Changeset 15 in flair-src for trunk/lib/FlairSensorActuator/src
- Timestamp:
- Apr 8, 2016, 3:40:57 PM (9 years ago)
- Location:
- trunk/lib/FlairSensorActuator/src
- Files:
-
- 78 edited
Legend:
- Unmodified
- Added
- Removed
-
trunk/lib/FlairSensorActuator/src/AfroBldc.cpp
r3 r15 30 30 using namespace flair::gui; 31 31 32 namespace flair { namespace actuator { 32 namespace flair { 33 namespace actuator { 33 34 34 AfroBldc::AfroBldc(const IODevice* parent,Layout* layout,string name,uint8_t motors_count,I2cPort* i2cport) : Bldc(parent,layout,name,motors_count) { 35 pimpl_=new AfroBldc_impl(this,layout,i2cport); 35 AfroBldc::AfroBldc(const IODevice *parent, Layout *layout, string name, 36 uint8_t motors_count, I2cPort *i2cport) 37 : Bldc(parent, layout, name, motors_count) { 38 pimpl_ = new AfroBldc_impl(this, layout, i2cport); 36 39 } 37 40 38 AfroBldc::~AfroBldc() { 39 delete pimpl_; 40 } 41 AfroBldc::~AfroBldc() { delete pimpl_; } 41 42 42 void AfroBldc::SetMotors(float* values) { 43 pimpl_->SetMotors(values); 44 } 43 void AfroBldc::SetMotors(float *values) { pimpl_->SetMotors(values); } 45 44 46 45 } // end namespace actuator -
trunk/lib/FlairSensorActuator/src/AfroBldc.h
r3 r15 16 16 #include "Bldc.h" 17 17 18 namespace flair 19 { 20 namespace core 21 { 22 class FrameworkManager; 23 class I2cPort; 24 } 25 namespace sensor 26 { 27 class BatteryMonitor; 28 } 18 namespace flair { 19 namespace core { 20 class FrameworkManager; 21 class I2cPort; 22 } 23 namespace sensor { 24 class BatteryMonitor; 25 } 29 26 } 30 27 31 28 class AfroBldc_impl; 32 29 33 namespace flair 34 { 35 namespace actuator 36 { 37 /*! \class AfroBldc 38 * 39 * \brief Class for Mikrokopter's blctrlv2 40 * 41 * blctrlv2 drivers can also monitor the battery level. See GetBatteryMonitor(). 42 */ 43 class AfroBldc : public Bldc 44 { 45 friend class ::AfroBldc_impl; 30 namespace flair { 31 namespace actuator { 32 /*! \class AfroBldc 33 * 34 * \brief Class for Mikrokopter's blctrlv2 35 * 36 * blctrlv2 drivers can also monitor the battery level. See GetBatteryMonitor(). 37 */ 38 class AfroBldc : public Bldc { 39 friend class ::AfroBldc_impl; 46 40 47 public: 48 /*! 49 * \brief Constructor 50 * 51 * Construct a AfroBldc. 52 * 53 * \param parent parent 54 * \param layout layout 55 * \param name name 56 * \param motors_count number of motors 57 * \param i2cport I2cPort 58 */ 59 AfroBldc(const core::IODevice* parent,gui::Layout* layout,std::string name,uint8_t motors_count,core::I2cPort* i2cport); 41 public: 42 /*! 43 * \brief Constructor 44 * 45 * Construct a AfroBldc. 46 * 47 * \param parent parent 48 * \param layout layout 49 * \param name name 50 * \param motors_count number of motors 51 * \param i2cport I2cPort 52 */ 53 AfroBldc(const core::IODevice *parent, gui::Layout *layout, std::string name, 54 uint8_t motors_count, core::I2cPort *i2cport); 60 55 61 62 63 64 65 56 /*! 57 * \brief Destructor 58 * 59 */ 60 ~AfroBldc(); 66 61 67 68 69 70 71 72 73 74 bool HasSpeedMeasurement(void) const{return false;};62 /*! 63 * \brief Has speed measurement 64 * 65 * Reimplemented from Bldc. \n 66 * 67 * \return true if it has speed measurement 68 */ 69 bool HasSpeedMeasurement(void) const { return false; }; 75 70 76 77 78 79 80 81 82 83 bool HasCurrentMeasurement(void) const{return false;};71 /*! 72 * \brief Has current measurement 73 * 74 * Reimplemented from Bldc. \n 75 * 76 * \return true if it has current measurement 77 */ 78 bool HasCurrentMeasurement(void) const { return false; }; 84 79 85 86 87 88 89 90 91 92 93 94 void SetMotors(float*values);80 private: 81 /*! 82 * \brief Set motors values 83 * 84 * Reimplemented from Bldc. \n 85 * Values size must be the same as MotorsCount() 86 * 87 * \param values motor values 88 */ 89 void SetMotors(float *values); 95 90 96 class AfroBldc_impl*pimpl_;97 91 class AfroBldc_impl *pimpl_; 92 }; 98 93 } // end namespace actuator 99 94 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/AfroBldc_impl.cpp
r3 r15 34 34 using namespace flair::actuator; 35 35 36 AfroBldc_impl::AfroBldc_impl(AfroBldc * self,Layout *layout,I2cPort*i2cport) {37 this->self=self;38 this->i2cport=i2cport;39 nb_mot=self->MotorsCount();36 AfroBldc_impl::AfroBldc_impl(AfroBldc *self, Layout *layout, I2cPort *i2cport) { 37 this->self = self; 38 this->i2cport = i2cport; 39 nb_mot = self->MotorsCount(); 40 40 } 41 41 42 AfroBldc_impl::~AfroBldc_impl() { 42 AfroBldc_impl::~AfroBldc_impl() {} 43 43 44 void AfroBldc_impl::SetMotors(float *value) { 45 uint16_t tosend_value[nb_mot]; 46 47 for (int i = 0; i < nb_mot; i++) 48 tosend_value[i] = (uint16_t)(MAX_VALUE * value[i]); 49 50 i2cport->GetMutex(); 51 52 for (int i = 0; i < nb_mot; i++) { 53 i2cport->SetSlave(BASE_ADDRESS + i); 54 WriteValue(tosend_value[i]); 55 } 56 i2cport->ReleaseMutex(); 44 57 } 45 58 46 void AfroBldc_impl::SetMotors(float* value) { 47 uint16_t tosend_value[nb_mot]; 59 // I2cPort mutex must be taken before calling this function 60 void AfroBldc_impl::WriteValue(uint16_t value) { 61 uint8_t tx[2]; 62 ssize_t written; 48 63 49 for(int i=0; i<nb_mot; i++) tosend_value[i]=(uint16_t)(MAX_VALUE*value[i]); 50 51 i2cport->GetMutex(); 52 53 for(int i=0; i<nb_mot; i++) { 54 i2cport->SetSlave(BASE_ADDRESS+i); 55 WriteValue(tosend_value[i]); 56 } 57 i2cport->ReleaseMutex(); 64 tx[0] = (uint8_t)(value >> 3); // msb 65 tx[1] = (value & 0x07); // lsb 66 written = i2cport->Write(tx, 2); 67 if (written < 0) { 68 self->Err("rt_dev_write error (%s)\n", strerror(-written)); 69 } else if (written != sizeof(tx)) { 70 self->Err("rt_dev_write error %i/%i\n", written, sizeof(tx)); 71 } 58 72 } 59 60 //I2cPort mutex must be taken before calling this function61 void AfroBldc_impl::WriteValue(uint16_t value) {62 uint8_t tx[2];63 ssize_t written;64 65 tx[0]=(uint8_t)(value>>3);//msb66 tx[1]=(value&0x07);//lsb67 written =i2cport->Write(tx, 2);68 if(written<0) {69 self->Err("rt_dev_write error (%s)\n",strerror(-written));70 } else if (written != sizeof(tx)) {71 self->Err("rt_dev_write error %i/%i\n",written,sizeof(tx));72 }73 } -
trunk/lib/FlairSensorActuator/src/BatteryMonitor.cpp
r3 r15 16 16 /*********************************************************************/ 17 17 18 19 18 #include "BatteryMonitor.h" 20 19 #include <Layout.h> … … 26 25 using namespace flair::gui; 27 26 28 namespace flair { namespace sensor { 27 namespace flair { 28 namespace sensor { 29 29 30 BatteryMonitor::BatteryMonitor(const gui::LayoutPosition* position,string name) : GroupBox(position,name) { 31 battery=new Label(this->NewRow(),"battery"); 32 battery_thresh=new DoubleSpinBox(this->LastRowLastCol(),"threshold"," V",0,24,.1,1); 30 BatteryMonitor::BatteryMonitor(const gui::LayoutPosition *position, string name) 31 : GroupBox(position, name) { 32 battery = new Label(this->NewRow(), "battery"); 33 battery_thresh = new DoubleSpinBox(this->LastRowLastCol(), "threshold", " V", 34 0, 24, .1, 1); 33 35 } 34 36 35 BatteryMonitor::~BatteryMonitor() { 37 BatteryMonitor::~BatteryMonitor() {} 36 38 37 } 38 39 float BatteryMonitor::GetVoltage(void) const { 40 return batteryvalue; 41 } 39 float BatteryMonitor::GetVoltage(void) const { return batteryvalue; } 42 40 43 41 bool BatteryMonitor::IsBatteryLow(void) const { 44 if(batteryvalue<battery_thresh->Value())45 46 47 42 if (batteryvalue < battery_thresh->Value()) 43 return true; 44 else 45 return false; 48 46 } 49 47 50 48 void BatteryMonitor::SetBatteryValue(float value) { 51 batteryvalue=value;52 if(value>0) {53 battery->SetText("battery: %.1fV",value);54 55 56 49 batteryvalue = value; 50 if (value > 0) { 51 battery->SetText("battery: %.1fV", value); 52 } else { 53 battery->SetText("battery: unreadable"); 54 } 57 55 } 58 56 -
trunk/lib/FlairSensorActuator/src/BatteryMonitor.h
r3 r15 16 16 #include <GroupBox.h> 17 17 18 namespace flair 19 { 20 namespace gui 21 { 22 class LayoutPosition; 23 class Label; 24 class DoubleSpinBox; 25 } 18 namespace flair { 19 namespace gui { 20 class LayoutPosition; 21 class Label; 22 class DoubleSpinBox; 23 } 26 24 } 27 25 28 namespace flair 29 { 30 namespace sensor 31 { 26 namespace flair { 27 namespace sensor { 32 28 33 34 35 36 29 /*! \class BatteryMonitor 30 * 31 * \brief Base class for battery monitor 32 */ 37 33 38 class BatteryMonitor : public gui::GroupBox 39 { 40 public: 41 /*! 42 * \brief Constructor 43 * 44 * Construct a BatteryMonitor at given position. 45 * 46 * \param position position 47 * \param name name 48 */ 49 BatteryMonitor(const gui::LayoutPosition* position,std::string name); 34 class BatteryMonitor : public gui::GroupBox { 35 public: 36 /*! 37 * \brief Constructor 38 * 39 * Construct a BatteryMonitor at given position. 40 * 41 * \param position position 42 * \param name name 43 */ 44 BatteryMonitor(const gui::LayoutPosition *position, std::string name); 50 45 51 52 53 54 55 46 /*! 47 * \brief Destructor 48 * 49 */ 50 ~BatteryMonitor(); 56 51 57 58 59 60 61 62 63 52 /*! 53 * \brief Is batteru low? 54 * 55 * \return true if battery is below threshold 56 * 57 */ 58 bool IsBatteryLow(void) const; 64 59 65 66 67 68 69 70 71 60 /*! 61 * \brief Set battery value 62 * 63 * \param battery value 64 * 65 */ 66 void SetBatteryValue(float value); 72 67 73 74 75 76 77 78 79 68 /*! 69 * \brief Get battery voltage 70 * 71 * \return battery voltage 72 * 73 */ 74 float GetVoltage(void) const; 80 75 81 82 83 84 85 76 private: 77 float batteryvalue; 78 gui::DoubleSpinBox *battery_thresh; 79 gui::Label *battery; 80 }; 86 81 } // end namespace sensor 87 82 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/BlCtrlV2.cpp
r3 r15 31 31 using namespace flair::gui; 32 32 33 namespace flair 34 { 35 namespace actuator 36 { 33 namespace flair { 34 namespace actuator { 37 35 38 BlCtrlV2::BlCtrlV2(const IODevice* parent,Layout* layout,string name,uint8_t motors_count,I2cPort* i2cport) : Bldc(parent,layout,name,motors_count) 39 { 40 pimpl_=new BlCtrlV2_impl(this,layout,i2cport); 36 BlCtrlV2::BlCtrlV2(const IODevice *parent, Layout *layout, string name, 37 uint8_t motors_count, I2cPort *i2cport) 38 : Bldc(parent, layout, name, motors_count) { 39 pimpl_ = new BlCtrlV2_impl(this, layout, i2cport); 41 40 } 42 41 43 BlCtrlV2::~BlCtrlV2() 44 { 45 delete pimpl_; 42 BlCtrlV2::~BlCtrlV2() { delete pimpl_; } 43 44 BatteryMonitor *BlCtrlV2::GetBatteryMonitor(void) const { 45 return pimpl_->battery; 46 46 } 47 47 48 BatteryMonitor* BlCtrlV2::GetBatteryMonitor(void) const 49 { 50 return pimpl_->battery; 51 } 52 53 void BlCtrlV2::SetMotors(float* values) 54 { 55 pimpl_->SetMotors(values); 56 } 48 void BlCtrlV2::SetMotors(float *values) { pimpl_->SetMotors(values); } 57 49 58 50 } // end namespace actuator -
trunk/lib/FlairSensorActuator/src/BlCtrlV2.h
r3 r15 16 16 #include "Bldc.h" 17 17 18 namespace flair 19 { 20 namespace core 21 { 22 class FrameworkManager; 23 class I2cPort; 24 } 25 namespace sensor 26 { 27 class BatteryMonitor; 28 } 18 namespace flair { 19 namespace core { 20 class FrameworkManager; 21 class I2cPort; 22 } 23 namespace sensor { 24 class BatteryMonitor; 25 } 29 26 } 30 27 31 28 class BlCtrlV2_impl; 32 29 33 namespace flair 34 { 35 namespace actuator 36 { 37 /*! \class BlCtrlV2 38 * 39 * \brief Class for Mikrokopter's blctrlv2 40 * 41 * blctrlv2 drivers can also monitor the battery level. See GetBatteryMonitor(). 42 */ 43 class BlCtrlV2 : public Bldc 44 { 45 friend class ::BlCtrlV2_impl; 30 namespace flair { 31 namespace actuator { 32 /*! \class BlCtrlV2 33 * 34 * \brief Class for Mikrokopter's blctrlv2 35 * 36 * blctrlv2 drivers can also monitor the battery level. See GetBatteryMonitor(). 37 */ 38 class BlCtrlV2 : public Bldc { 39 friend class ::BlCtrlV2_impl; 46 40 47 public: 48 /*! 49 * \brief Constructor 50 * 51 * Construct a BlCtrlV2. 52 * 53 * \param parent parent 54 * \param layout layout 55 * \param name name 56 * \param motors_count number of motors 57 * \param i2cport I2cPort 58 */ 59 BlCtrlV2(const core::IODevice* parent,gui::Layout* layout,std::string name,uint8_t motors_count,core::I2cPort* i2cport); 41 public: 42 /*! 43 * \brief Constructor 44 * 45 * Construct a BlCtrlV2. 46 * 47 * \param parent parent 48 * \param layout layout 49 * \param name name 50 * \param motors_count number of motors 51 * \param i2cport I2cPort 52 */ 53 BlCtrlV2(const core::IODevice *parent, gui::Layout *layout, std::string name, 54 uint8_t motors_count, core::I2cPort *i2cport); 60 55 61 62 63 64 65 56 /*! 57 * \brief Destructor 58 * 59 */ 60 ~BlCtrlV2(); 66 61 67 68 69 70 71 72 sensor::BatteryMonitor*GetBatteryMonitor(void) const;62 /*! 63 * \brief Get battery monitor 64 * 65 * \return BatteryMonitor 66 */ 67 sensor::BatteryMonitor *GetBatteryMonitor(void) const; 73 68 74 75 76 77 78 79 80 81 bool HasSpeedMeasurement(void) const{return true;};69 /*! 70 * \brief Has speed measurement 71 * 72 * Reimplemented from Bldc. \n 73 * 74 * \return true if it has speed measurement 75 */ 76 bool HasSpeedMeasurement(void) const { return true; }; 82 77 83 84 85 86 87 88 89 90 bool HasCurrentMeasurement(void) const{return true;};78 /*! 79 * \brief Has current measurement 80 * 81 * Reimplemented from Bldc. \n 82 * 83 * \return true if it has current measurement 84 */ 85 bool HasCurrentMeasurement(void) const { return true; }; 91 86 92 93 94 95 96 97 98 99 100 101 void SetMotors(float*values);87 private: 88 /*! 89 * \brief Set motors values 90 * 91 * Reimplemented from Bldc. \n 92 * Values size must be the same as MotorsCount() 93 * 94 * \param values motor values 95 */ 96 void SetMotors(float *values); 102 97 103 class BlCtrlV2_impl*pimpl_;104 98 class BlCtrlV2_impl *pimpl_; 99 }; 105 100 } // end namespace actuator 106 101 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/BlCtrlV2_impl.cpp
r3 r15 35 35 using namespace flair::actuator; 36 36 37 BlCtrlV2_impl::BlCtrlV2_impl(BlCtrlV2* self,Layout *layout,I2cPort* i2cport) { 38 this->self=self; 39 this->i2cport=i2cport; 40 last_voltage_time=0; 41 42 DetectMotors(); 43 //if(nb_mot!=self->MotorsCount()) self->Err("motors count different from multiplex count\n"); 44 45 //BatteryMonitor 46 battery=new BatteryMonitor(layout->NewRow(),"battery"); 47 48 //user interface 49 GroupBox *setupgroupbox=new GroupBox(layout->NewRow(),"Motors"); 50 poles=new SpinBox(setupgroupbox->NewRow(),"nb poles:",0,255,1,14); 51 } 52 53 BlCtrlV2_impl::~BlCtrlV2_impl() { 54 55 } 56 57 void BlCtrlV2_impl::SetMotors(float* value) { 58 uint16_t tosend_value[nb_mot]; 59 //stocke dans une variable pour garder le moins longtemps l'i2c (pour ne pas bloquer sur le mutex de l'output) 60 float speeds[nb_mot]; 61 float currents[nb_mot]; 62 63 for(int i=0;i<nb_mot;i++) tosend_value[i]=(uint16_t)(MAX_VALUE*value[i]); 64 65 i2cport->GetMutex(); 66 67 for(int i=0;i<nb_mot;i++) { 68 i2cport->SetSlave(BASE_ADDRESS+i); 69 WriteValue(tosend_value[i]); 37 BlCtrlV2_impl::BlCtrlV2_impl(BlCtrlV2 *self, Layout *layout, I2cPort *i2cport) { 38 this->self = self; 39 this->i2cport = i2cport; 40 last_voltage_time = 0; 41 42 DetectMotors(); 43 // if(nb_mot!=self->MotorsCount()) self->Err("motors count different from 44 // multiplex count\n"); 45 46 // BatteryMonitor 47 battery = new BatteryMonitor(layout->NewRow(), "battery"); 48 49 // user interface 50 GroupBox *setupgroupbox = new GroupBox(layout->NewRow(), "Motors"); 51 poles = new SpinBox(setupgroupbox->NewRow(), "nb poles:", 0, 255, 1, 14); 52 } 53 54 BlCtrlV2_impl::~BlCtrlV2_impl() {} 55 56 void BlCtrlV2_impl::SetMotors(float *value) { 57 uint16_t tosend_value[nb_mot]; 58 // stocke dans une variable pour garder le moins longtemps l'i2c (pour ne pas 59 // bloquer sur le mutex de l'output) 60 float speeds[nb_mot]; 61 float currents[nb_mot]; 62 63 for (int i = 0; i < nb_mot; i++) 64 tosend_value[i] = (uint16_t)(MAX_VALUE * value[i]); 65 66 i2cport->GetMutex(); 67 68 for (int i = 0; i < nb_mot; i++) { 69 i2cport->SetSlave(BASE_ADDRESS + i); 70 WriteValue(tosend_value[i]); 71 } 72 73 for (int i = 0; i < nb_mot; i++) { 74 i2cport->SetSlave(BASE_ADDRESS + i); 75 76 if (i == 0 && GetTime() > (last_voltage_time + 5 * (Time)1000000000)) { 77 // toute les 5 secondes sur moteur 0 78 float voltage; 79 GetCurrentSpeedAndVoltage(currents[i], speeds[i], voltage); 80 battery->SetBatteryValue(voltage); 81 last_voltage_time = GetTime(); 82 } else { 83 GetCurrentAndSpeed(currents[i], speeds[i]); 70 84 } 71 72 for(int i=0;i<nb_mot;i++) { 73 i2cport->SetSlave(BASE_ADDRESS+i); 74 75 if(i==0 && GetTime()>(last_voltage_time+5*(Time)1000000000)) { 76 //toute les 5 secondes sur moteur 0 77 float voltage; 78 GetCurrentSpeedAndVoltage(currents[i],speeds[i],voltage); 79 battery->SetBatteryValue(voltage); 80 last_voltage_time=GetTime(); 81 } else { 82 GetCurrentAndSpeed(currents[i],speeds[i]); 83 } 85 } 86 // printf("%f %f %f %f\n",speeds[0],speeds[1],speeds[2],speeds[3]); 87 /* 88 if(GetTime()>(last_voltage_time+5*(Time)1000000000))//toute les 5 secondes 89 { 90 i2cport->SetSlave(BASE_ADDRESS); 91 battery->SetBatteryValue(ReadVoltage()); 92 last_voltage_time=GetTime(); 93 } 94 */ 95 i2cport->ReleaseMutex(); 96 97 // on prend une fois pour toute le mutex et on fait des accès directs 98 cvmatrix *output = self->output; 99 output->GetMutex(); 100 for (int i = 0; i < nb_mot; i++) 101 output->SetValueNoMutex(i, 0, speeds[i]); 102 for (int i = 0; i < nb_mot; i++) 103 output->SetValueNoMutex(i, 1, currents[i]); 104 output->ReleaseMutex(); 105 } 106 107 // I2cPort mutex must be taken before calling this function 108 void BlCtrlV2_impl::WriteValue(uint16_t value) { 109 uint8_t tx[2]; 110 ssize_t written; 111 112 tx[0] = (uint8_t)(value >> 3); // msb 113 tx[1] = (value & 0x07); 114 ; //+16+8; //pour recuperer la vitesse en premier 115 written = i2cport->Write(tx, 2); 116 if (written < 0) { 117 self->Err("rt_dev_write error (%s)\n", strerror(-written)); 118 } else if (written != sizeof(tx)) { 119 self->Err("rt_dev_write error %i/%i\n", written, sizeof(tx)); 120 } 121 } 122 123 // I2cPort mutex must be taken before calling this function 124 void BlCtrlV2_impl::GetCurrentAndSpeed(float ¤t, float &speed) { 125 ssize_t read; 126 uint8_t value[4]; 127 read = i2cport->Read(value, sizeof(value)); 128 129 if (read < 0) { 130 self->Err("rt_dev_read error (%s)\n", strerror(-read)); 131 speed = -1; 132 current = -1; 133 } else if (read != sizeof(value)) { 134 self->Err("rt_dev_read error %i/%i\n", read, sizeof(value)); 135 speed = -1; 136 current = -1; 137 } else { 138 current = value[0] / 10.; 139 speed = value[3] * 780. / poles->Value(); 140 } 141 } 142 143 // I2cPort mutex must be taken before calling this function 144 void BlCtrlV2_impl::GetCurrentSpeedAndVoltage(float ¤t, float &speed, 145 float &voltage) { 146 ssize_t read; 147 uint8_t value[6]; 148 read = i2cport->Read(value, sizeof(value)); 149 150 if (read < 0) { 151 self->Err("rt_dev_read error (%s)\n", strerror(-read)); 152 speed = -1; 153 voltage = -1; 154 current = -1; 155 } else if (read != sizeof(value)) { 156 self->Err("rt_dev_read error %i/%i\n", read, sizeof(value)); 157 speed = -1; 158 voltage = -1; 159 current = -1; 160 } else { 161 current = value[0] / 10.; 162 voltage = value[5] / 10.; 163 speed = value[3] * 780. / poles->Value(); 164 } 165 } 166 167 void BlCtrlV2_impl::DetectMotors(void) { 168 int nb = 0; 169 ssize_t read, nb_write; 170 uint8_t value[3]; 171 uint8_t tx[2]; 172 173 i2cport->GetMutex(); 174 175 for (int i = 0; i < MAX_MOTORS; i++) { 176 // printf("test %i\n",i); 177 i2cport->SetSlave(BASE_ADDRESS + i); 178 tx[0] = 0; 179 tx[1] = 16 + 8; // 16+8 pour recuperer la vitesse 180 181 nb_write = i2cport->Write(tx, 2); 182 183 if (nb_write != sizeof(tx)) { 184 continue; 84 185 } 85 //printf("%f %f %f %f\n",speeds[0],speeds[1],speeds[2],speeds[3]); 86 /* 87 if(GetTime()>(last_voltage_time+5*(Time)1000000000))//toute les 5 secondes 88 { 89 i2cport->SetSlave(BASE_ADDRESS); 90 battery->SetBatteryValue(ReadVoltage()); 91 last_voltage_time=GetTime(); 186 nb++; 187 } 188 189 for (int i = 0; i < MAX_MOTORS; i++) { 190 i2cport->SetSlave(BASE_ADDRESS + i); 191 read = i2cport->Read(value, 3); 192 193 if (read != sizeof(value)) { 194 continue; 92 195 } 93 */ 94 i2cport->ReleaseMutex(); 95 96 //on prend une fois pour toute le mutex et on fait des accès directs 97 cvmatrix* output=self->output; 98 output->GetMutex(); 99 for(int i=0;i<nb_mot;i++) output->SetValueNoMutex(i,0,speeds[i]); 100 for(int i=0;i<nb_mot;i++) output->SetValueNoMutex(i,1,currents[i]); 101 output->ReleaseMutex(); 102 } 103 104 //I2cPort mutex must be taken before calling this function 105 void BlCtrlV2_impl::WriteValue(uint16_t value) { 106 uint8_t tx[2]; 107 ssize_t written; 108 109 tx[0]=(uint8_t)(value>>3);//msb 110 tx[1]=(value&0x07);;//+16+8; //pour recuperer la vitesse en premier 111 written =i2cport->Write(tx, 2); 112 if(written<0) { 113 self->Err("rt_dev_write error (%s)\n",strerror(-written)); 114 } else if (written != sizeof(tx)) { 115 self->Err("rt_dev_write error %i/%i\n",written,sizeof(tx)); 116 } 117 } 118 119 //I2cPort mutex must be taken before calling this function 120 void BlCtrlV2_impl::GetCurrentAndSpeed(float ¤t,float &speed) { 121 ssize_t read; 122 uint8_t value[4]; 123 read = i2cport->Read(value, sizeof(value)); 124 125 if(read<0) { 126 self->Err("rt_dev_read error (%s)\n",strerror(-read)); 127 speed=-1; 128 current=-1; 129 } else if (read != sizeof(value)) { 130 self->Err("rt_dev_read error %i/%i\n",read,sizeof(value)); 131 speed=-1; 132 current=-1; 133 } else { 134 current=value[0]/10.; 135 speed= value[3]*780./poles->Value(); 136 } 137 } 138 139 //I2cPort mutex must be taken before calling this function 140 void BlCtrlV2_impl::GetCurrentSpeedAndVoltage(float ¤t,float &speed,float &voltage) { 141 ssize_t read; 142 uint8_t value[6]; 143 read = i2cport->Read(value, sizeof(value)); 144 145 if(read<0) { 146 self->Err("rt_dev_read error (%s)\n",strerror(-read)); 147 speed=-1; 148 voltage=-1; 149 current=-1; 150 } else if (read != sizeof(value)) { 151 self->Err("rt_dev_read error %i/%i\n",read,sizeof(value)); 152 speed=-1; 153 voltage=-1; 154 current=-1; 155 } else { 156 current=value[0]/10.; 157 voltage=value[5]/10.; 158 speed= value[3]*780./poles->Value(); 159 } 160 } 161 162 void BlCtrlV2_impl::DetectMotors(void) { 163 int nb=0; 164 ssize_t read,nb_write; 165 uint8_t value[3]; 166 uint8_t tx[2]; 167 168 i2cport->GetMutex(); 169 170 for(int i=0;i<MAX_MOTORS;i++) { 171 //printf("test %i\n",i); 172 i2cport->SetSlave(BASE_ADDRESS+i); 173 tx[0]=0; 174 tx[1]=16+8;//16+8 pour recuperer la vitesse 175 176 nb_write = i2cport->Write(tx, 2); 177 178 if (nb_write != sizeof(tx)) { 179 continue; 180 } 181 nb++; 182 } 183 184 for(int i=0;i<MAX_MOTORS;i++) { 185 i2cport->SetSlave(BASE_ADDRESS+i); 186 read = i2cport->Read(value, 3); 187 188 if (read != sizeof(value)) { 189 continue; 190 } 191 } 192 193 i2cport->ReleaseMutex(); 194 195 Printf("BlCtrlV2: Dectected motors: %i\n",nb); 196 if(nb==4) { 197 Printf("BlCtrlV2: Configuration X4\n"); 198 } else if(nb==8) { 199 Printf("BlCtrlV2: Configuration X8\n"); 200 } else { 201 //self->Err("Error, configuration not supported (%i/%i)\n",nb,MAX_MOTORS); 202 } 203 204 nb_mot=nb; 205 } 196 } 197 198 i2cport->ReleaseMutex(); 199 200 Printf("BlCtrlV2: Dectected motors: %i\n", nb); 201 if (nb == 4) { 202 Printf("BlCtrlV2: Configuration X4\n"); 203 } else if (nb == 8) { 204 Printf("BlCtrlV2: Configuration X8\n"); 205 } else { 206 // self->Err("Error, configuration not supported (%i/%i)\n",nb,MAX_MOTORS); 207 } 208 209 nb_mot = nb; 210 } -
trunk/lib/FlairSensorActuator/src/BlCtrlV2_x4_speed.cpp
r3 r15 38 38 using namespace flair::gui; 39 39 40 namespace flair 41 { 42 namespace actuator 43 { 44 BlCtrlV2_x4_speed::BlCtrlV2_x4_speed(FrameworkManager* parent,string name,I2cPort* i2cport,uint8_t base_address,uint8_t priority) : Thread(parent,name,priority),IODevice(parent,name) 45 { 46 this->i2cport=i2cport; 47 slave_address=base_address; 48 tested_motor=-1; 49 enabled=false; 50 int_av_g=0; 51 int_av_d=0; 52 int_ar_g=0; 53 int_ar_d=0; 54 55 //flight time 56 FILE *file; 57 file=fopen("/etc/flight_time","r"); 58 if (file == NULL) 59 { 60 Printf("fichier d'info de vol vide\n"); 61 time_sec=0; 40 namespace flair { 41 namespace actuator { 42 BlCtrlV2_x4_speed::BlCtrlV2_x4_speed(FrameworkManager *parent, string name, 43 I2cPort *i2cport, uint8_t base_address, 44 uint8_t priority) 45 : Thread(parent, name, priority), IODevice(parent, name) { 46 this->i2cport = i2cport; 47 slave_address = base_address; 48 tested_motor = -1; 49 enabled = false; 50 int_av_g = 0; 51 int_av_d = 0; 52 int_ar_g = 0; 53 int_ar_d = 0; 54 55 // flight time 56 FILE *file; 57 file = fopen("/etc/flight_time", "r"); 58 if (file == NULL) { 59 Printf("fichier d'info de vol vide\n"); 60 time_sec = 0; 61 } else { 62 char ligne[32]; 63 fgets(ligne, 32, file); 64 time_sec = atoi(ligne); 65 Printf("temps de vol total: %is = %imin = %ih\n", time_sec, time_sec / 60, 66 time_sec / 3600); 67 fclose(file); 68 } 69 70 // station sol 71 main_tab = new Tab(parent->GetTabWidget(), name); 72 tab = new TabWidget(main_tab->NewRow(), name); 73 Tab *sensor_tab = new Tab(tab, "Reglages"); 74 reglages_groupbox = new GroupBox(sensor_tab->NewRow(), name); 75 poles = new SpinBox(reglages_groupbox->NewRow(), "nb poles", 0, 255, 1); 76 kp = new DoubleSpinBox(reglages_groupbox->LastRowLastCol(), "kp", 0., 255, 77 0.001, 4); 78 ki = new DoubleSpinBox(reglages_groupbox->LastRowLastCol(), "ki", 0., 255, 79 0.001, 4); 80 min = new SpinBox(reglages_groupbox->NewRow(), "min pwm", 0., 2048, 1); 81 max = 82 new SpinBox(reglages_groupbox->LastRowLastCol(), "max pwm", 0., 2048, 1); 83 test = new SpinBox(reglages_groupbox->LastRowLastCol(), "test value", 0., 84 2048, 1); 85 start_value = new SpinBox(reglages_groupbox->NewRow(), "valeur demarrage", 0, 86 10000, 10); 87 trim = new DoubleSpinBox(reglages_groupbox->LastRowLastCol(), "pas decollage", 88 0, 1000, .1); 89 90 av_g = new ComboBox(reglages_groupbox->NewRow(), "avant gauche"); 91 av_g->AddItem("1"); 92 av_g->AddItem("2"); 93 av_g->AddItem("3"); 94 av_g->AddItem("4"); 95 button_avg = new PushButton(reglages_groupbox->LastRowLastCol(), "test avg"); 96 97 av_d = new ComboBox(reglages_groupbox->LastRowLastCol(), "avant droite:"); 98 av_d->AddItem("1"); 99 av_d->AddItem("2"); 100 av_d->AddItem("3"); 101 av_d->AddItem("4"); 102 button_avd = new PushButton(reglages_groupbox->LastRowLastCol(), "test avd"); 103 104 ar_g = new ComboBox(reglages_groupbox->NewRow(), "arriere gauche:"); 105 ar_g->AddItem("1"); 106 ar_g->AddItem("2"); 107 ar_g->AddItem("3"); 108 ar_g->AddItem("4"); 109 button_arg = new PushButton(reglages_groupbox->LastRowLastCol(), "test arg"); 110 111 ar_d = new ComboBox(reglages_groupbox->LastRowLastCol(), "arriere droite:"); 112 ar_d->AddItem("1"); 113 ar_d->AddItem("2"); 114 ar_d->AddItem("3"); 115 ar_d->AddItem("4"); 116 button_ard = new PushButton(reglages_groupbox->LastRowLastCol(), "test ard"); 117 118 pas = new ComboBox(reglages_groupbox->NewRow(), "pas helice avant gauche:"); 119 pas->AddItem("normal"); 120 pas->AddItem("inverse"); 121 122 input = new cvmatrix((IODevice *)this, 8, 1, floatType); 123 124 cvmatrix_descriptor *desc = new cvmatrix_descriptor(4, 2); 125 desc->SetElementName(0, 0, "avant gauche"); 126 desc->SetElementName(1, 0, "arriere droite"); 127 desc->SetElementName(2, 0, "avant droite"); 128 desc->SetElementName(3, 0, "arriere gauche"); 129 130 desc->SetElementName(0, 1, "cons avant gauche"); 131 desc->SetElementName(1, 1, "cons arriere droite"); 132 desc->SetElementName(2, 1, "cons avant droite"); 133 desc->SetElementName(3, 1, "cons arriere gauche"); 134 output = new cvmatrix((IODevice *)this, desc, floatType); 135 136 /* 137 138 //le 3ieme lu est la tension batteire 139 if(i2c_mutex!=NULL) i2c_mutex->GetMutex(); 140 uint16_t pwm_moteur; 141 pwm_moteur=0; 142 ssize_t read; 143 uint8_t rx[8]; 144 SetSlave(slave_address); 145 146 for(int j=0;j<10;j++) 147 { 148 149 150 WriteValue(pwm_moteur); 151 152 153 read = rt_dev_read(i2c_fd, rx, sizeof(rx)); 154 155 if(read<0) 156 { 157 rt_printf("BlCtrlV2_x4_speed::BlCtrlV2_x4_speed: %s, erreur 158 rt_dev_read (%s)\n",IODevice::ObjectName().c_str(),strerror(-read)); 159 } 160 else if (read != sizeof(rx)) 161 { 162 rt_printf("BlCtrlV2_x4_speed::BlCtrlV2_x4_speed: %s, erreur 163 rt_dev_read %i/2\n",IODevice::ObjectName().c_str(),read); 164 165 } 166 for(int i=0;i<sizeof(rx);i++) printf("%i ",rx[i]); 167 168 printf("\n"); 169 170 } 171 172 if(i2c_mutex!=NULL) i2c_mutex->ReleaseMutex();*/ 173 } 174 175 BlCtrlV2_x4_speed::~BlCtrlV2_x4_speed(void) { 176 SafeStop(); 177 Join(); 178 delete main_tab; 179 } 180 181 void BlCtrlV2_x4_speed::UseDefaultPlot(void) { 182 Tab *plot_tab = new Tab(tab, "Mesures"); 183 DataPlot1D *av_g_plot = new DataPlot1D(plot_tab->NewRow(), "avg", 0, 10000); 184 av_g_plot->AddCurve(output->Element(0, 0)); 185 av_g_plot->AddCurve(output->Element(0, 1), DataPlot::Blue); 186 DataPlot1D *av_d_plot = 187 new DataPlot1D(plot_tab->LastRowLastCol(), "avd", 0, 10000); 188 av_d_plot->AddCurve(output->Element(2, 0)); 189 av_d_plot->AddCurve(output->Element(2, 1), DataPlot::Blue); 190 DataPlot1D *ar_g_plot = new DataPlot1D(plot_tab->NewRow(), "arg", 0, 10000); 191 ar_g_plot->AddCurve(output->Element(3, 0)); 192 ar_g_plot->AddCurve(output->Element(3, 1), DataPlot::Blue); 193 DataPlot1D *ar_d_plot = 194 new DataPlot1D(plot_tab->LastRowLastCol(), "ard", 0, 10000); 195 ar_d_plot->AddCurve(output->Element(1, 0)); 196 ar_d_plot->AddCurve(output->Element(1, 1), DataPlot::Blue); 197 } 198 199 float BlCtrlV2_x4_speed::TrimValue(void) { return (float)trim->Value(); } 200 201 int BlCtrlV2_x4_speed::StartValue(void) { return start_value->Value(); } 202 203 void BlCtrlV2_x4_speed::Run(void) { 204 WarnUponSwitches(true); 205 206 SetPeriodUS(TAU_US); 207 208 while (!ToBeStopped()) { 209 WaitPeriod(); 210 211 Update(); 212 } 213 214 WarnUponSwitches(false); 215 } 216 217 void BlCtrlV2_x4_speed::Update(void) { 218 float u_roll, u_pitch, u_yaw, u_gaz; 219 float trim_roll, trim_pitch, trim_yaw; 220 float pwm[4]; 221 uint16_t pwm_moteur[4]; 222 223 // on prend une fois pour toute le mutex et on fait des accès directs 224 input->GetMutex(); 225 226 u_roll = input->ValueNoMutex(0, 0); 227 u_pitch = input->ValueNoMutex(1, 0); 228 u_yaw = input->ValueNoMutex(2, 0); 229 u_gaz = 230 input->ValueNoMutex(3, 0) + 231 input->ValueNoMutex(7, 0) * input->ValueNoMutex(7, 0); // ugaz+trim*trim 232 trim_roll = input->ValueNoMutex(4, 0); 233 trim_pitch = input->ValueNoMutex(5, 0); 234 trim_yaw = input->ValueNoMutex(6, 0); 235 236 input->ReleaseMutex(); 237 238 if (pas->CurrentIndex() == 1) { 239 trim_yaw = -trim_yaw; 240 u_yaw = -u_yaw; 241 } 242 243 // rt_printf("%f %f %f %f\n",u_roll,u_pitch,u_yaw,u_gaz); 244 // if(u_gaz!