.m_jointAxis[2]);
con->set_childbodyindex(clientCmd.m_userConstraintArguments.m_childBodyIndex);
con->set_childjointindex(clientCmd.m_userConstraintArguments.m_childJointIndex);
con->set_parentbodyindex(clientCmd.m_userConstraintArguments.m_parentBodyIndex);
con->set_parentjointindex(clientCmd.m_userConstraintArguments.m_parentJointIndex);
con->set_jointtype(clientCmd.m_userConstraintArguments.m_jointType);
if (clientCmd.m_updateFlags&USER_CONSTRAINT_CHANGE_MAX_FORCE)
{
con->set_maxappliedforce(clientCmd.m_userConstraintArguments.m_maxAppliedForce);
}
if (clientCmd.m_updateFlags&USER_CONSTRAINT_CHANGE_GEAR_RATIO)
{
con->set_gearratio(clientCmd.m_userConstraintArguments.m_gearRatio);
}
if (clientCmd.m_updateFlags&USER_CONSTRAINT_CHANGE_GEAR_AUX_LINK)
{
con->set_gearauxlink(clientCmd.m_userConstraintArguments.m_gearAuxLink);
}
if (clientCmd.m_updateFlags&USER_CONSTRAINT_CHANGE_RELATIVE_POSITION_TARGET)
{
con->set_relativepositiontarget(clientCmd.m_userConstraintArguments.m_relativePositionTarget);
}
if (clientCmd.m_updateFlags&USER_CONSTRAINT_CHANGE_ERP)
{
con->set_erp(clientCmd.m_userConstraintArguments.m_erp);
}
con->set_userconstraintuniqueid(-1);
break;
}
case CMD_STEP_FORWARD_SIMULATION:
{
grpcCmdPtr = &grpcCommand;
break;
}
case CMD_LOAD_URDF:
{
::pybullet_grpc::LoadUrdfCommand* urdfCmd = grpcCommand.mutable_loadurdfcommand();
grpcCmdPtr = &grpcCommand;
urdfCmd->set_filename(clientCmd.m_urdfArguments.m_urdfFileName);
if (clientCmd.m_updateFlags &URDF_ARGS_INITIAL_POSITION)
{
urdfCmd->mutable_initialposition()->set_x(clientCmd.m_urdfArguments.m_initialPosition[0]);
urdfCmd->mutable_initialposition()->set_y(clientCmd.m_urdfArguments.m_initialPosition[1]);
urdfCmd->mutable_initialposition()->set_z(clientCmd.m_urdfArguments.m_initialPosition[2]);
}
if (clientCmd.m_updateFlags &URDF_ARGS_INITIAL_ORIENTATION)
{
urdfCmd->mutable_initialorientation()->set_x(clientCmd.m_urdfArguments.m_initialOrientation[0]);
urdfCmd->mutable_initialorientation()->set_y(clientCmd.m_urdfArguments.m_initialOrientation[1]);
urdfCmd->mutable_initialorientation()->set_z(clientCmd.m_urdfArguments.m_initialOrientation[2]);
urdfCmd->mutable_initialorientation()->set_w(clientCmd.m_urdfArguments.m_initialOrientation[3]);
}
if (clientCmd.m_updateFlags &URDF_ARGS_USE_MULTIBODY)
{
urdfCmd->set_usemultibody(clientCmd.m_urdfArguments.m_useMultiBody);
}
if (clientCmd.m_updateFlags &URDF_ARGS_USE_FIXED_BASE)
{
urdfCmd->set_usefixedbase(clientCmd.m_urdfArguments.m_useFixedBase);
}
if (clientCmd.m_updateFlags &URDF_ARGS_USE_GLOBAL_SCALING)
{
urdfCmd->set_globalscaling(clientCmd.m_urdfArguments.m_globalScaling);
}
if (clientCmd.m_updateFlags &URDF_ARGS_HAS_CUSTOM_URDF_FLAGS)
{
urdfCmd->set_flags(clientCmd.m_urdfArguments.m_urdfFlags);
}
break;
}
case CMD_INIT_POSE:
{
grpcCmdPtr = &grpcCommand;
::pybullet_grpc::InitPoseCommand* pose = grpcCommand.mutable_initposecommand();
{
pose->set_bodyuniqueid(clientCmd.m_initPoseArgs.m_bodyUniqueId);
pose->set_updateflags(clientCmd.m_updateFlags);
int maxQ = 0;
for (int q = 0; q < MAX_DEGREE_OF_FREEDOM; q++)
{
if (clientCmd.m_initPoseArgs.m_hasInitialStateQ[q])
{
maxQ = q+1;
}
if (clientCmd.m_initPoseArgs.m_hasInitialStateQdot[q])
{
maxQ = q+1;
}
}
for (int q = 0; q < maxQ; q++)
{
pose->add_hasinitialstateq(clientCmd.m_initPoseArgs.m_hasInitialStateQ[q]);
pose->add_hasinitialstateqdot(clientCmd.m_initPoseArgs.m_hasInitialStateQdot[q]);
pose->add_initialstateq(clientCmd.m_initPoseArgs.m_initialStateQ[q]);
pose->add_initialstateqdot(clientCmd.m_initPoseArgs.m_initialStateQdot[q]);
}
}
break;
}
case CMD_REQUEST_ACTUAL_STATE:
{
grpcCmdPtr = &grpcCommand;
::pybullet_grpc::RequestActualStateCommand* grpcCmd = grpcCommand.mutable_requestactualstatecommand();
grpcCmd->set_bodyuniqueid(clientCmd.m_requestActualStateInformationCommandArgument.m_bodyUniqueId);
if (clientCmd.m_updateFlags & ACTUAL_STATE_COMPUTE_FORWARD_KINEMATICS)
{
grpcCmd->set_computeforwardkinematics(true);
}
if (clientCmd.m_updateFlags & ACTUAL_STATE_COMPUTE_LINKVELOCITY)
{
grpcCmd->set_computelinkvelocities(true);
}
break;
}
case CMD_SEND_DESIRED_STATE:
{
::pybullet_grpc::JointMotorControlCommand* motor = grpcCommand.mutable_jointmotorcontrolcommand();
motor->set_bodyuniqueid(clientCmd.m_sendDesiredStateCommandArgument.m_bodyUniqueId);
motor->set_controlmode(clientCmd.m_sendDesiredStateCommandArgument.m_controlMode);
motor->set_updateflags(clientCmd.m_updateFlags);
int maxQ = 0;
for (int q = 0; q < MAX_DEGREE_OF_FREEDOM; q++)
{
if (clientCmd.m_sendDesiredStateCommandArgument.m_hasDesiredStateFlags[q])
{
maxQ = q + 1;
}
}
for (int q = 0; q < maxQ; q++)
{
motor->add_desiredstateq(clientCmd.m_sendDesiredStateCommandArgument.m_desiredStateQ[q]);
motor->add_desiredstateqdot(clientCmd.m_sendDesiredStateCommandArgument.m_desiredStateQdot[q]);
motor->add_desiredstateforcetorque(clientCmd.m_sendDesiredStateCommandArgument.m_desiredStateForceTorque[q]);
motor->add_kd(clientCmd.m_sendDesiredStateCommandArgument.m_Kp[q]);
motor->add_kp(clientCmd.m_sendDesiredStateCommandArgument.m_Kp[q]);
motor->add_maxvelocity(clientCmd.m_sendDesiredStateCommandArgument.m_rhsClamp[q]);
motor->add_hasdesiredstateflags(clientCmd.m_sendDesiredStateCommandArgument.m_hasDesiredStateFlags[q]);
}
grpcCmdPtr = &grpcCommand;
//b3JointControlCommandInit2Internal
break;
}
case CMD_SEND_PHYSICS_SIMULATION_PARAMETERS:
{
grpcCmdPtr = &grpcCommand;
::pybullet_grpc::PhysicsSimulationParametersCommand* grpcCmd = grpcCommand.mutable_setphysicssimulationparameterscommand();
grpcCmd->set_updateflags(clientCmd.m_updateFlags);
::pybullet_grpc::PhysicsSimulationParameters* params = grpcCmd->mutable_params();
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_DELTA_TIME)
{
params->set_deltatime(clientCmd.m_physSimParamArgs.m_deltaTime);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_GRAVITY)
{
::pybullet_grpc::vec3* grav = params->mutable_gravityacceleration();
grav->set_x(clientCmd.m_physSimParamArgs.m_gravityAcceleration[0]);
grav->set_y(clientCmd.m_physSimParamArgs.m_gravityAcceleration[1]);
grav->set_z(clientCmd.m_physSimParamArgs.m_gravityAcceleration[2]);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_NUM_SOLVER_ITERATIONS)
{
params->set_numsolveriterations(clientCmd.m_physSimParamArgs.m_numSolverIterations);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_NUM_SIMULATION_SUB_STEPS)
{
params->set_numsimulationsubsteps(clientCmd.m_physSimParamArgs.m_numSimulationSubSteps);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_REAL_TIME_SIMULATION)
{
params->set_userealtimesimulation(clientCmd.m_physSimParamArgs.m_useRealTimeSimulation);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_DEFAULT_CONTACT_ERP)
{
params->set_defaultcontacterp(clientCmd.m_physSimParamArgs.m_defaultContactERP);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_INTERNAL_SIMULATION_FLAGS)
{
params->set_internalsimflags(clientCmd.m_physSimParamArgs.m_internalSimFlags);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_USE_SPLIT_IMPULSE)
{
params->set_usesplitimpulse(clientCmd.m_physSimParamArgs.m_useSplitImpulse);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_SPLIT_IMPULSE_PENETRATION_THRESHOLD)
{
params->set_splitimpulsepenetrationthreshold(clientCmd.m_physSimParamArgs.m_splitImpulsePenetrationThreshold);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_COLLISION_FILTER_MODE)
{
params->set_collisionfiltermode(clientCmd.m_physSimParamArgs.m_collisionFilterMode);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_CONTACT_BREAKING_THRESHOLD)
