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00034 #include "pr2_mechanism_model/robot.h"
00035 #include "pr2_mechanism_model/transmission.h"
00036 #include <tinyxml/tinyxml.h>
00037 #include <urdf/model.h>
00038 #include <pluginlib/class_loader.h>
00039 #include "pr2_hardware_interface/hardware_interface.h"
00040
00041
00042 using namespace pr2_mechanism_model;
00043 using namespace pr2_hardware_interface;
00044
00045
00046 Robot::Robot(HardwareInterface *hw)
00047 :hw_(hw)
00048 {}
00049
00050
00051 bool Robot::initXml(TiXmlElement *root)
00052 {
00053
00054 if (!hw_){
00055 ROS_ERROR("Mechanism Model received an invalid hardware interface");
00056 return false;
00057 }
00058
00059
00060 if (!robot_model_.initXml(root)){
00061 ROS_ERROR("Mechanism Model failed to parse the URDF xml into a robot model");
00062 return false;
00063 }
00064
00065
00066 transmission_loader_.reset(new pluginlib::ClassLoader<pr2_mechanism_model::Transmission>(
00067 "pr2_mechanism_model", "pr2_mechanism_model::Transmission"));
00068
00069
00070 TiXmlElement *xit = NULL;
00071 for (xit = root->FirstChildElement("transmission"); xit;
00072 xit = xit->NextSiblingElement("transmission"))
00073 {
00074 std::string type(xit->Attribute("type"));
00075 Transmission *t = NULL;
00076 try {
00077
00078 if (!transmission_loader_->isClassAvailable(type))
00079 {
00080 std::vector<std::string> classes = transmission_loader_->getDeclaredClasses();
00081 for(unsigned int i = 0; i < classes.size(); ++i)
00082 {
00083 if(type == transmission_loader_->getName(classes[i]))
00084 {
00085 ROS_WARN("The deprecated transmission type %s was not found. Using the namespaced version %s instead. "
00086 "Please update your urdf file to use the namespaced version.",
00087 type.c_str(), classes[i].c_str());
00088 type = classes[i];
00089 break;
00090 }
00091 }
00092 }
00093 t = transmission_loader_->createClassInstance(type);
00094 }
00095 catch (const std::runtime_error &ex)
00096 {
00097 ROS_ERROR("Could not load class %s: %s", type.c_str(), ex.what());
00098 }
00099
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00119 if (!t)
00120 ROS_ERROR("Unknown transmission type: %s", type.c_str());
00121 else if (!t->initXml(xit, this)){
00122 ROS_ERROR("Failed to initialize transmission");
00123 delete t;
00124 }
00125 else
00126 transmissions_.push_back(t);
00127 }
00128
00129 return true;
00130 }
00131
00132 ros::Time Robot::getTime()
00133 {
00134 return hw_->current_time_;
00135 }
00136
00137 template <class T>
00138 int findIndexByName(const std::vector<T*>& v, const std::string &name)
00139 {
00140 for (unsigned int i = 0; i < v.size(); ++i)
00141 {
00142 if (v[i]->name_ == name)
00143 return i;
00144 }
00145 return -1;
00146 }
00147
00148 int Robot::getTransmissionIndex(const std::string &name) const
00149 {
00150 return findIndexByName(transmissions_, name);
00151 }
00152
00153 Actuator* Robot::getActuator(const std::string &name) const
00154 {
00155 return hw_->getActuator(name);
00156 }
00157
00158 Transmission* Robot::getTransmission(const std::string &name) const
00159 {
00160 int i = getTransmissionIndex(name);
00161 return i >= 0 ? transmissions_[i] : NULL;
00162 }
00163
00164
00165
00166
00167
00168 RobotState::RobotState(Robot *model)
00169 : model_(model)
00170 {
00171 assert(model_);
00172
00173 transmissions_in_.resize(model->transmissions_.size());
00174 transmissions_out_.resize(model->transmissions_.size());
00175
00176
00177 unsigned int js_size = 0;
00178 for (unsigned int i = 0; i < model_->transmissions_.size(); ++i)
00179 {
00180 Transmission *t = model_->transmissions_[i];