=0) rt_printf("gaz: %f\n",u_gaz); 245 246 // avant gauche 247 if (u_gaz + u_pitch + u_roll + u_yaw > 0) { 248 pwm[0] = trim_pitch + trim_roll + trim_yaw + 249 sqrtf(u_gaz + u_pitch + u_roll + u_yaw); 250 } else { 251 pwm[0] = trim_pitch + trim_roll + trim_yaw; 252 } 253 254 // arriere gauche 255 if (u_gaz - u_pitch + u_roll - u_yaw > 0) { 256 pwm[3] = -trim_pitch + trim_roll - trim_yaw + 257 sqrtf(u_gaz - u_pitch + u_roll - u_yaw); 258 } else { 259 pwm[3] = -trim_pitch + trim_roll - trim_yaw; 260 } 261 262 // arriere droit 263 if (u_gaz - u_pitch - u_roll + u_yaw > 0) { 264 pwm[1] = -trim_pitch - trim_roll + trim_yaw + 265 sqrtf(u_gaz - u_pitch - u_roll + u_yaw); 266 } else { 267 pwm[1] = -trim_pitch - trim_roll + trim_yaw; 268 } 269 270 // avant droit 271 if (u_gaz + u_pitch - u_roll - u_yaw > 0) { 272 pwm[2] = trim_pitch - trim_roll - trim_yaw + 273 sqrtf(u_gaz + u_pitch - u_roll - u_yaw); 274 } else { 275 pwm[2] = trim_pitch - trim_roll - trim_yaw; 276 } 277 278 int_av_g += ki->Value() * (pwm[0] - speed_av_g); 279 pwm[0] = kp->Value() * (pwm[0] - speed_av_g) + int_av_g; 280 281 int_ar_g += ki->Value() * (pwm[3] - speed_ar_g); 282 pwm[3] = kp->Value() * (pwm[3] - speed_ar_g) + int_ar_g; 283 284 int_ar_d += ki->Value() * (pwm[1] - speed_ar_d); 285 pwm[1] = kp->Value() * (pwm[1] - speed_ar_d) + int_ar_d; 286 287 int_av_d += ki->Value() * (pwm[2] - speed_av_d); 288 pwm[2] = kp->Value() * (pwm[2] - speed_av_d) + int_av_d; 289 290 // rt_printf("%f\n",pwm[0]); 291 for (int i = 0; i < 4; i++) 292 pwm_moteur[i] = SatPWM(pwm[i], min->Value(), max->Value()); 293 294 if (button_avg->Clicked() == true) { 295 tested_motor = 0; 296 StartTest(); 297 } 298 if (button_avd->Clicked() == true) { 299 tested_motor = 2; 300 StartTest(); 301 } 302 if (button_arg->Clicked() == true) { 303 tested_motor = 3; 304 StartTest(); 305 } 306 if (button_ard->Clicked() == true) { 307 tested_motor = 1; 308 StartTest(); 309 } 310 311 if (tested_motor != -1) { 312 for (int i = 0; i < 4; i++) { 313 pwm_moteur[i] = 0; 62 314 } 63 else 64 { 65 char ligne[32]; 66 fgets(ligne, 32, file); 67 time_sec=atoi(ligne); 68 Printf("temps de vol total: %is = %imin = %ih\n",time_sec,time_sec/60,time_sec/3600); 69 fclose(file); 315 pwm_moteur[tested_motor] = (uint16_t)test->Value(); 316 317 if (GetTime() > (start_time + 2 * 1000000000)) 318 StopTest(); 319 } 320 321 i2cport->GetMutex(); 322 323 if (enabled == true) { 324 i2cport->SetSlave(slave_address + av_g->CurrentIndex()); 325 WriteValue(pwm_moteur[0]); 326 327 i2cport->SetSlave(slave_address + av_d->CurrentIndex()); 328 WriteValue(pwm_moteur[2]); 329 330 i2cport->SetSlave(slave_address + ar_g->CurrentIndex()); 331 WriteValue(pwm_moteur[3]); 332 333 i2cport->SetSlave(slave_address + ar_d->CurrentIndex()); 334 WriteValue(pwm_moteur[1]); 335 336 } else { 337 for (int i = 0; i < 4; i++) { 338 i2cport->SetSlave(slave_address + i); 339 WriteValue(0); 70 340 } 71 72 //station sol 73 main_tab=new Tab(parent->GetTabWidget(),name); 74 tab=new TabWidget(main_tab->NewRow(),name); 75 Tab *sensor_tab=new Tab(tab,"Reglages"); 76 reglages_groupbox=new GroupBox(sensor_tab->NewRow(),name); 77 poles=new SpinBox(reglages_groupbox->NewRow(),"nb poles",0,255,1); 78 kp=new DoubleSpinBox(reglages_groupbox->LastRowLastCol(),"kp",0.,255,0.001,4); 79 ki=new DoubleSpinBox(reglages_groupbox->LastRowLastCol(),"ki",0.,255,0.001,4); 80 min=new SpinBox(reglages_groupbox->NewRow(),"min pwm",0.,2048,1); 81 max=new SpinBox(reglages_groupbox->LastRowLastCol(),"max pwm",0.,2048,1); 82 test=new SpinBox(reglages_groupbox->LastRowLastCol(),"test value",0.,2048,1); 83 start_value=new SpinBox(reglages_groupbox->NewRow(),"valeur demarrage",0,10000,10); 84 trim=new DoubleSpinBox(reglages_groupbox->LastRowLastCol(),"pas decollage",0,1000,.1); 85 86 av_g=new ComboBox(reglages_groupbox->NewRow(),"avant gauche"); 87 av_g->AddItem("1"); 88 av_g->AddItem("2"); 89 av_g->AddItem("3"); 90 av_g->AddItem("4"); 91 button_avg=new PushButton(reglages_groupbox->LastRowLastCol(),"test avg"); 92 93 av_d=new ComboBox(reglages_groupbox->LastRowLastCol(),"avant droite:"); 94 av_d->AddItem("1"); 95 av_d->AddItem("2"); 96 av_d->AddItem("3"); 97 av_d->AddItem("4"); 98 button_avd=new PushButton(reglages_groupbox->LastRowLastCol(),"test avd"); 99 100 ar_g=new ComboBox(reglages_groupbox->NewRow(),"arriere gauche:"); 101 ar_g->AddItem("1"); 102 ar_g->AddItem("2"); 103 ar_g->AddItem("3"); 104 ar_g->AddItem("4"); 105 button_arg=new PushButton(reglages_groupbox->LastRowLastCol(),"test arg"); 106 107 ar_d=new ComboBox(reglages_groupbox->LastRowLastCol(),"arriere droite:"); 108 ar_d->AddItem("1"); 109 ar_d->AddItem("2"); 110 ar_d->AddItem("3"); 111 ar_d->AddItem("4"); 112 button_ard=new PushButton(reglages_groupbox->LastRowLastCol(),"test ard"); 113 114 pas=new ComboBox(reglages_groupbox->NewRow(),"pas helice avant gauche:"); 115 pas->AddItem("normal"); 116 pas->AddItem("inverse"); 117 118 input=new cvmatrix((IODevice*)this,8,1,floatType); 119 120 cvmatrix_descriptor* desc=new cvmatrix_descriptor(4,2); 121 desc->SetElementName(0,0,"avant gauche"); 122 desc->SetElementName(1,0,"arriere droite"); 123 desc->SetElementName(2,0,"avant droite"); 124 desc->SetElementName(3,0,"arriere gauche"); 125 126 desc->SetElementName(0,1,"cons avant gauche"); 127 desc->SetElementName(1,1,"cons arriere droite"); 128 desc->SetElementName(2,1,"cons avant droite"); 129 desc->SetElementName(3,1,"cons arriere gauche"); 130 output=new cvmatrix((IODevice*)this,desc,floatType); 131 132 133 134 /* 135 136 //le 3ieme lu est la tension batteire 137 if(i2c_mutex!=NULL) i2c_mutex->GetMutex(); 138 uint16_t pwm_moteur; 139 pwm_moteur=0; 140 ssize_t read; 141 uint8_t rx[8]; 142 SetSlave(slave_address); 143 144 for(int j=0;j<10;j++) 145 { 146 147 148 WriteValue(pwm_moteur); 149 150 151 read = rt_dev_read(i2c_fd, rx, sizeof(rx)); 152 153 if(read<0) 154 { 155 rt_printf("BlCtrlV2_x4_speed::BlCtrlV2_x4_speed: %s, erreur rt_dev_read (%s)\n",IODevice::ObjectName().c_str(),strerror(-read)); 156 } 157 else if (read != sizeof(rx)) 158 { 159 rt_printf("BlCtrlV2_x4_speed::BlCtrlV2_x4_speed: %s, erreur rt_dev_read %i/2\n",IODevice::ObjectName().c_str(),read); 160 161 } 162 for(int i=0;i<sizeof(rx);i++) printf("%i ",rx[i]); 163 164 printf("\n"); 165 341 int_av_g = 0; 342 int_av_d = 0; 343 int_ar_g = 0; 344 int_ar_d = 0; 345 } 346 347 i2cport->SetSlave(slave_address + av_g->CurrentIndex()); 348 speed_av_g = GetSpeed(); 349 350 i2cport->SetSlave(slave_address + av_d->CurrentIndex()); 351 speed_av_d = GetSpeed(); 352 353 i2cport->SetSlave(slave_address + ar_g->CurrentIndex()); 354 speed_ar_g = GetSpeed(); 355 356 i2cport->SetSlave(slave_address + ar_d->CurrentIndex()); 357 speed_ar_d = GetSpeed(); 358 359 i2cport->ReleaseMutex(); 360 361 // on prend une fois pour toute le mutex et on fait des accès directs 362 output->GetMutex(); 363 output->SetValueNoMutex(0, 0, speed_av_g); 364 output->SetValueNoMutex(1, 0, speed_ar_d); 365 output->SetValueNoMutex(2, 0, speed_av_d); 366 output->SetValueNoMutex(3, 0, speed_ar_g); 367 // rt_printf("%i %i %i 368 // %i\n",pwm_moteur[0],pwm_moteur[1],pwm_moteur[2],pwm_moteur[3]); 369 output->ReleaseMutex(); 370 371 output->SetDataTime(GetTime()); 372 ProcessUpdate(output); 373 } 374 375 void BlCtrlV2_x4_speed::StartTest(void) { 376 start_time = GetTime(); 377 SetEnabled(true); 378 } 379 380 void BlCtrlV2_x4_speed::StopTest(void) { 381 SetEnabled(false); 382 tested_motor = -1; 383 } 384 385 uint16_t BlCtrlV2_x4_speed::SatPWM(float vel_cons, uint16_t min, uint16_t max) { 386 uint16_t sat_value = (uint16_t)vel_cons; 387 388 if (vel_cons > ((float)sat_value + 0.5)) 389 sat_value++; 390 391 if (vel_cons < (float)min) 392 sat_value = min; 393 if (vel_cons > (float)max) 394 sat_value = max; 395 396 return sat_value; 397 } 398 399 void BlCtrlV2_x4_speed::LockUserInterface(void) { 400 reglages_groupbox->setEnabled(false); 401 } 402 403 void BlCtrlV2_x4_speed::UnlockUserInterface(void) { 404 reglages_groupbox->setEnabled(true); 405 } 406 407 void BlCtrlV2_x4_speed::SetEnabled(bool status) { 408 enabled = status; 409 if (enabled == true) { 410 LockUserInterface(); 411 412 flight_start_time = GetTime(); 413 } else { 414 UnlockUserInterface(); 415 416 Time now = GetTime(); 417 int t_sec; 418 FILE *file; 419 char ligne[32]; 420 421 t_sec = (now - flight_start_time) / 1000000000; 422 time_sec += t_sec; 423 424 Printf("temps de vol: %is = %imin\n", t_sec, t_sec / 60); 425 Printf("temps de vol total: %is = %imin = %ih\n", time_sec, time_sec / 60, 426 time_sec / 3600); 427 428 file = fopen("/etc/flight_time", "w"); 429 if (file == NULL) { 430 Thread::Err("Erreur a l'ouverture du fichier d'info vol\n"); 431 } else { 432 sprintf(ligne, "%i", time_sec); 433 fputs(ligne, file); 434 fclose(file); 166 435 } 167 168 if(i2c_mutex!=NULL) i2c_mutex->ReleaseMutex();*/ 169 } 170 171 BlCtrlV2_x4_speed::~BlCtrlV2_x4_speed(void) 172 { 173 SafeStop(); 174 Join(); 175 delete main_tab; 176 } 177 178 void BlCtrlV2_x4_speed::UseDefaultPlot(void) 179 { 180 Tab *plot_tab=new Tab(tab,"Mesures"); 181 DataPlot1D *av_g_plot=new DataPlot1D(plot_tab->NewRow(),"avg",0,10000); 182 av_g_plot->AddCurve(output->Element(0,0)); 183 av_g_plot->AddCurve(output->Element(0,1),DataPlot::Blue); 184 DataPlot1D *av_d_plot=new DataPlot1D(plot_tab->LastRowLastCol(),"avd",0,10000); 185 av_d_plot->AddCurve(output->Element(2,0)); 186 av_d_plot->AddCurve(output->Element(2,1),DataPlot::Blue); 187 DataPlot1D *ar_g_plot=new DataPlot1D(plot_tab->NewRow(),"arg",0,10000); 188 ar_g_plot->AddCurve(output->Element(3,0)); 189 ar_g_plot->AddCurve(output->Element(3,1),DataPlot::Blue); 190 DataPlot1D *ar_d_plot=new DataPlot1D(plot_tab->LastRowLastCol(),"ard",0,10000); 191 ar_d_plot->AddCurve(output->Element(1,0)); 192 ar_d_plot->AddCurve(output->Element(1,1),DataPlot::Blue); 193 } 194 195 float BlCtrlV2_x4_speed::TrimValue(void) 196 { 197 return (float)trim->Value(); 198 } 199 200 int BlCtrlV2_x4_speed::StartValue(void) 201 { 202 return start_value->Value(); 203 } 204 205 void BlCtrlV2_x4_speed::Run(void) 206 { 207 WarnUponSwitches(true); 208 209 SetPeriodUS(TAU_US); 210 211 while(!ToBeStopped()) 212 { 213 WaitPeriod(); 214 215 Update(); 216 } 217 218 WarnUponSwitches(false); 219 } 220 221 void BlCtrlV2_x4_speed::Update(void) 222 { 223 float u_roll,u_pitch,u_yaw,u_gaz; 224 float trim_roll,trim_pitch,trim_yaw; 225 float pwm[4]; 226 uint16_t pwm_moteur[4]; 227 228 229 //on prend une fois pour toute le mutex et on fait des accès directs 230 input->GetMutex(); 231 232 u_roll=input->ValueNoMutex(0,0); 233 u_pitch=input->ValueNoMutex(1,0); 234 u_yaw=input->ValueNoMutex(2,0); 235 u_gaz=input->ValueNoMutex(3,0)+input->ValueNoMutex(7,0)*input->ValueNoMutex(7,0);//ugaz+trim*trim 236 trim_roll=input->ValueNoMutex(4,0); 237 trim_pitch=input->ValueNoMutex(5,0); 238 trim_yaw=input->ValueNoMutex(6,0); 239 240 input->ReleaseMutex(); 241 242 if(pas->CurrentIndex()==1) 243 { 244 trim_yaw=-trim_yaw; 245 u_yaw=-u_yaw; 246 } 247 248 //rt_printf("%f %f %f %f\n",u_roll,u_pitch,u_yaw,u_gaz); 249 //if(u_gaz!=0) rt_printf("gaz: %f\n",u_gaz); 250 251 //avant gauche 252 if(u_gaz+u_pitch+u_roll+u_yaw>0) 253 { 254 pwm[0]=trim_pitch+trim_roll+trim_yaw+sqrtf(u_gaz+u_pitch+u_roll+u_yaw); 255 }else 256 { 257 pwm[0]=trim_pitch+trim_roll+trim_yaw; 258 } 259 260 //arriere gauche 261 if(u_gaz-u_pitch+u_roll-u_yaw>0) 262 { 263 pwm[3]=-trim_pitch+trim_roll-trim_yaw+sqrtf(u_gaz-u_pitch+u_roll-u_yaw); 264 }else 265 { 266 pwm[3]=-trim_pitch+trim_roll-trim_yaw; 267 } 268 269 //arriere droit 270 if(u_gaz-u_pitch-u_roll+u_yaw>0) 271 { 272 pwm[1]=-trim_pitch-trim_roll+trim_yaw+sqrtf(u_gaz-u_pitch-u_roll+u_yaw); 273 }else 274 { 275 pwm[1]=-trim_pitch-trim_roll+trim_yaw; 276 } 277 278 //avant droit 279 if(u_gaz+u_pitch-u_roll-u_yaw>0) 280 { 281 pwm[2]=trim_pitch-trim_roll-trim_yaw+sqrtf(u_gaz+u_pitch-u_roll-u_yaw); 282 }else 283 { 284 pwm[2]=trim_pitch-trim_roll-trim_yaw; 285 } 286 287 288 int_av_g+=ki->Value()*(pwm[0]-speed_av_g); 289 pwm[0]=kp->Value()*(pwm[0]-speed_av_g)+int_av_g; 290 291 int_ar_g+=ki->Value()*(pwm[3]-speed_ar_g); 292 pwm[3]=kp->Value()*(pwm[3]-speed_ar_g)+int_ar_g; 293 294 int_ar_d+=ki->Value()*(pwm[1]-speed_ar_d); 295 pwm[1]=kp->Value()*(pwm[1]-speed_ar_d)+int_ar_d; 296 297 int_av_d+=ki->Value()*(pwm[2]-speed_av_d); 298 pwm[2]=kp->Value()*(pwm[2]-speed_av_d)+int_av_d; 299 300 //rt_printf("%f\n",pwm[0]); 301 for(int i=0;i<4;i++) pwm_moteur[i]=SatPWM(pwm[i],min->Value(),max->Value()); 302 303 if(button_avg->Clicked()==true) 304 { 305 tested_motor=0; 306 StartTest(); 307 } 308 if(button_avd->Clicked()==true) 309 { 310 tested_motor=2; 311 StartTest(); 312 } 313 if(button_arg->Clicked()==true) 314 { 315 tested_motor=3; 316 StartTest(); 317 } 318 if(button_ard->Clicked()==true) 319 { 320 tested_motor=1; 321 StartTest(); 322 } 323 324 if(tested_motor!=-1) 325 { 326 for(int i=0;i<4;i++) 327 { 328 pwm_moteur[i]=0; 329 } 330 pwm_moteur[tested_motor]=(uint16_t)test->Value(); 331 332 if(GetTime()>(start_time+2*1000000000)) StopTest(); 333 } 334 335 336 i2cport->GetMutex(); 337 338 if(enabled==true) 339 { 340 i2cport->SetSlave(slave_address+av_g->CurrentIndex()); 341 WriteValue(pwm_moteur[0]); 342 343 i2cport->SetSlave(slave_address+av_d->CurrentIndex()); 344 WriteValue(pwm_moteur[2]); 345 346 i2cport->SetSlave(slave_address+ar_g->CurrentIndex()); 347 WriteValue(pwm_moteur[3]); 348 349 i2cport->SetSlave(slave_address+ar_d->CurrentIndex()); 350 WriteValue(pwm_moteur[1]); 351 352 } 353 else 354 { 355 for(int i=0;i<4;i++) 356 { 357 i2cport->SetSlave(slave_address+i); 358 WriteValue(0); 359 } 360 int_av_g=0; 361 int_av_d=0; 362 int_ar_g=0; 363 int_ar_d=0; 364 } 365 366 i2cport->SetSlave(slave_address+av_g->CurrentIndex()); 367 speed_av_g=GetSpeed(); 368 369 i2cport->SetSlave(slave_address+av_d->CurrentIndex()); 370 speed_av_d=GetSpeed(); 371 372 i2cport->SetSlave(slave_address+ar_g->CurrentIndex()); 373 speed_ar_g=GetSpeed(); 374 375 i2cport->SetSlave(slave_address+ar_d->CurrentIndex()); 376 speed_ar_d=GetSpeed(); 377 378 i2cport->ReleaseMutex(); 379 380 381 //on prend une fois pour toute le mutex et on fait des accès directs 382 output->GetMutex(); 383 output->SetValueNoMutex(0,0,speed_av_g); 384 output->SetValueNoMutex(1,0,speed_ar_d); 385 output->SetValueNoMutex(2,0,speed_av_d); 386 output->SetValueNoMutex(3,0,speed_ar_g); 387 // rt_printf("%i %i %i %i\n",pwm_moteur[0],pwm_moteur[1],pwm_moteur[2],pwm_moteur[3]); 388 output->ReleaseMutex(); 389 390 output->SetDataTime(GetTime()); 391 ProcessUpdate(output); 392 393 } 394 395 void BlCtrlV2_x4_speed::StartTest(void) 396 { 397 start_time=GetTime(); 398 SetEnabled(true); 399 } 400 401 void BlCtrlV2_x4_speed::StopTest(void) 402 { 403 SetEnabled(false); 404 tested_motor=-1; 405 } 406 407 uint16_t BlCtrlV2_x4_speed::SatPWM(float vel_cons,uint16_t min,uint16_t max) 408 { 409 uint16_t sat_value=(uint16_t)vel_cons; 410 411 if(vel_cons>((float)sat_value+0.5)) sat_value++; 412 413 if(vel_cons<(float)min) sat_value=min; 414 if(vel_cons>(float)max) sat_value=max; 415 416 return sat_value; 417 } 418 419 void BlCtrlV2_x4_speed::LockUserInterface(void) 420 { 421 reglages_groupbox->setEnabled(false); 422 } 423 424 void BlCtrlV2_x4_speed::UnlockUserInterface(void) 425 { 426 reglages_groupbox->setEnabled(true); 427 } 428 429 void BlCtrlV2_x4_speed::SetEnabled(bool status) 430 { 431 enabled=status; 432 if(enabled==true) 433 { 434 LockUserInterface(); 435 436 flight_start_time = GetTime(); 437 } 438 else 439 { 440 UnlockUserInterface(); 441 442 Time now= GetTime(); 443 int t_sec; 444 FILE *file; 445 char ligne[32]; 446 447 t_sec=(now - flight_start_time)/1000000000; 448 time_sec+=t_sec; 449 450 Printf("temps de vol: %is = %imin\n",t_sec,t_sec/60); 451 Printf("temps de vol total: %is = %imin = %ih\n",time_sec,time_sec/60,time_sec/3600); 452 453 file=fopen("/etc/flight_time","w"); 454 if (file == NULL) 455 { 456 Thread::Err("Erreur a l'ouverture du fichier d'info vol\n"); 457 } 458 else 459 { 460 sprintf(ligne,"%i",time_sec); 461 fputs(ligne,file); 462 fclose(file); 463 } 464 } 465 } 466 467 void BlCtrlV2_x4_speed::SetUroll(float value) 468 { 469 input->SetValue(0,0,value); 470 } 471 472 void BlCtrlV2_x4_speed::SetUpitch(float value) 473 { 474 input->SetValue(1,0,value); 475 } 476 477 void BlCtrlV2_x4_speed::SetUyaw(float value) 478 { 479 input->SetValue(2,0,value); 480 } 481 482 void BlCtrlV2_x4_speed::SetUgaz(float value) 483 { 484 input->SetValue(3,0,value); 485 } 486 487 void BlCtrlV2_x4_speed::SetRollTrim(float value) 488 { 489 input->SetValue(4,0,value); 490 } 491 492 void BlCtrlV2_x4_speed::SetPitchTrim(float value) 493 { 494 input->SetValue(5,0,value); 495 } 496 497 void BlCtrlV2_x4_speed::SetYawTrim(float value) 498 { 499 input->SetValue(6,0,value); 500 } 501 502 void BlCtrlV2_x4_speed::SetGazTrim(float value) 503 { 504 input->SetValue(7,0,value); 505 } 506 507 void BlCtrlV2_x4_speed::WriteValue(uint16_t value) 508 { 509 unsigned char tx[2]; 510 ssize_t written; 511 512 tx[0]=(unsigned char)(value>>3);//msb 513 tx[1]=16+8+(value&0x07);//16+8 pour recuperer la vitesse 514 written = i2cport->Write(tx, 2); 515 if(written<0) 516 { 517 Thread::Err("erreur rt_dev_write (%s)\n",strerror(-written)); 518 } 519 else if (written != 2) 520 { 521 Thread::Err("erreur rt_dev_write %i/2\n",written); 522 } 523 } 524 525 float BlCtrlV2_x4_speed::GetSpeed(void) 526 { 527 ssize_t read; 528 uint8_t value; 529 read = i2cport->Read(&value, 1); 530 531 if(read<0) 532 { 533 Thread::Err("erreur rt_dev_read (%s)\n",strerror(-read)); 534 } 535 else if (read != 1) 536 { 537 Thread::Err("erreur rt_dev_read %i/2\n",read); 538 539 } 540 541 return value*780./poles->Value(); 436 } 437 } 438 439 void BlCtrlV2_x4_speed::SetUroll(float value) { input->SetValue(0, 0, value); } 440 441 void BlCtrlV2_x4_speed::SetUpitch(float value) { input->SetValue(1, 0, value); } 442 443 void BlCtrlV2_x4_speed::SetUyaw(float value) { input->SetValue(2, 0, value); } 444 445 void BlCtrlV2_x4_speed::SetUgaz(float value) { input->SetValue(3, 0, value); } 446 447 void BlCtrlV2_x4_speed::SetRollTrim(float value) { 448 input->SetValue(4, 0, value); 449 } 450 451 void BlCtrlV2_x4_speed::SetPitchTrim(float value) { 452 input->SetValue(5, 0, value); 453 } 454 455 void BlCtrlV2_x4_speed::SetYawTrim(float value) { 456 input->SetValue(6, 0, value); 457 } 458 459 void BlCtrlV2_x4_speed::SetGazTrim(float value) { 460 input->SetValue(7, 0, value); 461 } 462 463 void BlCtrlV2_x4_speed::WriteValue(uint16_t value) { 464 unsigned char tx[2]; 465 ssize_t written; 466 467 tx[0] = (unsigned char)(value >> 3); // msb 468 tx[1] = 16 + 8 + (value & 0x07); // 16+8 pour recuperer la vitesse 469 written = i2cport->Write(tx, 2); 470 if (written < 0) { 471 Thread::Err("erreur rt_dev_write (%s)\n", strerror(-written)); 472 } else if (written != 2) { 473 Thread::Err("erreur rt_dev_write %i/2\n", written); 474 } 475 } 476 477 float BlCtrlV2_x4_speed::GetSpeed(void) { 478 ssize_t read; 479 uint8_t value; 480 read = i2cport->Read(&value, 1); 481 482 if (read < 0) { 483 Thread::Err("erreur rt_dev_read (%s)\n", strerror(-read)); 484 } else if (read != 1) { 485 Thread::Err("erreur rt_dev_read %i/2\n", read); 486 } 487 488 return value * 780. / poles->Value(); 542 489 } 543 490 -
trunk/lib/FlairSensorActuator/src/BlCtrlV2_x4_speed.h
r3 r15 16 16 /*********************************************************************/ 17 17 18 19 18 #ifndef BLCTRLV2_X4_SPEED_H 20 19 #define BLCTRLV2_X4_SPEED_H … … 23 22 #include <Thread.h> 24 23 25 namespace flair 26 { 27 namespace core 28 { 29 class cvmatrix; 30 class FrameworkManager; 31 class I2cPort; 32 33 } 34 namespace gui 35 { 36 class TabWidget; 37 class Tab; 38 class SpinBox; 39 class DoubleSpinBox; 40 class ComboBox; 41 class PushButton; 42 class GroupBox; 43 } 24 namespace flair { 25 namespace core { 26 class cvmatrix; 27 class FrameworkManager; 28 class I2cPort; 29 } 30 namespace gui { 31 class TabWidget; 32 class Tab; 33 class SpinBox; 34 class DoubleSpinBox; 35 class ComboBox; 36 class PushButton; 37 class GroupBox; 38 } 44 39 } 45 40 46 namespace flair 47 { 48 namespace actuator 49 { 50 class BlCtrlV2_x4_speed : public core::Thread,public core::IODevice 51 { 41 namespace flair { 42 namespace actuator { 43 class BlCtrlV2_x4_speed : public core::Thread, public core::IODevice { 52 44 53 public: 54 BlCtrlV2_x4_speed(core::FrameworkManager* parent,std::string name,core::I2cPort* i2cport,uint8_t base_address,uint8_t priority); 55 ~BlCtrlV2_x4_speed(); 56 void UseDefaultPlot(void); 57 void LockUserInterface(void); 58 void UnlockUserInterface(void); 59 void SetEnabled(bool status); 60 void SetUroll(float value); 61 void SetUpitch(float value); 62 void SetUyaw(float value); 63 void SetUgaz(float value); 64 void SetRollTrim(float value); 65 void SetPitchTrim(float value); 66 void SetYawTrim(float value); 67 void SetGazTrim(float value); 68 float TrimValue(void); 69 int StartValue(void); 45 public: 46 BlCtrlV2_x4_speed(core::FrameworkManager *parent, std::string name, 47 core::I2cPort *i2cport, uint8_t base_address, 48 uint8_t priority); 49 ~BlCtrlV2_x4_speed(); 50 void UseDefaultPlot(void); 51 void LockUserInterface(void); 52 void UnlockUserInterface(void); 53 void SetEnabled(bool status); 54 void SetUroll(float value); 55 void SetUpitch(float value); 56 void SetUyaw(float value); 57 void SetUgaz(float value); 58 void SetRollTrim(float value); 59 void SetPitchTrim(float value); 60 void SetYawTrim(float value); 61 void SetGazTrim(float value); 62 float TrimValue(void); 63 int StartValue(void); 70 64 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 gui::Tab*main_tab;93 gui::TabWidget*tab;94 gui::GroupBox*reglages_groupbox;95 gui::SpinBox *min,*max,*test;96 gui::PushButton *button_avg,*button_avd,*button_arg,*button_ard;97 gui::ComboBox *av_g,*av_d,*ar_g,*ar_d,*pas;98 gui::DoubleSpinBox *trim,*kp,*ki;99 gui::SpinBox *start_value,*poles;100 core::Time start_time,flight_start_time;101 102 float speed_av_g,speed_av_d,speed_ar_g,speed_ar_d;103 float int_av_g,int_av_d,int_ar_g,int_ar_d;65 private: 66 /*! 67 * \brief Update using provided datas 68 * 69 * Reimplemented from IODevice. 70 * 71 * \param data data from the parent to process 72 */ 73 void UpdateFrom(core::io_data *data){}; 74 void WriteValue(uint16_t value); 75 float GetSpeed(void); 76 void StartTest(void); 77 void StopTest(void); 78 /*! 79 * \brief Run function 80 * 81 * Reimplemented from Thread. 82 * 83 */ 84 void Run(void); 85 void Update(void); 86 gui::Tab *main_tab; 87 gui::TabWidget *tab; 88 gui::GroupBox *reglages_groupbox; 89 gui::SpinBox *min, *max, *test; 90 gui::PushButton *button_avg, *button_avd, *button_arg, *button_ard; 91 gui::ComboBox *av_g, *av_d, *ar_g, *ar_d, *pas; 92 gui::DoubleSpinBox *trim, *kp, *ki; 93 gui::SpinBox *start_value, *poles; 94 core::Time start_time, flight_start_time; 95 int time_sec; 96 float speed_av_g, speed_av_d, speed_ar_g, speed_ar_d; 97 float int_av_g, int_av_d, int_ar_g, int_ar_d; 104 98 105 //matrix106 107 99 // matrix 100 core::cvmatrix *input; 101 core::cvmatrix *output; 108 102 109 110 core::I2cPort*i2cport;111 103 int tested_motor; 104 core::I2cPort *i2cport; 105 uint8_t slave_address; 112 106 113 107 bool enabled; 114 108 115 uint16_t SatPWM(float vel_cons,uint16_t min,uint16_t max);116 109 uint16_t SatPWM(float vel_cons, uint16_t min, uint16_t max); 110 }; 117 111 } // end namespace actuator 118 112 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/Bldc.cpp
r3 r15 27 27 using namespace flair::gui; 28 28 29 namespace flair { namespace actuator { 29 namespace flair { 30 namespace actuator { 30 31 31 Bldc::Bldc(const IODevice* parent,Layout* layout,string name,uint8_t motors_count) : IODevice(parent,name) { 32 pimpl_=new Bldc_impl(this,layout,name,motors_count); 32 Bldc::Bldc(const IODevice *parent, Layout *layout, string name, 33 uint8_t motors_count) 34 : IODevice(parent, name) { 35 pimpl_ = new Bldc_impl(this, layout, name, motors_count); 33 36 34 cvmatrix_descriptor* desc=new cvmatrix_descriptor(motors_count,2);35 for(int i=0;i<motors_count;i++) {36 ostringstream speed,current;37 38 desc->SetElementName(i,0,speed.str());37 cvmatrix_descriptor *desc = new cvmatrix_descriptor(motors_count, 2); 38 for (int i = 0; i < motors_count; i++) { 39 ostringstream speed, current; 40 speed << "speed_" << i; 41 desc->SetElementName(i, 0, speed.str()); 39 42 40 41 desc->SetElementName(i,1,current.str());42 43 current << "current_" << i; 44 desc->SetElementName(i, 1, current.str()); 45 } 43 46 44 output=new cvmatrix(this,desc,floatType);45 47 output = new cvmatrix(this, desc, floatType); 48 AddDataToLog(output); 46 49 } 47 50 48 Bldc::Bldc(const Object* parent,string name,uint8_t motors_count) : IODevice(parent,name) { 49 pimpl_=new Bldc_impl(this,motors_count); 51 Bldc::Bldc(const Object *parent, string name, uint8_t motors_count) 52 : IODevice(parent, name) { 53 pimpl_ = new Bldc_impl(this, motors_count); 50 54 } 51 55 52 Bldc::~Bldc() { 53 delete pimpl_; 56 Bldc::~Bldc() { delete pimpl_; } 57 58 void Bldc::UpdateFrom(const io_data *data) { pimpl_->UpdateFrom(data); } 59 60 void Bldc::LockUserInterface(void) const { pimpl_->LockUserInterface(); } 61 62 void Bldc::UnlockUserInterface(void) const { pimpl_->UnlockUserInterface(); } 63 64 Layout *Bldc::GetLayout(void) const { return (Layout *)pimpl_->layout; } 65 66 void Bldc::UseDefaultPlot(TabWidget *tabwidget) { 67 pimpl_->UseDefaultPlot(tabwidget); 54 68 } 55 69 56 void Bldc::UpdateFrom(const io_data *data) { 57 pimpl_->UpdateFrom(data); 70 uint8_t Bldc::MotorsCount(void) const { return pimpl_->motors_count; } 71 72 cvmatrix *Bldc::Output(void) const { return output; } 73 74 bool Bldc::AreEnabled(void) const { return pimpl_->are_enabled; } 75 76 void Bldc::SetEnabled(bool status) { 77 if (pimpl_->are_enabled != status) { 78 pimpl_->are_enabled = status; 79 if (pimpl_->are_enabled) { 80 LockUserInterface(); 81 } else { 82 UnlockUserInterface(); 83 } 84 } 58 85 } 59 86 60 void Bldc::LockUserInterface(void) const { 61 pimpl_->LockUserInterface(); 62 } 63 64 void Bldc::UnlockUserInterface(void) const { 65 pimpl_->UnlockUserInterface(); 66 } 67 68 Layout* Bldc::GetLayout(void) const { 69 return (Layout*)pimpl_->layout; 70 } 71 72 void Bldc::UseDefaultPlot(TabWidget* tabwidget) { 73 pimpl_->UseDefaultPlot(tabwidget); 74 } 75 76 uint8_t Bldc::MotorsCount(void) const { 77 return pimpl_->motors_count; 78 } 79 80 cvmatrix *Bldc::Output(void) const { 81 return output; 82 } 83 84 bool Bldc::AreEnabled(void) const { 85 return pimpl_->are_enabled; 86 } 87 88 void Bldc::SetEnabled(bool status) { 89 if(pimpl_->are_enabled!=status) { 90 pimpl_->are_enabled=status; 91 if(pimpl_->are_enabled) { 92 LockUserInterface(); 93 } else { 94 UnlockUserInterface(); 95 } 96 } 97 } 98 99 void Bldc::SetPower(int motor_id,float value) { 100 //use output mutex to avoid making a new mutex 101 output->GetMutex(); 102 pimpl_->power[motor_id]=value; 103 output->ReleaseMutex(); 87 void Bldc::SetPower(int motor_id, float value) { 88 // use output mutex to avoid making a new mutex 89 output->GetMutex(); 90 pimpl_->power[motor_id] = value; 91 output->ReleaseMutex(); 104 92 } 105 93 -
trunk/lib/FlairSensorActuator/src/Bldc.h