{
params->set_contactbreakingthreshold(clientCmd.m_physSimParamArgs.m_contactBreakingThreshold);
}
if (clientCmd.m_updateFlags&SIM_PARAM_ENABLE_CONE_FRICTION)
{
params->set_enableconefriction(clientCmd.m_physSimParamArgs.m_enableConeFriction);
}
if (clientCmd.m_updateFlags&SIM_PARAM_ENABLE_FILE_CACHING)
{
params->set_enablefilecaching(clientCmd.m_physSimParamArgs.m_enableFileCaching);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_RESTITUTION_VELOCITY_THRESHOLD)
{
params->set_restitutionvelocitythreshold(clientCmd.m_physSimParamArgs.m_restitutionVelocityThreshold);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_DEFAULT_NON_CONTACT_ERP)
{
params->set_defaultnoncontacterp(clientCmd.m_physSimParamArgs.m_defaultNonContactERP);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_DEFAULT_FRICTION_ERP)
{
params->set_frictionerp(clientCmd.m_physSimParamArgs.m_frictionERP);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_DETERMINISTIC_OVERLAPPING_PAIRS)
{
params->set_deterministicoverlappingpairs(clientCmd.m_physSimParamArgs.m_deterministicOverlappingPairs);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_CCD_ALLOWED_PENETRATION)
{
params->set_allowedccdpenetration(clientCmd.m_physSimParamArgs.m_allowedCcdPenetration);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_JOINT_FEEDBACK_MODE)
{
params->set_jointfeedbackmode(clientCmd.m_physSimParamArgs.m_jointFeedbackMode);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_DEFAULT_GLOBAL_CFM)
{
params->set_defaultglobalcfm(clientCmd.m_physSimParamArgs.m_defaultGlobalCFM);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_DEFAULT_FRICTION_CFM)
{
params->set_frictioncfm(clientCmd.m_physSimParamArgs.m_frictionCFM);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_SOLVER_RESIDULAL_THRESHOLD)
{
params->set_solverresidualthreshold(clientCmd.m_physSimParamArgs.m_solverResidualThreshold);
}
if (clientCmd.m_updateFlags&SIM_PARAM_UPDATE_CONTACT_SLOP)
{
params->set_contactslop(clientCmd.m_physSimParamArgs.m_contactSlop);
}
if (clientCmd.m_updateFlags&SIM_PARAM_ENABLE_SAT)
{
params->set_enablesat(clientCmd.m_physSimParamArgs.m_enableSAT);
}
if (clientCmd.m_updateFlags&SIM_PARAM_CONSTRAINT_SOLVER_TYPE)
{
params->set_constraintsolvertype(clientCmd.m_physSimParamArgs.m_constraintSolverType);
}
if (clientCmd.m_updateFlags&SIM_PARAM_CONSTRAINT_MIN_SOLVER_ISLAND_SIZE)
{
params->set_minimumsolverislandsize(clientCmd.m_physSimParamArgs.m_minimumSolverIslandSize);
}
break;
}
case CMD_REQUEST_BODY_INFO:
{
grpcCmdPtr = &grpcCommand;
::pybullet_grpc::RequestBodyInfoCommand* grpcCmd = grpcCommand.mutable_requestbodyinfocommand();
grpcCmd->set_bodyuniqueid(clientCmd.m_sdfRequestInfoArgs.m_bodyUniqueId);
break;
}
case CMD_REQUEST_PHYSICS_SIMULATION_PARAMETERS:
{
grpcCmdPtr = &grpcCommand;
break;
}
case CMD_SYNC_BODY_INFO:
{
grpcCmdPtr = &grpcCommand;
break;
}
case CMD_REQUEST_INTERNAL_DATA:
{
grpcCmdPtr = &grpcCommand;
break;
}
case CMD_CONFIGURE_OPENGL_VISUALIZER:
{
grpcCmdPtr = &grpcCommand;
::pybullet_grpc::ConfigureOpenGLVisualizerCommand* vizCmd = grpcCommand.mutable_configureopenglvisualizercommand();
vizCmd->set_updateflags(clientCmd.m_updateFlags);
vizCmd->set_cameradistance(clientCmd.m_configureOpenGLVisualizerArguments.m_cameraDistance);
vizCmd->set_camerapitch(clientCmd.m_configureOpenGLVisualizerArguments.m_cameraPitch);
vizCmd->set_camerayaw(clientCmd.m_configureOpenGLVisualizerArguments.m_cameraYaw);
vizCmd->set_setflag(clientCmd.m_configureOpenGLVisualizerArguments.m_setFlag);
vizCmd->set_setenabled(clientCmd.m_configureOpenGLVisualizerArguments.m_setEnabled);
::pybullet_grpc::vec3* targetPos = vizCmd->mutable_cameratargetposition();
targetPos->set_x(clientCmd.m_configureOpenGLVisualizerArguments.m_cameraTargetPosition[0]);
targetPos->set_y(clientCmd.m_configureOpenGLVisualizerArguments.m_cameraTargetPosition[1]);
targetPos->set_z(clientCmd.m_configureOpenGLVisualizerArguments.m_cameraTargetPosition[2]);
break;
}
case CMD_REQUEST_CAMERA_IMAGE_DATA:
{
grpcCmdPtr = &grpcCommand;
::pybullet_grpc::RequestCameraImageCommand* cam = grpcCommand.mutable_requestcameraimagecommand();
cam->set_updateflags(clientCmd.m_updateFlags);
cam->set_startpixelindex(clientCmd.m_requestPixelDataArguments.m_startPixelIndex);
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_PIXEL_WIDTH_HEIGHT)
{
cam->set_pixelwidth(clientCmd.m_requestPixelDataArguments.m_pixelWidth);
cam->set_pixelheight(clientCmd.m_requestPixelDataArguments.m_pixelHeight);
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_SPECULAR_COEFF)
{
cam->set_lightspecularcoeff(clientCmd.m_requestPixelDataArguments.m_lightSpecularCoeff);
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_HAS_FLAGS)
{
cam->set_cameraflags(clientCmd.m_requestPixelDataArguments.m_flags);
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_SHADOW)
{
cam->set_hasshadow(clientCmd.m_requestPixelDataArguments.m_hasShadow);
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_AMBIENT_COEFF)
{
cam->set_lightambientcoeff(clientCmd.m_requestPixelDataArguments.m_lightAmbientCoeff);
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_DIFFUSE_COEFF)
{
cam->set_lightdiffusecoeff(clientCmd.m_requestPixelDataArguments.m_lightDiffuseCoeff);
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_LIGHT_DISTANCE)
{
cam->set_lightdistance(clientCmd.m_requestPixelDataArguments.m_lightDistance);
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_LIGHT_COLOR)
{
::pybullet_grpc::vec3* lightColor = cam->mutable_lightcolor();
lightColor->set_x(clientCmd.m_requestPixelDataArguments.m_lightColor[0]);
lightColor->set_y(clientCmd.m_requestPixelDataArguments.m_lightColor[1]);
lightColor->set_z(clientCmd.m_requestPixelDataArguments.m_lightColor[2]);
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_LIGHT_DIRECTION)
{
::pybullet_grpc::vec3* lightDir = cam->mutable_lightdirection();
lightDir->set_x(clientCmd.m_requestPixelDataArguments.m_lightDirection[0]);
lightDir->set_y(clientCmd.m_requestPixelDataArguments.m_lightDirection[1]);
lightDir->set_z(clientCmd.m_requestPixelDataArguments.m_lightDirection[2]);
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_HAS_CAMERA_MATRICES)
{
::pybullet_grpc::matrix4x4* projMat = cam->mutable_projectionmatrix();
::pybullet_grpc::matrix4x4* viewMat = cam->mutable_viewmatrix();
for (int i = 0; i < 16; i++)
{
projMat->add_elems(clientCmd.m_requestPixelDataArguments.m_projectionMatrix[i]);
viewMat->add_elems(clientCmd.m_requestPixelDataArguments.m_viewMatrix[i]);
}
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_HAS_PROJECTIVE_TEXTURE_MATRICES)
{
::pybullet_grpc::matrix4x4* projectiveProjMat = cam->mutable_projectivetextureprojectionmatrix();
::pybullet_grpc::matrix4x4* projectiveViewMat = cam->mutable_projectivetextureviewmatrix();
for (int i = 0; i < 16; i++)
{
projectiveProjMat->add_elems(clientCmd.m_requestPixelDataArguments.m_projectiveTextureProjectionMatrix[i]);
projectiveViewMat->add_elems(clientCmd.m_requestPixelDataArguments.m_projectiveTextureViewMatrix[i]);
}
}
break;
}
default:
{
printf("convertBulletToGRPCCommand: Unknown command\n");
//assert(0);
}
};
if (0 == grpcCmdPtr)
{
grpcCmdPtr = &grpcCommand;
//printf("Warning: slow fallback of convertBulletToGRPCCommand (%d)", clientCmd.m_type);
//convert an unknown command as binary blob
int sz = sizeof(SharedMemoryCommand);
if (sz > 0)
{
grpcCommand.add_unknowncommandbinaryblob((const char*)&clientCmd, sz);
}
}
btAssert(grpcCmdPtr);
return grpcCmdPtr;
}