00181 for (unsigned int j = 0; j < t->actuator_names_.size(); ++j)
00182 {
00183 Actuator *act = model_->getActuator(t->actuator_names_[j]);
00184 assert(act != NULL);
00185 transmissions_in_[i].push_back(act);
00186 }
00187 js_size += t->joint_names_.size();
00188 }
00189
00190
00191 joint_states_.resize(js_size);
00192 unsigned int js_id = 0;
00193 for (unsigned int i = 0; i < model_->transmissions_.size(); ++i)
00194 {
00195 Transmission *t = model_->transmissions_[i];
00196 for (unsigned int j = 0; j < t->joint_names_.size(); ++j)
00197 {
00198 joint_states_[js_id].joint_ = model_->robot_model_.getJoint(t->joint_names_[j]);
00199 joint_states_map_[t->joint_names_[j]] = &(joint_states_[js_id]);
00200 transmissions_out_[i].push_back(&(joint_states_[js_id]));
00201 js_id++;
00202 }
00203 }
00204
00205
00206 if (model_->transmissions_.empty())
00207 ROS_WARN("No transmissions were specified in the robot description.");
00208 if (js_size == 0)
00209 ROS_WARN("None of the joints in the robot desription matches up to a motor. The robot is uncontrollable.");
00210 }
00211
00212
00213 JointState *RobotState::getJointState(const std::string &name)
00214 {
00215 std::map<std::string, JointState*>::iterator it = joint_states_map_.find(name);
00216 if (it == joint_states_map_.end())
00217 return NULL;
00218 else
00219 return it->second;
00220 }
00221
00222 const JointState *RobotState::getJointState(const std::string &name) const
00223 {
00224 std::map<std::string, JointState*>::const_iterator it = joint_states_map_.find(name);
00225 if (it == joint_states_map_.end())
00226 return NULL;
00227 else
00228 return it->second;
00229 }
00230
00231 void RobotState::propagateActuatorPositionToJointPosition()
00232 {
00233 for (unsigned int i = 0; i < model_->transmissions_.size(); ++i)
00234 {
00235 model_->transmissions_[i]->propagatePosition(transmissions_in_[i],
00236 transmissions_out_[i]);
00237 }
00238
00239 for (unsigned int i = 0; i < joint_states_.size(); i++)
00240 {
00241 joint_states_[i].joint_statistics_.update(&(joint_states_[i]));
00242 }
00243 }
00244
00245 void RobotState::propagateJointEffortToActuatorEffort()
00246 {
00247 for (unsigned int i = 0; i < model_->transmissions_.size(); ++i)
00248 {
00249 model_->transmissions_[i]->propagateEffort(transmissions_out_[i],
00250 transmissions_in_[i]);
00251 }
00252 }
00253
00254 bool RobotState::isHalted()
00255 {
00256 for (unsigned int t = 0; t < transmissions_in_.size(); ++t){
00257 for (unsigned int a = 0; a < transmissions_in_[t].size(); a++){
00258 if (transmissions_in_[t][a]->state_.halted_)
00259 return true;
00260 }
00261 }
00262
00263 return false;
00264 }
00265
00266 void RobotState::enforceSafety()
00267 {
00268 for (unsigned int i = 0; i < joint_states_.size(); ++i)
00269 {
00270 joint_states_[i].enforceLimits();
00271 }
00272 }
00273
00274 void RobotState::zeroCommands()
00275 {
00276 for (unsigned int i = 0; i < joint_states_.size(); ++i)
00277 joint_states_[i].commanded_effort_ = 0;
00278 }
00279
00280 void RobotState::propagateJointPositionToActuatorPosition()
00281 {
00282 for (unsigned int i = 0; i < model_->transmissions_.size(); ++i)
00283 {
00284 model_->transmissions_[i]->propagatePositionBackwards(transmissions_out_[i],
00285 transmissions_in_[i]);
00286 }
00287 }
00288
00289 void RobotState::propagateActuatorEffortToJointEffort()
00290 {
00291 for (unsigned int i = 0; i < model_->transmissions_.size(); ++i)
00292 {
00293 model_->transmissions_[i]->propagateEffortBackwards(transmissions_in_[i],
00294 transmissions_out_[i]);
00295 }
00296 }
00297
00298