r3 r15 17 17 #include <stdint.h> 18 18 19 namespace flair 20 { 21 namespace core 22 { 23 class FrameworkManager; 24 class cvmatrix; 25 } 26 namespace gui 27 { 28 class Layout; 29 class TabWidget; 30 } 19 namespace flair { 20 namespace core { 21 class FrameworkManager; 22 class cvmatrix; 23 } 24 namespace gui { 25 class Layout; 26 class TabWidget; 27 } 31 28 } 32 29 33 30 class Bldc_impl; 34 31 35 namespace flair 36 { 37 namespace actuator 38 { 39 /*! \class Bldc 40 * 41 * \brief Base class for brushless motors drivers 42 */ 43 class Bldc : public core::IODevice 44 { 45 friend class ::Bldc_impl; 32 namespace flair { 33 namespace actuator { 34 /*! \class Bldc 35 * 36 * \brief Base class for brushless motors drivers 37 */ 38 class Bldc : public core::IODevice { 39 friend class ::Bldc_impl; 46 40 47 public: 48 /*! 49 * \brief Constructor 50 * 51 * Construct a Bldc. 52 * 53 * \param parent parent 54 * \param layout layout 55 * \param name name 56 * \param motors_count number of motors 57 */ 58 Bldc(const core::IODevice* parent,gui::Layout* layout,std::string name,uint8_t motors_count); 41 public: 42 /*! 43 * \brief Constructor 44 * 45 * Construct a Bldc. 46 * 47 * \param parent parent 48 * \param layout layout 49 * \param name name 50 * \param motors_count number of motors 51 */ 52 Bldc(const core::IODevice *parent, gui::Layout *layout, std::string name, 53 uint8_t motors_count); 59 54 60 61 62 63 64 65 66 67 68 69 70 Bldc(const core::Object* parent,std::string name,uint8_t motors_count);55 /*! 56 * \brief Constructor 57 * 58 * Construct a Bldc. \n 59 * This contructor must only be called for a simulated device. 60 * 61 * \param parent parent 62 * \param name name 63 * \param motors_count number of motors 64 */ 65 Bldc(const core::Object *parent, std::string name, uint8_t motors_count); 71 66 72 73 74 75 76 67 /*! 68 * \brief Destructor 69 * 70 */ 71 ~Bldc(); 77 72 78 79 80 81 82 73 /*! 74 * \brief Lock user interface 75 * 76 */ 77 void LockUserInterface(void) const; 83 78 84 85 86 87 88 79 /*! 80 * \brief Unlock user interface 81 * 82 */ 83 void UnlockUserInterface(void) const; 89 84 90 91 92 93 94 95 void UseDefaultPlot(gui::TabWidget*tabwidget);85 /*! 86 * \brief Use default plot 87 * 88 * \param tabwidget TabWidget to draw plots 89 */ 90 void UseDefaultPlot(gui::TabWidget *tabwidget); 96 91 97 /*! 98 * \brief Output from motors 99 * 100 * First column is real speed if available, secund column is current if available 101 * 102 */ 103 core::cvmatrix *Output(void) const; 92 /*! 93 * \brief Output from motors 94 * 95 * First column is real speed if available, secund column is current if 96 *available 97 * 98 */ 99 core::cvmatrix *Output(void) const; 104 100 105 106 107 108 109 110 101 /*! 102 * \brief Motors count 103 * 104 * \return number of motors 105 */ 106 uint8_t MotorsCount(void) const; 111 107 112 113 114 115 116 117 108 /*! 109 * \brief Enable motors 110 * 111 * \param true to enable all motors 112 */ 113 void SetEnabled(bool status); 118 114 119 120 121 122 123 124 115 /*! 116 * \brief Are motors enabled? 117 * 118 * \return true if motors are enabled 119 */ 120 bool AreEnabled(void) const; 125 121 126 /*! 127 * \brief Set motor power 128 * 129 * Changes the power (from 0 to 1) of a specific motor. \n 130 * By default power is set to 1 for each motor which has no effect. \n 131 * A value <1 will decrease the power of a motor sent to the reimplemented Bldc class through SetMotors. \n 132 * The power value is applied after applying saturation between min value and max value. 133 * So the resulting value cannot be higher than max value 134 * but it can be lower than min value. 135 * 136 * \param motor_id id of the motor 137 * \param value power value (from 0 to 1) 138 * 139 */ 140 void SetPower(int motor_id,float value); 122 /*! 123 * \brief Set motor power 124 * 125 * Changes the power (from 0 to 1) of a specific motor. \n 126 * By default power is set to 1 for each motor which has no effect. \n 127 * A value <1 will decrease the power of a motor sent to the reimplemented Bldc 128 *class through SetMotors. \n 129 * The power value is applied after applying saturation between min value and 130 *max value. 131 * So the resulting value cannot be higher than max value 132 * but it can be lower than min value. 133 * 134 * \param motor_id id of the motor 135 * \param value power value (from 0 to 1) 136 * 137 */ 138 void SetPower(int motor_id, float value); 141 139 142 143 144 145 146 147 148 149 gui::Layout*GetLayout(void) const;140 /*! 141 * \brief Layout 142 * 143 * This the same Layout as passed to the constructor 144 * 145 * \return a Layout 146 */ 147 gui::Layout *GetLayout(void) const; 150 148 151 152 153 154 155 156 virtual bool HasSpeedMeasurement(void) const=0;149 /*! 150 * \brief Has speed measurement 151 * 152 * \return true if it has speed measurement 153 */ 154 virtual bool HasSpeedMeasurement(void) const = 0; 157 155 158 159 160 161 162 163 virtual bool HasCurrentMeasurement(void) const=0;156 /*! 157 * \brief Has current measurement 158 * 159 * \return true if it has current measurement 160 */ 161 virtual bool HasCurrentMeasurement(void) const = 0; 164 162 165 166 163 protected: 164 core::cvmatrix *output; 167 165 168 169 170 171 172 173 174 175 176 166 private: 167 /*! 168 * \brief Update using provided datas 169 * 170 * Reimplemented from IODevice. 171 * 172 * \param data data from the parent to process 173 */ 174 void UpdateFrom(const core::io_data *data); 177 175 178 179 180 181 182 183 184 185 virtual void SetMotors(float* values)=0;176 /*! 177 * \brief Set motors values 178 * 179 * values size must be the same as MotorsCount() 180 * 181 * \param values set motors values 182 */ 183 virtual void SetMotors(float *values) = 0; 186 184 187 class Bldc_impl*pimpl_;188 185 class Bldc_impl *pimpl_; 186 }; 189 187 } // end namespace actuator 190 188 } // end namespace framewor -
trunk/lib/FlairSensorActuator/src/Bldc_impl.cpp
r3 r15 35 35 using namespace flair::actuator; 36 36 37 Bldc_impl::Bldc_impl(Bldc* self,Layout* layout,string name,uint8_t motors_count) { 38 this->self=self; 39 this->motors_count=motors_count; 40 this->layout=layout; 41 are_enabled=false; 42 is_running=false; 43 tested_motor=-1; 44 45 values=(float*)malloc(motors_count*sizeof(float)); 46 power=(float*)malloc(motors_count*sizeof(float)); 47 for(int i=0;i<motors_count;i++) power[i]=1; 48 49 //station sol 50 GroupBox* groupbox=new GroupBox(layout->NewRow(),"bldc"); 51 flight_time=new Label(groupbox->NewRow(),"flight time"); 52 min_value=new DoubleSpinBox(groupbox->NewRow(),"min value:",0,1,.1,2); 53 max_value=new DoubleSpinBox(groupbox->LastRowLastCol(),"max value:",0,1,.1,2); 54 test_value=new DoubleSpinBox(groupbox->LastRowLastCol(),"test value:",0,1,0.1); 55 56 int index=0; 57 button_test=(PushButton**)malloc(motors_count*sizeof(PushButton*)); 58 for(int i=0;i<motors_count/2;i++) { 59 for(int j=0;j<2;j++) { 60 ostringstream test_name; 61 test_name << "test motor " << index; 62 button_test[index]=new PushButton(groupbox->At(2+i,j),test_name.str()); 63 index++; 64 } 65 } 66 67 //flight time 68 FILE *file; 69 file=fopen("/etc/flight_time","r"); 37 Bldc_impl::Bldc_impl(Bldc *self, Layout *layout, string name, 38 uint8_t motors_count) { 39 this->self = self; 40 this->motors_count = motors_count; 41 this->layout = layout; 42 are_enabled = false; 43 is_running = false; 44 tested_motor = -1; 45 46 values = (float *)malloc(motors_count * sizeof(float)); 47 power = (float *)malloc(motors_count * sizeof(float)); 48 for (int i = 0; i < motors_count; i++) 49 power[i] = 1; 50 51 // station sol 52 GroupBox *groupbox = new GroupBox(layout->NewRow(), "bldc"); 53 flight_time = new Label(groupbox->NewRow(), "flight time"); 54 min_value = new DoubleSpinBox(groupbox->NewRow(), "min value:", 0, 1, .1, 2); 55 max_value = 56 new DoubleSpinBox(groupbox->LastRowLastCol(), "max value:", 0, 1, .1, 2); 57 test_value = 58 new DoubleSpinBox(groupbox->LastRowLastCol(), "test value:", 0, 1, 0.1); 59 60 int index = 0; 61 button_test = (PushButton **)malloc(motors_count * sizeof(PushButton *)); 62 for (int i = 0; i < motors_count / 2; i++) { 63 for (int j = 0; j < 2; j++) { 64 ostringstream test_name; 65 test_name << "test motor " << index; 66 button_test[index] = 67 new PushButton(groupbox->At(2 + i, j), test_name.str()); 68 index++; 69 } 70 } 71 72 // flight time 73 FILE *file; 74 file = fopen("/etc/flight_time", "r"); 75 if (file == NULL) { 76 time_sec = 0; 77 } else { 78 char ligne[32]; 79 fgets(ligne, 32, file); 80 time_sec = atoi(ligne); 81 fclose(file); 82 } 83 flight_time->SetText("total flight time: %is = %imin = %ih\n", time_sec, 84 time_sec / 60, time_sec / 3600); 85 } 86 87 Bldc_impl::Bldc_impl(Bldc *self, uint8_t motors_count) { 88 this->self = self; 89 this->motors_count = motors_count; 90 values = NULL; 91 button_test = NULL; 92 power = NULL; 93 } 94 95 Bldc_impl::~Bldc_impl() { 96 if (values != NULL) 97 free(values); 98 if (button_test != NULL) 99 free(button_test); 100 if (power != NULL) 101 free(power); 102 } 103 104 void Bldc_impl::UseDefaultPlot(TabWidget *tab) { 105 Tab *plot_tab = new Tab(tab, "speeds"); 106 plots = new DataPlot1D(plot_tab->NewRow(), "values", 0, 1); 107 for (int i = 0; i < motors_count; i++) { 108 plots->AddCurve(self->output->Element(i)); 109 } 110 } 111 112 void Bldc_impl::UpdateFrom(const io_data *data) { 113 cvmatrix *input = (cvmatrix *)data; 114 bool is_motor_running = false; 115 116 if (values == NULL) 117 return; // nothing to do in simulator 118 119 if (input->Rows() != motors_count) { 120 self->Err("nb motors mismatch\n"); 121 return; 122 } 123 124 input->GetMutex(); 125 for (int i = 0; i < motors_count; i++) { 126 if (input->ValueNoMutex(i, 0) != 0) 127 is_motor_running = true; 128 if (are_enabled) { 129 // Printf("%i %f %f\n",i,input->ValueNoMutex(i,0),power[i]); 130 values[i] = power[i] * Sat(input->ValueNoMutex(i, 0)); 131 // Printf("%i %f\n",i,values[i]); 132 } else { 133 values[i] = 0; 134 } 135 } 136 input->ReleaseMutex(); 137 138 if (are_enabled && is_motor_running && !is_running) { 139 flight_start_time = GetTime(); 140 is_running = true; 141 } 142 if ((!are_enabled || !is_motor_running) && is_running) { 143 Time now = GetTime(); 144 int t_sec; 145 FILE *file; 146 char ligne[32]; 147 148 t_sec = (now - flight_start_time) / 1000000000; 149 time_sec += t_sec; 150 151 Printf("temps de vol: %is = %imin\n", t_sec, t_sec / 60); 152 // Printf("temps de vol total: %is = %imin = 153 // %ih\n",time_sec,time_sec/60,time_sec/3600); 154 flight_time->SetText("total flight time: %is = %imin = %ih\n", time_sec, 155 time_sec / 60, time_sec / 3600); 156 157 file = fopen("/etc/flight_time", "w"); 70 158 if (file == NULL) { 71 time_sec=0;159 Printf("Erreur a l'ouverture du fichier d'info vol\n"); 72 160 } else { 73 char ligne[32]; 74 fgets(ligne, 32, file); 75 time_sec=atoi(ligne); 76 fclose(file); 77 } 78 flight_time->SetText("total flight time: %is = %imin = %ih\n",time_sec,time_sec/60,time_sec/3600); 79 } 80 81 Bldc_impl::Bldc_impl(Bldc* self,uint8_t motors_count) { 82 this->self=self; 83 this->motors_count=motors_count; 84 values=NULL; 85 button_test=NULL; 86 power=NULL; 87 } 88 89 Bldc_impl::~Bldc_impl() { 90 if(values!=NULL) free(values); 91 if(button_test!=NULL) free(button_test); 92 if(power!=NULL) free(power); 93 } 94 95 void Bldc_impl::UseDefaultPlot(TabWidget* tab) { 96 Tab* plot_tab=new Tab(tab,"speeds"); 97 plots=new DataPlot1D(plot_tab->NewRow(),"values",0,1); 98 for(int i=0;i<motors_count;i++) { 99 plots->AddCurve(self->output->Element(i)); 100 } 101 } 102 103 void Bldc_impl::UpdateFrom(const io_data *data) { 104 cvmatrix* input=(cvmatrix*)data; 105 bool is_motor_running=false; 106 107 if(values==NULL) return;//nothing to do in simulator 108 109 if(input->Rows()!=motors_count) { 110 self->Err("nb motors mismatch\n"); 111 return; 112 } 113 114 input->GetMutex(); 115 for(int i=0;i<motors_count;i++) { 116 if(input->ValueNoMutex(i,0)!=0) is_motor_running=true; 117 if(are_enabled) { 118 //Printf("%i %f %f\n",i,input->ValueNoMutex(i,0),power[i]); 119 values[i]=power[i]*Sat(input->ValueNoMutex(i,0)); 120 //Printf("%i %f\n",i,values[i]); 121 } else { 122 values[i]=0; 123 } 124 } 125 input->ReleaseMutex(); 126 127 if(are_enabled && is_motor_running && !is_running) { 128 flight_start_time = GetTime(); 129 is_running=true; 130 } 131 if((!are_enabled || !is_motor_running) && is_running) { 132 Time now= GetTime(); 133 int t_sec; 134 FILE *file; 135 char ligne[32]; 136 137 t_sec=(now - flight_start_time)/1000000000; 138 time_sec+=t_sec; 139 140 Printf("temps de vol: %is = %imin\n",t_sec,t_sec/60); 141 //Printf("temps de vol total: %is = %imin = %ih\n",time_sec,time_sec/60,time_sec/3600); 142 flight_time->SetText("total flight time: %is = %imin = %ih\n",time_sec,time_sec/60,time_sec/3600); 143 144 file=fopen("/etc/flight_time","w"); 145 if (file == NULL) { 146 Printf("Erreur a l'ouverture du fichier d'info vol\n"); 147 } else { 148 sprintf(ligne,"%i",time_sec); 149 fputs(ligne,file); 150 fclose(file); 151 } 152 is_running=false; 153 } 154 155 for(int i=0;i<motors_count;i++) { 156 if(button_test[i]->Clicked()==true) { 157 if(!are_enabled) { 158 tested_motor=i; 159 test_start_time=GetTime(); 160 LockUserInterface(); 161 } else { 162 self->Warn("testing motor is not possible when enabled\n"); 163 } 164 } 165 } 166 if(tested_motor!=-1) { 167 for(int i=0;i<motors_count;i++) { 168 values[i]=0; 169 } 170 values[tested_motor]=test_value->Value(); 171 172 if(GetTime()>(test_start_time+2*1000000000)) { 173 tested_motor=-1; 174 UnlockUserInterface(); 175 } 176 } 177 178 self->SetMotors(values); 179 self->output->SetDataTime(data->DataTime()); 180 self->ProcessUpdate(self->output); 161 sprintf(ligne, "%i", time_sec); 162 fputs(ligne, file); 163 fclose(file); 164 } 165 is_running = false; 166 } 167 168 for (int i = 0; i < motors_count; i++) { 169 if (button_test[i]->Clicked() == true) { 170 if (!are_enabled) { 171 tested_motor = i; 172 test_start_time = GetTime(); 173 LockUserInterface(); 174 } else { 175 self->Warn("testing motor is not possible when enabled\n"); 176 } 177 } 178 } 179 if (tested_motor != -1) { 180 for (int i = 0; i < motors_count; i++) { 181 values[i] = 0; 182 } 183 values[tested_motor] = test_value->Value(); 184 185 if (GetTime() > (test_start_time + 2 * 1000000000)) { 186 tested_motor = -1; 187 UnlockUserInterface(); 188 } 189 } 190 191 self->SetMotors(values); 192 self->output->SetDataTime(data->DataTime()); 193 self->ProcessUpdate(self->output); 181 194 } 182 195 183 196 float Bldc_impl::Sat(float value) { 184 float result=value; 185 186 if(result<min_value->Value()) { 187 result=min_value->Value(); 188 } 189 if(result>max_value->Value()) { 190 result=max_value->Value(); 191 } 192 193 return result; 194 } 195 196 void Bldc_impl::LockUserInterface(void) const { 197 layout->setEnabled(false); 198 } 199 200 void Bldc_impl::UnlockUserInterface(void) const { 201 layout->setEnabled(true); 202 } 197 float result = value; 198 199 if (result < min_value->Value()) { 200 result = min_value->Value(); 201 } 202 if (result > max_value->Value()) { 203 result = max_value->Value(); 204 } 205 206 return result; 207 } 208 209 void Bldc_impl::LockUserInterface(void) const { layout->setEnabled(false); } 210 211 void Bldc_impl::UnlockUserInterface(void) const { layout->setEnabled(true); } -
trunk/lib/FlairSensorActuator/src/Camera.cpp
r3 r15 31 31 using namespace flair::gui; 32 32 33 namespace flair { namespace sensor { 33 namespace flair { 34 namespace sensor { 34 35 35 Camera::Camera(const FrameworkManager* parent,string name,uint16_t width,uint16_t height,cvimage::Type::Format format) : IODevice(parent,name) { 36 plot_tab=NULL; 36 Camera::Camera(const FrameworkManager *parent, string name, uint16_t width, 37 uint16_t height, cvimage::Type::Format format) 38 : IODevice(parent, name) { 39 plot_tab = NULL; 37 40 38 //do not allocate imagedata, allocation is done by the camera39 output=new cvimage((IODevice*)this,width,height,format,"out",false);41 // do not allocate imagedata, allocation is done by the camera 42 output = new cvimage((IODevice *)this, width, height, format, "out", false); 40 43 41 //station sol42 main_tab=new Tab(parent->GetTabWidget(),name);43 tab=new TabWidget(main_tab->NewRow(),name);44 sensor_tab=new Tab(tab,"Setup");45 setup_groupbox=new GroupBox(sensor_tab->NewRow(),name);46 setup_layout=new GridLayout(sensor_tab->NewRow(),"setup");44 // station sol 45 main_tab = new Tab(parent->GetTabWidget(), name); 46 tab = new TabWidget(main_tab->NewRow(), name); 47 sensor_tab = new Tab(tab, "Setup"); 48 setup_groupbox = new GroupBox(sensor_tab->NewRow(), name); 49 setup_layout = new GridLayout(sensor_tab->NewRow(), "setup"); 47 50 } 48 51 49 Camera::Camera(const IODevice* parent,std::string name) : IODevice(parent,name) { 50 plot_tab=NULL; 51 main_tab=NULL; 52 tab=NULL; 53 sensor_tab=NULL; 54 setup_groupbox=NULL; 52 Camera::Camera(const IODevice *parent, std::string name) 53 : IODevice(parent, name) { 54 plot_tab = NULL; 55 main_tab = NULL; 56 tab = NULL; 57 sensor_tab = NULL; 58 setup_groupbox = NULL; 55 59 56 output=NULL;60 output = NULL; 57 61 } 58 62 59 63 Camera::~Camera() { 60 if(main_tab!=NULL) delete main_tab; 64 if (main_tab != NULL) 65 delete main_tab; 61 66 } 62 67 63 68 DataType const &Camera::GetOutputDataType() const { 64 69 return output->GetDataType(); 65 70 } 66 71 67 GroupBox* Camera::GetGroupBox(void) const { 68 return setup_groupbox; 72 GroupBox *Camera::GetGroupBox(void) const { return setup_groupbox; } 73 74 GridLayout *Camera::GetLayout(void) const { return setup_layout; } 75 76 void Camera::UseDefaultPlot(const core::cvimage *image) { 77 if (tab == NULL) { 78 Err("not applicable for simulation part.\n"); 79 return; 80 } 81 82 plot_tab = new Tab(tab, "Picture"); 83 Picture *plot = new Picture(plot_tab->NewRow(), ObjectName(), image); 69 84 } 70 85 71 GridLayout* Camera::GetLayout(void) const { 72 return setup_layout; 86 Tab *Camera::GetPlotTab(void) const { return plot_tab; } 87 88 uint16_t Camera::Width(void) const { return output->GetDataType().GetWidth(); } 89 90 uint16_t Camera::Height(void) const { 91 return output->GetDataType().GetHeight(); 73 92 } 74 93 75 void Camera::UseDefaultPlot(const core::cvimage *image) { 76 if(tab==NULL) { 77 Err("not applicable for simulation part.\n"); 78 return; 79 } 80 81 plot_tab=new Tab(tab,"Picture"); 82 Picture* plot=new Picture(plot_tab->NewRow(),ObjectName(),image); 83 } 84 85 Tab* Camera::GetPlotTab(void) const { 86 return plot_tab; 87 } 88 89 uint16_t Camera::Width(void) const { 90 return output->GetDataType().GetWidth(); 91 } 92 93 uint16_t Camera::Height(void) const { 94 return output->GetDataType().GetHeight(); 95 } 96 97 core::cvimage* Camera::Output(void) { 98 return output; 99 } 94 core::cvimage *Camera::Output(void) { return output; } 100 95 101 96 void Camera::SaveToFile(string filename) const { 102 Printf("saving %s, size %i\n",filename.c_str(),output->img->imageSize);103 104 pFile.open(filename);105 106 107 97 Printf("saving %s, size %i\n", filename.c_str(), output->img->imageSize); 98 std::ofstream pFile; 99 pFile.open(filename); 100 output->GetMutex(); 101 pFile.write(output->img->imageData, output->img->imageSize); 102 output->ReleaseMutex(); 108 103 109 104 pFile.close(); 110 105 } 111 106 -
trunk/lib/FlairSensorActuator/src/Camera.h
r3 r15 18 18 #include <cvimage.h> 19 19 20 namespace flair 21 { 22 namespace gui 23 { 24 class GroupBox; 25 class Tab; 26 class TabWidget; 27 class Picture; 28 class GridLayout; 29 } 20 namespace flair { 21 namespace gui { 22 class GroupBox; 23 class Tab; 24 class TabWidget; 25 class Picture; 26 class GridLayout; 27 } 30 28 } 31 29 32 namespace flair 33 { 34 namespace sensor 35 { 36 /*! \class Camera 37 * 38 * \brief Base class for Camera 39 * 40 * Use this class to define a custom Camera. 41 * 42 */ 43 class Camera : public core::IODevice 44 { 45 public: 46 /*! 47 * \brief Constructor 48 * 49 * Construct a Camera. 50 * 51 * \param parent parent 52 * \param name name 53 * \param width width 54 * \param height height 55 * \param format image format 56 */ 57 Camera(const core::FrameworkManager* parent,std::string name,uint16_t width,uint16_t height,core::cvimage::Type::Format format); 30 namespace flair { 31 namespace sensor { 32 /*! \class Camera 33 * 34 * \brief Base class for Camera 35 * 36 * Use this class to define a custom Camera. 37 * 38 */ 39 class Camera : public core::IODevice { 40 public: 41 /*! 42 * \brief Constructor 43 * 44 * Construct a Camera. 45 * 46 * \param parent parent 47 * \param name name 48 * \param width width 49 * \param height height 50 * \param format image format 51 */ 52 Camera(const core::FrameworkManager *parent, std::string name, uint16_t width, 53 uint16_t height, core::cvimage::Type::Format format); 58 54 59 60 61 62 63 64 65 66 67 68 Camera(const core::IODevice* parent,std::string name);55 /*! 56 * \brief Constructor 57 * 58 * Construct a Camera. \n 59 * This contructor must only be called for a simulated device. 60 * 61 * \param parent parent 62 * \param name name 63 */ 64 Camera(const core::IODevice *parent, std::string name); 69 65 70 71 72 73 74 66 /*! 67 * \brief Destructor 68 * 69 */ 70 ~Camera(); 75 71 76 77 78 79 80 81 72 /*! 73 * \brief Use default plot 74 * 75 * \param image image to display 76 */ 77 void UseDefaultPlot(const core::cvimage *image); 82 78 83 84 85 86 87 88 gui::GridLayout*GetLayout(void) const;79 /*! 80 * \brief get Layout 81 * 82 * \return a Layout available 83 */ 84 gui::GridLayout *GetLayout(void) const; 89 85 90 91 92 93 94 95 gui::Tab*GetPlotTab(void) const;86 /*! 87 * \brief plot tab 88 * 89 * \return plot tab 90 */ 91 gui::Tab *GetPlotTab(void) const; 96 92 97 98 99 100 101 102 93 /*! 94 * \brief Save picture to file 95 * 96 * \param filename filename 97 */ 98 void SaveToFile(std::string filename) const; 103 99 104 105 106 107 108 109 100 /*! 101 * \brief Width 102 * 103 * \return width 104 */ 105 uint16_t Width(void) const; 110 106 111 112 113 114 115 116 107 /*! 108 * \brief Height 109 * 110 * \return height 111 */ 112 uint16_t Height(void) const; 117 113 118 119 120 121 122 123 124 125 core::cvimage*Output(void);114 /*! 115 * \brief Output matrix 116 * 117 * Output matrix is of the same size as declared in constructor. \n 118 * 119 * \return the output matrix 120 */ 121 core::cvimage *Output(void); 126 122 127 123 core::DataType const &GetOutputDataType() const; 128 124 129 130 131 132 133 134 135 gui::GroupBox*GetGroupBox(void) const;125 protected: 126 /*! 127 * \brief get GroupBox 128 * 129 * \return a GroupBox available 130 */ 131 gui::GroupBox *GetGroupBox(void) const; 136 132 137 133 core::cvimage *output; 138 134 139 140 gui::Tab *main_tab,*sensor_tab,*plot_tab;141 142 gui::GroupBox*setup_groupbox;143 gui::GridLayout*setup_layout;144 135 private: 136 gui::Tab *main_tab, *sensor_tab, *plot_tab; 137 gui::TabWidget *tab; 138 gui::GroupBox *setup_groupbox; 139 gui::GridLayout *setup_layout; 140 }; 145 141 } // end namespace sensor 146 142 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/Controller.cpp
r3 r15 19 19 using namespace flair::core; 20 20 21 namespace flair { namespace sensor { 21 namespace flair { 22 namespace sensor { 22 23 23 RumbleMessage::RumbleMessage(unsigned int leftForce,unsigned int leftTimeout,unsigned int rightForce,unsigned int rightTimeout):Message(sizeof(ControllerAction)+sizeof(leftForce)+sizeof(leftTimeout)+sizeof(rightForce)+sizeof(rightTimeout)) { 24 SetLeftForce(leftForce); 25 SetLeftTimeout(leftTimeout); 26 SetRightForce(rightForce); 27 SetRightTimeout(rightTimeout); 28 buffer[0]=(char)ControllerAction::Rumble; 24 RumbleMessage::RumbleMessage(unsigned int leftForce, unsigned int leftTimeout, 25 unsigned int rightForce, unsigned int rightTimeout) 26 : Message(sizeof(ControllerAction) + sizeof(leftForce) + 27 sizeof(leftTimeout) + sizeof(rightForce) + sizeof(rightTimeout)) { 28 SetLeftForce(leftForce); 29 SetLeftTimeout(leftTimeout); 30 SetRightForce(rightForce); 31 SetRightTimeout(rightTimeout); 32 buffer[0] = (char)ControllerAction::Rumble; 29 33 } 30 34 31 35 unsigned int RumbleMessage::GetLeftForce() const { 32 33 memcpy(&leftForce,buffer+leftForceOffset,sizeof(leftForce));34 36 unsigned int leftForce; 37 memcpy(&leftForce, buffer + leftForceOffset, sizeof(leftForce)); 38 return leftForce; 35 39 } 36 40 37 41 unsigned int RumbleMessage::GetLeftTimeout() const { 38 39 memcpy(&leftTimeout,buffer+leftTimeoutOffset,sizeof(leftTimeout));40 42 unsigned int leftTimeout; 43 memcpy(&leftTimeout, buffer + leftTimeoutOffset, sizeof(leftTimeout)); 44 return leftTimeout; 41 45 } 42 46 43 47 unsigned int RumbleMessage::GetRightForce() const { 44 45 memcpy(&rightForce,buffer+rightForceOffset,sizeof(rightForce));46 48 unsigned int rightForce; 49 memcpy(&rightForce, buffer + rightForceOffset, sizeof(rightForce)); 50 return rightForce; 47 51 } 48 52 49 53 unsigned int RumbleMessage::GetRightTimeout() const { 50 51 memcpy(&rightTimeout,buffer+rightTimeoutOffset,sizeof(rightTimeout));52 54 unsigned int rightTimeout; 55 memcpy(&rightTimeout, buffer + rightTimeoutOffset, sizeof(rightTimeout)); 56 return rightTimeout; 53 57 } 54 58 55 59 void RumbleMessage::SetLeftForce(unsigned int leftForce) { 56 memcpy(buffer+leftForceOffset,&leftForce,sizeof(leftForce));60 memcpy(buffer + leftForceOffset, &leftForce, sizeof(leftForce)); 57 61 } 58 62 59 63 void RumbleMessage::SetLeftTimeout(unsigned int leftTimeout) { 60 memcpy(buffer+leftTimeoutOffset,&leftTimeout,sizeof(leftTimeout));64 memcpy(buffer + leftTimeoutOffset, &leftTimeout, sizeof(leftTimeout)); 61 65 } 62 66 63 67 void RumbleMessage::SetRightForce(unsigned int rightForce) { 64 memcpy(buffer+rightForceOffset,&rightForce,sizeof(rightForce));68 memcpy(buffer + rightForceOffset, &rightForce, sizeof(rightForce)); 65 69 } 66 70 67 void RumbleMessage::SetRightTimeout(unsigned int rightTimeout) {68 memcpy(buffer+rightTimeoutOffset,&rightTimeout,sizeof(rightTimeout));71 void RumbleMessage::SetRightTimeout(unsigned int rightTimeout) { 72 memcpy(buffer + rightTimeoutOffset, &rightTimeout, sizeof(rightTimeout)); 69 73 } 70 74 71 SwitchLedMessage::SwitchLedMessage(bool isOn, unsigned int ledId):Message(sizeof(ControllerAction)+sizeof(isOn)+sizeof(ledId)) { 72 if (isOn) SetOn(); else SetOff(); 73 SetLedId(ledId); 75 SwitchLedMessage::SwitchLedMessage(bool isOn, unsigned int ledId) 76 : Message(sizeof(ControllerAction) + sizeof(isOn) + sizeof(ledId)) { 77 if (isOn) 78 SetOn(); 79 else 80 SetOff(); 81 SetLedId(ledId); 74 82 } 75 83 76 84 bool SwitchLedMessage::IsOn() const { 77 78 memcpy(&isOn,buffer+isOnOffset,sizeof(isOn));79 85 bool isOn; 86 memcpy(&isOn, buffer + isOnOffset, sizeof(isOn)); 87 return isOn; 80 88 } 81 89 82 90 unsigned int SwitchLedMessage::GetLedId() const { 83 84 memcpy(&ledId,buffer+ledIdOffset,sizeof(ledId));85 91 unsigned int ledId; 92 memcpy(&ledId, buffer + ledIdOffset, sizeof(ledId)); 93 return ledId; 86 94 } 87 95 88 96 void SwitchLedMessage::SetOn() { 89 bool isOn=true;90 memcpy(buffer+isOnOffset,&isOn,sizeof(isOn));97 bool isOn = true; 98 memcpy(buffer + isOnOffset, &isOn, sizeof(isOn)); 91 99 } 92 100 93 101 void SwitchLedMessage::SetOff() { 94 bool isOn=false;95 memcpy(buffer+isOnOffset,&isOn,sizeof(isOn));102 bool isOn = false; 103 memcpy(buffer + isOnOffset, &isOn, sizeof(isOn)); 96 104 } 97 105 98 106 void SwitchLedMessage::SetLedId(unsigned int ledId) { 99 memcpy(buffer+ledIdOffset,&ledId,sizeof(ledId));107 memcpy(buffer + ledIdOffset, &ledId, sizeof(ledId)); 100 108 } 101 109 102 FlashLedMessage::FlashLedMessage(unsigned int ledId,unsigned int onTime,unsigned int offTime):Message(sizeof(ControllerAction)+sizeof(ledId)+sizeof(onTime)+sizeof(offTime)) { 103 SetLedId(ledId); 104 SetOnTime(onTime); 105 SetOffTime(offTime); 110 FlashLedMessage::FlashLedMessage(unsigned int ledId, unsigned int onTime, 111 unsigned int offTime) 112 : Message(sizeof(ControllerAction) + sizeof(ledId) + sizeof(onTime) + 113 sizeof(offTime)) { 114 SetLedId(ledId); 115 SetOnTime(onTime); 116 SetOffTime(offTime); 106 117 } 107 118 108 119 unsigned int FlashLedMessage::GetLedId() const { 109 110 memcpy(&ledId,buffer+ledIdOffset,sizeof(ledId));111 120 unsigned int ledId; 121 memcpy(&ledId, buffer + ledIdOffset, sizeof(ledId)); 122 return ledId; 112 123 } 113 124 114 125 unsigned int FlashLedMessage::GetOnTime() const { 115 116 memcpy(&onTime,buffer+onTimeOffset,sizeof(onTime));117 126 unsigned int onTime; 127 memcpy(&onTime, buffer + onTimeOffset, sizeof(onTime)); 128 return onTime; 118 129 } 119 130 120 131 unsigned int FlashLedMessage::GetOffTime() const { 121 122 memcpy(&offTime,buffer+offTimeOffset,sizeof(offTime));123 132 unsigned int offTime; 133 memcpy(&offTime, buffer + offTimeOffset, sizeof(offTime)); 134 return offTime; 124 135 } 125 136 126 137 void FlashLedMessage::SetLedId(unsigned int ledId) { 127 memcpy(buffer+ledIdOffset,&ledId,sizeof(ledId));138 memcpy(buffer + ledIdOffset, &ledId, sizeof(ledId)); 128 139 } 129 140 130 141 void FlashLedMessage::SetOnTime(unsigned int onTime) { 131 memcpy(buffer+onTimeOffset,&onTime,sizeof(onTime));142 memcpy(buffer + onTimeOffset, &onTime, sizeof(onTime)); 132 143 } 133 144 134 145 void FlashLedMessage::SetOffTime(unsigned int offTime) { 135 memcpy(buffer+offTimeOffset,&offTime,sizeof(offTime));146 memcpy(buffer + offTimeOffset, &offTime, sizeof(offTime)); 136 147 } 137 148 -
trunk/lib/FlairSensorActuator/src/Controller.h