SharedMemoryCommand* convertGRPCToBulletCommand(const PyBulletCommand& grpcCommand, SharedMemoryCommand& cmd)
{
SharedMemoryCommand* cmdPtr = 0;
cmd.m_type = grpcCommand.commandtype();
if (cmd.m_type == CMD_INVALID)
{
//derive it from the contents instead
if (grpcCommand.has_changedynamicscommand())
{
cmd.m_type = CMD_CHANGE_DYNAMICS_INFO;
}
if (grpcCommand.has_resetsimulationcommand())
{
cmd.m_type = CMD_RESET_SIMULATION;
}
if (grpcCommand.has_loadurdfcommand())
{
cmd.m_type = CMD_LOAD_URDF;
}
if (grpcCommand.has_loadsdfcommand())
{
cmd.m_type = CMD_LOAD_SDF;
}
if (grpcCommand.has_loadmjcfcommand())
{
cmd.m_type = CMD_LOAD_MJCF;
}
if (grpcCommand.has_changedynamicscommand())
{
cmd.m_type = CMD_CHANGE_DYNAMICS_INFO;
}
if (grpcCommand.has_getdynamicscommand())
{
cmd.m_type = CMD_GET_DYNAMICS_INFO;
}
if (grpcCommand.has_initposecommand())
{
cmd.m_type = CMD_INIT_POSE;
}
if (grpcCommand.has_requestactualstatecommand())
{
cmd.m_type = CMD_REQUEST_ACTUAL_STATE;
}
if (grpcCommand.has_stepsimulationcommand())
{
cmd.m_type = CMD_STEP_FORWARD_SIMULATION;
}
}
int sz = grpcCommand.unknowncommandbinaryblob_size();
if (sz)
{
if (sz == 1)
{
const char* data = grpcCommand.unknowncommandbinaryblob().Get(0).c_str();
int numBytes = grpcCommand.unknowncommandbinaryblob().Get(0).size();
btAssert(sizeof(SharedMemoryCommand) == numBytes);
if (sizeof(SharedMemoryCommand) == numBytes)
{
memcpy(&cmd, data, numBytes);
}
//printf("slow fallback on command type %d\n", cmd.m_type);
}
else
{
printf("Ignore unexpected unknowncommandbinaryblob\n");
}
cmdPtr = &cmd;
}
if (cmdPtr == 0)
{
switch (cmd.m_type)
{
case CMD_RESET_SIMULATION:
{
cmdPtr = &cmd;
break;
}
case CMD_REQUEST_KEYBOARD_EVENTS_DATA:
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
b3RequestKeyboardEventsCommandInit2(commandHandle);
break;
}
case CMD_USER_CONSTRAINT:
{
SharedMemoryCommand& clientCmd = cmd;
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
const ::pybullet_grpc::UserConstraintCommand* con = &grpcCommand.userconstraintcommand();
clientCmd.m_updateFlags = con->updateflags();
clientCmd.m_userConstraintArguments.m_childFrame[0] = con->childframe().origin().x();
clientCmd.m_userConstraintArguments.m_childFrame[1] = con->childframe().origin().y();
clientCmd.m_userConstraintArguments.m_childFrame[2] = con->childframe().origin().z();
clientCmd.m_userConstraintArguments.m_childFrame[3] = con->childframe().orientation().x();
clientCmd.m_userConstraintArguments.m_childFrame[4] = con->childframe().orientation().y();
clientCmd.m_userConstraintArguments.m_childFrame[5] = con->childframe().orientation().z();
clientCmd.m_userConstraintArguments.m_childFrame[6] = con->childframe().orientation().w();
clientCmd.m_userConstraintArguments.m_parentFrame[0] = con->parentframe().origin().x();
clientCmd.m_userConstraintArguments.m_parentFrame[1] = con->parentframe().origin().y();
clientCmd.m_userConstraintArguments.m_parentFrame[2] = con->parentframe().origin().z();
clientCmd.m_userConstraintArguments.m_parentFrame[3] = con->parentframe().orientation().x();
clientCmd.m_userConstraintArguments.m_parentFrame[4] = con->parentframe().orientation().y();
clientCmd.m_userConstraintArguments.m_parentFrame[5] = con->parentframe().orientation().z();
clientCmd.m_userConstraintArguments.m_parentFrame[6] = con->parentframe().orientation().w();
clientCmd.m_userConstraintArguments.m_jointAxis[0] = con->jointaxis().x();
clientCmd.m_userConstraintArguments.m_jointAxis[1] = con->jointaxis().y();
clientCmd.m_userConstraintArguments.m_jointAxis[2] = con->jointaxis().z();
clientCmd.m_userConstraintArguments.m_childBodyIndex = con->childbodyindex();
clientCmd.m_userConstraintArguments.m_childJointIndex = con->childjointindex();
clientCmd.m_userConstraintArguments.m_parentBodyIndex = con->parentbodyindex();
clientCmd.m_userConstraintArguments.m_parentJointIndex = con->parentjointindex();
clientCmd.m_userConstraintArguments.m_jointType = con->jointtype();
if (clientCmd.m_updateFlags&USER_CONSTRAINT_CHANGE_MAX_FORCE)
{
clientCmd.m_userConstraintArguments.m_maxAppliedForce = con->maxappliedforce();
}
if (clientCmd.m_updateFlags&USER_CONSTRAINT_CHANGE_GEAR_RATIO)
{
clientCmd.m_userConstraintArguments.m_gearRatio = con->gearratio();
}
if (clientCmd.m_updateFlags&USER_CONSTRAINT_CHANGE_GEAR_AUX_LINK)
{
clientCmd.m_userConstraintArguments.m_gearAuxLink = con->gearauxlink();
}
if (clientCmd.m_updateFlags&USER_CONSTRAINT_CHANGE_RELATIVE_POSITION_TARGET)
{
clientCmd.m_userConstraintArguments.m_relativePositionTarget = con->relativepositiontarget();
}
if (clientCmd.m_updateFlags&USER_CONSTRAINT_CHANGE_ERP)
{
clientCmd.m_userConstraintArguments.m_erp = con->erp();
}
break;
}
case CMD_STEP_FORWARD_SIMULATION:
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
b3InitStepSimulationCommand2(commandHandle);
break;
}
case CMD_LOAD_URDF:
{
btAssert(grpcCommand.has_loadurdfcommand());
if (grpcCommand.has_loadurdfcommand())
{
const ::pybullet_grpc::LoadUrdfCommand& grpcCmd = grpcCommand.loadurdfcommand();
std::string fileName = grpcCmd.filename();
if (fileName.length())
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
b3LoadUrdfCommandInit2(commandHandle, fileName.c_str());
if (grpcCmd.has_initialposition())
{
const ::pybullet_grpc::vec3& pos = grpcCmd.initialposition();
b3LoadUrdfCommandSetStartPosition(commandHandle, pos.x(), pos.y(), pos.z());
}
if (grpcCmd.has_initialorientation())
{
const ::pybullet_grpc::quat4& orn = grpcCmd.initialorientation();
b3LoadUrdfCommandSetStartOrientation(commandHandle, orn.x(), orn.y(), orn.z(), orn.w());
}
if (grpcCmd.hasUseMultiBody_case() == ::pybullet_grpc::LoadUrdfCommand::HasUseMultiBodyCase::kUseMultiBody)
{
b3LoadUrdfCommandSetUseMultiBody(commandHandle, grpcCmd.usemultibody());
}
if (grpcCmd.hasGlobalScaling_case() == ::pybullet_grpc::LoadUrdfCommand::HasGlobalScalingCase::kGlobalScaling)
{
b3LoadUrdfCommandSetGlobalScaling(commandHandle, grpcCmd.globalscaling());
}
if (grpcCmd.hasUseFixedBase_case() == ::pybullet_grpc::LoadUrdfCommand::HasUseFixedBaseCase::kUseFixedBase)
{
b3LoadUrdfCommandSetUseFixedBase(commandHandle, grpcCmd.usefixedbase());
}
if (grpcCmd.flags())
{
b3LoadUrdfCommandSetFlags(commandHandle, grpcCmd.flags());
}
}
}
break;
}
case CMD_INIT_POSE:
{
btAssert(grpcCommand.has_initposecommand());
if (grpcCommand.has_initposecommand())
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
const ::pybullet_grpc::InitPoseCommand& grpcCmd = grpcCommand.initposecommand();
b3CreatePoseCommandInit2(commandHandle, grpcCmd.bodyuniqueid());
cmd.m_updateFlags = grpcCmd.updateflags();
double initialQ[MAX_DEGREE_OF_FREEDOM] = { 0 };
double initialQdot[MAX_DEGREE_OF_FREEDOM] = { 0 };
int hasInitialQ[MAX_DEGREE_OF_FREEDOM] = { 0 };
int hasInitialQdot[MAX_DEGREE_OF_FREEDOM] = { 0 };
if (grpcCmd.initialstateq_size() == grpcCmd.hasinitialstateq_size())
{
int numInitial = btMin(grpcCmd.initialstateq_size(), MAX_DEGREE_OF_FREEDOM);
for (int i = 0; i < numInitial; i++)
{
initialQ[i] = grpcCmd.initialstateq(i);
hasInitialQ[i] = grpcCmd.hasinitialstateq(i);
}
if (numInitial)
{
b3CreatePoseCommandSetQ(commandHandle, numInitial, initialQ, hasInitialQ);
}
}
else
{
printf("Error: if (grpcCmd.initialstateq_size() != grpcCmd.hasinitialstateq_size())\n");
}
if (grpcCmd.initialstateqdot_size() == grpcCmd.hasinitialstateqdot_size())
{
int numInitial = btMin(grpcCmd.initialstateqdot_size(), MAX_DEGREE_OF_FREEDOM);
for (int i = 0; i < numInitial; i++)
{
initialQdot[i] = grpcCmd.initialstateqdot(i);
hasInitialQdot[i] = grpcCmd.hasinitialstateqdot(i);