r3 r15 23 23 24 24 namespace flair { 25 26 27 25 namespace core { 26 class Message; 27 } 28 28 } 29 29 30 namespace flair { namespace sensor { 30 namespace flair { 31 namespace sensor { 31 32 32 enum class ControllerAction { 33 SetLedOn, 34 SetLedOff, 35 Rumble, 36 FlashLed, 37 Exit 38 }; 33 enum class ControllerAction { SetLedOn, SetLedOff, Rumble, FlashLed, Exit }; 39 34 40 class RumbleMessage: public core::Message { 41 public: 42 RumbleMessage(unsigned int leftForce,unsigned int leftTimeout,unsigned int rightForce,unsigned int rightTimeout); 43 unsigned int GetLeftForce() const; 44 unsigned int GetLeftTimeout() const; 45 unsigned int GetRightForce() const; 46 unsigned int GetRightTimeout() const; 47 void SetLeftForce(unsigned int leftForce); 48 void SetLeftTimeout(unsigned int leftTimeout); 49 void SetRightForce(unsigned int rightForce); 50 void SetRightTimeout(unsigned int rightTimeout); 51 private: 52 static const unsigned int leftForceOffset=sizeof(ControllerAction); 53 static const unsigned int leftTimeoutOffset=sizeof(ControllerAction)+sizeof(unsigned int); 54 static const unsigned int rightForceOffset=sizeof(ControllerAction)+2*sizeof(unsigned int); 55 static const unsigned int rightTimeoutOffset=sizeof(ControllerAction)+3*sizeof(unsigned int); 56 }; 35 class RumbleMessage : public core::Message { 36 public: 37 RumbleMessage(unsigned int leftForce, unsigned int leftTimeout, 38 unsigned int rightForce, unsigned int rightTimeout); 39 unsigned int GetLeftForce() const; 40 unsigned int GetLeftTimeout() const; 41 unsigned int GetRightForce() const; 42 unsigned int GetRightTimeout() const; 43 void SetLeftForce(unsigned int leftForce); 44 void SetLeftTimeout(unsigned int leftTimeout); 45 void SetRightForce(unsigned int rightForce); 46 void SetRightTimeout(unsigned int rightTimeout); 57 47 58 class SwitchLedMessage: public core::Message { 59 public: 60 SwitchLedMessage(bool isOn,unsigned int ledId); 61 bool IsOn() const; 62 unsigned int GetLedId() const; 63 void SetOn(); 64 void SetOff(); 65 void SetLedId(unsigned int ledId); 66 private: 67 static const unsigned int isOnOffset=sizeof(ControllerAction); 68 static const unsigned int ledIdOffset=sizeof(ControllerAction)+sizeof(bool); 69 }; 48 private: 49 static const unsigned int leftForceOffset = sizeof(ControllerAction); 50 static const unsigned int leftTimeoutOffset = 51 sizeof(ControllerAction) + sizeof(unsigned int); 52 static const unsigned int rightForceOffset = 53 sizeof(ControllerAction) + 2 * sizeof(unsigned int); 54 static const unsigned int rightTimeoutOffset = 55 sizeof(ControllerAction) + 3 * sizeof(unsigned int); 56 }; 70 57 71 class FlashLedMessage: public core::Message { 72 public: 73 FlashLedMessage(unsigned int ledId,unsigned int onTime,unsigned int offTime); 74 unsigned int GetLedId() const; 75 unsigned int GetOnTime() const; 76 unsigned int GetOffTime() const; 77 void SetLedId(unsigned int ledId); 78 void SetOnTime(unsigned int onTime); 79 void SetOffTime(unsigned int offTime); 80 private: 81 static const unsigned int ledIdOffset=sizeof(ControllerAction); 82 static const unsigned int onTimeOffset=sizeof(ControllerAction)+sizeof(unsigned int); 83 static const unsigned int offTimeOffset=sizeof(ControllerAction)+2*sizeof(unsigned int); 84 }; 58 class SwitchLedMessage : public core::Message { 59 public: 60 SwitchLedMessage(bool isOn, unsigned int ledId); 61 bool IsOn() const; 62 unsigned int GetLedId() const; 63 void SetOn(); 64 void SetOff(); 65 void SetLedId(unsigned int ledId); 85 66 86 }} 67 private: 68 static const unsigned int isOnOffset = sizeof(ControllerAction); 69 static const unsigned int ledIdOffset = 70 sizeof(ControllerAction) + sizeof(bool); 71 }; 72 73 class FlashLedMessage : public core::Message { 74 public: 75 FlashLedMessage(unsigned int ledId, unsigned int onTime, 76 unsigned int offTime); 77 unsigned int GetLedId() const; 78 unsigned int GetOnTime() const; 79 unsigned int GetOffTime() const; 80 void SetLedId(unsigned int ledId); 81 void SetOnTime(unsigned int onTime); 82 void SetOffTime(unsigned int offTime); 83 84 private: 85 static const unsigned int ledIdOffset = sizeof(ControllerAction); 86 static const unsigned int onTimeOffset = 87 sizeof(ControllerAction) + sizeof(unsigned int); 88 static const unsigned int offTimeOffset = 89 sizeof(ControllerAction) + 2 * sizeof(unsigned int); 90 }; 91 } 92 } 87 93 88 94 #endif // CONTROLLER_H -
trunk/lib/FlairSensorActuator/src/Gps.cpp
r3 r15 38 38 using namespace flair::gui; 39 39 40 namespace flair 41 { 42 namespace sensor 43 { 44 45 Gps::Gps(const FrameworkManager* parent,string name,NMEAFlags_t NMEAFlags) : IODevice(parent,name) 46 { 47 this->NMEAFlags=NMEAFlags; 48 49 nmea_zero_INFO(&info); 50 nmea_parser_init(&parser); 51 alt_ref=0; 52 53 54 if((NMEAFlags&GGA)==0) 40 namespace flair { 41 namespace sensor { 42 43 Gps::Gps(const FrameworkManager *parent, string name, NMEAFlags_t NMEAFlags) 44 : IODevice(parent, name) { 45 this->NMEAFlags = NMEAFlags; 46 47 nmea_zero_INFO(&info); 48 nmea_parser_init(&parser); 49 alt_ref = 0; 50 51 if ((NMEAFlags & GGA) == 0) { 52 Err("Enable at least GGA sentence\n"); 53 } 54 55 int index = 0; 56 if ((NMEAFlags & GGA) != 0) { 57 index += 3; 58 } 59 if ((NMEAFlags & VTG) != 0) { 60 index += 2; 61 } 62 if ((NMEAFlags & GST) != 0) { 63 index += 3; 64 } 65 66 cvmatrix_descriptor *desc = new cvmatrix_descriptor(index, 1); 67 index = 0; 68 if ((NMEAFlags & GGA) != 0) { 69 desc->SetElementName(0, 0, "e"); 70 desc->SetElementName(1, 0, "n"); 71 desc->SetElementName(2, 0, "u"); 72 index += 3; 73 } 74 if ((NMEAFlags & VTG) != 0) { 75 desc->SetElementName(index, 0, "ve"); 76 desc->SetElementName(index + 1, 0, "vn"); 77 index += 2; 78 } 79 if ((NMEAFlags & GST) != 0) { 80 desc->SetElementName(index, 0, "dev_lat"); 81 desc->SetElementName(index + 1, 0, "dev_lon"); 82 desc->SetElementName(index + 2, 0, "dev_elv"); 83 index += 3; 84 } 85 output = new cvmatrix((IODevice *)this, desc, floatType); 86 AddDataToLog(output); 87 88 // station sol 89 main_tab = new Tab(parent->GetTabWidget(), name); 90 tab = new TabWidget(main_tab->NewRow(), name); 91 sensor_tab = new Tab(tab, "Reglages"); 92 GroupBox *reglages_groupbox = new GroupBox(sensor_tab->NewRow(), name); 93 button_ref = new PushButton(reglages_groupbox->NewRow(), "set ref"); 94 nb_sat_label = new Label(reglages_groupbox->NewRow(), "nb_sat"); 95 fix_label = new Label(reglages_groupbox->LastRowLastCol(), "fix"); 96 97 position = new GeoCoordinate((IODevice *)this, "position", 0, 0, 0); 98 99 fix = FixQuality_t::Invalid; 100 nb_sat = 0; 101 take_ref = false; 102 nb_sat_label->SetText("nb_sat: %i", nb_sat); 103 fix_label->SetText("fix: %i", fix); 104 } 105 106 Gps::~Gps() { 107 nmea_parser_destroy(&parser); 108 delete main_tab; 109 } 110 111 void Gps::UseDefaultPlot(void) { 112 int index = 0; 113 plot_tab = new Tab(tab, "Mesures"); 114 115 if ((NMEAFlags & GGA) != 0) { 116 e_plot = new DataPlot1D(plot_tab->NewRow(), "e", -10, 10); 117 e_plot->AddCurve(output->Element(index)); 118 n_plot = new DataPlot1D(plot_tab->LastRowLastCol(), "n", -10, 10); 119 n_plot->AddCurve(output->Element(index + 1)); 120 u_plot = new DataPlot1D(plot_tab->LastRowLastCol(), "u", -10, 10); 121 u_plot->AddCurve(output->Element(index + 2)); 122 index += 3; 123 } 124 if ((NMEAFlags & VTG) != 0) { 125 ve_plot = new DataPlot1D(plot_tab->NewRow(), "ve", -10, 10); 126 ve_plot->AddCurve(output->Element(index)); 127 vn_plot = new DataPlot1D(plot_tab->LastRowLastCol(), "vn", -10, 10); 128 vn_plot->AddCurve(output->Element(index + 1)); 129 index += 2; 130 } 131 132 Tab *map_tab = new Tab(tab, "carte"); 133 map = new Map(map_tab->NewRow(), "map"); 134 map->AddPoint(position, "drone"); 135 } 136 137 DataPlot1D *Gps::EPlot(void) const { 138 if ((NMEAFlags & GGA) != 0) { 139 return e_plot; 140 } else { 141 Err("GGA sentence not requested\n"); 142 return NULL; 143 } 144 } 145 146 DataPlot1D *Gps::NPlot(void) const { 147 if ((NMEAFlags & GGA) != 0) { 148 return n_plot; 149 } else { 150 Err("GGA sentence not requested\n"); 151 return NULL; 152 } 153 } 154 155 DataPlot1D *Gps::UPlot(void) const { 156 if ((NMEAFlags & GGA) != 0) { 157 return u_plot; 158 } else { 159 Err("GGA sentence not requested\n"); 160 return NULL; 161 } 162 } 163 164 DataPlot1D *Gps::VEPlot(void) const { 165 if ((NMEAFlags & VTG) != 0) { 166 return ve_plot; 167 } else { 168 Err("GGA sentence not requested\n"); 169 return NULL; 170 } 171 } 172 173 DataPlot1D *Gps::VNPlot(void) const { 174 if ((NMEAFlags & VTG) != 0) { 175 return vn_plot; 176 } else { 177 Err("GGA sentence not requested\n"); 178 return NULL; 179 } 180 } 181 182 Layout *Gps::GetLayout(void) const { return sensor_tab; } 183 184 Tab *Gps::GetPlotTab(void) const { return plot_tab; } 185 186 TabWidget *Gps::GetTab(void) const { return tab; } 187 188 uint16_t Gps::NbSat(void) const { 189 output->GetMutex(); 190 uint16_t result = nb_sat; 191 output->ReleaseMutex(); 192 return result; 193 } 194 195 Gps::FixQuality_t Gps::FixQuality(void) const { 196 output->GetMutex(); 197 FixQuality_t result = fix; 198 output->ReleaseMutex(); 199 return result; 200 } 201 202 void Gps::SetRef(void) { take_ref = true; } 203 204 void Gps::GetENUPosition(Vector3D *point) { 205 output->GetMutex(); 206 point->x = output->ValueNoMutex(0, 0); 207 point->y = output->ValueNoMutex(1, 0); 208 point->z = output->ValueNoMutex(2, 0); 209 output->ReleaseMutex(); 210 } 211 212 void Gps::parseFrame(const char *frame, int frame_size) { 213 214 int result; 215 216 result = nmea_parse(&parser, frame, frame_size, &info); 217 if (result != 1) { 218 Warn("unrecognized nmea sentence\n"); 219 Warn("%s\n", frame); 220 } 221 222 result = nmea_parse_GPGGA(frame, frame_size, &pack); 223 224 if (result == 1) { 225 // Printf("%s\n",frame); 226 // Printf("nb:%i fix:%i lat:%f long:%f alt:%f vel:%f 227 // angle:%f\n",pack.satinuse,pack.sig,info.lat,info.lon,info.elv,info.speed*1000./3600.,info.direction); 228 // Printf("lat:%f long:%f\n",pos.lat,pos.lon); 229 output->GetMutex(); // on utilise le mutex de l'output pour fix et nb_sat 230 if ((int)fix != pack.sig) { 231 fix = (FixQuality_t)pack.sig; 232 fix_label->SetText("fix: %i", fix); 233 } 234 if (nb_sat != pack.satinuse) { 235 nb_sat = pack.satinuse; 236 nb_sat_label->SetText("nb_sat: %i", nb_sat); 237 } 238 output->ReleaseMutex(); 239 240 nmea_info2pos(&info, &pos); 241 position->SetCoordinates(Euler::ToDegree(pos.lat), Euler::ToDegree(pos.lon), 242 info.elv); 243 244 if ((info.sig == 2 && alt_ref == 0) || button_ref->Clicked() == true || 245 take_ref == true) { 246 Printf("prise pos ref\n"); 247 lat_ref = pos.lat; 248 long_ref = pos.lon; 249 alt_ref = info.elv; 250 take_ref = false; 251 } 252 // if(alt_ref!=0) 55 253 { 56 Err("Enable at least GGA sentence\n"); 57 } 58 59 int index=0; 60 if((NMEAFlags&GGA)!=0) 61 { 62 index+=3; 63 } 64 if((NMEAFlags&VTG)!=0) 65 { 66 index+=2; 67 } 68 if((NMEAFlags&GST)!=0) 69 { 70 index+=3; 71 } 72 73 cvmatrix_descriptor* desc=new cvmatrix_descriptor(index,1); 74 index=0; 75 if((NMEAFlags&GGA)!=0) 76 { 77 desc->SetElementName(0,0,"e"); 78 desc->SetElementName(1,0,"n"); 79 desc->SetElementName(2,0,"u"); 80 index+=3; 81 } 82 if((NMEAFlags&VTG)!=0) 83 { 84 desc->SetElementName(index,0,"ve"); 85 desc->SetElementName(index+1,0,"vn"); 86 index+=2; 87 } 88 if((NMEAFlags&GST)!=0) 89 { 90 desc->SetElementName(index,0,"dev_lat"); 91 desc->SetElementName(index+1,0,"dev_lon"); 92 desc->SetElementName(index+2,0,"dev_elv"); 93 index+=3; 94 } 95 output=new cvmatrix((IODevice*)this,desc,floatType); 96 AddDataToLog(output); 97 98 //station sol 99 main_tab=new Tab(parent->GetTabWidget(),name); 100 tab=new TabWidget(main_tab->NewRow(),name); 101 sensor_tab=new Tab(tab,"Reglages"); 102 GroupBox* reglages_groupbox=new GroupBox(sensor_tab->NewRow(),name); 103 button_ref=new PushButton(reglages_groupbox->NewRow(),"set ref"); 104 nb_sat_label=new Label(reglages_groupbox->NewRow(),"nb_sat"); 105 fix_label=new Label(reglages_groupbox->LastRowLastCol(),"fix"); 106 107 position=new GeoCoordinate((IODevice*)this,"position",0,0,0); 108 109 fix=FixQuality_t::Invalid; 110 nb_sat=0; 111 take_ref=false; 112 nb_sat_label->SetText("nb_sat: %i",nb_sat); 113 fix_label->SetText("fix: %i",fix); 114 } 115 116 Gps::~Gps() 117 { 118 nmea_parser_destroy(&parser); 119 delete main_tab; 120 } 121 122 void Gps::UseDefaultPlot(void) 123 { 124 int index=0; 125 plot_tab=new Tab(tab,"Mesures"); 126 127 if((NMEAFlags&GGA)!=0) 128 { 129 e_plot=new DataPlot1D(plot_tab->NewRow(),"e",-10,10); 130 e_plot->AddCurve(output->Element(index)); 131 n_plot=new DataPlot1D(plot_tab->LastRowLastCol(),"n",-10,10); 132 n_plot->AddCurve(output->Element(index+1)); 133 u_plot=new DataPlot1D(plot_tab->LastRowLastCol(),"u",-10,10); 134 u_plot->AddCurve(output->Element(index+2)); 135 index+=3; 136 } 137 if((NMEAFlags&VTG)!=0) 138 { 139 ve_plot=new DataPlot1D(plot_tab->NewRow(),"ve",-10,10); 140 ve_plot->AddCurve(output->Element(index)); 141 vn_plot=new DataPlot1D(plot_tab->LastRowLastCol(),"vn",-10,10); 142 vn_plot->AddCurve(output->Element(index+1)); 143 index+=2; 144 } 145 146 Tab* map_tab=new Tab(tab,"carte"); 147 map=new Map(map_tab->NewRow(),"map"); 148 map->AddPoint(position,"drone"); 149 } 150 151 DataPlot1D* Gps::EPlot(void) const 152 { 153 if((NMEAFlags&GGA)!=0) 154 { 155 return e_plot; 156 } 157 else 158 { 159 Err("GGA sentence not requested\n"); 160 return NULL; 161 } 162 } 163 164 DataPlot1D* Gps::NPlot(void) const 165 { 166 if((NMEAFlags&GGA)!=0) 167 { 168 return n_plot; 169 } 170 else 171 { 172 Err("GGA sentence not requested\n"); 173 return NULL; 174 } 175 } 176 177 DataPlot1D* Gps::UPlot(void) const 178 { 179 if((NMEAFlags&GGA)!=0) 180 { 181 return u_plot; 182 } 183 else 184 { 185 Err("GGA sentence not requested\n"); 186 return NULL; 187 } 188 } 189 190 DataPlot1D* Gps::VEPlot(void) const 191 { 192 if((NMEAFlags&VTG)!=0) 193 { 194 return ve_plot; 195 } 196 else 197 { 198 Err("GGA sentence not requested\n"); 199 return NULL; 200 } 201 } 202 203 DataPlot1D* Gps::VNPlot(void) const 204 { 205 if((NMEAFlags&VTG)!=0) 206 { 207 return vn_plot; 208 } 209 else 210 { 211 Err("GGA sentence not requested\n"); 212 return NULL; 213 } 214 } 215 216 Layout* Gps::GetLayout(void) const 217 { 218 return sensor_tab; 219 } 220 221 Tab* Gps::GetPlotTab(void) const 222 { 223 return plot_tab; 224 } 225 226 TabWidget* Gps::GetTab(void) const 227 { 228 return tab; 229 } 230 231 uint16_t Gps::NbSat(void) const 232 { 233 output->GetMutex(); 234 uint16_t result=nb_sat; 235 output->ReleaseMutex(); 236 return result; 237 } 238 239 Gps::FixQuality_t Gps::FixQuality(void) const 240 { 241 output->GetMutex(); 242 FixQuality_t result=fix; 243 output->ReleaseMutex(); 244 return result; 245 } 246 247 void Gps::SetRef(void) 248 { 249 take_ref=true; 250 } 251 252 void Gps::GetENUPosition(Vector3D *point) 253 { 254 output->GetMutex(); 255 point->x=output->ValueNoMutex(0,0); 256 point->y=output->ValueNoMutex(1,0); 257 point->z=output->ValueNoMutex(2,0); 258 output->ReleaseMutex(); 259 } 260 261 void Gps::parseFrame(const char *frame, int frame_size){ 262 263 int result; 264 265 result=nmea_parse(&parser, frame, frame_size, &info); 266 if(result!=1) 267 { 268 Warn("unrecognized nmea sentence\n"); 269 Warn("%s\n",frame); 270 } 271 272 result=nmea_parse_GPGGA(frame, frame_size, &pack); 273 274 if(result==1) 275 { 276 //Printf("%s\n",frame); 277 //Printf("nb:%i fix:%i lat:%f long:%f alt:%f vel:%f angle:%f\n",pack.satinuse,pack.sig,info.lat,info.lon,info.elv,info.speed*1000./3600.,info.direction); 278 //Printf("lat:%f long:%f\n",pos.lat,pos.lon); 279 output->GetMutex();//on utilise le mutex de l'output pour fix et nb_sat 280 if((int)fix!=pack.sig) 281 { 282 fix=(FixQuality_t)pack.sig; 283 fix_label->SetText("fix: %i",fix); 284 } 285 if(nb_sat!=pack.satinuse) 286 { 287 nb_sat=pack.satinuse; 288 nb_sat_label->SetText("nb_sat: %i",nb_sat); 289 } 290 output->ReleaseMutex(); 291 292 293 nmea_info2pos(&info,&pos); 294 position->SetCoordinates(Euler::ToDegree(pos.lat),Euler::ToDegree(pos.lon),info.elv); 295 296 if((info.sig==2 && alt_ref==0) || button_ref->Clicked()==true || take_ref==true) 297 { 298 Printf("prise pos ref\n"); 299 lat_ref=pos.lat; 300 long_ref=pos.lon; 301 alt_ref=info.elv; 302 take_ref=false; 303 } 304 //if(alt_ref!=0) 305 { 306 double x,y,z; 307 double e,n,u; 308 Geographique_2_ECEF(pos.lon,pos.lat,info.elv,x,y,z); 309 ECEF_2_ENU(x,y,z,e, n, u,long_ref,lat_ref,alt_ref); 310 //Printf("lon:%f lat:%f elv:%f\n",pos.lon,pos.lat,info.elv); 311 312 //on prend une fois pour toute le mutex et on fait des accès directs 313 output->GetMutex(); 314 output->SetValueNoMutex( 0, 0,e); 315 output->SetValueNoMutex( 1, 0,n); 316 output->SetValueNoMutex( 2, 0,u); 317 318 int index=3; 319 if((NMEAFlags&VTG)!=0) 320 { 321 output->SetValueNoMutex( index, 0,info.speed*1000./3600.*sin(Euler::ToRadian(info.direction))); 322 output->SetValueNoMutex( index+1, 0,info.speed*1000./3600.*cos(Euler::ToRadian(info.direction))); 323 index+=2; 324 } 325 if((NMEAFlags&GST)!=0) 326 { 327 //Thread::Printf("dev_lon:%f dev_lat:%f dev_elv:%f\n",info.dev_lat,info.dev_lon,info.dev_elv); 328 output->SetValueNoMutex( index, 0,info.dev_lat); 329 output->SetValueNoMutex( index+1, 0,info.dev_lon); 330 output->SetValueNoMutex( index+2, 0,info.dev_elv); 331 index+=3; 332 } 333 output->ReleaseMutex(); 334 335 output->SetDataTime(GetTime()); 336 ProcessUpdate(output); 337 } 338 } 254 double x, y, z; 255 double e, n, u; 256 Geographique_2_ECEF(pos.lon, pos.lat, info.elv, x, y, z); 257 ECEF_2_ENU(x, y, z, e, n, u, long_ref, lat_ref, alt_ref); 258 // Printf("lon:%f lat:%f elv:%f\n",pos.lon,pos.lat,info.elv); 259 260 // on prend une fois pour toute le mutex et on fait des accès directs 261 output->GetMutex(); 262 output->SetValueNoMutex(0, 0, e); 263 output->SetValueNoMutex(1, 0, n); 264 output->SetValueNoMutex(2, 0, u); 265 266 int index = 3; 267 if ((NMEAFlags & VTG) != 0) { 268 output->SetValueNoMutex(index, 0, 269 info.speed * 1000. / 3600. * 270 sin(Euler::ToRadian(info.direction))); 271 output->SetValueNoMutex(index + 1, 0, 272 info.speed * 1000. / 3600. * 273 cos(Euler::ToRadian(info.direction))); 274 index += 2; 275 } 276 if ((NMEAFlags & GST) != 0) { 277 // Thread::Printf("dev_lon:%f dev_lat:%f 278 // dev_elv:%f\n",info.dev_lat,info.dev_lon,info.dev_elv); 279 output->SetValueNoMutex(index, 0, info.dev_lat); 280 output->SetValueNoMutex(index + 1, 0, info.dev_lon); 281 output->SetValueNoMutex(index + 2, 0, info.dev_elv); 282 index += 3; 283 } 284 output->ReleaseMutex(); 285 286 output->SetDataTime(GetTime()); 287 ProcessUpdate(output); 288 } 289 } 339 290 } 340 291 -
trunk/lib/FlairSensorActuator/src/Gps.h
r3 r15 17 17 #include <nmea/nmea.h> 18 18 19 namespace flair 20 { 21 namespace core 22 { 23 class cvmatrix; 24 class FrameworkManager; 25 class GeoCoordinate; 26 class Vector3D; 27 } 28 namespace gui 29 { 30 class Layout; 31 class DataPlot1D; 32 class Tab; 33 class TabWidget; 34 class PushButton; 35 class Map; 36 class Label; 37 } 19 namespace flair { 20 namespace core { 21 class cvmatrix; 22 class FrameworkManager; 23 class GeoCoordinate; 24 class Vector3D; 38 25 } 39 40 namespace flair 41 { 42 namespace sensor 43 { 44 /*! \class Gps 45 * 46 * \brief Base class for GPS 47 */ 48 class Gps : public core::IODevice 49 { 50 public: 51 /*! 52 \enum FixQuality_t 53 \brief Fix qualty indicators 54 */ 55 enum class FixQuality_t { 56 Invalid=0,/*!< invalid */ 57 Gps=1,/*!< Gps */ 58 DGps=2,/*!< Differential Gps */ 59 Pps=3,/*!< Pps */ 60 Rtk=4,/*!< RTK */ 61 RtkFloat=5,/*!< RTK float */ 62 Estimated=6,/*!< Estimated */ 63 Manual=7,/*!< Manual */ 64 Simulation=8,/*!< Simulation */ 65 }; 66 67 /*! 68 \enum NMEAFlags_t 69 \brief NMEA flags 70 */ 71 enum NMEAFlags_t { 72 GGA=0x01,/*!< GGA */ 73 VTG=0x02,/*!< VTG */ 74 GST=0x04,/*!< GST */ 75 }; 76 77 /*! 78 * \brief Constructor 79 * 80 * Construct a Gps. 81 * 82 * \param parent parent 83 * \param name name 84 * \param NMEAFlags NMEA sentances to enable 85 */ 86 Gps(const core::FrameworkManager* parent,std::string name,NMEAFlags_t NMEAFlags); 87 88 /*! 89 * \brief Destructor 90 * 91 */ 92 ~Gps(); 93 94 /*! 95 * \brief Use default plot 96 * 97 */ 98 void UseDefaultPlot(void); 99 100 /*! 101 * \brief East plot 102 * 103 * \return east plot 104 */ 105 gui::DataPlot1D* EPlot(void) const; 106 107 /*! 108 * \brief North plot 109 * 110 * \return north plot 111 */ 112 gui::DataPlot1D* NPlot(void) const; 113 114 /*! 115 * \brief Up plot 116 * 117 * \return up plot 118 */ 119 gui::DataPlot1D* UPlot(void) const; 120 121 /*! 122 * \brief East velocity plot 123 * 124 * \return east velocity plot 125 */ 126 gui::DataPlot1D* VEPlot(void) const; 127 128 /*! 129 * \brief North velocity plot 130 * 131 * \return north velocity plot 132 */ 133 gui::DataPlot1D* VNPlot(void) const; 134 135 /*! 136 * \brief Main tab 137 * 138 * \return main tab 139 */ 140 gui::TabWidget* GetTab(void) const; 141 142 /*! 143 * \brief Setup Layout 144 * 145 * \return setup Layout 146 */ 147 gui::Layout* GetLayout(void) const; 148 149 /*! 150 * \brief Plot tab 151 * 152 * \return plot Tab 153 */ 154 gui::Tab* GetPlotTab(void) const; 155 156 /*! 157 * \brief Number of used satellites 158 * 159 * \return number of used satellites 160 */ 161 uint16_t NbSat(void) const; 162 163 /*! 164 * \brief Fix Quality 165 * 166 * \return fix quality 167 */ 168 FixQuality_t FixQuality(void) const; 169 170 /*! 171 * \brief Set reference for ENU coordinates 172 * 173 * The actual position is used as reference to calculate 174 * ENU coordinates. 175 * 176 * \return fix quality 177 */ 178 void SetRef(void); 179 180 /*! 181 * \brief Get ENU position 182 * 183 * \param point to store position 184 */ 185 void GetENUPosition(core::Vector3D *point); 186 187 protected: 188 /*! 189 * \brief Parse a NMEA frame 190 * 191 * This function must be called by the reimplemented class. \n 192 * When a frame is parsed, GPS datas are filled. 193 * 194 * \param frame NMEA frame 195 * \param frame_size frame size 196 * 197 */ 198 void parseFrame(const char *frame, int frame_size); 199 200 NMEAFlags_t NMEAFlags; 201 202 protected: 203 core::GeoCoordinate *position; 204 205 private: 206 /*! 207 * \brief Update using provided datas 208 * 209 * Reimplemented from IODevice. 210 * 211 * \param data data from the parent to process 212 */ 213 void UpdateFrom(const core::io_data *data){}; 214 215 gui::Tab *main_tab,*sensor_tab; 216 gui::TabWidget* tab; 217 gui::PushButton *button_ref; 218 gui::DataPlot1D* e_plot; 219 gui::DataPlot1D* n_plot; 220 gui::DataPlot1D* u_plot; 221 gui::DataPlot1D* ve_plot; 222 gui::DataPlot1D* vn_plot; 223 gui::Tab* plot_tab; 224 gui::Map *map; 225 gui::Label *nb_sat_label,*fix_label; 226 uint16_t nb_sat; 227 FixQuality_t fix; 228 bool take_ref; 229 nmeaINFO info; 230 nmeaPARSER parser; 231 nmeaGPGGA pack; 232 nmeaPOS pos; 233 double lat_ref,long_ref,alt_ref; 234 235 //matrix 236 core::cvmatrix *output; 237 }; 26 namespace gui { 27 class Layout; 28 class DataPlot1D; 29 class Tab; 30 class TabWidget; 31 class PushButton; 32 class Map; 33 class Label; 34 } 35 } 36 37 namespace flair { 38 namespace sensor { 39 /*! \class Gps 40 * 41 * \brief Base class for GPS 42 */ 43 class Gps : public core::IODevice { 44 public: 45 /*! 46 \enum FixQuality_t 47 \brief Fix qualty indicators 48 */ 49 enum class FixQuality_t { 50 Invalid = 0, /*!< invalid */ 51 Gps = 1, /*!< Gps */ 52 DGps = 2, /*!< Differential Gps */ 53 Pps = 3, /*!< Pps */ 54 Rtk = 4, /*!< RTK */ 55 RtkFloat = 5, /*!< RTK float */ 56 Estimated = 6, /*!< Estimated */ 57 Manual = 7, /*!< Manual */ 58 Simulation = 8, /*!< Simulation */ 59 }; 60 61 /*! 62 \enum NMEAFlags_t 63 \brief NMEA flags 64 */ 65 enum NMEAFlags_t { 66 GGA = 0x01, /*!< GGA */ 67 VTG = 0x02, /*!< VTG */ 68 GST = 0x04, /*!< GST */ 69 }; 70 71 /*! 72 * \brief Constructor 73 * 74 * Construct a Gps. 75 * 76 * \param parent parent 77 * \param name name 78 * \param NMEAFlags NMEA sentances to enable 79 */ 80 Gps(const core::FrameworkManager *parent, std::string name, 81 NMEAFlags_t NMEAFlags); 82 83 /*! 84 * \brief Destructor 85 * 86 */ 87 ~Gps(); 88 89 /*! 90 * \brief Use default plot 91 * 92 */ 93 void UseDefaultPlot(void); 94 95 /*! 96 * \brief East plot 97 * 98 * \return east plot 99 */ 100 gui::DataPlot1D *EPlot(void) const; 101 102 /*! 103 * \brief North plot 104 * 105 * \return north plot 106 */ 107 gui::DataPlot1D *NPlot(void) const; 108 109 /*! 110 * \brief Up plot 111 * 112 * \return up plot 113 */ 114 gui::DataPlot1D *UPlot(void) const; 115 116 /*! 117 * \brief East velocity plot 118 * 119 * \return east velocity plot 120 */ 121 gui::DataPlot1D *VEPlot(void) const; 122 123 /*! 124 * \brief North velocity plot 125 * 126 * \return north velocity plot 127 */ 128 gui::DataPlot1D *VNPlot(void) const; 129 130 /*! 131 * \brief Main tab 132 * 133 * \return main tab 134 */ 135 gui::TabWidget *GetTab(void) const; 136 137 /*! 138 * \brief Setup Layout 139 * 140 * \return setup Layout 141 */ 142 gui::Layout *GetLayout(void) const; 143 144 /*! 145 * \brief Plot tab 146 * 147 * \return plot Tab 148 */ 149 gui::Tab *GetPlotTab(void) const; 150 151 /*! 152 * \brief Number of used satellites 153 * 154 * \return number of used satellites 155 */ 156 uint16_t NbSat(void) const; 157 158 /*! 159 * \brief Fix Quality 160 * 161 * \return fix quality 162 */ 163 FixQuality_t FixQuality(void) const; 164 165 /*! 166 * \brief Set reference for ENU coordinates 167 * 168 * The actual position is used as reference to calculate 169 * ENU coordinates. 170 * 171 * \return fix quality 172 */ 173 void SetRef(void); 174 175 /*! 176 * \brief Get ENU position 177 * 178 * \param point to store position 179 */ 180 void GetENUPosition(core::Vector3D *point); 181 182 protected: 183 /*! 184 * \brief Parse a NMEA frame 185 * 186 * This function must be called by the reimplemented class. \n 187 * When a frame is parsed, GPS datas are filled. 188 * 189 * \param frame NMEA frame 190 * \param frame_size frame size 191 * 192 */ 193 void parseFrame(const char *frame, int frame_size); 194 195 NMEAFlags_t NMEAFlags; 196 197 protected: 198 core::GeoCoordinate *position; 199 200 private: 201 /*! 202 * \brief Update using provided datas 203 * 204 * Reimplemented from IODevice. 205 * 206 * \param data data from the parent to process 207 */ 208 void UpdateFrom(const core::io_data *data){}; 209 210 gui::Tab *main_tab, *sensor_tab; 211 gui::TabWidget *tab; 212 gui::PushButton *button_ref; 213 gui::DataPlot1D *e_plot; 214 gui::DataPlot1D *n_plot; 215 gui::DataPlot1D *u_plot; 216 gui::DataPlot1D *ve_plot; 217 gui::DataPlot1D *vn_plot; 218 gui::Tab *plot_tab; 219 gui::Map *map; 220 gui::Label *nb_sat_label, *fix_label; 221 uint16_t nb_sat; 222 FixQuality_t fix; 223 bool take_ref; 224 nmeaINFO info; 225 nmeaPARSER parser; 226 nmeaGPGGA pack; 227 nmeaPOS pos; 228 double lat_ref, long_ref, alt_ref; 229 230 // matrix 231 core::cvmatrix *output; 232 }; 238 233 } // end namespace sensor 239 234 } // end namespace framewor -
trunk/lib/FlairSensorActuator/src/Gx3_25_imu.cpp
r3 r15 25 25 using namespace flair::core; 26 26 27 namespace flair { namespace sensor { 27 namespace flair { 28 namespace sensor { 28 29 29 Gx3_25_imu::Gx3_25_imu(const FrameworkManager* parent,string name,SerialPort* serialport,Command_t command,uint8_t priority) : Imu(parent,name),Thread(parent,name,priority) { 30 pimpl_=new Gx3_25_imu_impl(this,name,serialport,command,GetGroupBox()); 30 Gx3_25_imu::Gx3_25_imu(const FrameworkManager *parent, string name, 31 SerialPort *serialport, Command_t command, 32 uint8_t priority) 33 : Imu(parent, name), Thread(parent, name, priority) { 34 pimpl_ = new Gx3_25_imu_impl(this, name, serialport, command, GetGroupBox()); 31 35 32 if(command==EulerAnglesAndAngularRates) {36 if (command == EulerAnglesAndAngularRates) { 33 37 34 } else if(command==AccelerationAngularRateAndOrientationMatrix) {35 36 37 Thread::Err("command not supported (%i)\n",command);38 39 //AddDataToLog(imudata);38 } else if (command == AccelerationAngularRateAndOrientationMatrix) { 39 Thread::Err("oneaxis rotation of rotation matrix is not yet implemented\n"); 40 } else { 41 Thread::Err("command not supported (%i)\n", command); 42 } 43 // AddDataToLog(imudata); 40 44 } 41 45 42 46 Gx3_25_imu::~Gx3_25_imu() { 43 44 45 47 SafeStop(); 48 Join(); 49 delete pimpl_; 46 50 } 47 51 48 void Gx3_25_imu::Run(void) { 49 pimpl_->Run(); 50 } 52 void Gx3_25_imu::Run(void) { pimpl_->Run(); } 51 53 52 54 } // end namespace sensor -
trunk/lib/FlairSensorActuator/src/Gx3_25_imu.h
r3 r15 18 18 19 19 namespace flair { 20 21 22 23 20 namespace core { 21 class FrameworkManager; 22 class SerialPort; 23 } 24 24 } 25 25 26 26 class Gx3_25_imu_impl; 27 27 28 namespace flair { namespace sensor { 29 /*! \class Gx3_25_imu 30 * 31 * \brief Class for 3dmgx3-25 Imu 32 */ 33 class Gx3_25_imu : public Imu, public core::Thread { 34 friend class ::Gx3_25_imu_impl; 28 namespace flair { 29 namespace sensor { 30 /*! \class Gx3_25_imu 31 * 32 * \brief Class for 3dmgx3-25 Imu 33 */ 34 class Gx3_25_imu : public Imu, public core::Thread { 35 friend class ::Gx3_25_imu_impl; 35 36 36 public: 37 /*! 38 \enum Command_t 39 \brief Command for the continuous mode 40 */ 41 enum Command_t{ 42 EulerAnglesAndAngularRates=0xcf,/*!< Euler angles and angular rates */ 43 AccelerationAngularRateAndOrientationMatrix=0xc8,/*!< Acceleration, angular rate and orientation matrix */ 44 }; 37 public: 38 /*! 39 \enum Command_t 40 \brief Command for the continuous mode 41 */ 42 enum Command_t { 43 EulerAnglesAndAngularRates = 0xcf, /*!< Euler angles and angular rates */ 44 AccelerationAngularRateAndOrientationMatrix = 45 0xc8, /*!< Acceleration, angular rate and orientation matrix */ 46 }; 45 47 46 /*! 47 * \brief Constructor 48 * 49 * Construct a Gx3_25_imu. 50 * 51 * \param parent parent 52 * \param name name 53 * \param serialport SerialPort 54 * \param command command for continuous mode 55 * \param priority priority of the Thread 56 */ 57 Gx3_25_imu(const core::FrameworkManager* parent,std::string name,core::SerialPort *serialport,Command_t command,uint8_t priority); 48 /*! 49 * \brief Constructor 50 * 51 * Construct a Gx3_25_imu. 52 * 53 * \param parent parent 54 * \param name name 55 * \param serialport SerialPort 56 * \param command command for continuous mode 57 * \param priority priority of the Thread 58 */ 59 Gx3_25_imu(const core::FrameworkManager *parent, std::string name, 60 core::SerialPort *serialport, Command_t command, uint8_t priority); 58 61 59 60 61 62 63 62 /*! 63 * \brief Destructor 64 * 65 */ 66 ~Gx3_25_imu(); 64 67 65 66 67 68 69 70 71 72 68 private: 69 /*! 70 * \brief Run function 71 * 72 * Reimplemented from Thread. 73 * 74 */ 75 void Run(void); 73 76 74 75 76 77 78 79 80 81 77 /*! 78 * \brief Update using provided datas 79 * 80 * Reimplemented from IODevice. 81 * 82 * \param data data from the parent to process 83 */ 84 void UpdateFrom(const core::io_data *data){}; 82 85 83 class Gx3_25_imu_impl*pimpl_;84 86 class Gx3_25_imu_impl *pimpl_; 87 }; 85 88 } // end namespace sensor 86 89 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/Gx3_25_imu_impl.cpp
r3 r15 38 38 using namespace flair::sensor; 39 39 40 Gx3_25_imu_impl::Gx3_25_imu_impl(Gx3_25_imu* self,string name,SerialPort *serialport,Gx3_25_imu::Command_t command,GroupBox* setupgroupbox) { 41 int err = 0; 42 43 this->self=self; 44 this->command=(uint8_t)command; 45 this->setupgroupbox=setupgroupbox; 46 this->serialport=serialport; 47 48 ahrsData=new AhrsData((Imu*)self); 49 50 //station sol 51 button_bias=new PushButton(setupgroupbox->NewRow(),"gyros bias"); 52 data_rate=new SpinBox(setupgroupbox->NewRow(),"data rate (Hz):",1,500,1,200); 53 data_rate_label=new Label(setupgroupbox->LastRowLastCol(),"data_rate"); 54 gyro_acc_size=new SpinBox(setupgroupbox->NewRow(),"gyro and acc filter win size:",1,32,1,15); 55 mag_size=new SpinBox(setupgroupbox->LastRowLastCol(),"mag filter win size:",1,32,1,17); 56 up_comp=new SpinBox(setupgroupbox->NewRow(),"up compensation (s):",1,1000,1,10); 57 north_comp=new SpinBox(setupgroupbox->LastRowLastCol(),"north compensation (s):",1,1000,1,10); 58 coning=new CheckBox(setupgroupbox->NewRow(),"enable Coning&Sculling:",true); 59 disable_magn=new CheckBox(setupgroupbox->LastRowLastCol(),"disable magnetometer:",true); 60 disable_north_comp=new CheckBox(setupgroupbox->NewRow(),"disable magnetic north compensation:",false); 61 disable_grav_comp=new CheckBox(setupgroupbox->NewRow(),"disable gravity compensation:",false); 62 } 63 64 Gx3_25_imu_impl::~Gx3_25_imu_impl() { 65 } 40 Gx3_25_imu_impl::Gx3_25_imu_impl(Gx3_25_imu *self, string name, 41 SerialPort *serialport, 42 Gx3_25_imu::Command_t command, 43 GroupBox *setupgroupbox) { 44 int err = 0; 45 46 this->self = self; 47 this->command = (uint8_t)command; 48 this->setupgroupbox = setupgroupbox; 49 this->serialport = serialport; 50 51 ahrsData = new AhrsData((Imu *)self); 52 53 // station sol 54 button_bias = new PushButton(setupgroupbox->NewRow(), "gyros bias"); 55 data_rate = 56 new SpinBox(setupgroupbox->NewRow(), "data rate (Hz):", 1, 500, 1, 200); 57 data_rate_label = new Label(setupgroupbox->LastRowLastCol(), "data_rate"); 58 gyro_acc_size = new SpinBox(setupgroupbox->NewRow(), 59 "gyro and acc filter win size:", 1, 32, 1, 15); 60 mag_size = new SpinBox(setupgroupbox->LastRowLastCol(), 61 "mag filter win size:", 1, 32, 1, 17); 62 up_comp = new SpinBox(setupgroupbox->NewRow(), "up compensation (s):", 1, 63 1000, 1, 10); 64 north_comp = new SpinBox(setupgroupbox->LastRowLastCol(), 65 "north compensation (s):", 1, 1000, 1, 10); 66 coning = 67 new CheckBox(setupgroupbox->NewRow(), "enable Coning&Sculling:", true); 68 disable_magn = new CheckBox(setupgroupbox->LastRowLastCol(), 69 "disable magnetometer:", true); 70 disable_north_comp = new CheckBox( 71 setupgroupbox->NewRow(), "disable magnetic north compensation:", false); 72 disable_grav_comp = new CheckBox(setupgroupbox->NewRow(), 73 "disable gravity compensation:", false); 74 } 75 76 Gx3_25_imu_impl::~Gx3_25_imu_impl() {} 66 77 67 78 void Gx3_25_imu_impl::Run(void) { 68 Time imuTime; 69 ImuData* imuData; 70 self->GetDatas(&imuData); 71 72 self->WarnUponSwitches(true); 73 74 //reset IMU to be sure it is at 115200 75 Printf("Gx3_25_imu::Reset IMU at 921600\n"); 76 serialport->SetBaudrate(921600); 77 DeviceReset(); 78 self->Thread::SleepMS(100); 79 serialport->FlushInput(); 80 serialport->SetBaudrate(115200); 81 82 SetBaudrate(921600); 83 Printf("Gx3_25_imu firmware number: %i\n",FirmwareNumber()); 84 PrintModelInfo(); 85 SamplingSettings(); 86 GyrosBias(); 87 //RealignUpNorth(true,true); 88 89 //on provoque les 9 ValueChanged 90 for(int i=0; i<9; i++) { 91 if(data_rate->ValueChanged()==true || disable_magn->ValueChanged()==true ||disable_north_comp->ValueChanged()==true ||disable_grav_comp->ValueChanged()==true ||coning->ValueChanged()==true 92 || gyro_acc_size->ValueChanged()==true || mag_size->ValueChanged()==true ||up_comp->ValueChanged()==true || north_comp->ValueChanged()==true) { 93 if(setupgroupbox->isEnabled()==true) SamplingSettings(); 94 } 95 } 96 97 //periode a passer an argument (reglable) 98 //ou plutot laisser la periode geree par le centrale (polling) 99 //self->SetPeriodMS(2); 100 SetContinuousMode(command); 101 102 //_printf("firmware version: %i\n",get_firmware_number()); 103 104 while(!self->ToBeStopped()) { 105 if(command==Gx3_25_imu::EulerAnglesAndAngularRates) { 106 uint8_t response[31] = {0}; 107 uint8_t *buf=&response[1]; 108 GetData(response,sizeof(response),&imuTime); 109 110 Euler eulerAngles; 111 eulerAngles.roll=Dequeue(&buf); 112 eulerAngles.pitch=Dequeue(&buf); 113 eulerAngles.yaw=Dequeue(&buf); 114 115 Vector3D filteredAngRates; 116 filteredAngRates.x=Dequeue(&buf); 117 filteredAngRates.y=Dequeue(&buf); 118 filteredAngRates.z=Dequeue(&buf); 119 120 ahrsData->SetQuaternionAndAngularRates(eulerAngles.ToQuaternion(),filteredAngRates); 121 } else if(command==Gx3_25_imu::AccelerationAngularRateAndOrientationMatrix) { 122 uint8_t response[67] = {0}; 123 uint8_t *buf=&response[1]; 124 GetData(response,sizeof(response),&imuTime); 125 126 Vector3D rawAcc; 127 rawAcc.x=9.80665*Dequeue(&buf); 128 rawAcc.y=9.80665*Dequeue(&buf); 129 rawAcc.z=9.80665*Dequeue(&buf); 130 131 Vector3D filteredAngRates; 132 filteredAngRates.x=Dequeue(&buf); 133 filteredAngRates.y=Dequeue(&buf); 134 filteredAngRates.z=Dequeue(&buf); 135 136 RotationMatrix matrix; 137 matrix(0,0)=Dequeue(&buf); 138 matrix(0,1)=Dequeue(&buf); 139 matrix(0,2)=Dequeue(&buf); 140 matrix(1,0)=Dequeue(&buf); 141 matrix(1,1)=Dequeue(&buf); 142 matrix(1,2)=Dequeue(&buf); 143 matrix(2,0)=Dequeue(&buf); 144 matrix(2,1)=Dequeue(&buf); 145 matrix(2,2)=Dequeue(&buf); 146 147 ahrsData->SetQuaternionAndAngularRates(matrix.ToEuler().ToQuaternion(),filteredAngRates); 148 imuData->SetRawAcc(rawAcc); 149 } 150 151 //change settings as soon as possible 152 //we assume that new imu datas will not come so fast 153 //so newt message from imu is an ack from the change settings 154 if(button_bias->Clicked()==true) GyrosBias(); 155 156 if(data_rate->ValueChanged()==true || disable_magn->ValueChanged()==true ||disable_north_comp->ValueChanged()==true ||disable_grav_comp->ValueChanged()==true ||coning->ValueChanged()==true 157 || gyro_acc_size->ValueChanged()==true || mag_size->ValueChanged()==true ||up_comp->ValueChanged()==true || north_comp->ValueChanged()==true) { 158 if(setupgroupbox->isEnabled()==true) SamplingSettings(); 159 } 160 161 imuData->SetDataTime(imuTime); 162 ahrsData->SetDataTime(imuTime); 163 self->UpdateImu(); 164 self->ProcessUpdate(ahrsData); 165 } 166 SetContinuousMode(0); 167 SetBaudrate(115200); 168 169 self->WarnUponSwitches(false); 170 } 171 172 void Gx3_25_imu_impl::GetData(uint8_t* buf,ssize_t buf_size,Time *time) { 79 Time imuTime; 80 ImuData *imuData; 81 self->GetDatas(&imuData); 82 83 self->WarnUponSwitches(true); 84 85 // reset IMU to be sure it is at 115200 86 Printf("Gx3_25_imu::Reset IMU at 921600\n"); 87 serialport->SetBaudrate(921600); 88 DeviceReset(); 89 self->Thread::SleepMS(100); 90 serialport->FlushInput(); 91 serialport->SetBaudrate(115200); 92 93 SetBaudrate(921600); 94 Printf("Gx3_25_imu firmware number: %i\n", FirmwareNumber()); 95 PrintModelInfo(); 96 SamplingSettings(); 97 GyrosBias(); 98 // RealignUpNorth(true,true); 99 100 // on provoque les 9 ValueChanged 101 for (int i = 0; i < 9; i++) { 102 if (data_rate->ValueChanged() == true || 103 disable_magn->ValueChanged() == true || 104 disable_north_comp->ValueChanged() == true || 105 disable_grav_comp->ValueChanged() == true || 106 coning->ValueChanged() == true || 107 gyro_acc_size->ValueChanged() == true || 108 mag_size->ValueChanged() == true || up_comp->ValueChanged() == true || 109 north_comp->ValueChanged() == true) { 110 if (setupgroupbox->isEnabled() == true) 111 SamplingSettings(); 112 } 113 } 114 115 // periode a passer an argument (reglable) 116 // ou plutot laisser la periode geree par le centrale (polling) 117 // self->SetPeriodMS(2); 118 SetContinuousMode(command); 119 120 //_printf("firmware version: %i\n",get_firmware_number()); 121 122 while (!self->ToBeStopped()) { 123 if (command == Gx3_25_imu::EulerAnglesAndAngularRates) { 124 uint8_t response[31] = {0}; 125 uint8_t *buf = &response[1]; 126 GetData(response, sizeof(response), &imuTime); 127 128 Euler eulerAngles; 129 eulerAngles.roll = Dequeue(&buf); 130 eulerAngles.pitch = Dequeue(&buf); 131 eulerAngles.yaw = Dequeue(&buf); 132 133 Vector3D filteredAngRates; 134 filteredAngRates.x = Dequeue(&buf); 135 filteredAngRates.y = Dequeue(&buf); 136 filteredAngRates.z = Dequeue(&buf); 137 138 ahrsData->SetQuaternionAndAngularRates(eulerAngles.ToQuaternion(), 139 filteredAngRates); 140 } else if (command == 141 Gx3_25_imu::AccelerationAngularRateAndOrientationMatrix) { 142 uint8_t response[67] = {0}; 143 uint8_t *buf = &response[1]; 144 GetData(response, sizeof(response), &imuTime); 145 146 Vector3D rawAcc; 147 rawAcc.x = 9.80665 * Dequeue(&buf); 148 rawAcc.y = 9.80665 * Dequeue(&buf); 149 rawAcc.z = 9.80665 * Dequeue(&buf); 150 151 Vector3D filteredAngRates; 152 filteredAngRates.x = Dequeue(&buf); 153 filteredAngRates.y = Dequeue(&buf); 154 filteredAngRates.z = Dequeue(&buf); 155 156 RotationMatrix matrix; 157 matrix(0, 0) = Dequeue(&buf); 158 matrix(0, 1) = Dequeue(&buf); 159 matrix(0, 2) = Dequeue(&buf); 160 matrix(1, 0) = Dequeue(&buf); 161 matrix(1, 1) = Dequeue(&buf); 162 matrix(1, 2) = Dequeue(&buf); 163 matrix(2, 0) = Dequeue(&buf); 164 matrix(2, 1) = Dequeue(&buf); 165 matrix(2, 2) = Dequeue(&buf); 166 167 ahrsData->SetQuaternionAndAngularRates(matrix.ToEuler().ToQuaternion(), 168 filteredAngRates); 169 imuData->SetRawAcc(rawAcc); 170 } 171 172 // change settings as soon as possible 173 // we assume that new imu datas will not come so fast 174 // so newt message from imu is an ack from the change settings 175 if (button_bias->Clicked() == true) 176 GyrosBias(); 177 178 if (data_rate->ValueChanged() == true || 179 disable_magn->ValueChanged() == true || 180 disable_north_comp->ValueChanged() == true || 181 disable_grav_comp->ValueChanged() == true || 182 coning->ValueChanged() == true || 183 gyro_acc_size->ValueChanged() == true || 184 mag_size->ValueChanged() == true || up_comp->ValueChanged() == true || 185 north_comp->ValueChanged() == true) { 186 if (setupgroupbox->isEnabled() == true) 187 SamplingSettings(); 188 } 189 190 imuData->SetDataTime(imuTime); 191 ahrsData->SetDataTime(imuTime); 192 self->UpdateImu(); 193 self->ProcessUpdate(ahrsData); 194 } 195 SetContinuousMode(0); 196 SetBaudrate(115200); 197 198 self->WarnUponSwitches(false); 199 } 200 201 void Gx3_25_imu_impl::GetData(uint8_t *buf, ssize_t buf_size, Time *time) { 202 ssize_t read = 0; 203 ssize_t written = 0; 204 /* 205 written = serialport->Write(&command, sizeof(command)); 206 if(written<0) 207 { 208 self->Thread::Err("Write error (%s)\n",strerror(-written)); 209 } 210 else if (written != sizeof(command)) 211 { 212 self->Thread::Err("Write error %i/%i\n",written,sizeof(command)); 213 } 214 */ 215 read = serialport->Read(buf, buf_size); 216 *time = GetTime(); 217 if (read < 0) { 218 self->Thread::Err("Read error (%s)\n", strerror(-read)); 219 } else if (read != buf_size) { 220 self->Thread::Err("Read error %i/%i\n", read, buf_size); 221 } 222 223 if (CalcChecksum(buf, buf_size) == false) { 224 self->Thread::Err("wrong checksum\n"); 225 return; 226 } 227 } 228 229 float Gx3_25_imu_impl::Dequeue(uint8_t **buf) { 230 union float_4uint8 { 231 float f; 232 uint8_t b[4]; 233 } float_value; 234 235 float_value.b[0] = (*buf)[3]; 236 float_value.b[1] = (*buf)[2]; 237 float_value.b[2] = (*buf)[1]; 238 float_value.b[3] = (*buf)[0]; 239 (*buf) += sizeof(float); 240 241 return float_value.f; 242 } 243 244 void Gx3_25_imu_impl::GyrosBias(void) { 245 if (setupgroupbox->isEnabled() == true) { // devrait toujours etre bon 246 uint8_t response[19] = {0}; 247 uint8_t command[5]; 173 248 ssize_t read = 0; 174 249 ssize_t written = 0; 175 /* 176 written = serialport->Write(&command, sizeof(command)); 177 if(written<0) 178 { 179 self->Thread::Err("Write error (%s)\n",strerror(-written)); 180 } 181 else if (written != sizeof(command)) 182 { 183 self->Thread::Err("Write error %i/%i\n",written,sizeof(command)); 184 } 185 */ 186 read = serialport->Read(buf,buf_size); 187 *time=GetTime(); 188 if(read<0) { 189 self->Thread::Err("Read error (%s)\n",strerror(-read)); 190 } else if (read != buf_size) { 191 self->Thread::Err("Read error %i/%i\n",read,buf_size); 192 } 193 194 if(CalcChecksum(buf,buf_size)==false) { 195 self->Thread::Err("wrong checksum\n"); 196 return; 197 } 198 } 199 200 float Gx3_25_imu_impl::Dequeue(uint8_t** buf) { 201 union float_4uint8 { 202 float f; 203 uint8_t b[4]; 204 } 205 float_value; 206 207 float_value.b[0]=(*buf)[3]; 208 float_value.b[1]=(*buf)[2]; 209 float_value.b[2]=(*buf)[1]; 210 float_value.b[3]=(*buf)[0]; 211 (*buf)+=sizeof(float); 212 213 return float_value.f; 214 } 215 216 void Gx3_25_imu_impl::GyrosBias(void) { 217 if(setupgroupbox->isEnabled()==true) { //devrait toujours etre bon 218 uint8_t response[19] = {0}; 219 uint8_t command[5]; 220 ssize_t read = 0; 221 ssize_t written = 0; 222 223 Printf("Gx3_25_imu::gyros_bias: %s\n",self->IODevice::ObjectName().c_str()); 224 225 command[0]=0xcd;//entete 226 command[1]=0xc1;//confirm 227 command[2]=0x29;//confirm 228 command[3]=0x27;//time MSB en us 229 command[4]=0x10;//time LSB en us 230 231 written = serialport->Write( &command, sizeof(command)); 232 if(written<0) { 233 self->Thread::Err("Write error (%s)\n",strerror(-written)); 234 } else if (written != sizeof(command)) { 235 self->Thread::Err("Write error %i/%i\n",written,sizeof(command)); 236 } 237 238 self->SleepUS(1.1*(command[3]*256+command[4]));//on fait un sleep un peu plus grand 239 240 read = serialport->Read(&response[0],sizeof(response)); 241 if(read<0) { 242 self->Thread::Err("Read error (%s)\n",strerror(-read)); 243 } else if (read != sizeof(response)) { 244 self->Thread::Err("Read error %i/%i\n",read,sizeof(response)); 245 } 246 247 if(CalcChecksum(response,sizeof(response))==false) { 248 self->Thread::Err("wrong checksum\n"); 249 //return -1; 250 } 251 252 Printf("Gx3_25_imu::gyros_bias: %s ok\n",self->IODevice::ObjectName().c_str()); 253 254 } else { 255 self->Thread::Err("error locked\n"); 256 } 250 251 Printf("Gx3_25_imu::gyros_bias: %s\n", 252 self->IODevice::ObjectName().c_str()); 253 254 command[0] = 0xcd; // entete 255 command[1] = 0xc1; // confirm 256 command[2] = 0x29; // confirm 257 command[3] = 0x27; // time MSB en us 258 command[4] = 0x10; // time LSB en us 259 260 written = serialport->Write(&command, sizeof(command)); 261 if (written < 0) { 262 self->Thread::Err("Write error (%s)\n", strerror(-written)); 263 } else if (written != sizeof(command)) { 264 self->Thread::Err("Write error %i/%i\n", written, sizeof(command)); 265 } 266 267 self->SleepUS(1.1 * (command[3] * 256 + 268 command[4])); // on fait un sleep un peu plus grand 269 270 read = serialport->Read(&response[0], sizeof(response)); 271 if (read < 0) { 272 self->Thread::Err("Read error (%s)\n", strerror(-read)); 273 } else if (read != sizeof(response)) { 274 self->Thread::Err("Read error %i/%i\n", read, sizeof(response)); 275 } 276 277 if (CalcChecksum(response, sizeof(response)) == false) { 278 self->Thread::Err("wrong checksum\n"); 279 // return -1; 280 } 281 282 Printf("Gx3_25_imu::gyros_bias: %s ok\n", 283 self->IODevice::ObjectName().c_str()); 284 285 } else { 286 self->Thread::Err("error locked\n"); 287 } 257 288 } 258 289 259 290 void Gx3_25_imu_impl::SetContinuousMode(uint8_t continuous_command) { 260 uint8_t response[8] = {0}; 261 uint8_t command[4]; 262 ssize_t read = 0; 263 ssize_t written = 0; 264 265 command[0]=0xc4;//entete 266 command[1]=0xc1;//confirm 267 command[2]=0x29;//confirm 268 command[3]=continuous_command; 269 270 written = serialport->Write(command,sizeof(command)); 271 if(written<0) { 272 self->Thread::Err("Write error (%s)\n",strerror(-written)); 291 uint8_t response[8] = {0}; 292 uint8_t command[4]; 293 ssize_t read = 0; 294 ssize_t written = 0; 295 296 command[0] = 0xc4; // entete 297 command[1] = 0xc1; // confirm 298 command[2] = 0x29; // confirm 299 command[3] = continuous_command; 300 301 written = serialport->Write(command, sizeof(command)); 302 if (written < 0) { 303 self->Thread::Err("Write error (%s)\n", strerror(-written)); 304 } else if (written != sizeof(command)) { 305 self->Thread::Err("Write error %i/%i\n", written, sizeof(command)); 306 } 307 308 read = serialport->Read(response, sizeof(response)); 309 if (read < 0) { 310 self->Thread::Err("Read error (%s)\n", strerror(-read)); 311 } else if (read != sizeof(response)) { 312 self->Thread::Err("Read error %i/%i\n", read, sizeof(response)); 313 } 314 315 if (CalcChecksum(response, sizeof(response)) == false) { 316 self->Thread::Err("wrong checksum\n", self->IODevice::ObjectName().c_str()); 317 } 318 } 319 320 void Gx3_25_imu_impl::SamplingSettings(void) { 321 uint8_t response[19] = {0}; 322 uint8_t command[20]; 323 uint8_t result; 324 ssize_t read = 0; 325 ssize_t written = 0; 326 327 uint16_t rate = 1000 / data_rate->Value(); 328 329 command[0] = 0xdb; // entete 330 command[1] = 0xa8; // confirm 331 command[2] = 0xb9; // confirm 332 command[3] = 1; // change values 333 command[4] = (rate >> 8) & 0xff; // data rate MSB 334 command[5] = rate & 0xff; // data rate LSB 335 result = 0; 336 if (disable_magn->IsChecked() == true) 337 result |= 0x01; 338 if (disable_north_comp->IsChecked() == true) 339 result |= 0x04; 340 if (disable_grav_comp->IsChecked() == true) 341 result |= 0x08; 342 343 command[6] = result; 344 result = 0x01; // Calculate orientation 345 if (coning->IsChecked() == true) 346 result |= 0x02; 347 348 command[7] = result; 349 command[8] = gyro_acc_size->Value(); // gyro acc filter window 350 command[9] = mag_size->Value(); // mag filter window 351 command[10] = (up_comp->Value() >> 8) & 0xff; // up comp MSB 352 command[11] = up_comp->Value() & 0xff; // up comp LSB 353 command[12] = (north_comp->Value() >> 8) & 0xff; // north comp MSB 354 command[13] = north_comp->Value() & 0xff; // north comp LSB 355 command[14] = 0; // reserved 356 command[15] = 0; // reserved 357 command[16] = 0; // reserved 358 command[17] = 0; // reserved 359 command[18] = 0; // reserved 360 command[19] = 0; // reserved 361 362 written = serialport->Write(&command, sizeof(command)); 363 if (written < 0) { 364 self->Thread::Err("Write error (%s)\n", strerror(-written)); 365 } else if (written != sizeof(command)) { 366 self->Thread::Err("Write error %i/%i\n", written, sizeof(command)); 367 } 368 369 read = serialport->Read(&response[0], sizeof(response)); 370 if (read < 0) { 371 self->Thread::Err("Read error (%s)\n", strerror(-read)); 372 } else if (read != sizeof(response)) { 373 self->Thread::Err("Read error %i/%i\n", read, sizeof(response)); 374 } 375 376 if (CalcChecksum(response, sizeof(response)) == false) { 377 self->Thread::Err("wrong checksum\n", self->IODevice::ObjectName().c_str()); 378 } else { 379 data_rate_label->SetText("real: %.2fHz", 1000. / rate); 380 } 381 } 382 383 void Gx3_25_imu_impl::SetBaudrate(int value) { 384 uint8_t response[10] = {0}; 385 uint8_t command[11]; 386 ssize_t read = 0; 387 ssize_t written = 0; 388 389 union int32_4uint8 { 390 int32_t i; 391 uint8_t b[4]; 392 } baudrate_value; 393 394 baudrate_value.i = value; 395 Printf("Gx3_25_imu::SetBaudrate: %s ->%i\n", 396 self->IODevice::ObjectName().c_str(), baudrate_value.i); 397 398 command[0] = 0xd9; // entete 399 command[1] = 0xc3; // confirm 400 command[2] = 0x55; // confirm 401 command[3] = 1; // primary uart 402 command[4] = 1; // chgt temporaire 403 command[5] = baudrate_value.b[3]; 404 command[6] = baudrate_value.b[2]; 405 command[7] = baudrate_value.b[1]; 406 command[8] = baudrate_value.b[0]; 407 command[9] = 2; // uart enabled 408 command[10] = 0; // reserved 409 410 written = serialport->Write(&command, sizeof(command)); 411 if (written < 0) { 412 self->Thread::Err("Write error (%s)\n", strerror(-written)); 413 } else if (written != sizeof(command)) { 414 self->Thread::Err("Write error %i/%i\n", written, sizeof(command)); 415 } 416 417 read = serialport->Read(&response[0], sizeof(response)); 418 if (read < 0) { 419 self->Thread::Err("Read error (%s)\n", strerror(-read)); 420 } else if (read != sizeof(response)) { 421 self->Thread::Err("Read error %i/%i\n", read, sizeof(response)); 422 } 423 424 if (CalcChecksum(response, sizeof(response)) == false) { 425 self->Thread::Err("wrong checksum\n"); 426 return; 427 } 428 429 serialport->SetBaudrate(value); 430 } 431 432 int Gx3_25_imu_impl::FirmwareNumber(void) { 433 uint8_t response[7] = {0}; 434 uint8_t command; 435 ssize_t read = 0; 436 ssize_t written = 0; 437 union int32_4uint8 { 438 int32_t i; 439 uint8_t b[4]; 440 } value; 441 442 command = 0xe9; // entete 443 444 written = serialport->Write(&command, sizeof(command)); 445 if (written < 0) { 446 self->Thread::Err("Write error (%s)\n", strerror(-written)); 447 } else if (written != sizeof(command)) { 448 self->Thread::Err("Write error %i/%i\n", written, sizeof(command)); 449 } 450 451 read = serialport->Read(&response[0], sizeof(response)); 452 if (read < 0) { 453 self->Thread::Err("Read error (%s)\n", strerror(-read)); 454 } else if (read != sizeof(response)) { 455 self->Thread::Err("Read error %i/%i\n", read, sizeof(response)); 456 } 457 458 if (CalcChecksum(response, sizeof(response)) == false) { 459 self->Thread::Err("wrong checksum\n"); 460 return -1; 461 } 462 463 value.b[3] = response[1]; 464 value.b[2] = response[2]; 465 value.b[1] = response[3]; 466 value.b[0] = response[4]; 467 468 return value.i; 469 } 470 471 void Gx3_25_imu_impl::PrintModelInfo(void) { 472 uint8_t response[20] = {0}; 473 uint8_t command[2]; 474 ssize_t read = 0; 475 ssize_t written = 0; 476 477 for (int i = 0; i < 3; i++) { 478 command[0] = 0xea; // entete 479 command[1] = i; // entete 480 481 written = serialport->Write(&command, sizeof(command)); 482 if (written < 0) { 483 self->Thread::Err("Write error (%s)\n", strerror(-written)); 273 484 } else if (written != sizeof(command)) { 274 self->Thread::Err("Write error %i/%i\n",written,sizeof(command));275 } 276 277 read = serialport->Read( response,sizeof(response));278 if (read<0) {279 self->Thread::Err("Read error (%s)\n",strerror(-read));485 self->Thread::Err("Write error %i/%i\n", written, sizeof(command)); 486 } 487 488 read = serialport->Read(&response[0], sizeof(response)); 489 if (read < 0) { 490 self->Thread::Err("Read error (%s)\n", strerror(-read)); 280 491 } else if (read != sizeof(response)) { 281 self->Thread::Err("Read error %i/%i\n",read,sizeof(response)); 282 } 283 284 if(CalcChecksum(response,sizeof(response))==false) { 285 self->Thread::Err("wrong checksum\n",self->IODevice::ObjectName().c_str()); 286 } 287 } 288 289 void Gx3_25_imu_impl::SamplingSettings(void) { 290 uint8_t response[19] = {0}; 291 uint8_t command[20]; 292 uint8_t result; 293 ssize_t read = 0; 294 ssize_t written = 0; 295 296 uint16_t rate=1000/data_rate->Value(); 297 298 command[0]=0xdb;//entete 299 command[1]=0xa8;//confirm 300 command[2]=0xb9;//confirm 301 command[3]=1;//change values 302 command[4]=(rate>>8)&0xff;//data rate MSB 303 command[5]=rate&0xff;//data rate LSB 304 result=0; 305 if(disable_magn->IsChecked()==true) result|=0x01; 306 if(disable_north_comp->IsChecked()==true) result|=0x04; 307 if(disable_grav_comp->IsChecked()==true) result|=0x08; 308 309 command[6]=result; 310 result=0x01;//Calculate orientation 311 if(coning->IsChecked()==true) result|=0x02; 312 313 command[7]=result; 314 command[8]=gyro_acc_size->Value();//gyro acc filter window 315 command[9]=mag_size->Value();//mag filter window 316 command[10]=(up_comp->Value()>>8)&0xff;//up comp MSB 317 command[11]=up_comp->Value()&0xff;//up comp LSB 318 command[12]=(north_comp->Value()>>8)&0xff;//north comp MSB 319 command[13]=north_comp->Value()&0xff;//north comp LSB 320 command[14]=0;//reserved 321 command[15]=0;//reserved 322 command[16]=0;//reserved 323 command[17]=0;//reserved 324 command[18]=0;//reserved 325 command[19]=0;//reserved 326 327 written = serialport->Write(&command, sizeof(command)); 328 if(written<0) { 329 self->Thread::Err("Write error (%s)\n",strerror(-written)); 330 } else if (written != sizeof(command)) { 331 self->Thread::Err("Write error %i/%i\n",written,sizeof(command)); 332 } 333 334 read = serialport->Read(&response[0],sizeof(response)); 335 if(read<0) { 336 self->Thread::Err("Read error (%s)\n",strerror(-read)); 337 } else if (read != sizeof(response)) { 338 self->Thread::Err("Read error %i/%i\n",read,sizeof(response)); 339 } 340 341 if(CalcChecksum(response,sizeof(response))==false) { 342 self->Thread::Err("wrong checksum\n",self->IODevice::ObjectName().c_str()); 343 } else { 344 data_rate_label->SetText("real: %.2fHz",1000./rate); 345 } 346 } 347 348 void Gx3_25_imu_impl::SetBaudrate(int value) { 349 uint8_t response[10] = {0}; 350 uint8_t command[11]; 351 ssize_t read = 0; 352 ssize_t written = 0; 353 354 union int32_4uint8 { 355 int32_t i; 356 uint8_t b[4]; 357 } 358 baudrate_value; 359 360 baudrate_value.i=value; 361 Printf("Gx3_25_imu::SetBaudrate: %s ->%i\n",self->IODevice::ObjectName().c_str(),baudrate_value.i); 362 363 command[0]=0xd9;//entete 364 command[1]=0xc3;//confirm 365 command[2]=0x55;//confirm 366 command[3]=1;//primary uart 367 command[4]=1;//chgt temporaire 368 command[5]=baudrate_value.b[3]; 369 command[6]=baudrate_value.b[2]; 370 command[7]=baudrate_value.b[1]; 371 command[8]=baudrate_value.b[0]; 372 command[9]=2;//uart enabled 373 command[10]=0;//reserved 374 375 written = serialport->Write(&command, sizeof(command)); 376 if(written<0) { 377 self->Thread::Err("Write error (%s)\n",strerror(-written)); 378 } else if (written != sizeof(command)) { 379 self->Thread::Err("Write error %i/%i\n",written,sizeof(command)); 380 } 381 382 read = serialport->Read(&response[0],sizeof(response)); 383 if(read<0) { 384 self->Thread::Err("Read error (%s)\n",strerror(-read)); 385 } else if (read != sizeof(response)) { 386 self->Thread::Err("Read error %i/%i\n",read,sizeof(response)); 387 } 388 389 if(CalcChecksum(response,sizeof(response))==false) { 390 self->Thread::Err("wrong checksum\n"); 391 return ; 392 } 393 394 serialport->SetBaudrate(value); 395 } 396 397 int Gx3_25_imu_impl::FirmwareNumber(void) { 398 uint8_t response[7] = {0}; 399 uint8_t command; 400 ssize_t read = 0; 401 ssize_t written = 0; 402 union int32_4uint8 { 403 int32_t i; 404 uint8_t b[4]; 405 } 406 value; 407 408 command=0xe9;//entete 409 410 written = serialport->Write(&command, sizeof(command)); 411 if(written<0) { 412 self->Thread::Err("Write error (%s)\n",strerror(-written)); 413 } else if (written != sizeof(command)) { 414 self->Thread::Err("Write error %i/%i\n",written,sizeof(command)); 415 } 416 417 read = serialport->Read(&response[0],sizeof(response)); 418 if(read<0) { 419 self->Thread::Err("Read error (%s)\n",strerror(-read)); 420 } else if (read != sizeof(response)) { 421 self->Thread::Err("Read error %i/%i\n",read,sizeof(response)); 422 } 423 424 if(CalcChecksum(response,sizeof(response))==false) { 425 self->Thread::Err("wrong checksum\n"); 426 return -1; 427 } 428 429 value.b[3]=response[1]; 430 value.b[2]=response[2]; 431 value.b[1]=response[3]; 432 value.b[0]=response[4]; 433 434 return value.i; 435 436 } 437 438 void Gx3_25_imu_impl::PrintModelInfo(void) { 439 uint8_t response[20] = {0}; 440 uint8_t command[2]; 441 ssize_t read = 0; 442 ssize_t written = 0; 443 444 for(int i=0; i<3; i++) { 445 command[0]=0xea;//entete 446 command[1]=i;//entete 447 448 written = serialport->Write(&command, sizeof(command)); 449 if(written<0) { 450 self->Thread::Err("Write error (%s)\n",strerror(-written)); 451 } else if (written != sizeof(command)) { 452 self->Thread::Err("Write error %i/%i\n",written,sizeof(command)); 453 } 454 455 read = serialport->Read(&response[0],sizeof(response)); 456 if(read<0) { 457 self->Thread::Err("Read error (%s)\n",strerror(-read)); 458 } else if (read != sizeof(response)) { 459 self->Thread::Err("Read error %i/%i\n",read,sizeof(response)); 460 } 461 462 if(CalcChecksum(response,sizeof(response))==false) { 463 self->Thread::Err("wrong checksum\n"); 464 //return -1; 465 } 466 467 char* msg=(char*)(&response[2]); 468 msg[16]=0; 469 switch(i) { 470 case 0: 471 Printf("Gx3_25_imu model number: %s\n",msg); 472 break; 473 case 1: 474 Printf("Gx3_25_imu serial number: %s\n",msg); 475 break; 476 case 2: 477 Printf("Gx3_25_imu model name: %s\n",msg); 478 break; 479 } 480 } 481 482 } 483 484 void Gx3_25_imu_impl::RealignUpNorth(bool realign_up,bool realign_north) { 485 uint8_t response[7] = {0}; 486 uint8_t command[10]; 487 ssize_t read = 0; 488 ssize_t written = 0; 489 490 command[0]=0xdd;//entete 491 command[1]=0x54;//confirm 492 command[2]=0x4c;//confirm 493 command[3]=0;//send reply 494 command[4]=255;//up realign 495 command[5]=1;//north realign 496 command[6]=0;//reserved 497 command[7]=0;//reserved 498 command[8]=0;//reserved 499 command[9]=0;//reserved 500 501 written = serialport->Write(&command, sizeof(command)); 502 if(written<0) { 503 self->Thread::Err("Write error (%s)\n",strerror(-written)); 504 } else if (written != sizeof(command)) { 505 self->Thread::Err("Write error %i/%i\n",written,sizeof(command)); 506 } 507 508 read = serialport->Read(&response[0],sizeof(response)); 509 if(read<0) { 510 self->Thread::Err("Read error(%s)\n",strerror(-read)); 511 } else if (read != sizeof(response)) { 512 self->Thread::Err("Read error %i/%i\n",read,sizeof(response)); 513 } 514 515 if(CalcChecksum(response,sizeof(response))==false) { 516 self->Thread::Err("wrong checksum\n"); 517 } 492 self->Thread::Err("Read error %i/%i\n", read, sizeof(response)); 493 } 494 495 if (CalcChecksum(response, sizeof(response)) == false) { 496 self->Thread::Err("wrong checksum\n"); 497 // return -1; 498 } 499 500 char *msg = (char *)(&response[2]); 501 msg[16] = 0; 502 switch (i) { 503 case 0: 504 Printf("Gx3_25_imu model number: %s\n", msg); 505 break; 506 case 1: 507 Printf("Gx3_25_imu serial number: %s\n", msg); 508 break; 509 case 2: 510 Printf("Gx3_25_imu model name: %s\n", msg); 511 break; 512 } 513 } 514 } 515 516 void Gx3_25_imu_impl::RealignUpNorth(bool realign_up, bool realign_north) { 517 uint8_t response[7] = {0}; 518 uint8_t command[10]; 519 ssize_t read = 0; 520 ssize_t written = 0; 521 522 command[0] = 0xdd; // entete 523 command[1] = 0x54; // confirm 524 command[2] = 0x4c; // confirm 525 command[3] = 0; // send reply 526 command[4] = 255; // up realign 527 command[5] = 1; // north realign 528 command[6] = 0; // reserved 529 command[7] = 0; // reserved 530 command[8] = 0; // reserved 531 command[9] = 0; // reserved 532 533 written = serialport->Write(&command, sizeof(command)); 534 if (written < 0) { 535 self->Thread::Err("Write error (%s)\n", strerror(-written)); 536 } else if (written != sizeof(command)) { 537 self->Thread::Err("Write error %i/%i\n", written, sizeof(command)); 538 } 539 540 read = serialport->Read(&response[0], sizeof(response)); 541 if (read < 0) { 542 self->Thread::Err("Read error(%s)\n", strerror(-read)); 543 } else if (read != sizeof(response)) { 544 self->Thread::Err("Read error %i/%i\n", read, sizeof(response)); 545 } 546 547 if (CalcChecksum(response, sizeof(response)) == false) { 548 self->Thread::Err("wrong checksum\n"); 549 } 518 550 } 519 551 520 552 void Gx3_25_imu_impl::DeviceReset(void) { 521 uint8_t command[3]; 522 ssize_t written = 0; 523 524 command[0]=0xfe;//entete 525 command[1]=0x9e;//confirm 526 command[2]=0x3a;//confirm 527 528 written = serialport->Write(&command, sizeof(command)); 529 if(written<0) { 530 self->Thread::Err("Write error (%s)\n",strerror(-written)); 531 } else if (written != sizeof(command)) { 532 self->Thread::Err("Write error %i/%i\n",written,sizeof(command)); 533 } 534 } 535 536 bool Gx3_25_imu_impl::CalcChecksum(uint8_t *buf,int size) { 537 uint16_t tChksum,tResponseChksum; 538 539 tChksum = 0; 540 for (int i = 0; i < size - 2; i++) tChksum += buf[i]; 541 // Extract the big-endian checksum from reply 542 tResponseChksum = 0; 543 tResponseChksum = buf[size - 2] << 8; 544 tResponseChksum += buf[size - 1]; 545 546 if(tChksum!=tResponseChksum) 547 return false; 548 else 549 return true; 550 } 553 uint8_t command[3]; 554 ssize_t written = 0; 555 556 command[0] = 0xfe; // entete 557 command[1] = 0x9e; // confirm 558 command[2] = 0x3a; // confirm 559 560 written = serialport->Write(&command, sizeof(command)); 561 if (written < 0) { 562 self->Thread::Err("Write error (%s)\n", strerror(-written)); 563 } else if (written != sizeof(command)) { 564 self->Thread::Err("Write error %i/%i\n", written, sizeof(command)); 565 } 566 } 567 568 bool Gx3_25_imu_impl::CalcChecksum(uint8_t *buf, int size) { 569 uint16_t tChksum, tResponseChksum; 570 571 tChksum = 0; 572 for (int i = 0; i < size - 2; i++) 573 tChksum += buf[i]; 574 // Extract the big-endian checksum from reply 575 tResponseChksum = 0; 576 tResponseChksum = buf[size - 2] << 8; 577 tResponseChksum += buf[size - 1]; 578 579 if (tChksum != tResponseChksum) 580 return false; 581 else 582 return true; 583 } -