}
if (numInitial)
{
b3CreatePoseCommandSetQdots(commandHandle, numInitial, initialQdot, hasInitialQdot);
}
}
else
{
printf("Error: (grpcCmd.initialstateqdot_size() != grpcCmd.hasinitialstateqdot_size())\n");
}
}
break;
}
case CMD_REQUEST_ACTUAL_STATE:
{
btAssert(grpcCommand.has_requestactualstatecommand());
if (grpcCommand.has_requestactualstatecommand())
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
const ::pybullet_grpc::RequestActualStateCommand& grpcCmd = grpcCommand.requestactualstatecommand();
b3RequestActualStateCommandInit2(commandHandle, grpcCmd.bodyuniqueid());
if (grpcCmd.computeforwardkinematics())
{
b3RequestActualStateCommandComputeForwardKinematics(commandHandle, grpcCmd.computeforwardkinematics());
}
if (grpcCmd.computelinkvelocities())
{
b3RequestActualStateCommandComputeLinkVelocity(commandHandle, grpcCmd.computelinkvelocities());
}
}
break;
}
case CMD_SEND_DESIRED_STATE:
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
const ::pybullet_grpc::JointMotorControlCommand* motor = &grpcCommand.jointmotorcontrolcommand();
b3JointControlCommandInit2Internal(commandHandle, motor->bodyuniqueid(), motor->controlmode());
int maxQ = motor->hasdesiredstateflags_size();
for (int q = 0; q < maxQ; q++)
{
if (motor->hasdesiredstateflags(q)&SIM_DESIRED_STATE_HAS_Q)
{
b3JointControlSetDesiredPosition(commandHandle, q, motor->desiredstateq(q));
}
if (motor->hasdesiredstateflags(q)&SIM_DESIRED_STATE_HAS_QDOT)
{
b3JointControlSetDesiredVelocity(commandHandle, q, motor->desiredstateqdot(q));
}
if (motor->hasdesiredstateflags(q)&SIM_DESIRED_STATE_HAS_KD)
{
b3JointControlSetKd(commandHandle, q, motor->kd(q));
}
if (motor->hasdesiredstateflags(q)&SIM_DESIRED_STATE_HAS_KP)
{
b3JointControlSetKd(commandHandle, q, motor->kp(q));
}
if (motor->hasdesiredstateflags(q)&SIM_DESIRED_STATE_HAS_MAX_FORCE)
{
b3JointControlSetMaximumForce(commandHandle, q, motor->desiredstateforcetorque(q));
}
if (motor->hasdesiredstateflags(q)&SIM_DESIRED_STATE_HAS_RHS_CLAMP)
{
b3JointControlSetMaximumVelocity(commandHandle, q, motor->maxvelocity(q));
}
}
//b3JointControlCommandInit2Internal
break;
}
case CMD_SEND_PHYSICS_SIMULATION_PARAMETERS:
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
b3InitPhysicsParamCommand2(commandHandle);
int updateFlags = grpcCommand.setphysicssimulationparameterscommand().updateflags();
const ::pybullet_grpc::PhysicsSimulationParameters* params = &grpcCommand.setphysicssimulationparameterscommand().params();
if (updateFlags&SIM_PARAM_UPDATE_DELTA_TIME)
{
b3PhysicsParamSetTimeStep(commandHandle, params->deltatime());
}
if (updateFlags&SIM_PARAM_UPDATE_GRAVITY)
{
const ::pybullet_grpc::vec3* grav = &params->gravityacceleration();
b3PhysicsParamSetGravity(commandHandle, grav->x(), grav->y(), grav->z());
}
if (updateFlags&SIM_PARAM_UPDATE_NUM_SOLVER_ITERATIONS)
{
b3PhysicsParamSetNumSolverIterations(commandHandle, params->numsolveriterations());
}
if (updateFlags&SIM_PARAM_UPDATE_NUM_SIMULATION_SUB_STEPS)
{
b3PhysicsParamSetNumSubSteps(commandHandle, params->numsimulationsubsteps());
}
if (updateFlags&SIM_PARAM_UPDATE_REAL_TIME_SIMULATION)
{
b3PhysicsParamSetRealTimeSimulation(commandHandle, params->userealtimesimulation());
}
if (updateFlags&SIM_PARAM_UPDATE_DEFAULT_CONTACT_ERP)
{
b3PhysicsParamSetDefaultContactERP(commandHandle, params->defaultcontacterp());
}
if (updateFlags&SIM_PARAM_UPDATE_INTERNAL_SIMULATION_FLAGS)
{
b3PhysicsParamSetInternalSimFlags(commandHandle, params->internalsimflags());
}
if (updateFlags&SIM_PARAM_UPDATE_USE_SPLIT_IMPULSE)
{
b3PhysicsParamSetUseSplitImpulse(commandHandle, params->usesplitimpulse());
}
if (updateFlags&SIM_PARAM_UPDATE_SPLIT_IMPULSE_PENETRATION_THRESHOLD)
{
b3PhysicsParamSetSplitImpulsePenetrationThreshold(commandHandle, params->splitimpulsepenetrationthreshold());
}
if (updateFlags&SIM_PARAM_UPDATE_COLLISION_FILTER_MODE)
{
b3PhysicsParamSetCollisionFilterMode(commandHandle, params->collisionfiltermode());
}
if (updateFlags&SIM_PARAM_UPDATE_CONTACT_BREAKING_THRESHOLD)
{
b3PhysicsParamSetContactBreakingThreshold(commandHandle, params->contactbreakingthreshold());
}
if (updateFlags&SIM_PARAM_ENABLE_CONE_FRICTION)
{
b3PhysicsParamSetEnableConeFriction(commandHandle, params->enableconefriction());
}
if (updateFlags&SIM_PARAM_ENABLE_FILE_CACHING)
{
b3PhysicsParamSetEnableFileCaching(commandHandle, params->enablefilecaching());
}
if (updateFlags&SIM_PARAM_UPDATE_RESTITUTION_VELOCITY_THRESHOLD)
{
b3PhysicsParamSetRestitutionVelocityThreshold(commandHandle, params->restitutionvelocitythreshold());
}
if (updateFlags&SIM_PARAM_UPDATE_DEFAULT_NON_CONTACT_ERP)
{
b3PhysicsParamSetDefaultNonContactERP(commandHandle, params->defaultnoncontacterp());
}
if (updateFlags&SIM_PARAM_UPDATE_DEFAULT_FRICTION_ERP)
{
b3PhysicsParamSetDefaultFrictionERP(commandHandle, params->frictionerp());
}
if (updateFlags&SIM_PARAM_UPDATE_DETERMINISTIC_OVERLAPPING_PAIRS)
{
b3PhysicsParameterSetDeterministicOverlappingPairs(commandHandle, params->deterministicoverlappingpairs());
}
if (updateFlags&SIM_PARAM_UPDATE_CCD_ALLOWED_PENETRATION)
{
b3PhysicsParameterSetAllowedCcdPenetration(commandHandle, params->allowedccdpenetration());
}
if (updateFlags&SIM_PARAM_UPDATE_JOINT_FEEDBACK_MODE)
{
b3PhysicsParameterSetJointFeedbackMode(commandHandle, params->jointfeedbackmode());
}
if (updateFlags&SIM_PARAM_UPDATE_DEFAULT_GLOBAL_CFM)
{
b3PhysicsParamSetDefaultGlobalCFM(commandHandle, params->defaultglobalcfm());
}
if (updateFlags&SIM_PARAM_UPDATE_DEFAULT_FRICTION_CFM)
{
b3PhysicsParamSetDefaultFrictionCFM(commandHandle, params->frictioncfm());
}
if (updateFlags&SIM_PARAM_UPDATE_SOLVER_RESIDULAL_THRESHOLD)
{
b3PhysicsParamSetSolverResidualThreshold(commandHandle, params->solverresidualthreshold());
}
if (updateFlags&SIM_PARAM_UPDATE_CONTACT_SLOP)
{
b3PhysicsParamSetContactSlop(commandHandle, params->contactslop());
}
if (updateFlags&SIM_PARAM_ENABLE_SAT)
{
b3PhysicsParameterSetEnableSAT(commandHandle, params->enablesat());
}
if (updateFlags&SIM_PARAM_CONSTRAINT_SOLVER_TYPE)
{
b3PhysicsParameterSetConstraintSolverType(commandHandle, params->constraintsolvertype());
}
if (updateFlags&SIM_PARAM_CONSTRAINT_MIN_SOLVER_ISLAND_SIZE)
{
b3PhysicsParameterSetMinimumSolverIslandSize(commandHandle, params->minimumsolverislandsize());
}
break;
}
case CMD_REQUEST_BODY_INFO:
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
cmd.m_sdfRequestInfoArgs.m_bodyUniqueId = grpcCommand.requestbodyinfocommand().bodyuniqueid();
break;
}
case CMD_REQUEST_PHYSICS_SIMULATION_PARAMETERS:
{
cmdPtr = &cmd;
break;
}
case CMD_SYNC_BODY_INFO:
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
break;
}
case CMD_REQUEST_INTERNAL_DATA:
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
break;
}
case CMD_CONFIGURE_OPENGL_VISUALIZER:
{
btAssert(grpcCommand.has_configureopenglvisualizercommand());
if (grpcCommand.has_configureopenglvisualizercommand())
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
const ::pybullet_grpc::ConfigureOpenGLVisualizerCommand& grpcCmd = grpcCommand.configureopenglvisualizercommand();
b3InitConfigureOpenGLVisualizer2(commandHandle);
cmd.m_updateFlags = grpcCmd.updateflags();
cmd.m_configureOpenGLVisualizerArguments.m_cameraDistance = grpcCmd.cameradistance();
cmd.m_configureOpenGLVisualizerArguments.m_cameraPitch = grpcCmd.camerapitch();
cmd.m_configureOpenGLVisualizerArguments.m_cameraYaw = grpcCmd.camerayaw();
cmd.m_configureOpenGLVisualizerArguments.m_cameraTargetPosition[0] = grpcCmd.cameratargetposition().x();
cmd.m_configureOpenGLVisualizerArguments.m_cameraTargetPosition[1] = grpcCmd.cameratargetposition().y();
cmd.m_configureOpenGLVisualizerArguments.m_cameraTargetPosition[2] = grpcCmd.cameratargetposition().z();
cmd.m_configureOpenGLVisualizerArguments.m_setEnabled = grpcCmd.setenabled();
cmd.m_configureOpenGLVisualizerArguments.m_setFlag = grpcCmd.setflag();
}
break;
}
case CMD_REQUEST_CAMERA_IMAGE_DATA:
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
SharedMemoryCommand& clientCmd = cmd;
const ::pybullet_grpc::RequestCameraImageCommand* cam = &grpcCommand.requestcameraimagecommand();
b3InitRequestCameraImage2(commandHandle);
clientCmd.m_updateFlags = cam->updateflags();
clientCmd.m_requestPixelDataArguments.m_startPixelIndex = cam->startpixelindex();
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_PIXEL_WIDTH_HEIGHT)
{
clientCmd.m_requestPixelDataArguments.m_pixelWidth = cam->pixelwidth();
clientCmd.m_requestPixelDataArguments.m_pixelHeight = cam->pixelheight();
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_SPECULAR_COEFF)
{
clientCmd.m_requestPixelDataArguments.m_lightSpecularCoeff = cam->lightspecularcoeff();
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_HAS_FLAGS)
{
clientCmd.m_requestPixelDataArguments.m_flags = cam->cameraflags();
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_SHADOW)
{
clientCmd.m_requestPixelDataArguments.m_hasShadow = cam->hasshadow();
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_AMBIENT_COEFF)
{
clientCmd.m_requestPixelDataArguments.m_lightAmbientCoeff = cam->lightambientcoeff();
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_DIFFUSE_COEFF)
{
clientCmd.m_requestPixelDataArguments.m_lightDiffuseCoeff = cam->lightdiffusecoeff();
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_LIGHT_DISTANCE)
{
clientCmd.m_requestPixelDataArguments.m_lightDistance = cam->lightdistance();
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_LIGHT_COLOR)
{
const ::pybullet_grpc::vec3* lightColor = &cam->lightcolor();
clientCmd.m_requestPixelDataArguments.m_lightColor[0] = lightColor->x();
clientCmd.m_requestPixelDataArguments.m_lightColor[1] = lightColor->y();
clientCmd.m_requestPixelDataArguments.m_lightColor[2] = lightColor->z();
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_SET_LIGHT_DIRECTION)
{
const ::pybullet_grpc::vec3* lightDir = &cam->lightdirection();
clientCmd.m_requestPixelDataArguments.m_lightDirection[0] = lightDir->x();
clientCmd.m_requestPixelDataArguments.m_lightDirection[1] = lightDir->y();
clientCmd.m_requestPixelDataArguments.m_lightDirection[2] = lightDir->z();
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_HAS_CAMERA_MATRICES)
{
const ::pybullet_grpc::matrix4x4* projMat = &cam->projectionmatrix();
const ::pybullet_grpc::matrix4x4* viewMat = &cam->viewmatrix();
for (int i = 0; i < 16; i++)
{
clientCmd.m_requestPixelDataArguments.m_projectionMatrix[i] = projMat->elems(i);
clientCmd.m_requestPixelDataArguments.m_viewMatrix[i] = viewMat->elems(i);
}
}
if (clientCmd.m_updateFlags&REQUEST_PIXEL_ARGS_HAS_PROJECTIVE_TEXTURE_MATRICES)
{
const ::pybullet_grpc::matrix4x4* projectiveProjMat = &cam->projectivetextureprojectionmatrix();
const ::pybullet_grpc::matrix4x4* projectiveViewMat = &cam->projectivetextureviewmatrix();
for (int i = 0; i < 16; i++)
{
clientCmd.m_requestPixelDataArguments.m_projectiveTextureProjectionMatrix[i] = projectiveProjMat->elems(i);
clientCmd.m_requestPixelDataArguments.m_projectiveTextureViewMatrix[i] = projectiveViewMat->elems(i);
}
}
break;
}
#ifdef ALLOW_GRPC_COMMAND_CONVERSION
case CMD_LOAD_SDF:
{
btAssert(grpcCommand.has_loadsdfcommand());
if (grpcCommand.has_loadsdfcommand())
{
const ::pybullet_grpc::LoadSdfCommand& grpcCmd = grpcCommand.loadsdfcommand();
std::string fileName = grpcCmd.filename();
if (fileName.length())
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
b3LoadSdfCommandInit2(commandHandle, fileName.c_str());
if (grpcCmd.hasUseMultiBody_case() == ::pybullet_grpc::LoadSdfCommand::HasUseMultiBodyCase::kUseMultiBody)
{
b3LoadSdfCommandSetUseMultiBody(commandHandle, grpcCmd.usemultibody());
}
if (grpcCmd.hasGlobalScaling_case() == ::pybullet_grpc::LoadSdfCommand::HasGlobalScalingCase::kGlobalScaling)
{
b3LoadSdfCommandSetUseGlobalScaling(commandHandle, grpcCmd.globalscaling());
}
}
}
break;
}
case CMD_LOAD_MJCF:
{
btAssert(grpcCommand.has_loadmjcfcommand());
if (grpcCommand.has_loadmjcfcommand())
{
const pybullet_grpc::LoadMjcfCommand& grpcCmd = grpcCommand.loadmjcfcommand();
std::string fileName = grpcCmd.filename();
if (fileName.length())
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
b3LoadMJCFCommandInit2(commandHandle, fileName.c_str());
if (grpcCmd.flags())
{
b3LoadMJCFCommandSetFlags(commandHandle, grpcCmd.flags());
}
}
}
break;
}
case CMD_CHANGE_DYNAMICS_INFO:
{
btAssert(grpcCommand.has_changedynamicscommand());
if (grpcCommand.has_changedynamicscommand())
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
const ::pybullet_grpc::ChangeDynamicsCommand& grpcCmd = grpcCommand.changedynamicscommand();
int bodyUniqueId = grpcCmd.bodyuniqueid();
int linkIndex = grpcCmd.linkindex();
b3InitChangeDynamicsInfo2(commandHandle);
if (grpcCmd.hasMass_case() == ::pybullet_grpc::ChangeDynamicsCommand::HasMassCase::kMass)
{
b3ChangeDynamicsInfoSetMass(commandHandle, bodyUniqueId, linkIndex, grpcCmd.mass());
}
if (grpcCmd.hasLateralFriction_case() == ::pybullet_grpc::ChangeDynamicsCommand::HasLateralFrictionCase::kLateralFriction)
{
b3ChangeDynamicsInfoSetLateralFriction(commandHandle, bodyUniqueId, linkIndex, grpcCmd.lateralfriction());
}
if (grpcCmd.hasSpinningFriction_case() == ::pybullet_grpc::ChangeDynamicsCommand::HasSpinningFrictionCase::kSpinningFriction)
{
b3ChangeDynamicsInfoSetSpinningFriction(commandHandle, bodyUniqueId, linkIndex, grpcCmd.spinningfriction());
}
if (grpcCmd.hasRollingFriction_case() == ::pybullet_grpc::ChangeDynamicsCommand::HasRollingFrictionCase::kRollingFriction)
{
b3ChangeDynamicsInfoSetRollingFriction(commandHandle, bodyUniqueId, linkIndex, grpcCmd.rollingfriction());
}
if (grpcCmd.hasRestitution_case() == ::pybullet_grpc::ChangeDynamicsCommand::HasRestitutionCase::kRestitution)
{
b3ChangeDynamicsInfoSetRestitution(commandHandle, bodyUniqueId, linkIndex, grpcCmd.restitution());
}
if (grpcCmd.haslinearDamping_case() == ::pybullet_grpc::ChangeDynamicsCommand::HaslinearDampingCase::kLinearDamping)
{
b3ChangeDynamicsInfoSetLinearDamping(commandHandle, bodyUniqueId, grpcCmd.lineardamping());
}
if (grpcCmd.hasangularDamping_case() == ::pybullet_grpc::ChangeDynamicsCommand::HasangularDampingCase::kAngularDamping)
{
b3ChangeDynamicsInfoSetAngularDamping(commandHandle, bodyUniqueId, grpcCmd.angulardamping());
}
bool hasContactDamping = grpcCmd.hasContactDamping_case() == ::pybullet_grpc::ChangeDynamicsCommand::HasContactDampingCase::kContactDamping;
bool hasContactStiffness = grpcCmd.hasContactStiffness_case() == ::pybullet_grpc::ChangeDynamicsCommand::HasContactStiffnessCase::kContactStiffness;
if (hasContactDamping && hasContactStiffness)
{
b3ChangeDynamicsInfoSetContactStiffnessAndDamping(commandHandle, bodyUniqueId, linkIndex, grpcCmd.contactstiffness(), grpcCmd.contactdamping());
}
if (grpcCmd.hasLocalInertiaDiagonal_case() == ::pybullet_grpc::ChangeDynamicsCommand::HasLocalInertiaDiagonalCase::kLocalInertiaDiagonal)
{
double localInertiaDiag[3] = { grpcCmd.localinertiadiagonal().x(), grpcCmd.localinertiadiagonal().y(), grpcCmd.localinertiadiagonal().z() };