trunk/lib/FlairSensorActuator/src/HokuyoUTM30Lx.cpp
r3 r15 32 32 using namespace flair::gui; 33 33 34 namespace flair 35 { 36 namespace sensor 37 { 38 39 HokuyoUTM30Lx::HokuyoUTM30Lx(const FrameworkManager* parent,string name,SerialPort *serialport,uint8_t priority) : LaserRangeFinder(parent,name), Thread(parent,name,priority) 40 { 41 main_tab=new Tab(parent->GetTabWidget(),name); 42 cvmatrix_descriptor* desc=new cvmatrix_descriptor(1081,1); 43 output=new cvmatrix((IODevice*)this,desc,SignedIntegerType(16)); 44 45 bufRetMut = new Mutex(reinterpret_cast<Object*>(this),(string)name+"BufRetMut"); 46 sendingCmdMut = new Mutex(reinterpret_cast<Object*>(this),(string)name+"SendingCmdMut"); 47 48 this->serialport=serialport; 49 serialport->SetRxTimeout(100000000); 50 } 51 52 HokuyoUTM30Lx::~HokuyoUTM30Lx() 53 { 54 delete main_tab; 55 SafeStop(); 56 Join(); 57 } 58 59 void HokuyoUTM30Lx::Run(void) 60 { 61 /** Debut init **/ 62 char c,lastC; 63 int startStep; 64 bool mustDecode=false; 65 stringstream ss; 66 vector<string> ret; 67 lastC=c=0; 68 69 /** Fin init **/ 70 resetConfig(); 71 startLaser(); 72 Printf("Laser started\r\n"); 73 74 /** Debut running loop **/ 75 WarnUponSwitches(true); 76 77 while(!ToBeStopped()) 78 { 79 ss.clear(); 80 ss.str(""); 81 do{ 82 lastC=c; 83 serialport->Read(&c,1); 84 ss << c; 85 }while(!(c=='\n'&&lastC=='\n')); 86 ret=explode(ss.str(),'\n'); 87 if(!checkSum(ret.at(1))) 88 perror("Bad Checksum !"); 89 if(ret.at(0).substr(0,2)=="MD") 90 mustDecode=true; 91 92 startStep=atoi(ret.at(0).substr(2,4).c_str()); 93 ret.erase(ret.begin()); 94 bufRetMut->GetMutex(); 95 bufRet.push(ret.at(0).substr(0,2)); 96 bufRetMut->ReleaseMutex(); 97 if(mustDecode){ 98 mustDecode=false; 99 ss.clear(); 100 ss.str(""); 101 do{ 102 lastC=c; 103 serialport->Read(&c,1); 104 ss << c; 105 }while(!(c=='\n'&&lastC=='\n')); 106 ret=explode(ss.str(),'\n'); 107 ret.erase(ret.begin()); 108 ret.erase(ret.begin()); 109 if(ret.at(0).size()==5) 110 if(!checkSum(ret.at(0))) 111 perror("TimeStamp checksum error!"); 112 ret.erase(ret.begin()); 113 Printf("!post\r\n"); 114 ret.pop_back(); 115 decodeDatas(ret, startStep); 116 } 34 namespace flair { 35 namespace sensor { 36 37 HokuyoUTM30Lx::HokuyoUTM30Lx(const FrameworkManager *parent, string name, 38 SerialPort *serialport, uint8_t priority) 39 : LaserRangeFinder(parent, name), Thread(parent, name, priority) { 40 main_tab = new Tab(parent->GetTabWidget(), name); 41 cvmatrix_descriptor *desc = new cvmatrix_descriptor(1081, 1); 42 output = new cvmatrix((IODevice *)this, desc, SignedIntegerType(16)); 43 44 bufRetMut = 45 new Mutex(reinterpret_cast<Object *>(this), (string)name + "BufRetMut"); 46 sendingCmdMut = new Mutex(reinterpret_cast<Object *>(this), 47 (string)name + "SendingCmdMut"); 48 49 this->serialport = serialport; 50 serialport->SetRxTimeout(100000000); 51 } 52 53 HokuyoUTM30Lx::~HokuyoUTM30Lx() { 54 delete main_tab; 55 SafeStop(); 56 Join(); 57 } 58 59 void HokuyoUTM30Lx::Run(void) { 60 /** Debut init **/ 61 char c, lastC; 62 int startStep; 63 bool mustDecode = false; 64 stringstream ss; 65 vector<string> ret; 66 lastC = c = 0; 67 68 /** Fin init **/ 69 resetConfig(); 70 startLaser(); 71 Printf("Laser started\r\n"); 72 73 /** Debut running loop **/ 74 WarnUponSwitches(true); 75 76 while (!ToBeStopped()) { 77 ss.clear(); 78 ss.str(""); 79 do { 80 lastC = c; 81 serialport->Read(&c, 1); 82 ss << c; 83 } while (!(c == '\n' && lastC == '\n')); 84 ret = explode(ss.str(), '\n'); 85 if (!checkSum(ret.at(1))) 86 perror("Bad Checksum !"); 87 if (ret.at(0).substr(0, 2) == "MD") 88 mustDecode = true; 89 90 startStep = atoi(ret.at(0).substr(2, 4).c_str()); 91 ret.erase(ret.begin()); 92 bufRetMut->GetMutex(); 93 bufRet.push(ret.at(0).substr(0, 2)); 94 bufRetMut->ReleaseMutex(); 95 if (mustDecode) { 96 mustDecode = false; 97 ss.clear(); 98 ss.str(""); 99 do { 100 lastC = c; 101 serialport->Read(&c, 1); 102 ss << c; 103 } while (!(c == '\n' && lastC == '\n')); 104 ret = explode(ss.str(), '\n'); 105 ret.erase(ret.begin()); 106 ret.erase(ret.begin()); 107 if (ret.at(0).size() == 5) 108 if (!checkSum(ret.at(0))) 109 perror("TimeStamp checksum error!"); 110 ret.erase(ret.begin()); 111 Printf("!post\r\n"); 112 ret.pop_back(); 113 decodeDatas(ret, startStep); 117 114 } 118 /** fin running loop **/ 119 stopLaser(); 120 WarnUponSwitches(false); 121 } 122 123 124 void HokuyoUTM30Lx::decodeDatas(vector<string> datas, int startStep){ 125 stringstream ss; 126 for (unsigned i=0; i<datas.size(); i++){ 127 if(datas.at(i).size()!=0){ 128 if(!checkSum(datas.at(i))) 129 perror("Datas checksum error !"); 130 datas.at(i).erase(datas.at(i).end()-1); 131 ss << datas.at(i); 132 } 133 } 134 output->GetMutex(); 135 for(unsigned i=0;i<1080;i++){ 136 //TODO: remettre -1 pour les points non lus 137 output->SetValueNoMutex(i,0,0); 138 } 139 for(unsigned i=0;i<ss.str().size();i+=3){ 140 output->SetValueNoMutex(startStep+(i/3),0,decode3car(ss.str().substr(i,3).c_str())); 141 } 142 UpdateFrom(output); 143 ProcessUpdate(output); 144 output->ReleaseMutex(); 145 146 } 147 148 bool HokuyoUTM30Lx::checkSum(string data){ 149 return (char)encodeSum(data.substr(0,data.size()-1).c_str(),data.size()-1)==data.at(data.size()-1); 150 } 151 152 void HokuyoUTM30Lx::startLaser(){ 153 string ret = sendCommand("BM"); 154 #ifdef VERBOSE 155 if(ret == "00"){ 156 cout << "BM: Alright !" << endl; 157 }else if(ret == "01"){ 158 cout << "BM: Laser malfunction !" << endl; 159 }else if(ret == "02"){ 160 cout << "BM: Laser already started !" << endl; 161 } 162 #endif 163 } 164 165 void HokuyoUTM30Lx::stopLaser(){ 166 sendCommand("QT"); 167 } 168 169 void HokuyoUTM30Lx::resetConfig(){ 170 sendCommand("RS"); 171 } 172 173 vector<string> HokuyoUTM30Lx::explode(const string str, char delimiter){ 174 istringstream split(str); 175 vector<string> tokens; 176 for (string each; getline(split, each, delimiter); tokens.push_back(each)); 177 return tokens; 178 } 179 180 int HokuyoUTM30Lx::encodeSum(const char* code, int byte) { 181 unsigned char value = 0; 182 int i; 183 for (i = 0; i < byte; ++i) { 184 value+=code[i]; 115 } 116 /** fin running loop **/ 117 stopLaser(); 118 WarnUponSwitches(false); 119 } 120 121 void HokuyoUTM30Lx::decodeDatas(vector<string> datas, int startStep) { 122 stringstream ss; 123 for (unsigned i = 0; i < datas.size(); i++) { 124 if (datas.at(i).size() != 0) { 125 if (!checkSum(datas.at(i))) 126 perror("Datas checksum error !"); 127 datas.at(i).erase(datas.at(i).end() - 1); 128 ss << datas.at(i); 185 129 } 186 value &= 0x3f; 187 value += 0x30; 188 return value; 189 } 190 191 float HokuyoUTM30Lx::decode2car(const char* data){ 192 return ((data[0]-0x30)<<6)|((data[1]-0x30)); 193 } 194 float HokuyoUTM30Lx::decode3car(const char* data){ 195 return ((data[0]-0x30)<<12)|((data[1]-0x30)<<6)|((data[2]-0x30)); 196 } 197 float HokuyoUTM30Lx::decode4car(const char* data){ 198 return ((data[0]-0x30)<<18)|((data[1]-0x30)<<12)|((data[2]-0x30)<<6)|((data[3]-0x30)); 199 } 200 201 string HokuyoUTM30Lx::sendCommand(string command){ 202 char c; 203 string ret="00"; 204 c='\n'; 205 sendingCmdMut->GetMutex(); 206 serialport->Write(command.c_str(),command.size()); 207 serialport->Write(&c,1); 208 sendingCmdMut->ReleaseMutex(); 209 return ret; 210 } 211 212 void HokuyoUTM30Lx::getMesure(int startStep, int endStep,int clusterCount, int interval, int scanNumber){ 213 stringstream ss; 214 string ret; 215 ss << "MD" << std::setfill('0') << std::setw(4) << startStep << std::setw(4) << endStep << std::setw(2) << clusterCount << std::setw(1) << interval << std::setw(2) << scanNumber; 216 ret = sendCommand(ss.str()); 217 #ifdef VERBOSE 218 if(ret == "00"){ 219 cout << "MD: Alright !" << endl; 220 }else if(ret == "01"){ 221 cout << "MD: Laser malfunction !" << endl; 222 }else if(ret == "02"){ 223 cout << "MD: End Step has non-numeric value !" << endl; 224 }else if(ret == "03"){ 225 cout << "MD: Cluster Count has non-numeric value !" << endl; 226 }else if(ret == "04"){ 227 cout << "MD: End Step is out of range !" << endl; 228 }else if(ret == "05"){ 229 cout << "MD: End Step is smaller than Starting Step !" << endl; 230 }else if(ret == "06"){ 231 cout << "MD: Scan Interval has non-numeric value !" << endl; 232 }else if(ret == "07"){ 233 cout << "MD: Number of Scan has non-numeric value !" << endl; 234 }else if(ret == "98"){ 235 cout << "MD: Resumption of process after confirming normal HokuyoUTM30Lx operation." << endl; 236 }else{ 237 /* Concerne : 238 21~49 --- Processing stopped to verify the error. 239 50~97 --- Hardware trouble (such as laser, motor malfunctions etc.)*/ 240 cout << "MD: Malfunction !" << endl; 241 } 242 #endif 243 } 244 cvmatrix* HokuyoUTM30Lx::getDatas(){ 245 return output; 246 } 247 248 void HokuyoUTM30Lx::UseDefaultPlot(void) 249 { 250 plot=new RangeFinderPlot(main_tab->NewRow(),"plot","x",-100,100,"y",-0,100,output,-45,225,output->Rows()); 130 } 131 output->GetMutex(); 132 for (unsigned i = 0; i < 1080; i++) { 133 // TODO: remettre -1 pour les points non lus 134 output->SetValueNoMutex(i, 0, 0); 135 } 136 for (unsigned i = 0; i < ss.str().size(); i += 3) { 137 output->SetValueNoMutex(startStep + (i / 3), 0, 138 decode3car(ss.str().substr(i, 3).c_str())); 139 } 140 UpdateFrom(output); 141 ProcessUpdate(output); 142 output->ReleaseMutex(); 143 } 144 145 bool HokuyoUTM30Lx::checkSum(string data) { 146 return (char)encodeSum(data.substr(0, data.size() - 1).c_str(), 147 data.size() - 1) == data.at(data.size() - 1); 148 } 149 150 void HokuyoUTM30Lx::startLaser() { 151 string ret = sendCommand("BM"); 152 #ifdef VERBOSE 153 if (ret == "00") { 154 cout << "BM: Alright !" << endl; 155 } else if (ret == "01") { 156 cout << "BM: Laser malfunction !" << endl; 157 } else if (ret == "02") { 158 cout << "BM: Laser already started !" << endl; 159 } 160 #endif 161 } 162 163 void HokuyoUTM30Lx::stopLaser() { sendCommand("QT"); } 164 165 void HokuyoUTM30Lx::resetConfig() { sendCommand("RS"); } 166 167 vector<string> HokuyoUTM30Lx::explode(const string str, char delimiter) { 168 istringstream split(str); 169 vector<string> tokens; 170 for (string each; getline(split, each, delimiter); tokens.push_back(each)) 171 ; 172 return tokens; 173 } 174 175 int HokuyoUTM30Lx::encodeSum(const char *code, int byte) { 176 unsigned char value = 0; 177 int i; 178 for (i = 0; i < byte; ++i) { 179 value += code[i]; 180 } 181 value &= 0x3f; 182 value += 0x30; 183 return value; 184 } 185 186 float HokuyoUTM30Lx::decode2car(const char *data) { 187 return ((data[0] - 0x30) << 6) | ((data[1] - 0x30)); 188 } 189 float HokuyoUTM30Lx::decode3car(const char *data) { 190 return ((data[0] - 0x30) << 12) | ((data[1] - 0x30) << 6) | 191 ((data[2] - 0x30)); 192 } 193 float HokuyoUTM30Lx::decode4car(const char *data) { 194 return ((data[0] - 0x30) << 18) | ((data[1] - 0x30) << 12) | 195 ((data[2] - 0x30) << 6) | ((data[3] - 0x30)); 196 } 197 198 string HokuyoUTM30Lx::sendCommand(string command) { 199 char c; 200 string ret = "00"; 201 c = '\n'; 202 sendingCmdMut->GetMutex(); 203 serialport->Write(command.c_str(), command.size()); 204 serialport->Write(&c, 1); 205 sendingCmdMut->ReleaseMutex(); 206 return ret; 207 } 208 209 void HokuyoUTM30Lx::getMesure(int startStep, int endStep, int clusterCount, 210 int interval, int scanNumber) { 211 stringstream ss; 212 string ret; 213 ss << "MD" << std::setfill('0') << std::setw(4) << startStep << std::setw(4) 214 << endStep << std::setw(2) << clusterCount << std::setw(1) << interval 215 << std::setw(2) << scanNumber; 216 ret = sendCommand(ss.str()); 217 #ifdef VERBOSE 218 if (ret == "00") { 219 cout << "MD: Alright !" << endl; 220 } else if (ret == "01") { 221 cout << "MD: Laser malfunction !" << endl; 222 } else if (ret == "02") { 223 cout << "MD: End Step has non-numeric value !" << endl; 224 } else if (ret == "03") { 225 cout << "MD: Cluster Count has non-numeric value !" << endl; 226 } else if (ret == "04") { 227 cout << "MD: End Step is out of range !" << endl; 228 } else if (ret == "05") { 229 cout << "MD: End Step is smaller than Starting Step !" << endl; 230 } else if (ret == "06") { 231 cout << "MD: Scan Interval has non-numeric value !" << endl; 232 } else if (ret == "07") { 233 cout << "MD: Number of Scan has non-numeric value !" << endl; 234 } else if (ret == "98") { 235 cout << "MD: Resumption of process after confirming normal HokuyoUTM30Lx " 236 "operation." << endl; 237 } else { 238 /* Concerne : 239 21~49 --- Processing stopped to verify the error. 240 50~97 --- Hardware trouble (such as laser, motor malfunctions etc.)*/ 241 cout << "MD: Malfunction !" << endl; 242 } 243 #endif 244 } 245 cvmatrix *HokuyoUTM30Lx::getDatas() { return output; } 246 247 void HokuyoUTM30Lx::UseDefaultPlot(void) { 248 plot = new RangeFinderPlot(main_tab->NewRow(), "plot", "x", -100, 100, "y", 249 -0, 100, output, -45, 225, output->Rows()); 251 250 } 252 251 -
trunk/lib/FlairSensorActuator/src/HokuyoUTM30Lx.h
r3 r15 21 21 #include <vector> 22 22 23 namespace flair 24 { 25 namespace core 26 { 27 class cvmatrix; 28 class FrameworkManager; 29 class SerialPort; 30 class Mutex; 31 } 32 namespace gui 33 { 34 class Tab; 35 class TabWidget; 36 class RangeFinderPlot; 37 } 23 namespace flair { 24 namespace core { 25 class cvmatrix; 26 class FrameworkManager; 27 class SerialPort; 28 class Mutex; 29 } 30 namespace gui { 31 class Tab; 32 class TabWidget; 33 class RangeFinderPlot; 34 } 38 35 } 39 36 40 namespace flair 41 { 42 namespace sensor 43 { 44 /*! \class HokuyoUTM30Lx 45 * 46 * \brief Classe intégrant le telemetre laser Hokuyo UTM 30lx 47 */ 48 class HokuyoUTM30Lx : public core::Thread, public LaserRangeFinder 49 { 50 public: 37 namespace flair { 38 namespace sensor { 39 /*! \class HokuyoUTM30Lx 40 * 41 * \brief Classe intégrant le telemetre laser Hokuyo UTM 30lx 42 */ 43 class HokuyoUTM30Lx : public core::Thread, public LaserRangeFinder { 44 public: 45 /*! 46 * \brief Constructor 47 * 48 * Construct a Hokuyo UTM30-Lx. 49 * 50 * \param parent parent 51 * \param name name 52 * \param serialport serialport 53 * \param priority priority of the Thread 54 */ 55 HokuyoUTM30Lx(const core::FrameworkManager *parent, std::string name, 56 core::SerialPort *serialport, uint8_t priority); 57 void getMesure(int startStep, int endStep, int clusterCount, int interval, 58 int scanNumber = 0); 59 core::cvmatrix *getDatas(void); 51 60 52 /*! 53 * \brief Constructor 54 * 55 * Construct a Hokuyo UTM30-Lx. 56 * 57 * \param parent parent 58 * \param name name 59 * \param serialport serialport 60 * \param priority priority of the Thread 61 */ 62 HokuyoUTM30Lx(const core::FrameworkManager* parent,std::string name,core::SerialPort *serialport,uint8_t priority); 63 void getMesure(int startStep, int endStep,int clusterCount, int interval, int scanNumber=0); 64 core::cvmatrix* getDatas(void); 61 /*! 62 * \brief Use default plot 63 * 64 */ 65 void UseDefaultPlot(void); 66 /*! 67 * \brief Destructor 68 * 69 */ 70 ~HokuyoUTM30Lx(); 65 71 66 /*! 67 * \brief Use default plot 68 * 69 */ 70 void UseDefaultPlot(void); 71 /*! 72 * \brief Destructor 73 * 74 */ 75 ~HokuyoUTM30Lx(); 72 private: 73 core::SerialPort *serialport; 74 core::Mutex *bufRetMut; 75 core::Mutex *sendingCmdMut; 76 gui::Tab *main_tab; 77 gui::TabWidget *tab; 78 gui::RangeFinderPlot *plot; 76 79 77 private: 78 core::SerialPort *serialport; 79 core::Mutex* bufRetMut; 80 core::Mutex* sendingCmdMut; 81 gui::Tab* main_tab; 82 gui::TabWidget* tab; 83 gui::RangeFinderPlot* plot; 80 // matrix 81 core::cvmatrix *output; 84 82 85 //matrix 86 core::cvmatrix *output; 83 std::queue<std::string> bufRet; 87 84 88 std::queue<std::string> bufRet; 85 /*! 86 * \brief Run function 87 * 88 * Reimplemented from Thread. 89 * 90 */ 91 void Run(void); 92 /*! 93 * \brief Send a command 94 * \param command Command to send (see Hokuyo UTM 30-LX doc for more 95 * informations) 96 * \return Return code 97 */ 98 std::string sendCommand(std::string command); 99 /*! 100 * \brief Start the laser 101 * 102 */ 103 void startLaser(void); 104 /*! 105 * \brief Stop the laser 106 * 107 */ 108 void stopLaser(void); 109 /*! 110 * \brief Stop and reset the laser's settings 111 * 112 */ 113 void resetConfig(void); 114 /*! 115 * \brief Decode incomming datas 116 * \param datas Datas to decode 117 * \param startStep Set the first mesured point 118 * Decode mesured points from incoming datas and fill the output matrix 119 */ 120 void decodeDatas(std::vector<std::string> datas, int startStep); 121 /*! 122 * \brief Explode a string into a vector 123 * \param str The string to explode 124 * \param delimiter The character separating elements 125 * \return A vector containing the elements 126 */ 127 static std::vector<std::string> explode(const std::string str, 128 char delimiter); 129 /*! 130 * \brief Calculate the checksum 131 * \param code Data from which calculate 132 * \param byte Data's size 133 * \return A character corresponding to the code's checksum 134 */ 135 static int encodeSum(const char *code, int byte); 136 /*! 137 * \brief Check if a data correspond to its checksum 138 * \param data Datas to check 139 */ 140 static bool checkSum(std::string data); 141 /*! 142 * \brief Decode datas using the 2 character encoding 143 * \param data Datas to decode 144 * \return Decoded datas 145 */ 146 static float decode2car(const char *data); 147 /*! 148 * \brief Decode datas using the 3 character encoding 149 * \param data Datas to decode 150 * \return Decoded datas 151 */ 152 static float decode3car(const char *data); 153 /*! 154 * \brief Decode datas using the 4 character encoding 155 * \param data Datas to decode 156 * \return Decoded datas 157 */ 158 static float decode4car(const char *data); 89 159 90 /*! 91 * \brief Run function 92 * 93 * Reimplemented from Thread. 94 * 95 */ 96 void Run(void); 97 /*! 98 * \brief Send a command 99 * \param command Command to send (see Hokuyo UTM 30-LX doc for more informations) 100 * \return Return code 101 */ 102 std::string sendCommand(std::string command); 103 /*! 104 * \brief Start the laser 105 * 106 */ 107 void startLaser(void); 108 /*! 109 * \brief Stop the laser 110 * 111 */ 112 void stopLaser(void); 113 /*! 114 * \brief Stop and reset the laser's settings 115 * 116 */ 117 void resetConfig(void); 118 /*! 119 * \brief Decode incomming datas 120 * \param datas Datas to decode 121 * \param startStep Set the first mesured point 122 * Decode mesured points from incoming datas and fill the output matrix 123 */ 124 void decodeDatas(std::vector<std::string> datas, int startStep); 125 /*! 126 * \brief Explode a string into a vector 127 * \param str The string to explode 128 * \param delimiter The character separating elements 129 * \return A vector containing the elements 130 */ 131 static std::vector<std::string> explode(const std::string str, char delimiter); 132 /*! 133 * \brief Calculate the checksum 134 * \param code Data from which calculate 135 * \param byte Data's size 136 * \return A character corresponding to the code's checksum 137 */ 138 static int encodeSum(const char* code, int byte); 139 /*! 140 * \brief Check if a data correspond to its checksum 141 * \param data Datas to check 142 */ 143 static bool checkSum(std::string data); 144 /*! 145 * \brief Decode datas using the 2 character encoding 146 * \param data Datas to decode 147 * \return Decoded datas 148 */ 149 static float decode2car(const char* data); 150 /*! 151 * \brief Decode datas using the 3 character encoding 152 * \param data Datas to decode 153 * \return Decoded datas 154 */ 155 static float decode3car(const char* data); 156 /*! 157 * \brief Decode datas using the 4 character encoding 158 * \param data Datas to decode 159 * \return Decoded datas 160 */ 161 static float decode4car(const char* data); 162 163 /*! 164 * \brief Update using provided datas 165 * 166 * Reimplemented from IODevice. 167 * 168 * \param data data from the parent to process 169 */ 170 void UpdateFrom(const core::io_data *data){}; 171 172 }; 160 /*! 161 * \brief Update using provided datas 162 * 163 * Reimplemented from IODevice. 164 * 165 * \param data data from the parent to process 166 */ 167 void UpdateFrom(const core::io_data *data){}; 168 }; 173 169 } // end namespace sensor 174 170 } // end namespace framewor -
trunk/lib/FlairSensorActuator/src/HostEthController.cpp
r3 r15 11 11 // version: $Id: $ 12 12 // 13 // purpose: Base class for host side remote controls that talks to target side through ethernet connection 13 // purpose: Base class for host side remote controls that talks to target 14 // side through ethernet connection 14 15 // 15 16 // … … 37 38 using std::string; 38 39 39 namespace flair 40 { 41 namespace sensor 42 { 43 44 HostEthController::HostEthController(const FrameworkManager* parent,string name,string _address,int _port,uint32_t period,uint32_t _bitsPerAxis,uint8_t priority) : 45 Thread(parent,name,priority),IODevice(parent,name),tab(new Tab(parent->GetTabWidget(),name)),axisNumber(0),buttonNumber(0),targetAddress(_address),targetPort(_port), 46 bitsPerAxis(_bitsPerAxis),dataFrameBuffer(NULL),meaningfulDataAvailable(false) { 47 tabWidget=new TabWidget(tab->NewRow(),name); 48 49 const bool blocking=true; 50 controlSocket=new TcpSocket((Thread*)this,"eth controller control socket", blocking, !blocking); 51 dataSocket=new Socket((Thread*)this,"eth controller data socket",_address+":"+std::to_string(_port+1)); 52 dataSender=new DataSender((Thread*)this, this, "eth controller data sender thread"); 53 dataSender->SetPeriodMS(period); 54 dataSender->Start(); 55 56 //test binary 57 /* 58 uint16_t testValue=0b0111011010; //0x1DA 59 char buffer[3]={(char)0b10101011, (char)0b01100101, (char)0b10110110}; // 0xAB65B6 60 writeBits(testValue,10,buffer,7); // 0b1010101 0 11101101 0 0110110 0xAAED36 61 Thread::Info("Debug: buffer after bits written=%X %X\n",buffer[0],buffer[1]); 62 */ 63 connectionEstablishedMutex=new Mutex((Thread*)this); 40 namespace flair { 41 namespace sensor { 42 43 HostEthController::HostEthController(const FrameworkManager *parent, 44 string name, string _address, int _port, 45 uint32_t period, uint32_t _bitsPerAxis, 46 uint8_t priority) 47 : Thread(parent, name, priority), IODevice(parent, name), 48 tab(new Tab(parent->GetTabWidget(), name)), axisNumber(0), 49 buttonNumber(0), targetAddress(_address), targetPort(_port), 50 bitsPerAxis(_bitsPerAxis), dataFrameBuffer(NULL), 51 meaningfulDataAvailable(false) { 52 tabWidget = new TabWidget(tab->NewRow(), name); 53 54 const bool blocking = true; 55 controlSocket = new TcpSocket((Thread *)this, "eth controller control socket", 56 blocking, !blocking); 57 dataSocket = new Socket((Thread *)this, "eth controller data socket", 58 _address + ":" + std::to_string(_port + 1)); 59 dataSender = 60 new DataSender((Thread *)this, this, "eth controller data sender thread"); 61 dataSender->SetPeriodMS(period); 62 dataSender->Start(); 63 64 // test binary 65 /* 66 uint16_t testValue=0b0111011010; //0x1DA 67 char buffer[3]={(char)0b10101011, (char)0b01100101, (char)0b10110110}; // 68 0xAB65B6 69 writeBits(testValue,10,buffer,7); // 0b1010101 0 11101101 0 0110110 0xAAED36 70 Thread::Info("Debug: buffer after bits written=%X %X\n",buffer[0],buffer[1]); 71 */ 72 connectionEstablishedMutex = new Mutex((Thread *)this); 64 73 } 65 74 66 75 HostEthController::~HostEthController() { 76 SafeStop(); 77 Join(); 78 79 if (!getFrameworkManager()->ConnectionLost()) 80 delete tab; 81 } 82 83 void HostEthController::DrawUserInterface() { 84 Tab *plotTab = new Tab(tabWidget, "Measures"); 85 axisPlot = new DataPlot1D *[axisNumber]; 86 for (unsigned int i = 0; i < axisNumber; i++) { 87 // Start a new row or add up to the current row? We try to keep a 4/3 ratio 88 unsigned int columns = sqrt(4.0 * axisNumber / 3.0); 89 LayoutPosition *position; 90 if (i % columns == 0) { 91 position = plotTab->NewRow(); 92 } else { 93 position = plotTab->LastRowLastCol(); 94 } 95 axisPlot[i] = new DataPlot1D(position, axis->Name(i, 0), 96 -(1 << (nativeBitsPerAxis - 1)) * 1.2, 97 (1 << (nativeBitsPerAxis - 1)) * 1.5); 98 axisPlot[i]->AddCurve(axis->Element(i)); 99 } 100 // we don't plot the button state for now 101 } 102 103 string HostEthController::GetAxisDescription(unsigned int axis) { 104 return string("axis") + std::to_string(axis); 105 } 106 107 string HostEthController::GetButtonDescription(unsigned int button) { 108 return string("button") + std::to_string(button); 109 } 110 111 bool HostEthController::ControllerInitialization() { 112 113 buttonOffset = (axisNumber * bitsPerAxis) / 8; 114 if ((axisNumber * bitsPerAxis) % 8 != 0) 115 buttonOffset++; 116 dataFrameSize = buttonOffset + (buttonNumber / 8) * sizeof(uint8_t); 117 if ((buttonNumber % 8) != 0) 118 dataFrameSize++; 119 dataFrameBuffer = new char[dataFrameSize]; 120 return true; 121 } 122 123 void HostEthController::SendControllerInfo() { 124 // send axis info 125 controlSocket->WriteUInt32((uint32_t)axisNumber, 0); 126 controlSocket->WriteUInt32(bitsPerAxis, 0); 127 for (unsigned int i = 0; i < axisNumber; i++) { 128 // Thread::Info("Debug: sending axis name for axis %d = %s (takes up %d 129 // bytes)\n",i,GetAxisDescription(i).c_str(),GetAxisDescription(i).length()); 130 int stringLength = GetAxisDescription(i).length(); 131 controlSocket->WriteUInt32((uint32_t)stringLength, 0); 132 controlSocket->SendMessage(GetAxisDescription(i).c_str(), stringLength, 0); 133 } 134 135 // send button info 136 controlSocket->WriteUInt32((uint32_t)buttonNumber, 0); 137 for (unsigned int i = 0; i < buttonNumber; i++) { 138 int stringLength = GetButtonDescription(i).length(); 139 controlSocket->WriteUInt32((uint32_t)stringLength, 0); 140 controlSocket->SendMessage(GetButtonDescription(i).c_str(), stringLength, 141 0); 142 } 143 } 144 145 bool HostEthController::ConnectedWithTarget() { 146 char message[1024]; 147 ssize_t sent, received; 148 static bool connectionEstablished = false; 149 150 connectionEstablishedMutex->GetMutex(); 151 if (!connectionEstablished && 152 controlSocket->Connect(targetPort, targetAddress, 10)) { 153 Thread::Info("Connected to %s:%d\n", targetAddress.c_str(), targetPort); 154 SendControllerInfo(); 155 connectionEstablished = true; 156 } 157 connectionEstablishedMutex->ReleaseMutex(); 158 return connectionEstablished; 159 } 160 161 void HostEthController::Run() { 162 static int divider = 0; 163 Message *msgControllerAction = new Message(1024); 164 if (getFrameworkManager()->ErrorOccured() || !ControllerInitialization()) { 67 165 SafeStop(); 68 Join(); 69 70 if(!getFrameworkManager()->ConnectionLost()) delete tab; 71 } 72 73 void HostEthController::DrawUserInterface() { 74 Tab* plotTab=new Tab(tabWidget,"Measures"); 75 axisPlot=new DataPlot1D *[axisNumber]; 76 for (unsigned int i=0; i<axisNumber;i++) { 77 //Start a new row or add up to the current row? We try to keep a 4/3 ratio 78 unsigned int columns=sqrt(4.0*axisNumber/3.0); 79 LayoutPosition *position; 80 if (i%columns==0) { 81 position=plotTab->NewRow(); 82 } else { 83 position=plotTab->LastRowLastCol(); 166 Thread::Err("Une erreur a eu lieu, on ne lance pas la boucle\n"); 167 } 168 169 if (buttonNumber % 8 != 0) { 170 SafeStop(); 171 Thread::Err("Button number is not multiple of 8\n"); 172 } 173 174 while (!ToBeStopped()) { 175 // Thread::Info("Debug: entering acquisition loop\n"); 176 if (getFrameworkManager()->ConnectionLost() == true) 177 SafeStop(); 178 179 if (IsDataFrameReady()) { // wait for next data frame 180 meaningfulDataAvailable = true; 181 GetAxisData(); 182 GetButtonData(); 183 184 if (ConnectedWithTarget()) { 185 // read for commands from the target (remote control state change 186 // requests such as rumble or led on/off) 187 ssize_t bytesReceived = 188 controlSocket->RecvMessage((char *)msgControllerAction->buffer, 189 msgControllerAction->bufferSize); 190 if (bytesReceived > 0) { 191 // if the message is a cnx exit request we manage it here, if not it 192 // will be managed by the derived class 193 ControllerAction action; 194 memcpy(&action, msgControllerAction->buffer, 195 sizeof(ControllerAction)); 196 if (action == ControllerAction::Exit) { 197 // Thread::Info("Debug: exit request received from server\n"); 198 SafeStop(); 199 } 200 ProcessMessage(msgControllerAction); 84 201 } 85 axisPlot[i]=new DataPlot1D(position,axis->Name(i,0),-(1<<(nativeBitsPerAxis-1))*1.2,(1<<(nativeBitsPerAxis-1))*1.5); 86 axisPlot[i]->AddCurve(axis->Element(i)); 87 } 88 //we don't plot the button state for now 89 } 90 91 string HostEthController::GetAxisDescription(unsigned int axis) { 92 return string("axis")+std::to_string(axis); 93 } 94 95 string HostEthController::GetButtonDescription(unsigned int button) { 96 return string("button")+std::to_string(button); 97 } 98 99 bool HostEthController::ControllerInitialization() { 100 101 buttonOffset=(axisNumber*bitsPerAxis)/8; 102 if ((axisNumber*bitsPerAxis)%8!