b3ChangeDynamicsInfoSetLocalInertiaDiagonal(commandHandle, bodyUniqueId, linkIndex, localInertiaDiag);
}
if (grpcCmd.hasFrictionAnchor_case() == ::pybullet_grpc::ChangeDynamicsCommand::HasFrictionAnchorCase::kFrictionAnchor)
{
b3ChangeDynamicsInfoSetFrictionAnchor(commandHandle, bodyUniqueId, linkIndex, grpcCmd.frictionanchor());
}
if (grpcCmd.hasccdSweptSphereRadius_case() == ::pybullet_grpc::ChangeDynamicsCommand::HasccdSweptSphereRadiusCase::kCcdSweptSphereRadius)
{
b3ChangeDynamicsInfoSetCcdSweptSphereRadius(commandHandle, bodyUniqueId, linkIndex, grpcCmd.ccdsweptsphereradius());
}
if (grpcCmd.hasContactProcessingThreshold_case() == ::pybullet_grpc::ChangeDynamicsCommand::HasContactProcessingThresholdCase::kContactProcessingThreshold)
{
b3ChangeDynamicsInfoSetContactProcessingThreshold(commandHandle, bodyUniqueId, linkIndex, grpcCmd.contactprocessingthreshold());
}
if (grpcCmd.hasActivationState_case() == ::pybullet_grpc::ChangeDynamicsCommand::HasActivationStateCase::kActivationState)
{
b3ChangeDynamicsInfoSetActivationState(commandHandle, bodyUniqueId, grpcCmd.activationstate());
}
}
break;
}
case CMD_GET_DYNAMICS_INFO:
{
btAssert(grpcCommand.has_getdynamicscommand());
if (grpcCommand.has_getdynamicscommand())
{
cmdPtr = &cmd;
b3SharedMemoryCommandHandle commandHandle = (b3SharedMemoryCommandHandle)cmdPtr;
const ::pybullet_grpc::GetDynamicsCommand& grpcCmd = grpcCommand.getdynamicscommand();
b3GetDynamicsInfoCommandInit2(commandHandle, grpcCmd.bodyuniqueid(), grpcCmd.linkindex());
}
break;
}
#endif //ALLOW_GRPC_COMMAND_CONVERSION
default:
{
printf("unknown convertGRPCToBulletCommand");
assert(0);
}
}
}
if (0 == cmdPtr)
{
printf("Error converting convertGRPCToBulletCommand");
}
btAssert(cmdPtr);
return cmdPtr;
}
bool convertGRPCToStatus(const PyBulletStatus& grpcReply, SharedMemoryStatus& serverStatus, char* bufferServerToClient, int bufferSizeInBytes)
{
bool converted = false;
serverStatus.m_type = grpcReply.statustype();
int sz = grpcReply.binaryblob().size();
if (sz > 0)
{
if (sz == 1)
{
const char* data = grpcReply.binaryblob().Get(0).c_str();
int numBytes = grpcReply.binaryblob().Get(0).size();
printf("copied binary blob of %d bytes\n", numBytes);
memcpy(bufferServerToClient, data, numBytes);
serverStatus.m_numDataStreamBytes = numBytes;
}
else
{
printf("Ignore unexpected binary blobs\n");
}
}
#ifdef ALLOW_GRPC_STATUS_CONVERSION
switch (grpcReply.statustype())
{
case CMD_ACTUAL_STATE_UPDATE_COMPLETED:
{
converted = true;
const ::pybullet_grpc::SendActualStateStatus* stat = &grpcReply.actualstatestatus();
serverStatus.m_sendActualStateArgs.m_bodyUniqueId = stat->bodyuniqueid();
int numLinks = stat->numlinks();
serverStatus.m_sendActualStateArgs.m_numLinks = numLinks;
int numDegreeOfFreedomQ = stat->numdegreeoffreedomq();
int numDegreeOfFreedomU = stat->numdegreeoffreedomu();
serverStatus.m_sendActualStateArgs.m_numDegreeOfFreedomQ = numDegreeOfFreedomQ;
serverStatus.m_sendActualStateArgs.m_numDegreeOfFreedomU = numDegreeOfFreedomU;
for (int i = 0; i < numDegreeOfFreedomQ; i++)
{
serverStatus.m_sendActualStateArgs.m_actualStateQ[i] = stat->actualstateq(i);
}
for (int i = 0; i < numDegreeOfFreedomU; i++)
{
serverStatus.m_sendActualStateArgs.m_actualStateQdot[i] = stat->actualstateqdot(i);
}
for (int i = 0; i < 7; i++)
{
serverStatus.m_sendActualStateArgs.m_rootLocalInertialFrame[i] = stat->rootlocalinertialframe(i);
}
for (int i = 0; i < numLinks * 6; i++)
{
serverStatus.m_sendActualStateArgs.m_linkLocalInertialFrames[i] = stat->linklocalinertialframes(i);
}
for (int i = 0; i < numLinks * 6; i++)
{
serverStatus.m_sendActualStateArgs.m_jointReactionForces[i] = stat->jointreactionforces(i);
}
for (int i = 0; i < numLinks; i++)
{
serverStatus.m_sendActualStateArgs.m_jointMotorForce[i] = stat->jointmotorforce(i);
}
for (int i = 0; i < numLinks * 7; i++)
{
serverStatus.m_sendActualStateArgs.m_linkState[i] = stat->linkstate(i);
}
for (int i = 0; i < numLinks * 6; i++)
{
serverStatus.m_sendActualStateArgs.m_linkWorldVelocities[i] = stat->linkworldvelocities(i);
}
break;
}
case CMD_REQUEST_KEYBOARD_EVENTS_DATA_COMPLETED:
{
converted = true;
const ::pybullet_grpc::KeyboardEventsStatus* keys = &grpcReply.keyboardeventsstatus();
serverStatus.m_sendKeyboardEvents.m_numKeyboardEvents = keys->keyboardevents_size();
for (int i = 0; i < serverStatus.m_sendKeyboardEvents.m_numKeyboardEvents; i++)
{
const ::pybullet_grpc::KeyboardEvent* key = &keys->keyboardevents(i);
serverStatus.m_sendKeyboardEvents.m_keyboardEvents[i].m_keyCode = key->keycode();
serverStatus.m_sendKeyboardEvents.m_keyboardEvents[i].m_keyState = key->keystate();
}
break;
}
case CMD_REQUEST_PHYSICS_SIMULATION_PARAMETERS_COMPLETED:
{
const ::pybullet_grpc::PhysicsSimulationParameters* params = &grpcReply.requestphysicssimulationparametersstatus();
serverStatus.m_simulationParameterResultArgs.m_allowedCcdPenetration = params->allowedccdpenetration();
serverStatus.m_simulationParameterResultArgs.m_collisionFilterMode = params->collisionfiltermode();
serverStatus.m_simulationParameterResultArgs.m_constraintSolverType = params->constraintsolvertype();
serverStatus.m_simulationParameterResultArgs.m_contactBreakingThreshold = params->contactbreakingthreshold();
serverStatus.m_simulationParameterResultArgs.m_contactSlop = params->contactslop();
serverStatus.m_simulationParameterResultArgs.m_defaultContactERP = params->defaultcontacterp();
serverStatus.m_simulationParameterResultArgs.m_defaultGlobalCFM = params -> defaultglobalcfm();
serverStatus.m_simulationParameterResultArgs.m_defaultNonContactERP = params->defaultnoncontacterp();
serverStatus.m_simulationParameterResultArgs.m_deltaTime = params->deltatime();
serverStatus.m_simulationParameterResultArgs.m_deterministicOverlappingPairs = params->deterministicoverlappingpairs();
serverStatus.m_simulationParameterResultArgs.m_enableConeFriction = params->enableconefriction();
serverStatus.m_simulationParameterResultArgs.m_enableFileCaching = params->enablefilecaching();
serverStatus.m_simulationParameterResultArgs.m_enableSAT = params->enablesat();
serverStatus.m_simulationParameterResultArgs.m_frictionCFM = params -> frictioncfm();
serverStatus.m_simulationParameterResultArgs.m_frictionERP = params->frictionerp();
serverStatus.m_simulationParameterResultArgs.m_gravityAcceleration[0] = params->gravityacceleration().x();
serverStatus.m_simulationParameterResultArgs.m_gravityAcceleration[1] = params->gravityacceleration().y();
serverStatus.m_simulationParameterResultArgs.m_gravityAcceleration[2] = params->gravityacceleration().z();
serverStatus.m_simulationParameterResultArgs.m_internalSimFlags = params->internalsimflags();
serverStatus.m_simulationParameterResultArgs.m_jointFeedbackMode = params->jointfeedbackmode();
serverStatus.m_simulationParameterResultArgs.m_minimumSolverIslandSize = params->minimumsolverislandsize();
serverStatus.m_simulationParameterResultArgs.m_numSimulationSubSteps = params->numsimulationsubsteps();
serverStatus.m_simulationParameterResultArgs.m_numSolverIterations = params->numsolveriterations();
serverStatus.m_simulationParameterResultArgs.m_restitutionVelocityThreshold = params->restitutionvelocitythreshold();
serverStatus.m_simulationParameterResultArgs.m_solverResidualThreshold = params->solverresidualthreshold();
serverStatus.m_simulationParameterResultArgs.m_splitImpulsePenetrationThreshold = params->splitimpulsepenetrationthreshold();
serverStatus.m_simulationParameterResultArgs.m_useRealTimeSimulation = params->userealtimesimulation();