=0) buttonOffset++; 103 dataFrameSize=buttonOffset+(buttonNumber/8)*sizeof(uint8_t); 104 if ((buttonNumber%8)!=0) dataFrameSize++; 105 dataFrameBuffer=new char[dataFrameSize]; 106 return true; 107 } 108 109 void HostEthController::SendControllerInfo() { 110 //send axis info 111 controlSocket->WriteUInt32((uint32_t)axisNumber,0); 112 controlSocket->WriteUInt32(bitsPerAxis,0); 113 for (unsigned int i=0; i<axisNumber; i++) { 114 //Thread::Info("Debug: sending axis name for axis %d = %s (takes up %d bytes)\n",i,GetAxisDescription(i).c_str(),GetAxisDescription(i).length()); 115 int stringLength=GetAxisDescription(i).length(); 116 controlSocket->WriteUInt32((uint32_t)stringLength,0); 117 controlSocket->SendMessage(GetAxisDescription(i).c_str(), stringLength,0); 118 } 119 120 //send button info 121 controlSocket->WriteUInt32((uint32_t)buttonNumber,0); 122 for (unsigned int i=0; i<buttonNumber; i++) { 123 int stringLength=GetButtonDescription(i).length(); 124 controlSocket->WriteUInt32((uint32_t)stringLength,0); 125 controlSocket->SendMessage(GetButtonDescription(i).c_str(), stringLength,0); 126 } 127 } 128 129 bool HostEthController::ConnectedWithTarget() { 130 char message[1024]; 131 ssize_t sent,received; 132 static bool connectionEstablished=false; 133 134 connectionEstablishedMutex->GetMutex(); 135 if (!connectionEstablished && controlSocket->Connect(targetPort,targetAddress,10)) { 136 Thread::Info("Connected to %s:%d\n", targetAddress.c_str(), targetPort); 137 SendControllerInfo(); 138 connectionEstablished=true; 139 } 140 connectionEstablishedMutex->ReleaseMutex(); 141 return connectionEstablished; 142 } 143 144 void HostEthController::Run() { 145 static int divider=0; 146 Message *msgControllerAction=new Message(1024); 147 if(getFrameworkManager()->ErrorOccured()||!ControllerInitialization()) { 148 SafeStop(); 149 Thread::Err("Une erreur a eu lieu, on ne lance pas la boucle\n"); 150 } 151 152 if(buttonNumber%8!=0) { 153 SafeStop(); 154 Thread::Err("Button number is not multiple of 8\n"); 155 } 156 157 while(!ToBeStopped()) { 158 //Thread::Info("Debug: entering acquisition loop\n"); 159 if(getFrameworkManager()->ConnectionLost()==true) SafeStop(); 160 161 if (IsDataFrameReady()) { //wait for next data frame 162 meaningfulDataAvailable=true; 163 GetAxisData(); 164 GetButtonData(); 165 166 if (ConnectedWithTarget()) { 167 //read for commands from the target (remote control state change requests such as rumble or led on/off) 168 ssize_t bytesReceived=controlSocket->RecvMessage((char*)msgControllerAction->buffer,msgControllerAction->bufferSize); 169 if(bytesReceived>0) { 170 //if the message is a cnx exit request we manage it here, if not it will be managed by the derived class 171 ControllerAction action; 172 memcpy(&action,msgControllerAction->buffer,sizeof(ControllerAction)); 173 if (action==ControllerAction::Exit) { 174 //Thread::Info("Debug: exit request received from server\n"); 175 SafeStop(); 176 } 177 ProcessMessage(msgControllerAction); 178 } 179 } 180 } else {//try to connect even if host is not sending anything 181 ConnectedWithTarget(); 182 } 183 //Thread::Info("Debug: exiting acquisition loop\n"); 184 } 185 } 186 187 bool HostEthController::writeBits(uint16_t value,uint8_t valueSizeInBits,char *buffer,uint8_t offsetInBits) { 188 if (valueSizeInBits>16) return false; 189 uint8_t remainingBitsToWrite=valueSizeInBits; 190 //skip first bytes 191 buffer+=offsetInBits/8; 192 offsetInBits-=(offsetInBits/8)*8; 193 while (remainingBitsToWrite>0) { 194 uint8_t remainingBitsInByteBeforeWrite=8-offsetInBits; 195 uint8_t bitsToWrite=remainingBitsToWrite<remainingBitsInByteBeforeWrite?remainingBitsToWrite:remainingBitsInByteBeforeWrite; 196 uint8_t remainingBitsInByteAfterWrite=remainingBitsInByteBeforeWrite-bitsToWrite; 197 //write in the current byte 198 uint8_t byteMask=((1<<bitsToWrite)-1)<<remainingBitsInByteAfterWrite; 199 (*buffer)&=~byteMask; 200 uint16_t valueMask=(1<<remainingBitsToWrite)-1; 201 (*buffer)|=((value&valueMask)>>(remainingBitsToWrite-bitsToWrite))<<remainingBitsInByteAfterWrite; 202 //update state 203 remainingBitsToWrite-=bitsToWrite; 204 offsetInBits=(offsetInBits+bitsToWrite)%8; 205 buffer++; 206 } 207 return true; 202 } 203 } else { // try to connect even if host is not sending anything 204 ConnectedWithTarget(); 205 } 206 // Thread::Info("Debug: exiting acquisition loop\n"); 207 } 208 } 209 210 bool HostEthController::writeBits(uint16_t value, uint8_t valueSizeInBits, 211 char *buffer, uint8_t offsetInBits) { 212 if (valueSizeInBits > 16) 213 return false; 214 uint8_t remainingBitsToWrite = valueSizeInBits; 215 // skip first bytes 216 buffer += offsetInBits / 8; 217 offsetInBits -= (offsetInBits / 8) * 8; 218 while (remainingBitsToWrite > 0) { 219 uint8_t remainingBitsInByteBeforeWrite = 8 - offsetInBits; 220 uint8_t bitsToWrite = remainingBitsToWrite < remainingBitsInByteBeforeWrite 221 ? remainingBitsToWrite 222 : remainingBitsInByteBeforeWrite; 223 uint8_t remainingBitsInByteAfterWrite = 224 remainingBitsInByteBeforeWrite - bitsToWrite; 225 // write in the current byte 226 uint8_t byteMask = ((1 << bitsToWrite) - 1) 227 << remainingBitsInByteAfterWrite; 228 (*buffer) &= ~byteMask; 229 uint16_t valueMask = (1 << remainingBitsToWrite) - 1; 230 (*buffer) |= ((value & valueMask) >> (remainingBitsToWrite - bitsToWrite)) 231 << remainingBitsInByteAfterWrite; 232 // update state 233 remainingBitsToWrite -= bitsToWrite; 234 offsetInBits = (offsetInBits + bitsToWrite) % 8; 235 buffer++; 236 } 237 return true; 208 238 } 209 239 210 240 void HostEthController::BuildDataFrame() { 211 //int16_t testValue[4]={-120,-43,27,98}; //0x 88 d5 1b 62 212 for (unsigned int i=0;i<axisNumber;i++) { 213 //We shift value to always be positive (so that division/multiplication by power of 2 can easily be done with bit shifts) 214 uint16_t shiftedNativeAxisValue=axis->Value(i,0)+(1<<(nativeBitsPerAxis-1)); 215 //int16_t nativeAxisValue=testValue[i]; 216 uint16_t scaledAxisValue; 217 if (bitsPerAxis>nativeBitsPerAxis) { 218 scaledAxisValue=shiftedNativeAxisValue<<(bitsPerAxis-nativeBitsPerAxis); 219 } else { 220 scaledAxisValue=shiftedNativeAxisValue>>(nativeBitsPerAxis-bitsPerAxis); 221 } 222 //Thread::Info("Debug: shiftedNativeAxisValue=%#x, scaled axis value=%#x\n",shiftedNativeAxisValue,scaledAxisValue); 223 unsigned int offsetInBits=i*bitsPerAxis; 224 writeBits(scaledAxisValue,bitsPerAxis,dataFrameBuffer,offsetInBits); 225 } 226 //Thread::Info("Buffer après: %x %x %x\n", dataFrameBuffer[0], dataFrameBuffer[1], dataFrameBuffer[2]); 227 228 int currentButton=0; 229 uint8_t buttonArray[buttonNumber/8]; 230 for (unsigned int i=0;i<buttonNumber/8;i++) { 231 buttonArray[i]=0; 232 for(unsigned int j=0;j<8;j++) { 233 bool buttonValue=button->Value(currentButton,0); 234 if(buttonValue) buttonArray[i]+=1<<j; 235 currentButton++; 236 } 237 238 dataSocket->HostToNetwork((char *)&buttonArray[i],sizeof(uint8_t)); 239 memcpy(dataFrameBuffer+buttonOffset+i*sizeof(uint8_t),&buttonArray[i],sizeof(uint8_t)); 240 } 241 } 242 243 HostEthController::DataSender::DataSender(Object *parent,HostEthController* _hostEthController,string name,uint8_t priority):Thread(parent,name,priority),hostEthController(_hostEthController) { 244 245 } 241 // int16_t testValue[4]={-120,-43,27,98}; //0x 88 d5 1b 62 242 for (unsigned int i = 0; i < axisNumber; i++) { 243 // We shift value to always be positive (so that division/multiplication by 244 // power of 2 can easily be done with bit shifts) 245 uint16_t shiftedNativeAxisValue = 246 axis->Value(i, 0) + (1 << (nativeBitsPerAxis - 1)); 247 // int16_t nativeAxisValue=testValue[i]; 248 uint16_t scaledAxisValue; 249 if (bitsPerAxis > nativeBitsPerAxis) { 250 scaledAxisValue = shiftedNativeAxisValue 251 << (bitsPerAxis - nativeBitsPerAxis); 252 } else { 253 scaledAxisValue = 254 shiftedNativeAxisValue >> (nativeBitsPerAxis - bitsPerAxis); 255 } 256 // Thread::Info("Debug: shiftedNativeAxisValue=%#x, scaled axis 257 // value=%#x\n",shiftedNativeAxisValue,scaledAxisValue); 258 unsigned int offsetInBits = i * bitsPerAxis; 259 writeBits(scaledAxisValue, bitsPerAxis, dataFrameBuffer, offsetInBits); 260 } 261 // Thread::Info("Buffer après: %x %x %x\n", dataFrameBuffer[0], 262 // dataFrameBuffer[1], dataFrameBuffer[2]); 263 264 int currentButton = 0; 265 uint8_t buttonArray[buttonNumber / 8]; 266 for (unsigned int i = 0; i < buttonNumber / 8; i++) { 267 buttonArray[i] = 0; 268 for (unsigned int j = 0; j < 8; j++) { 269 bool buttonValue = button->Value(currentButton, 0); 270 if (buttonValue) 271 buttonArray[i] += 1 << j; 272 currentButton++; 273 } 274 275 dataSocket->HostToNetwork((char *)&buttonArray[i], sizeof(uint8_t)); 276 memcpy(dataFrameBuffer + buttonOffset + i * sizeof(uint8_t), 277 &buttonArray[i], sizeof(uint8_t)); 278 } 279 } 280 281 HostEthController::DataSender::DataSender(Object *parent, 282 HostEthController *_hostEthController, 283 string name, uint8_t priority) 284 : Thread(parent, name, priority), hostEthController(_hostEthController) {} 246 285 247 286 void HostEthController::DataSender::Run() { 248 if(getFrameworkManager()->ErrorOccured()==true) { 249 SafeStop(); 250 } 251 252 while(!ToBeStopped()) { 253 WaitPeriod(); 254 if (hostEthController->meaningfulDataAvailable && hostEthController->ConnectedWithTarget()) { 255 //send the data 256 hostEthController->BuildDataFrame(); 257 hostEthController->dataSocket->SendMessage(hostEthController->dataFrameBuffer,hostEthController->dataFrameSize); 258 } 259 } 287 if (getFrameworkManager()->ErrorOccured() == true) { 288 SafeStop(); 289 } 290 291 while (!ToBeStopped()) { 292 WaitPeriod(); 293 if (hostEthController->meaningfulDataAvailable && 294 hostEthController->ConnectedWithTarget()) { 295 // send the data 296 hostEthController->BuildDataFrame(); 297 hostEthController->dataSocket->SendMessage( 298 hostEthController->dataFrameBuffer, hostEthController->dataFrameSize); 299 } 300 } 260 301 } 261 302 -
trunk/lib/FlairSensorActuator/src/HostEthController.h
r3 r15 11 11 // version: $Id: $ 12 12 // 13 // purpose: Base class for host side remote controls that talks to target side through ethernet connection 13 // purpose: Base class for host side remote controls that talks to target 14 // side through ethernet connection 14 15 // 15 16 // … … 24 25 25 26 namespace flair { 26 27 28 29 30 31 32 33 34 35 36 37 27 namespace core { 28 class FrameworkManager; 29 class cvmatrix; 30 class TcpSocket; 31 class Socket; 32 class Mutex; 33 } 34 namespace gui { 35 class Tab; 36 class TabWidget; 37 class DataPlot1D; 38 } 38 39 } 39 40 40 namespace flair { namespace sensor { 41 enum class ControllerAction; 41 namespace flair { 42 namespace sensor { 43 enum class ControllerAction; 42 44 43 /*! \class HostEthController 44 * 45 * \brief Base Class for host side remote controls that talks to target side through ethernet connection 46 * 47 * There are 2 communication channels: 48 * - 1 connection with the ground station to display the values. Output for analog sticks is normalized in the range [-1, 1] (float values) 49 * - 1 connection with the target to send the controller values (and receive controller state modification requests) 50 */ 51 class HostEthController : public core::Thread, public core::IODevice { 52 public: 53 HostEthController(const core::FrameworkManager* parent,std::string name,std::string address,int port,uint32_t period=10,uint32_t _bitsPerAxis=7,uint8_t priority=0); 54 ~HostEthController(); 55 void DrawUserInterface(); 56 protected: 57 std::string controllerName; 58 core::TcpSocket *controlSocket; //connection to the target 59 core::Socket *dataSocket; 60 std::string targetAddress; 61 int targetPort; 62 gui::Tab *tab; 63 gui::TabWidget *tabWidget; 64 virtual bool IsDataFrameReady() { return true;}; 65 virtual void CompleteDataFrameGrab() {}; 66 // int8_t *datas; 67 // uint8_t dataSize; 68 char *dataFrameBuffer; 69 size_t dataFrameSize; 70 virtual void ProcessMessage(core::Message *controllerAction) {}; 45 /*! \class HostEthController 46 * 47 * \brief Base Class for host side remote controls that talks to target side 48 *through ethernet connection 49 * 50 * There are 2 communication channels: 51 * - 1 connection with the ground station to display the values. Output for 52 *analog sticks is normalized in the range [-1, 1] (float values) 53 * - 1 connection with the target to send the controller values (and receive 54 *controller state modification requests) 55 */ 56 class HostEthController : public core::Thread, public core::IODevice { 57 public: 58 HostEthController(const core::FrameworkManager *parent, std::string name, 59 std::string address, int port, uint32_t period = 10, 60 uint32_t _bitsPerAxis = 7, uint8_t priority = 0); 61 ~HostEthController(); 62 void DrawUserInterface(); 71 63 72 virtual std::string GetAxisDescription(unsigned int axis); 73 virtual void GetAxisData()=0; //responsible for getting the axis data from the hardware 74 unsigned int axisNumber; 75 core::cvmatrix* axis; 76 gui::DataPlot1D **axisPlot; 77 uint32_t bitsPerAxis; 78 uint32_t nativeBitsPerAxis; 64 protected: 65 std::string controllerName; 66 core::TcpSocket *controlSocket; // connection to the target 67 core::Socket *dataSocket; 68 std::string targetAddress; 69 int targetPort; 70 gui::Tab *tab; 71 gui::TabWidget *tabWidget; 72 virtual bool IsDataFrameReady() { return true; }; 73 virtual void CompleteDataFrameGrab(){}; 74 // int8_t *datas; 75 // uint8_t dataSize; 76 char *dataFrameBuffer; 77 size_t dataFrameSize; 78 virtual void ProcessMessage(core::Message *controllerAction){}; 79 79 80 virtual std::string GetButtonDescription(unsigned int button); 81 virtual void GetButtonData()=0; //responsible for getting the button data from the hardware 82 unsigned int buttonNumber; 83 core::cvmatrix* button; 84 uint8_t buttonOffset; 85 bool meaningfulDataAvailable; 80 virtual std::string GetAxisDescription(unsigned int axis); 81 virtual void 82 GetAxisData() = 0; // responsible for getting the axis data from the hardware 83 unsigned int axisNumber; 84 core::cvmatrix *axis; 85 gui::DataPlot1D **axisPlot; 86 uint32_t bitsPerAxis; 87 uint32_t nativeBitsPerAxis; 86 88 87 private: 88 class DataSender : public core::Thread { 89 public: 90 DataSender(Object* parent,HostEthController* hostEthController,std::string name,uint8_t priority=0); 91 void Run(); 92 private: 93 HostEthController* hostEthController; 94 }; 95 DataSender *dataSender; 89 virtual std::string GetButtonDescription(unsigned int button); 90 virtual void GetButtonData() = 0; // responsible for getting the button data 91 // from the hardware 92 unsigned int buttonNumber; 93 core::cvmatrix *button; 94 uint8_t buttonOffset; 95 bool meaningfulDataAvailable; 96 96 97 bool ControllerInitialization(); 98 bool ConnectedWithTarget(); 99 void SendControllerInfo(); 100 void Run(); 101 void BuildDataFrame(); 102 bool writeBits(uint16_t value,uint8_t valueSizeInBits,char *buffer,uint8_t offsetInBits); 103 core::Mutex *connectionEstablishedMutex; 104 }; 97 private: 98 class DataSender : public core::Thread { 99 public: 100 DataSender(Object *parent, HostEthController *hostEthController, 101 std::string name, uint8_t priority = 0); 102 void Run(); 105 103 106 }} 104 private: 105 HostEthController *hostEthController; 106 }; 107 DataSender *dataSender; 108 109 bool ControllerInitialization(); 110 bool ConnectedWithTarget(); 111 void SendControllerInfo(); 112 void Run(); 113 void BuildDataFrame(); 114 bool writeBits(uint16_t value, uint8_t valueSizeInBits, char *buffer, 115 uint8_t offsetInBits); 116 core::Mutex *connectionEstablishedMutex; 117 }; 118 } 119 } 107 120 108 121 #endif // HOSTETHCONTROLLER_H -
trunk/lib/FlairSensorActuator/src/Imu.cpp
r3 r15 30 30 using namespace flair::gui; 31 31 32 namespace flair { namespace sensor { 32 namespace flair { 33 namespace sensor { 33 34 34 Imu::Imu(const FrameworkManager * parent,string name) : IODevice(parent,name) {35 imuData=new ImuData(this);35 Imu::Imu(const FrameworkManager *parent, string name) : IODevice(parent, name) { 36 imuData = new ImuData(this); 36 37 37 //station sol38 mainTab=new Tab(parent->GetTabWidget(),name);39 tab=new TabWidget(mainTab->NewRow(),name);40 sensorTab=new Tab(tab,"Reglages");41 setupGroupbox=new GroupBox(sensorTab->NewRow(),name);42 rotation=new OneAxisRotation(sensorTab->NewRow(),"post rotation");38 // station sol 39 mainTab = new Tab(parent->GetTabWidget(), name); 40 tab = new TabWidget(mainTab->NewRow(), name); 41 sensorTab = new Tab(tab, "Reglages"); 42 setupGroupbox = new GroupBox(sensorTab->NewRow(), name); 43 rotation = new OneAxisRotation(sensorTab->NewRow(), "post rotation"); 43 44 } 44 45 45 Imu::Imu(const IODevice * parent,std::string name) : IODevice(parent,name) {46 imuData=new ImuData(this);47 mainTab=NULL;48 tab=NULL;49 sensorTab=NULL;50 setupGroupbox=NULL;51 rotation=NULL;46 Imu::Imu(const IODevice *parent, std::string name) : IODevice(parent, name) { 47 imuData = new ImuData(this); 48 mainTab = NULL; 49 tab = NULL; 50 sensorTab = NULL; 51 setupGroupbox = NULL; 52 rotation = NULL; 52 53 } 53 54 54 55 Imu::~Imu() { 55 if(mainTab!=NULL) delete mainTab; 56 if (mainTab != NULL) 57 delete mainTab; 56 58 } 57 59 58 void Imu::GetDatas(ImuData **outImuData) const { 59 *outImuData=imuData; 60 } 60 void Imu::GetDatas(ImuData **outImuData) const { *outImuData = imuData; } 61 61 void Imu::UpdateImu() { 62 if(rotation==NULL) {63 64 65 66 Vector3D rawAcc,rawMag,rawGyr;67 imuData->GetRawAccMagAndGyr(rawAcc,rawMag,rawGyr);68 69 70 71 imuData->SetRawAccMagAndGyr(rawAcc,rawMag,rawGyr);62 if (rotation == NULL) { 63 Err("not applicable for simulation part.\n"); 64 return; 65 } 66 Vector3D rawAcc, rawMag, rawGyr; 67 imuData->GetRawAccMagAndGyr(rawAcc, rawMag, rawGyr); 68 rotation->ComputeRotation(rawAcc); 69 rotation->ComputeRotation(rawGyr); 70 rotation->ComputeRotation(rawMag); 71 imuData->SetRawAccMagAndGyr(rawAcc, rawMag, rawGyr); 72 72 } 73 73 74 GroupBox* Imu::GetGroupBox(void) const { 75 return setupGroupbox; 76 } 74 GroupBox *Imu::GetGroupBox(void) const { return setupGroupbox; } 77 75 78 Layout* Imu::GetLayout(void) const { 79 return sensorTab; 80 } 76 Layout *Imu::GetLayout(void) const { return sensorTab; } 81 77 82 78 void Imu::LockUserInterface(void) const { 83 if(sensorTab==NULL) {84 85 86 87 79 if (sensorTab == NULL) { 80 Err("not applicable for simulation part.\n"); 81 return; 82 } 83 sensorTab->setEnabled(false); 88 84 } 89 85 90 86 void Imu::UnlockUserInterface(void) const { 91 if(sensorTab==NULL) {92 93 94 95 87 if (sensorTab == NULL) { 88 Err("not applicable for simulation part.\n"); 89 return; 90 } 91 sensorTab->setEnabled(true); 96 92 } 97 93 98 94 void Imu::UseDefaultPlot(void) { 99 if(tab==NULL) {100 101 102 95 if (tab == NULL) { 96 Err("not applicable for simulation part.\n"); 97 return; 98 } 103 99 104 plotTab=new Tab(tab,"IMU");105 axPlot=new DataPlot1D(plotTab->NewRow(),"acc_x",-10,10);106 107 ayPlot=new DataPlot1D(plotTab->LastRowLastCol(),"acc_y",-10,10);108 109 azPlot=new DataPlot1D(plotTab->LastRowLastCol(),"acc_z",-10,10);110 100 plotTab = new Tab(tab, "IMU"); 101 axPlot = new DataPlot1D(plotTab->NewRow(), "acc_x", -10, 10); 102 axPlot->AddCurve(imuData->Element(ImuData::RawAx)); 103 ayPlot = new DataPlot1D(plotTab->LastRowLastCol(), "acc_y", -10, 10); 104 ayPlot->AddCurve(imuData->Element(ImuData::RawAy)); 105 azPlot = new DataPlot1D(plotTab->LastRowLastCol(), "acc_z", -10, 10); 106 azPlot->AddCurve(imuData->Element(ImuData::RawAz)); 111 107 112 if(plotTab==NULL) plotTab=new Tab(tab,"IMU"); 113 gxPlot=new DataPlot1D(plotTab->NewRow(),"gyr_x",-500,500); 114 gxPlot->AddCurve(imuData->Element(ImuData::RawGxDeg)); 115 gyPlot=new DataPlot1D(plotTab->LastRowLastCol(),"gyr_y",-500,500); 116 gyPlot->AddCurve(imuData->Element(ImuData::RawGyDeg)); 117 gzPlot=new DataPlot1D(plotTab->LastRowLastCol(),"gyr_z",-500,500); 118 gzPlot->AddCurve(imuData->Element(ImuData::RawGzDeg)); 108 if (plotTab == NULL) 109 plotTab = new Tab(tab, "IMU"); 110 gxPlot = new DataPlot1D(plotTab->NewRow(), "gyr_x", -500, 500); 111 gxPlot->AddCurve(imuData->Element(ImuData::RawGxDeg)); 112 gyPlot = new DataPlot1D(plotTab->LastRowLastCol(), "gyr_y", -500, 500); 113 gyPlot->AddCurve(imuData->Element(ImuData::RawGyDeg)); 114 gzPlot = new DataPlot1D(plotTab->LastRowLastCol(), "gyr_z", -500, 500); 115 gzPlot->AddCurve(imuData->Element(ImuData::RawGzDeg)); 119 116 120 if(plotTab==NULL) plotTab=new Tab(tab,"IMU"); 121 mxPlot=new DataPlot1D(plotTab->NewRow(),"mag_x",-500,500); 122 mxPlot->AddCurve(imuData->Element(ImuData::RawMx)); 123 myPlot=new DataPlot1D(plotTab->LastRowLastCol(),"mag_y",-500,500); 124 myPlot->AddCurve(imuData->Element(ImuData::RawMy)); 125 mzPlot=new DataPlot1D(plotTab->LastRowLastCol(),"mag_z",-500,500); 126 mzPlot->AddCurve(imuData->Element(ImuData::RawMz)); 117 if (plotTab == NULL) 118 plotTab = new Tab(tab, "IMU"); 119 mxPlot = new DataPlot1D(plotTab->NewRow(), "mag_x", -500, 500); 120 mxPlot->AddCurve(imuData->Element(ImuData::RawMx)); 121 myPlot = new DataPlot1D(plotTab->LastRowLastCol(), "mag_y", -500, 500); 122 myPlot->AddCurve(imuData->Element(ImuData::RawMy)); 123 mzPlot = new DataPlot1D(plotTab->LastRowLastCol(), "mag_z", -500, 500); 124 mzPlot->AddCurve(imuData->Element(ImuData::RawMz)); 127 125 } 128 126 129 Tab* Imu::GetPlotTab(void) const { 130 return plotTab; 131 } 127 Tab *Imu::GetPlotTab(void) const { return plotTab; } 132 128 133 129 } // end namespace sensor -
trunk/lib/FlairSensorActuator/src/Imu.h
r3 r15 17 17 18 18 namespace flair { 19 20 21 22 23 24 25 26 27 28 29 19 namespace core { 20 class ImuData; 21 class OneAxisRotation; 22 } 23 namespace gui { 24 class Tab; 25 class TabWidget; 26 class GroupBox; 27 class Layout; 28 class DataPlot1D; 29 } 30 30 } 31 31 32 32 class Ahrs_impl; 33 33 34 namespace flair { namespace sensor { 35 /*! \class Imu 36 * 37 * \brief Base class for Imu 38 * 39 * Use this class to define a custom Imu. 40 * 41 */ 42 class Imu : public core::IODevice { 43 friend class ::Ahrs_impl; 34 namespace flair { 35 namespace sensor { 36 /*! \class Imu 37 * 38 * \brief Base class for Imu 39 * 40 * Use this class to define a custom Imu. 41 * 42 */ 43 class Imu : public core::IODevice { 44 friend class ::Ahrs_impl; 44 45 45 46 47 48 49 50 51 52 53 54 Imu(const core::FrameworkManager *parent,std::string name);46 public: 47 /*! 48 * \brief Constructor 49 * 50 * Construct an Imu. 51 * 52 * \param parent parent 53 * \param name name 54 */ 55 Imu(const core::FrameworkManager *parent, std::string name); 55 56 56 57 58 59 60 61 62 63 64 65 Imu(const core::IODevice *parent,std::string name);57 /*! 58 * \brief Constructor 59 * 60 * Construct an Imu. \n 61 * This contructor must only be called for a simulated device. 62 * 63 * \param parent parent 64 * \param name name 65 */ 66 Imu(const core::IODevice *parent, std::string name); 66 67 67 68 69 70 71 68 /*! 69 * \brief Destructor 70 * 71 */ 72 ~Imu(); 72 73 73 74 75 76 77 78 74 /*! 75 * \brief Setup Layout 76 * 77 * \return setup Layout 78 */ 79 gui::Layout *GetLayout(void) const; 79 80 80 81 82 83 84 81 /*! 82 * \brief Lock user interface 83 * 84 */ 85 void LockUserInterface(void) const; 85 86 86 87 88 89 90 87 /*! 88 * \brief Unlock user interface 89 * 90 */ 91 void UnlockUserInterface(void) const; 91 92 92 93 94 95 96 93 /*! 94 * \brief Use default plot 95 * 96 */ 97 void UseDefaultPlot(void); 97 98 98 99 100 101 102 103 99 /*! 100 * \brief Plot tab 101 * 102 * \return plot Tab 103 */ 104 gui::Tab *GetPlotTab(void) const; 104 105 105 106 107 108 109 110 111 106 protected: 107 /*! 108 * \brief Setup GroupBox 109 * 110 * \return setup GroupBox 111 */ 112 gui::GroupBox *GetGroupBox(void) const; 112 113 113 /*! 114 * \brief UpdateImu 115 * 116 * The reimplemented class must call this function as soon as IMU datas are available. \n 117 * It handles the data rotation if it was defined. 118 * 119 */ 120 void UpdateImu(); 114 /*! 115 * \brief UpdateImu 116 * 117 * The reimplemented class must call this function as soon as IMU datas are 118 *available. \n 119 * It handles the data rotation if it was defined. 120 * 121 */ 122 void UpdateImu(); 121 123 122 123 124 125 126 127 124 /*! 125 * \brief Get imu datas 126 * 127 * \param imuData imu datas 128 */ 129 void GetDatas(core::ImuData **imuData) const; 128 130 131 private: 132 gui::Tab *mainTab, *sensorTab, *plotTab; 133 gui::TabWidget *tab; 134 gui::GroupBox *setupGroupbox; 135 core::OneAxisRotation *rotation; 136 core::ImuData *imuData; 129 137 130 private: 131 gui::Tab *mainTab,*sensorTab,*plotTab; 132 gui::TabWidget* tab; 133 gui::GroupBox *setupGroupbox; 134 core::OneAxisRotation* rotation; 135 core::ImuData *imuData; 136 137 gui::DataPlot1D *axPlot,*ayPlot,*azPlot; 138 gui::DataPlot1D *gxPlot,*gyPlot,*gzPlot; 139 gui::DataPlot1D *mxPlot,*myPlot,*mzPlot; 140 }; 138 gui::DataPlot1D *axPlot, *ayPlot, *azPlot; 139 gui::DataPlot1D *gxPlot, *gyPlot, *gzPlot; 140 gui::DataPlot1D *mxPlot, *myPlot, *mzPlot; 141 }; 141 142 } // end namespace sensor 142 143 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/LaserRangeFinder.cpp
r3 r15 32 32 using namespace flair::gui; 33 33 34 namespace flair { namespace sensor { 34 namespace flair { 35 namespace sensor { 35 36 36 LaserRangeFinder::LaserRangeFinder(const FrameworkManager* parent,string name) : IODevice(parent,name) { 37 cvmatrix_descriptor* desc=new cvmatrix_descriptor(360,1); 38 output=new cvmatrix(this,desc,floatType); 39 AddDataToLog(output); 37 LaserRangeFinder::LaserRangeFinder(const FrameworkManager *parent, string name) 38 : IODevice(parent, name) { 39 cvmatrix_descriptor *desc = new cvmatrix_descriptor(360, 1); 40 output = new cvmatrix(this, desc, floatType); 41 AddDataToLog(output); 40 42 41 //station sol 42 main_tab=new Tab(parent->GetTabWidget(),name); 43 tab=new TabWidget(main_tab->NewRow(),name); 44 sensor_tab=new Tab(tab,"Reglages"); 45 setup_groupbox=new GroupBox(sensor_tab->NewRow(),name); 46 43 // station sol 44 main_tab = new Tab(parent->GetTabWidget(), name); 45 tab = new TabWidget(main_tab->NewRow(), name); 46 sensor_tab = new Tab(tab, "Reglages"); 47 setup_groupbox = new GroupBox(sensor_tab->NewRow(), name); 47 48 } 48 49 49 LaserRangeFinder::LaserRangeFinder(const IODevice * parent,std::string name) : IODevice(parent,name)50 {51 plot_tab=NULL;52 main_tab=NULL;53 tab=NULL;54 sensor_tab=NULL;55 setup_groupbox=NULL;50 LaserRangeFinder::LaserRangeFinder(const IODevice *parent, std::string name) 51 : IODevice(parent, name) { 52 plot_tab = NULL; 53 main_tab = NULL; 54 tab = NULL; 55 sensor_tab = NULL; 56 setup_groupbox = NULL; 56 57 57 output=NULL;58 output = NULL; 58 59 } 59 60 60 LaserRangeFinder::~LaserRangeFinder() 61 { 61 LaserRangeFinder::~LaserRangeFinder() {} 62 62 63 }63 GroupBox *LaserRangeFinder::GetGroupBox(void) const { return setup_groupbox; } 64 64 65 Layout *LaserRangeFinder::GetLayout(void) const { return sensor_tab; } 65 66 66 GroupBox* LaserRangeFinder::GetGroupBox(void) const 67 { 68 return setup_groupbox; 69 } 67 RangeFinderPlot *LaserRangeFinder::GetPlot(void) const { return plot; } 70 68 71 Layout* LaserRangeFinder::GetLayout(void) const 72 { 73 return sensor_tab; 74 } 69 void LaserRangeFinder::UseDefaultPlot(void) { 70 if (tab == NULL) { 71 Err("not applicable for simulation part.\n"); 72 return; 73 } 75 74 76 77 RangeFinderPlot* LaserRangeFinder::GetPlot(void) const 78 { 79 return plot; 80 } 81 82 void LaserRangeFinder::UseDefaultPlot(void) 83 { 84 if(tab==NULL) 85 { 86 Err("not applicable for simulation part.\n"); 87 return; 88 } 89 90 plot_tab=new Tab(tab,"Mesures"); 91 plot=new RangeFinderPlot(plot_tab->NewRow(),"plot","x",-30,30,"y",-30,30,output,0,359,output->Rows()); 75 plot_tab = new Tab(tab, "Mesures"); 76 plot = new RangeFinderPlot(plot_tab->NewRow(), "plot", "x", -30, 30, "y", -30, 77 30, output, 0, 359, output->Rows()); 92 78 } 93 79 } // end namespace sensor -