serverStatus.m_simulationParameterResultArgs.m_useSplitImpulse = params->usesplitimpulse();
converted = true;
break;
}
case CMD_BODY_INFO_COMPLETED:
{
converted = true;
serverStatus.m_dataStreamArguments.m_bodyUniqueId = grpcReply.requestbodyinfostatus().bodyuniqueid();
serverStatus.m_dataStreamArguments.m_bodyName[0] = 0;
serverStatus.m_dataStreamArguments.m_bulletFileName[0] = 0;
if (grpcReply.requestbodyinfostatus().bodyname().length())
{
strcpy(serverStatus.m_dataStreamArguments.m_bodyName, grpcReply.requestbodyinfostatus().bodyname().c_str());
}
break;
}
case CMD_SYNC_BODY_INFO_COMPLETED:
{
serverStatus.m_sdfLoadedArgs.m_numBodies = grpcReply.syncbodiesstatus().bodyuniqueids_size();
for (int i = 0; i < serverStatus.m_sdfLoadedArgs.m_numBodies; i++)
{
serverStatus.m_sdfLoadedArgs.m_bodyUniqueIds[i] = grpcReply.syncbodiesstatus().bodyuniqueids(i);
}
serverStatus.m_sdfLoadedArgs.m_numUserConstraints = grpcReply.syncbodiesstatus().userconstraintuniqueids_size();
for (int i = 0; i < serverStatus.m_sdfLoadedArgs.m_numUserConstraints; i++)
{
serverStatus.m_sdfLoadedArgs.m_userConstraintUniqueIds[i] = grpcReply.syncbodiesstatus().userconstraintuniqueids(i);
}
converted = true;
break;
}
case CMD_CLIENT_COMMAND_COMPLETED:
{
converted = true;
break;
}
case CMD_REQUEST_INTERNAL_DATA_COMPLETED:
{
converted = true;
break;
}
case CMD_URDF_LOADING_COMPLETED:
{
converted = true;
serverStatus.m_dataStreamArguments.m_bodyUniqueId = grpcReply.urdfstatus().bodyuniqueid();
if (grpcReply.urdfstatus().bodyname().length()>0 && grpcReply.urdfstatus().bodyname().length()<(MAX_FILENAME_LENGTH-1))
{
strcpy(serverStatus.m_dataStreamArguments.m_bodyName, grpcReply.urdfstatus().bodyname().c_str());
}
else
{
serverStatus.m_dataStreamArguments.m_bodyName[0] = 0;
}
if (grpcReply.urdfstatus().filename().length() > 0 && grpcReply.urdfstatus().filename().length() < (MAX_FILENAME_LENGTH - 1))
{
strcpy(serverStatus.m_dataStreamArguments.m_bulletFileName, grpcReply.urdfstatus().filename().c_str());
}
else
{
serverStatus.m_dataStreamArguments.m_bulletFileName[0] = 0;
}
break;
}
case CMD_DESIRED_STATE_RECEIVED_COMPLETED:
{
converted = true;
break;
}
case CMD_USER_CONSTRAINT_COMPLETED:
{
const ::pybullet_grpc::UserConstraintStatus* con = &grpcReply.userconstraintstatus();
serverStatus.m_userConstraintResultArgs.m_userConstraintUniqueId=con->userconstraintuniqueid();
serverStatus.m_userConstraintResultArgs.m_maxAppliedForce = con->maxappliedforce();
converted = true;
break;
}
case CMD_STEP_FORWARD_SIMULATION_COMPLETED:
{
converted = true;
break;
}
case CMD_RESET_SIMULATION_COMPLETED:
{
converted = true;
break;
}
case CMD_CAMERA_IMAGE_COMPLETED:
{
converted = true;
const ::pybullet_grpc::RequestCameraImageStatus* cam = &grpcReply.requestcameraimagestatus();
serverStatus.m_sendPixelDataArguments.m_imageWidth = cam->imagewidth();
serverStatus.m_sendPixelDataArguments.m_imageHeight = cam->imageheight();
serverStatus.m_sendPixelDataArguments.m_numPixelsCopied = cam->numpixelscopied();
serverStatus.m_sendPixelDataArguments.m_numRemainingPixels = cam->numremainingpixels();
serverStatus.m_sendPixelDataArguments.m_startingPixelIndex = cam->startingpixelindex();
break;
}
default:
{
#endif //ALLOW_GRPC_STATUS_CONVERSION
if (grpcReply.unknownstatusbinaryblob_size() > 0)
{
if (grpcReply.unknownstatusbinaryblob_size() == 1)
{
//printf("convertStatusToGRPC: slow fallback status (%d), slow fallback", grpcReply.statustype());
const char* data = grpcReply.unknownstatusbinaryblob().Get(0).c_str();
int numBytes = grpcReply.unknownstatusbinaryblob().Get(0).size();
btAssert(sizeof(SharedMemoryStatus)== numBytes);
if (sizeof(SharedMemoryStatus) == numBytes)
{
memcpy(&serverStatus, data, numBytes);
}
//printf("slow fallback on command type %d\n", serverStatus.m_type);
btAssert(grpcReply.statustype() == serverStatus.m_type);
converted = true;
}
else
{
printf("unexpected unknownstatusbinaryblob_size\n");
}
}
else
{
printf("unknown status and no slow fallback in convertStatusToGRPC %d\n", grpcReply.statustype());
}
#ifdef ALLOW_GRPC_STATUS_CONVERSION
}
};
#endif //ALLOW_GRPC_STATUS_CONVERSION
return converted;
}
bool convertStatusToGRPC(const SharedMemoryStatus& serverStatus, char* bufferServerToClient, int bufferSizeInBytes, PyBulletStatus& grpcReply)
{
bool converted = false;
grpcReply.set_statustype(serverStatus.m_type);
if (serverStatus.m_numDataStreamBytes)
{
grpcReply.add_binaryblob(bufferServerToClient, serverStatus.m_numDataStreamBytes);
}
#ifdef ALLOW_GRPC_STATUS_CONVERSION
switch (serverStatus.m_type)
{
case CMD_REQUEST_KEYBOARD_EVENTS_DATA_COMPLETED:
{
converted = true;
::pybullet_grpc::KeyboardEventsStatus* keys = grpcReply.mutable_keyboardeventsstatus();
for (int i = 0; i < serverStatus.m_sendKeyboardEvents.m_numKeyboardEvents; i++)
{
::pybullet_grpc::KeyboardEvent* key = keys->add_keyboardevents();
key->set_keycode(serverStatus.m_sendKeyboardEvents.m_keyboardEvents[i].m_keyCode);
key->set_keystate(serverStatus.m_sendKeyboardEvents.m_keyboardEvents[i].m_keyState);
}
break;
}
case CMD_REQUEST_PHYSICS_SIMULATION_PARAMETERS_COMPLETED:
{
::pybullet_grpc::PhysicsSimulationParameters* params = grpcReply.mutable_requestphysicssimulationparametersstatus();
params->set_allowedccdpenetration(serverStatus.m_simulationParameterResultArgs.m_allowedCcdPenetration);
params->set_collisionfiltermode(serverStatus.m_simulationParameterResultArgs.m_collisionFilterMode);
params->set_constraintsolvertype(serverStatus.m_simulationParameterResultArgs.m_constraintSolverType);
params->set_contactbreakingthreshold(serverStatus.m_simulationParameterResultArgs.m_contactBreakingThreshold);
params->set_contactslop(serverStatus.m_simulationParameterResultArgs.m_contactSlop);
params->set_defaultcontacterp(serverStatus.m_simulationParameterResultArgs.m_defaultContactERP);
params->set_defaultglobalcfm(serverStatus.m_simulationParameterResultArgs.m_defaultGlobalCFM);
params->set_defaultnoncontacterp(serverStatus.m_simulationParameterResultArgs.m_defaultNonContactERP);
params->set_deltatime(serverStatus.m_simulationParameterResultArgs.m_deltaTime);
params->set_deterministicoverlappingpairs(serverStatus.m_simulationParameterResultArgs.m_deterministicOverlappingPairs);
params->set_enableconefriction(serverStatus.m_simulationParameterResultArgs.m_enableConeFriction);
params->set_enablefilecaching(serverStatus.m_simulationParameterResultArgs.m_enableFileCaching);
params->set_enablesat(serverStatus.m_simulationParameterResultArgs.m_enableSAT);
params->set_frictioncfm(serverStatus.m_simulationParameterResultArgs.m_frictionCFM);
params->set_frictionerp(serverStatus.m_simulationParameterResultArgs.m_frictionERP);
::pybullet_grpc::vec3* grav = params->mutable_gravityacceleration();
grav->set_x(serverStatus.m_simulationParameterResultArgs.m_gravityAcceleration[0]);
grav->set_y(serverStatus.m_simulationParameterResultArgs.m_gravityAcceleration[1]);
grav->set_z(serverStatus.m_simulationParameterResultArgs.m_gravityAcceleration[2]);
params->set_internalsimflags(serverStatus.m_simulationParameterResultArgs.m_internalSimFlags);
params->set_jointfeedbackmode(serverStatus.m_simulationParameterResultArgs.m_jointFeedbackMode);
params->set_minimumsolverislandsize(serverStatus.m_simulationParameterResultArgs.m_minimumSolverIslandSize);
params->set_numsimulationsubsteps(serverStatus.m_simulationParameterResultArgs.m_numSimulationSubSteps);
params->set_numsolveriterations(serverStatus.m_simulationParameterResultArgs.m_numSolverIterations);
params->set_restitutionvelocitythreshold(serverStatus.m_simulationParameterResultArgs.m_restitutionVelocityThreshold);
params->set_solverresidualthreshold(serverStatus.m_simulationParameterResultArgs.m_solverResidualThreshold);
params->set_splitimpulsepenetrationthreshold(serverStatus.m_simulationParameterResultArgs.m_splitImpulsePenetrationThreshold);
params->set_userealtimesimulation(serverStatus.m_simulationParameterResultArgs.m_useRealTimeSimulation);
params->set_usesplitimpulse(serverStatus.m_simulationParameterResultArgs.m_useSplitImpulse);
converted = true;
break;
}
case CMD_BODY_INFO_COMPLETED:
{
converted = true;
::pybullet_grpc::RequestBodyInfoStatus* stat = grpcReply.mutable_requestbodyinfostatus();
stat->set_bodyuniqueid(serverStatus.m_dataStreamArguments.m_bodyUniqueId);
stat->set_bodyname(serverStatus.m_dataStreamArguments.m_bodyName);
break;
}
case CMD_SYNC_BODY_INFO_COMPLETED:
{
::pybullet_grpc::SyncBodiesStatus* stat = grpcReply.mutable_syncbodiesstatus();
for (int i = 0; i < serverStatus.m_sdfLoadedArgs.m_numBodies; i++)
{
stat->add_bodyuniqueids(serverStatus.m_sdfLoadedArgs.m_bodyUniqueIds[i]);
}
for (int i = 0; i < serverStatus.m_sdfLoadedArgs.m_numUserConstraints; i++)
{
stat->add_userconstraintuniqueids(serverStatus.m_sdfLoadedArgs.m_userConstraintUniqueIds[i]);
}
converted = true;
break;
}
case CMD_REQUEST_INTERNAL_DATA_COMPLETED:
{
converted = true;
break;
}
case CMD_URDF_LOADING_COMPLETED:
{
converted = true;
::pybullet_grpc::LoadUrdfStatus* stat = grpcReply.mutable_urdfstatus();
b3SharedMemoryStatusHandle statusHandle = (b3SharedMemoryStatusHandle)&serverStatus;
int objectUniqueId = b3GetStatusBodyIndex(statusHandle);
stat->set_bodyuniqueid(objectUniqueId);
break;
}
case CMD_SDF_LOADING_COMPLETED:
{
converted = true;
int bodyIndicesOut[MAX_SDF_BODIES];
::pybullet_grpc::SdfLoadedStatus* stat = grpcReply.mutable_sdfstatus();
b3SharedMemoryStatusHandle statusHandle = (b3SharedMemoryStatusHandle)&serverStatus;
int numBodies = b3GetStatusBodyIndices(statusHandle, bodyIndicesOut, MAX_SDF_BODIES);
if (numBodies > MAX_SDF_BODIES)
{
printf("SDF exceeds body capacity: %d > %d", numBodies, MAX_SDF_BODIES);
}
for (int i = 0; i < numBodies; i++)
{
stat->add_bodyuniqueids(bodyIndicesOut[i]);
}
break;
}
case CMD_MJCF_LOADING_COMPLETED:
{
converted = true;
int bodyIndicesOut[MAX_SDF_BODIES];
::pybullet_grpc::MjcfLoadedStatus* stat = grpcReply.mutable_mjcfstatus();
b3SharedMemoryStatusHandle statusHandle = (b3SharedMemoryStatusHandle)&serverStatus;
int numBodies = b3GetStatusBodyIndices(statusHandle, bodyIndicesOut, MAX_SDF_BODIES);
if (numBodies > MAX_SDF_BODIES)
{
printf("MJCF exceeds body capacity: %d > %d", numBodies, MAX_SDF_BODIES);
}
for (int i = 0; i < numBodies; i++)
{
stat->add_bodyuniqueids(bodyIndicesOut[i]);
}
break;
}
case CMD_GET_DYNAMICS_INFO_COMPLETED:
{
converted = true;
b3DynamicsInfo info;
b3SharedMemoryStatusHandle statusHandle = (b3SharedMemoryStatusHandle)&serverStatus;
if (b3GetDynamicsInfo(statusHandle, &info))
{
::pybullet_grpc::GetDynamicsStatus*stat = grpcReply.mutable_getdynamicsstatus();
stat->set_mass(info.m_mass);
stat->set_lateralfriction(info.m_lateralFrictionCoeff);
stat->set_spinningfriction(info.m_spinningFrictionCoeff);
stat->set_rollingfriction(info.m_rollingFrictionCoeff);
stat->set_restitution(info.m_restitution);
stat->set_lineardamping(info.m_linearDamping);
stat->set_angulardamping(info.m_angularDamping);
stat->set_contactstiffness(info.m_contactStiffness);
stat->set_contactdamping(info.m_contactDamping);
pybullet_grpc::vec3* localInertia = stat->mutable_localinertiadiagonal();
localInertia->set_x(info.m_localInertialDiagonal[0]);
localInertia->set_y(info.m_localInertialDiagonal[1]);
localInertia->set_z(info.m_localInertialDiagonal[2]);
stat->set_frictionanchor(info.m_frictionAnchor);
stat->set_ccdsweptsphereradius(info.m_ccdSweptSphereRadius);
stat->set_contactprocessingthreshold(info.m_contactProcessingThreshold);
stat->set_activationstate(info.m_activationState);
}
break;
}
case CMD_ACTUAL_STATE_UPDATE_COMPLETED:
{
converted = true;
b3SharedMemoryStatusHandle statusHandle = (b3SharedMemoryStatusHandle)&serverStatus;
int bodyUniqueId;
int numLinks;
int numDegreeOfFreedomQ;
int numDegreeOfFreedomU;
const double* rootLocalInertialFramePtr=0;
const double* actualStateQptr=0;
const double* actualStateQdotPtr=0;
const double* jointReactionForcesPtr = 0;
const double* linkLocalInertialFrames = 0;
const double* jointMotorForces = 0;
const double* linkStates = 0;
const double* linkWorldVelocities = 0;
if (b3GetStatusActualState2(
statusHandle, &bodyUniqueId,&numLinks,
&numDegreeOfFreedomQ,
&numDegreeOfFreedomU,
&rootLocalInertialFramePtr,
&actualStateQptr,
&actualStateQdotPtr,
&jointReactionForcesPtr,
&linkLocalInertialFrames,
&jointMotorForces,
&linkStates,
&linkWorldVelocities))
{
::pybullet_grpc::SendActualStateStatus* stat = grpcReply.mutable_actualstatestatus();
stat->set_bodyuniqueid(bodyUniqueId);
stat->set_numlinks(numLinks);
stat->set_numdegreeoffreedomq(numDegreeOfFreedomQ);
stat->set_numdegreeoffreedomu(numDegreeOfFreedomU);
for (int i = 0; i < numDegreeOfFreedomQ; i++)
{
stat->add_actualstateq( actualStateQptr[i]);
}
for (int i = 0; i < numDegreeOfFreedomU; i++)
{
stat->add_actualstateqdot( actualStateQdotPtr[i]);
}
for (int i = 0; i < 7; i++)
{
stat->add_rootlocalinertialframe(rootLocalInertialFramePtr[i]);
}
for (int i = 0; i < numLinks * 6; i++)
{
stat->add_linklocalinertialframes( linkLocalInertialFrames[i]);
}
for (int i = 0; i < numLinks * 6; i++)
{
stat->add_jointreactionforces(jointReactionForcesPtr[i]);
}
for (int i = 0; i < numLinks; i++)
{
stat->add_jointmotorforce(jointMotorForces[i]);
}
for (int i = 0; i < numLinks * 7; i++)
{
stat->add_linkstate(linkStates[i]);
}
for (int i = 0; i < numLinks * 6; i++)
{
stat->add_linkworldvelocities(linkWorldVelocities[i]);
}
}
break;
}
case CMD_CLIENT_COMMAND_COMPLETED:
{
converted = true;
//no action needed?
break;
}
case CMD_DESIRED_STATE_RECEIVED_COMPLETED:
{
converted = true;
break;
}
case CMD_USER_CONSTRAINT_COMPLETED:
{
::pybullet_grpc::UserConstraintStatus* con = grpcReply.mutable_userconstraintstatus();
con->set_userconstraintuniqueid(serverStatus.m_userConstraintResultArgs.m_userConstraintUniqueId);
con->set_maxappliedforce(serverStatus.m_userConstraintResultArgs.m_maxAppliedForce);
converted = true;
break;
}
case CMD_STEP_FORWARD_SIMULATION_COMPLETED:
{
converted = true;
break;
}
case CMD_RESET_SIMULATION_COMPLETED:
{
converted = true;
break;
}
case CMD_CAMERA_IMAGE_COMPLETED:
{
converted = true;
::pybullet_grpc::RequestCameraImageStatus* cam = grpcReply.mutable_requestcameraimagestatus();
cam->set_imagewidth(serverStatus.m_sendPixelDataArguments.m_imageWidth);
cam->set_imageheight(serverStatus.m_sendPixelDataArguments.m_imageHeight);
cam->set_numpixelscopied(serverStatus.m_sendPixelDataArguments.m_numPixelsCopied);
cam->set_numremainingpixels(serverStatus.m_sendPixelDataArguments.m_numRemainingPixels);
cam->set_startingpixelindex(serverStatus.m_sendPixelDataArguments.m_startingPixelIndex);
break;
}
/*
case CMD_USER_CONSTRAINT_INFO_COMPLETED:
{
}
case CMD_USER_CONSTRAINT_REQUEST_STATE_COMPLETED:
{
}
*/
default:
{
#endif //ALLOW_GRPC_STATUS_CONVERSION
//printf("convertStatusToGRPC: unknown status (%d), slow fallback", serverStatus.m_type);
int sz = sizeof(SharedMemoryStatus);
grpcReply.add_unknownstatusbinaryblob((const char*)&serverStatus, sz);
converted = true;
#ifdef ALLOW_GRPC_STATUS_CONVERSION
}
}
#endif //ALLOW_GRPC_STATUS_CONVERSION
return converted;
}