trunk/lib/FlairSensorActuator/src/LaserRangeFinder.h
r3 r15 16 16 #include <IODevice.h> 17 17 18 namespace flair 19 { 20 namespace core 21 { 22 class FrameworkManager; 23 class cvmatrix; 24 25 } 26 namespace gui 27 { 28 class Tab; 29 class TabWidget; 30 class GroupBox; 31 class Layout; 32 class RangeFinderPlot; 33 } 18 namespace flair { 19 namespace core { 20 class FrameworkManager; 21 class cvmatrix; 22 } 23 namespace gui { 24 class Tab; 25 class TabWidget; 26 class GroupBox; 27 class Layout; 28 class RangeFinderPlot; 29 } 34 30 } 35 31 36 namespace flair 37 { 38 namespace sensor 39 { 40 /*! \class LaserRangeFinder 41 * 42 * \brief Classe generique intégrant les telemetres laser 43 */ 44 class LaserRangeFinder : public core::IODevice 45 { 46 public: 47 /*! 48 * \brief Constructor 49 * 50 * Construct a Laser Range Finder. 51 * 52 * \param parent parent 53 * \param name name 54 */ 55 LaserRangeFinder(const core::FrameworkManager* parent,std::string name); 56 /*! 57 * \brief Constructor 58 * 59 * Construct a UsRangeFinder. Simulation part. 60 * 61 * \param parent parent 62 * \param name name 63 */ 64 LaserRangeFinder(const core::IODevice* parent,std::string name); 65 /*! 66 * \brief Destructor 67 * 68 */ 69 ~LaserRangeFinder(); 32 namespace flair { 33 namespace sensor { 34 /*! \class LaserRangeFinder 35 * 36 * \brief Classe generique intégrant les telemetres laser 37 */ 38 class LaserRangeFinder : public core::IODevice { 39 public: 40 /*! 41 * \brief Constructor 42 * 43 * Construct a Laser Range Finder. 44 * 45 * \param parent parent 46 * \param name name 47 */ 48 LaserRangeFinder(const core::FrameworkManager *parent, std::string name); 49 /*! 50 * \brief Constructor 51 * 52 * Construct a UsRangeFinder. Simulation part. 53 * 54 * \param parent parent 55 * \param name name 56 */ 57 LaserRangeFinder(const core::IODevice *parent, std::string name); 58 /*! 59 * \brief Destructor 60 * 61 */ 62 ~LaserRangeFinder(); 70 63 71 72 73 74 75 64 /*! 65 * \brief Use default plot 66 * 67 */ 68 void UseDefaultPlot(void); 76 69 77 78 79 80 81 82 gui::RangeFinderPlot*GetPlot(void) const;70 /*! 71 * \brief Plot 72 * 73 * \return DataPlot1D 74 */ 75 gui::RangeFinderPlot *GetPlot(void) const; 83 76 84 85 86 87 88 89 gui::Layout*GetLayout(void) const;77 /*! 78 * \brief Setup Layout 79 * 80 * \return a Layout available 81 */ 82 gui::Layout *GetLayout(void) const; 90 83 91 92 93 94 95 96 gui::Tab*GetPlotTab(void) const;84 /*! 85 * \brief Plot tab 86 * 87 * \return plot Tab 88 */ 89 gui::Tab *GetPlotTab(void) const; 97 90 98 99 100 101 102 103 91 /*! 92 * \brief Value 93 * 94 * \return output value 95 */ 96 float Value(void) const; 104 97 105 106 107 108 109 110 111 98 protected: 99 /*! 100 * \brief Output matrix 101 * 102 * \return output matrix 103 */ 104 core::cvmatrix *output; 112 105 113 114 115 116 117 118 gui::GroupBox*GetGroupBox(void) const;106 /*! 107 * \brief Setup GroupBox 108 * 109 * \return a GroupBox available 110 */ 111 gui::GroupBox *GetGroupBox(void) const; 119 112 120 121 122 123 124 125 126 127 128 113 private: 114 /*! 115 * \brief Update using provided datas 116 * 117 * Reimplemented from IODevice. 118 * 119 * \param data data from the parent to process 120 */ 121 void UpdateFrom(const core::io_data *data){}; 129 122 130 gui::Tab* main_tab; 131 gui::TabWidget *tab; 132 gui::GroupBox* setup_groupbox; 133 gui::Tab* sensor_tab; 134 gui::RangeFinderPlot* plot; 135 gui::Tab* plot_tab; 136 137 }; 123 gui::Tab *main_tab; 124 gui::TabWidget *tab; 125 gui::GroupBox *setup_groupbox; 126 gui::Tab *sensor_tab; 127 gui::RangeFinderPlot *plot; 128 gui::Tab *plot_tab; 129 }; 138 130 } // end namespace sensor 139 131 } // end namespace framewor -
trunk/lib/FlairSensorActuator/src/Mb800.cpp
r3 r15 24 24 using namespace flair::core; 25 25 26 namespace flair 27 { 28 namespace sensor 29 { 26 namespace flair { 27 namespace sensor { 30 28 31 Mb800::Mb800(const FrameworkManager* parent,string name,SerialPort *serialport,Gps::NMEAFlags_t NMEAFlags,uint8_t priority) : Gps(parent,name,NMEAFlags), Thread(parent,name,priority) 32 { 33 this->serialport=serialport; 34 serialport->SetRxTimeout(100000000); 29 Mb800::Mb800(const FrameworkManager *parent, string name, 30 SerialPort *serialport, Gps::NMEAFlags_t NMEAFlags, 31 uint8_t priority) 32 : Gps(parent, name, NMEAFlags), Thread(parent, name, priority) { 33 this->serialport = serialport; 34 serialport->SetRxTimeout(100000000); 35 35 } 36 36 37 Mb800::~Mb800() 38 { 39 SafeStop(); 40 Join(); 37 Mb800::~Mb800() { 38 SafeStop(); 39 Join(); 41 40 } 42 41 43 void Mb800::Run(void) 44 { 45 /** Debut init **/ 46 char response[200] = {0}; 47 int size; 42 void Mb800::Run(void) { 43 /** Debut init **/ 44 char response[200] = {0}; 45 int size; 48 46 49 47 /** Fin init **/ 50 48 51 /** Debut config **/ 52 char to_send[]="$PASHS,NME,ALL,A,OFF\r\n"; 49 /** Debut config **/ 50 char to_send[] = "$PASHS,NME,ALL,A,OFF\r\n"; 51 serialport->Write(to_send, sizeof(to_send)); 52 53 { 54 char to_send[] = "$PASHS,CPD,AFP,95.0\r\n"; 53 55 serialport->Write(to_send, sizeof(to_send)); 56 } 57 { 58 char to_send[] = "$PASHS,DIF,PRT,C,RT3\r\n"; 59 serialport->Write(to_send, sizeof(to_send)); 60 } 54 61 55 { 56 char to_send[]="$PASHS,CPD,AFP,95.0\r\n"; 57 serialport->Write(to_send, sizeof(to_send)); 62 if ((NMEAFlags & GGA) != 0) { 63 char to_send[] = "$PASHS,NME,GGA,A,ON,0.05\r\n"; 64 size = serialport->Write(to_send, sizeof(to_send)); 65 // Printf("ecrit %i\n",size); 66 } 67 if ((NMEAFlags & VTG) != 0) { 68 char to_send[] = "$PASHS,NME,VTG,A,ON,0.05\r\n"; 69 size = serialport->Write(to_send, sizeof(to_send)); 70 // Printf("%i\n",size); 71 } 72 if ((NMEAFlags & GST) != 0) { 73 char to_send[] = "$PASHS,NME,GST,A,ON,0.05\r\n"; 74 size = serialport->Write(to_send, sizeof(to_send)); 75 // Printf("%i\n",size); 76 } 77 78 Sync(); 79 80 /** Fin config **/ 81 82 /** Debut running loop **/ 83 WarnUponSwitches(true); 84 85 while (!ToBeStopped()) { 86 SleepMS(10); 87 size = 0; 88 while (!ToBeStopped()) { 89 ssize_t read = serialport->Read(&response[size], 1); 90 if (read < 0) { 91 Thread::Err("erreur Read (%s)\n", strerror(-read)); 92 } 93 94 if (response[size] == 0x0a) 95 break; 96 size++; 58 97 } 59 { 60 char to_send[]="$PASHS,DIF,PRT,C,RT3\r\n"; 61 serialport->Write(to_send, sizeof(to_send)); 62 } 63 64 if((NMEAFlags&GGA)!=0) 65 { 66 char to_send[]="$PASHS,NME,GGA,A,ON,0.05\r\n"; 67 size=serialport->Write(to_send, sizeof(to_send)); 68 //Printf("ecrit %i\n",size); 69 } 70 if((NMEAFlags&VTG)!=0) 71 { 72 char to_send[]="$PASHS,NME,VTG,A,ON,0.05\r\n"; 73 size=serialport->Write(to_send, sizeof(to_send)); 74 //Printf("%i\n",size); 75 } 76 if((NMEAFlags&GST)!=0) 77 { 78 char to_send[]="$PASHS,NME,GST,A,ON,0.05\r\n"; 79 size=serialport->Write(to_send, sizeof(to_send)); 80 //Printf("%i\n",size); 81 } 82 83 Sync(); 84 85 /** Fin config **/ 86 87 /** Debut running loop **/ 88 WarnUponSwitches(true); 89 90 while(!ToBeStopped()) 91 { 92 SleepMS(10); 93 size=0; 94 while(!ToBeStopped()) 95 { 96 ssize_t read = serialport->Read(&response[size],1); 97 if(read<0) 98 { 99 Thread::Err("erreur Read (%s)\n",strerror(-read)); 100 } 101 102 if(response[size]==0x0a) break; 103 size++; 104 } 105 size++; 106 parseFrame(response, size); 107 } 108 /** fin running loop **/ 109 WarnUponSwitches(false); 98 size++; 99 parseFrame(response, size); 100 } 101 /** fin running loop **/ 102 WarnUponSwitches(false); 110 103 } 111 104 112 void Mb800::Sync(void) 113 { 114 char data=0; 115 ssize_t read = 0; 105 void Mb800::Sync(void) { 106 char data = 0; 107 ssize_t read = 0; 116 108 117 //attente fin trame 118 while(data!=0x0a) 119 { 120 read = serialport->Read(&data,1); 121 if(read<0) 122 { 123 Thread::Err("erreur Read (%s)\n",strerror(-read)); 124 } 109 // attente fin trame 110 while (data != 0x0a) { 111 read = serialport->Read(&data, 1); 112 if (read < 0) { 113 Thread::Err("erreur Read (%s)\n", strerror(-read)); 125 114 } 115 } 126 116 } 127 117 -
trunk/lib/FlairSensorActuator/src/Mb800.h
r3 r15 17 17 #include <Gps.h> 18 18 19 namespace flair 20 { 21 namespace core 22 { 23 class FrameworkManager; 24 class SerialPort; 25 } 19 namespace flair { 20 namespace core { 21 class FrameworkManager; 22 class SerialPort; 23 } 26 24 } 27 25 28 namespace flair 29 { 30 namespace sensor 31 { 32 /*! \class Mb800 33 * 34 * \brief Class for mb800 gps receiver 35 */ 36 class Mb800 : public core::Thread, public Gps 37 { 38 public: 39 /*! 40 * \brief Constructor 41 * 42 * Construct a Mb800. 43 * 44 * \param parent parent 45 * \param name name 46 * \param serialport serialport 47 * \param NMEAFlags NMEA sentances to enable 48 * \param priority priority of the Thread 49 */ 50 Mb800(const core::FrameworkManager* parent,std::string name,core::SerialPort *serialport,Gps::NMEAFlags_t NMEAFlags,uint8_t priority); 26 namespace flair { 27 namespace sensor { 28 /*! \class Mb800 29 * 30 * \brief Class for mb800 gps receiver 31 */ 32 class Mb800 : public core::Thread, public Gps { 33 public: 34 /*! 35 * \brief Constructor 36 * 37 * Construct a Mb800. 38 * 39 * \param parent parent 40 * \param name name 41 * \param serialport serialport 42 * \param NMEAFlags NMEA sentances to enable 43 * \param priority priority of the Thread 44 */ 45 Mb800(const core::FrameworkManager *parent, std::string name, 46 core::SerialPort *serialport, Gps::NMEAFlags_t NMEAFlags, 47 uint8_t priority); 51 48 52 53 54 55 56 49 /*! 50 * \brief Destructor 51 * 52 */ 53 ~Mb800(); 57 54 58 59 60 61 62 63 64 65 66 55 private: 56 /*! 57 * \brief Update using provided datas 58 * 59 * Reimplemented from IODevice. 60 * 61 * \param data data from the parent to process 62 */ 63 void UpdateFrom(const core::io_data *data){}; 67 64 68 69 70 71 72 73 74 65 /*! 66 * \brief Run function 67 * 68 * Reimplemented from Thread. 69 * 70 */ 71 void Run(void); 75 72 76 77 78 73 void Sync(void); 74 core::SerialPort *serialport; 75 }; 79 76 } // end namespace sensor 80 77 } // end namespace framewor -
trunk/lib/FlairSensorActuator/src/Novatel.cpp
r3 r15 24 24 using namespace flair::core; 25 25 26 namespace flair 27 { 28 namespace sensor 29 { 26 namespace flair { 27 namespace sensor { 30 28 31 Novatel::Novatel(const FrameworkManager* parent,string name,SerialPort *serialport,Gps::NMEAFlags_t NMEAFlags,uint8_t priority) : Gps(parent,name,NMEAFlags), Thread(parent,name,priority) 32 { 33 this->serialport=serialport; 29 Novatel::Novatel(const FrameworkManager *parent, string name, 30 SerialPort *serialport, Gps::NMEAFlags_t NMEAFlags, 31 uint8_t priority) 32 : Gps(parent, name, NMEAFlags), Thread(parent, name, priority) { 33 this->serialport = serialport; 34 34 } 35 35 36 Novatel::~Novatel() 37 { 38 SafeStop(); 39 Join(); 36 Novatel::~Novatel() { 37 SafeStop(); 38 Join(); 40 39 } 41 40 42 void Novatel::Run(void) 43 { 44 char response[200] = {0}; 45 int size; 46 ssize_t written; 41 void Novatel::Run(void) { 42 char response[200] = {0}; 43 int size; 44 ssize_t written; 47 45 48 46 WarnUponSwitches(true); 49 47 50 char to_send[]="log gpggalong ontime 0.05\n"; 51 written=serialport->Write(to_send, sizeof(to_send)); 52 if(written<0) 53 { 54 Thread::Err("erreur write (%s)\n",strerror(-written)); 48 char to_send[] = "log gpggalong ontime 0.05\n"; 49 written = serialport->Write(to_send, sizeof(to_send)); 50 if (written < 0) { 51 Thread::Err("erreur write (%s)\n", strerror(-written)); 52 } 53 char to_send2[] = "log gpvtg ontime 0.05\n"; 54 written = serialport->Write(to_send2, sizeof(to_send2)); 55 if (written < 0) { 56 Thread::Err("erreur write (%s)\n", strerror(-written)); 57 } 58 59 Sync(); 60 61 while (!ToBeStopped()) { 62 size = 0; 63 while (1) { 64 // ssize_t read = rt_dev_read(uart_fd, &response[size],1); 65 ssize_t Read = serialport->Read(&response[size], 1); 66 if (Read < 0) { 67 Thread::Err("erreur Read (%s)\n", strerror(-Read)); 68 } 69 if (response[size] == 0x0a) 70 break; 71 size++; 55 72 } 56 char to_send2[]="log gpvtg ontime 0.05\n"; 57 written=serialport->Write(to_send2, sizeof(to_send2)); 58 if(written<0) 59 { 60 Thread::Err("erreur write (%s)\n",strerror(-written)); 61 } 73 size++; 74 parseFrame(response, size); 75 } 62 76 63 Sync(); 64 65 while(!ToBeStopped()) 66 { 67 size=0; 68 while(1) 69 { 70 //ssize_t read = rt_dev_read(uart_fd, &response[size],1); 71 ssize_t Read = serialport->Read(&response[size],1); 72 if(Read<0) 73 { 74 Thread::Err("erreur Read (%s)\n",strerror(-Read)); 75 } 76 if(response[size]==0x0a) break; 77 size++; 78 } 79 size++; 80 parseFrame(response, size); 81 } 82 83 WarnUponSwitches(false); 77 WarnUponSwitches(false); 84 78 } 85 79 86 void Novatel::Sync(void) 87 { 88 char data=0; 89 ssize_t Read = 0; 80 void Novatel::Sync(void) { 81 char data = 0; 82 ssize_t Read = 0; 90 83 91 //attente fin trame 92 while(data!=0x0a) 93 { 94 Read = serialport->Read(&data,1); 95 if(Read<0) 96 { 97 Thread::Err("erreur Read (%s)\n",strerror(-Read)); 98 } 84 // attente fin trame 85 while (data != 0x0a) { 86 Read = serialport->Read(&data, 1); 87 if (Read < 0) { 88 Thread::Err("erreur Read (%s)\n", strerror(-Read)); 99 89 } 90 } 100 91 } 101 92 -
trunk/lib/FlairSensorActuator/src/Novatel.h
r3 r15 17 17 #include <Gps.h> 18 18 19 namespace flair 20 { 21 namespace core 22 { 23 class FrameworkManager; 24 class SerialPort; 25 } 19 namespace flair { 20 namespace core { 21 class FrameworkManager; 22 class SerialPort; 23 } 26 24 } 27 25 28 namespace flair 29 { 30 namespace sensor 31 { 32 /*! \class Novatel 33 * 34 * \brief Class for Novatel gps receiver 35 */ 36 class Novatel : public core::Thread, public Gps 37 { 38 public: 39 /*! 40 * \brief Constructor 41 * 42 * Construct a Novatel. 43 * 44 * \param parent parent 45 * \param name name 46 * \param serialport serialport 47 * \param NMEAFlags NMEA sentances to enable 48 * \param priority priority of the Thread 49 */ 50 Novatel(const core::FrameworkManager* parent,std::string name,core::SerialPort *serialport,Gps::NMEAFlags_t NMEAFlags,uint8_t priority); 26 namespace flair { 27 namespace sensor { 28 /*! \class Novatel 29 * 30 * \brief Class for Novatel gps receiver 31 */ 32 class Novatel : public core::Thread, public Gps { 33 public: 34 /*! 35 * \brief Constructor 36 * 37 * Construct a Novatel. 38 * 39 * \param parent parent 40 * \param name name 41 * \param serialport serialport 42 * \param NMEAFlags NMEA sentances to enable 43 * \param priority priority of the Thread 44 */ 45 Novatel(const core::FrameworkManager *parent, std::string name, 46 core::SerialPort *serialport, Gps::NMEAFlags_t NMEAFlags, 47 uint8_t priority); 51 48 52 53 54 55 56 49 /*! 50 * \brief Destructor 51 * 52 */ 53 ~Novatel(); 57 54 58 59 60 61 62 63 64 65 66 55 private: 56 /*! 57 * \brief Update using provided datas 58 * 59 * Reimplemented from IODevice. 60 * 61 * \param data data from the parent to process 62 */ 63 void UpdateFrom(const core::io_data *data){}; 67 64 68 69 70 71 72 73 74 65 /*! 66 * \brief Run function 67 * 68 * Reimplemented from Thread. 69 * 70 */ 71 void Run(void); 75 72 76 77 78 73 core::SerialPort *serialport; 74 void Sync(void); 75 }; 79 76 } // end namespace sensor 80 77 } // end namespace framewor -
trunk/lib/FlairSensorActuator/src/Ps3Eye.cpp
r3 r15 29 29 using namespace flair::gui; 30 30 31 namespace flair 32 { 33 namespace sensor 34 { 31 namespace flair { 32 namespace sensor { 35 33 36 Ps3Eye::Ps3Eye(const FrameworkManager* parent,string name,int camera_index,uint8_t priority) 37 : V4LCamera(parent,name,camera_index,320,240,cvimage::Type::Format::YUYV,priority) { 34 Ps3Eye::Ps3Eye(const FrameworkManager *parent, string name, int camera_index, 35 uint8_t priority) 36 : V4LCamera(parent, name, camera_index, 320, 240, 37 cvimage::Type::Format::YUYV, priority) {} 38 38 39 } 40 41 Ps3Eye::~Ps3Eye() { 42 } 39 Ps3Eye::~Ps3Eye() {} 43 40 44 41 } // end namespace sensor -
trunk/lib/FlairSensorActuator/src/Ps3Eye.h
r3 r15 16 16 #include "V4LCamera.h" 17 17 18 namespace flair 19 { 20 namespace core 21 { 22 class cvimage; 23 class FrameworkManager; 24 } 25 namespace gui 26 { 27 class GridLayout; 28 class DoubleSpinBox; 29 class CheckBox; 30 } 18 namespace flair { 19 namespace core { 20 class cvimage; 21 class FrameworkManager; 22 } 23 namespace gui { 24 class GridLayout; 25 class DoubleSpinBox; 26 class CheckBox; 27 } 31 28 } 32 29 33 namespace flair 34 { 35 namespace sensor 36 { 37 /*! \class Ps3Eye 38 * 39 * \brief Class for Ps3Eye camera 40 */ 41 class Ps3Eye : public V4LCamera 42 { 30 namespace flair { 31 namespace sensor { 32 /*! \class Ps3Eye 33 * 34 * \brief Class for Ps3Eye camera 35 */ 36 class Ps3Eye : public V4LCamera { 43 37 44 public: 45 /*! 46 * \brief Constructor 47 * 48 * Construct a Ps3Eye. 49 * 50 * \param parent parent 51 * \param name name 52 * \param camera_index index of the camera, ie /dev/videox 53 * \param priority priority of the Thread 54 */ 55 Ps3Eye(const core::FrameworkManager* parent,std::string name,int camera_index,uint8_t priority); 38 public: 39 /*! 40 * \brief Constructor 41 * 42 * Construct a Ps3Eye. 43 * 44 * \param parent parent 45 * \param name name 46 * \param camera_index index of the camera, ie /dev/videox 47 * \param priority priority of the Thread 48 */ 49 Ps3Eye(const core::FrameworkManager *parent, std::string name, 50 int camera_index, uint8_t priority); 56 51 57 58 59 60 61 52 /*! 53 * \brief Destructor 54 * 55 */ 56 ~Ps3Eye(); 62 57 63 64 58 private: 59 }; 65 60 } // end namespace sensor 66 61 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/RadioReceiver.cpp
r3 r15 28 28 using namespace flair::gui; 29 29 30 namespace flair 31 { 32 namespace sensor 33 { 30 namespace flair { 31 namespace sensor { 34 32 35 RadioReceiver::RadioReceiver(const FrameworkManager* parent,string name,unsigned int nb_channels) : IODevice(parent,name) 36 { 37 is_connected=false; 38 this->nb_channels=nb_channels; 33 RadioReceiver::RadioReceiver(const FrameworkManager *parent, string name, 34 unsigned int nb_channels) 35 : IODevice(parent, name) { 36 is_connected = false; 37 this->nb_channels = nb_channels; 39 38 40 //init matrix 41 cvmatrix_descriptor* desc=new cvmatrix_descriptor(nb_channels,1); 42 for(int i=0;i<nb_channels;i++) 43 { 44 ostringstream channel_name; 45 channel_name << "channel " << i; 46 desc->SetElementName(i,0,channel_name.str()); 47 } 48 output=new cvmatrix(this,desc,floatType,name); 39 // init matrix 40 cvmatrix_descriptor *desc = new cvmatrix_descriptor(nb_channels, 1); 41 for (int i = 0; i < nb_channels; i++) { 42 ostringstream channel_name; 43 channel_name << "channel " << i; 44 desc->SetElementName(i, 0, channel_name.str()); 45 } 46 output = new cvmatrix(this, desc, floatType, name); 49 47 50 //station sol51 main_tab=new Tab(parent->GetTabWidget(),name);52 tab=new TabWidget(main_tab->NewRow(),name);53 setup_tab=new Tab(tab,"Setup");48 // station sol 49 main_tab = new Tab(parent->GetTabWidget(), name); 50 tab = new TabWidget(main_tab->NewRow(), name); 51 setup_tab = new Tab(tab, "Setup"); 54 52 55 53 AddDataToLog(output); 56 54 } 57 55 58 RadioReceiver::~RadioReceiver() 59 { 60 delete main_tab; 56 RadioReceiver::~RadioReceiver() { delete main_tab; } 57 58 Layout *RadioReceiver::GetLayout(void) const { return setup_tab; } 59 60 float RadioReceiver::ChannelValue(unsigned int id) const { 61 if (id < nb_channels) { 62 return output->Value(id, 0); 63 } else { 64 Err("channel %i/%i is out of bound\n", id, nb_channels); 65 return -1; 66 } 61 67 } 62 68 63 Layout* RadioReceiver::GetLayout(void) const 64 { 65 return setup_tab; 66 } 67 68 float RadioReceiver::ChannelValue(unsigned int id) const 69 { 70 if(id<nb_channels) 71 { 72 return output->Value(id,0); 73 } 74 else 75 { 76 Err("channel %i/%i is out of bound\n",id,nb_channels); 77 return -1; 78 } 79 } 80 81 bool RadioReceiver::IsConnected(void) const 82 { 83 return is_connected; 84 } 69 bool RadioReceiver::IsConnected(void) const { return is_connected; } 85 70 86 71 } // end namespace sensor -
trunk/lib/FlairSensorActuator/src/RadioReceiver.h
r3 r15 17 17 #include <stdint.h> 18 18 19 namespace flair 20 { 21 namespace core 22 { 23 class FrameworkManager; 24 class cvmatrix; 25 } 26 namespace gui 27 { 28 class Tab; 29 class TabWidget; 30 class Layout; 31 } 19 namespace flair { 20 namespace core { 21 class FrameworkManager; 22 class cvmatrix; 23 } 24 namespace gui { 25 class Tab; 26 class TabWidget; 27 class Layout; 28 } 32 29 } 33 30 34 namespace flair 35 { 36 namespace sensor 37 { 38 /*! \class RadioReceiver 39 * 40 * \brief Base class for radio receiver 41 */ 42 class RadioReceiver : public core::IODevice 43 { 44 public: 45 /*! 46 * \brief Constructor 47 * 48 * Construct a RadioReceiver. 49 * 50 * \param parent parent 51 * \param name name 52 * \param nb_channels number of supported channels 53 */ 54 RadioReceiver(const core::FrameworkManager* parent,std::string name,unsigned int nb_channels); 31 namespace flair { 32 namespace sensor { 33 /*! \class RadioReceiver 34 * 35 * \brief Base class for radio receiver 36 */ 37 class RadioReceiver : public core::IODevice { 38 public: 39 /*! 40 * \brief Constructor 41 * 42 * Construct a RadioReceiver. 43 * 44 * \param parent parent 45 * \param name name 46 * \param nb_channels number of supported channels 47 */ 48 RadioReceiver(const core::FrameworkManager *parent, std::string name, 49 unsigned int nb_channels); 55 50 56 57 58 59 60 51 /*! 52 * \brief Destructor 53 * 54 */ 55 ~RadioReceiver(); 61 56 62 63 64 65 66 67 68 69 57 /*! 58 * \brief get channel value 59 * 60 * \param id channel id 61 * \return value of the channel, between 0 and 1. 62 * Returns -1 if channel is out of bound 63 */ 64 float ChannelValue(unsigned int id) const; 70 65 71 72 73 74 75 76 66 /*! 67 * \brief Is transmitter connected? 68 * 69 * \return true if transmitter is connected 70 */ 71 bool IsConnected(void) const; 77 72 78 79 80 81 82 83 gui::Layout*GetLayout(void) const;73 /*! 74 * \brief Setup Layout 75 * 76 * \return a Layout available 77 */ 78 gui::Layout *GetLayout(void) const; 84 79 85 86 87 88 89 90 91 92 93 80 private: 81 /*! 82 * \brief Update using provided datas 83 * 84 * Reimplemented from IODevice. 85 * 86 * \param data data from the parent to process 87 */ 88 void UpdateFrom(const core::io_data *data){}; 94 89 95 96 97 98 gui::Tab*main_tab;99 gui::TabWidget*tab;100 gui::Tab*setup_tab;101 90 core::cvmatrix *output; 91 bool is_connected; 92 unsigned int nb_channels; 93 gui::Tab *main_tab; 94 gui::TabWidget *tab; 95 gui::Tab *setup_tab; 96 }; 102 97 } // end namespace sensor 103 98 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/SimuBldc.cpp
r3 r15 29 29 using namespace flair::gui; 30 30 31 namespace flair 32 { 33 namespace actuator 34 { 31 namespace flair { 32 namespace actuator { 35 33 36 SimuBldc::SimuBldc(const IODevice* parent,Layout* layout,string name,uint8_t motors_count,uint32_t dev_id) :Bldc(parent,layout,name,motors_count) 37 { 38 ostringstream dev_name; 39 dev_name << "simu_bldc_" << dev_id; 40 shmem=new SharedMem(this,dev_name.str().c_str(),motors_count*sizeof(float)); 34 SimuBldc::SimuBldc(const IODevice *parent, Layout *layout, string name, 35 uint8_t motors_count, uint32_t dev_id) 36 : Bldc(parent, layout, name, motors_count) { 37 ostringstream dev_name; 38 dev_name << "simu_bldc_" << dev_id; 39 shmem = 40 new SharedMem(this, dev_name.str().c_str(), motors_count * sizeof(float)); 41 41 42 GroupBox *groupbox=new GroupBox(layout->NewRow(),"simubldc");43 k=new DoubleSpinBox(groupbox->NewRow(),"k driver:",0,10000,1);42 GroupBox *groupbox = new GroupBox(layout->NewRow(), "simubldc"); 43 k = new DoubleSpinBox(groupbox->NewRow(), "k driver:", 0, 10000, 1); 44 44 } 45 45 46 SimuBldc::SimuBldc(const Object* parent,string name,uint8_t motors_count,uint32_t dev_id) :Bldc(parent,name,motors_count) { 47 ostringstream dev_name; 48 dev_name << "simu_bldc_" << dev_id; 49 shmem=new SharedMem(this,dev_name.str().c_str(),motors_count*sizeof(float)); 46 SimuBldc::SimuBldc(const Object *parent, string name, uint8_t motors_count, 47 uint32_t dev_id) 48 : Bldc(parent, name, motors_count) { 49 ostringstream dev_name; 50 dev_name << "simu_bldc_" << dev_id; 51 shmem = 52 new SharedMem(this, dev_name.str().c_str(), motors_count * sizeof(float)); 50 53 51 //reset values 52 float values[motors_count]; 53 for(int i=0;i<motors_count;i++) values[i]=0; 54 // reset values 55 float values[motors_count]; 56 for (int i = 0; i < motors_count; i++) 57 values[i] = 0; 54 58 55 shmem->Write((char*)&values,motors_count*sizeof(float));59 shmem->Write((char *)&values, motors_count * sizeof(float)); 56 60 } 57 61 58 SimuBldc::~SimuBldc() { 62 SimuBldc::~SimuBldc() {} 63 64 void SimuBldc::SetMotors(float *value) { 65 float values[MotorsCount()]; 66 67 for (int i = 0; i < MotorsCount(); i++) 68 values[i] = k->Value() * value[i]; 69 70 shmem->Write((char *)&values, MotorsCount() * sizeof(float)); 71 72 // on prend une fois pour toute le mutex et on fait des accès directs 73 output->GetMutex(); 74 for (int i = 0; i < MotorsCount(); i++) 75 output->SetValueNoMutex(i, 0, values[i]); 76 output->ReleaseMutex(); 59 77 } 60 78 61 void SimuBldc::SetMotors(float* value) { 62 float values[MotorsCount()]; 79 void SimuBldc::GetSpeeds(float *value) const { 80 float values[MotorsCount()]; 81 shmem->Read((char *)&values, MotorsCount() * sizeof(float)); 63 82 64 for(int i=0;i<MotorsCount();i++) values[i]=k->Value()*value[i]; 65 66 shmem->Write((char*)&values,MotorsCount()*sizeof(float)); 67 68 //on prend une fois pour toute le mutex et on fait des accès directs 69 output->GetMutex(); 70 for(int i=0;i<MotorsCount();i++) output->SetValueNoMutex(i,0,values[i]); 71 output->ReleaseMutex(); 72 } 73 74 void SimuBldc::GetSpeeds(float* value) const { 75 float values[MotorsCount()]; 76 shmem->Read((char*)&values,MotorsCount()*sizeof(float)); 77 78 for(int i=0;i<MotorsCount();i++) value[i]=values[i]; 83 for (int i = 0; i < MotorsCount(); i++) 84 value[i] = values[i]; 79 85 } 80 86 -
trunk/lib/FlairSensorActuator/src/SimuBldc.h
r3 r15 16 16 #include <Bldc.h> 17 17 18 namespace flair 19 { 20 namespace core 21 { 22 class SharedMem; 23 class IODevice; 24 class cvmatrix; 25 } 26 namespace gui 27 { 28 class DoubleSpinBox; 29 class Layout; 30 } 18 namespace flair { 19 namespace core { 20 class SharedMem; 21 class IODevice; 22 class cvmatrix; 23 } 24 namespace gui { 25 class DoubleSpinBox; 26 class Layout; 27 } 31 28 } 32 29 33 namespace flair 34 { 35 namespace actuator 36 { 37 /*! \class SimuBldc 38 * 39 * \brief Class for a simulation bldc 40 * 41 */ 42 class SimuBldc : public Bldc 43 { 44 public: 45 /*! 46 * \brief Constructor 47 * 48 * Construct a SimuBldc. Control part. 49 * 50 * \param parent parent 51 * \param layout layout 52 * \param name name 53 * \param motors_count number of motors 54 * \param dev_id device id 55 */ 56 SimuBldc(const core::IODevice* parent,gui::Layout* layout,std::string name,uint8_t motors_count,uint32_t dev_id); 30 namespace flair { 31 namespace actuator { 32 /*! \class SimuBldc 33 * 34 * \brief Class for a simulation bldc 35 * 36 */ 37 class SimuBldc : public Bldc { 38 public: 39 /*! 40 * \brief Constructor 41 * 42 * Construct a SimuBldc. Control part. 43 * 44 * \param parent parent 45 * \param layout layout 46 * \param name name 47 * \param motors_count number of motors 48 * \param dev_id device id 49 */ 50 SimuBldc(const core::IODevice *parent, gui::Layout *layout, std::string name, 51 uint8_t motors_count, uint32_t dev_id); 57 52 58 /*! 59 * \brief Constructor 60 * 61 * Construct a SimuBldc. Simulation part. 62 * 63 * \param parent parent 64 * \param name name 65 * \param motors_count number of motors 66 * \param dev_id device id 67 */ 68 SimuBldc(const core::Object* parent,std::string name,uint8_t motors_count,uint32_t dev_id); 53 /*! 54 * \brief Constructor 55 * 56 * Construct a SimuBldc. Simulation part. 57 * 58 * \param parent parent 59 * \param name name 60 * \param motors_count number of motors 61 * \param dev_id device id 62 */ 63 SimuBldc(const core::Object *parent, std::string name, uint8_t motors_count, 64 uint32_t dev_id); 69 65 70 71 72 73 74 66 /*! 67 * \brief Destructor 68 * 69 */ 70 ~SimuBldc(); 75 71 76 77 78 79 80 81 82 83 void GetSpeeds(float*value) const;72 /*! 73 * \brief Get motors speeds. 74 * 75 * This function should only be used for the simulation part. 76 * 77 * \param value array to store motors speeds 78 */ 79 void GetSpeeds(float *value) const; 84 80 85 86 87 88 89 90 91 92 bool HasSpeedMeasurement(void) const{return false;};81 /*! 82 * \brief Has speed measurement 83 * 84 * Reimplemented from Bldc. \n 85 * 86 * \return true if it has speed measurement 87 */ 88 bool HasSpeedMeasurement(void) const { return false; }; 93 89 94 95 96 97 98 99 100 101 bool HasCurrentMeasurement(void) const{return false;};90 /*! 91 * \brief Has current measurement 92 * 93 * Reimplemented from Bldc. \n 94 * 95 * \return true if it has current measurement 96 */ 97 bool HasCurrentMeasurement(void) const { return false; }; 102 98 103 104 105 106 107 108 109 110 111 112 void SetMotors(float*value);99 private: 100 /*! 101 * \brief Set motors values 102 * 103 * Reimplemented from Bldc. \n 104 * Values size must be the same as MotorsCount() 105 * 106 * \param values motor values 107 */ 108 void SetMotors(float *value); 113 109 114 115 116 110 core::SharedMem *shmem; 111 gui::DoubleSpinBox *k; 112 }; 117 113 } // end namespace actuator 118 114 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/SimuCamera.cpp
r3 r15 29 29 using namespace flair::gui; 30 30 31 namespace flair { namespace sensor { 31 namespace flair { 32 namespace sensor { 32 33 33 SimuCamera::SimuCamera(const FrameworkManager* parent,string name,uint16_t width,uint16_t height,uint8_t channels,uint32_t dev_id,uint8_t priority) :Thread(parent,name,priority),Camera(parent,name,width,height,cvimage::Type::Format::BGR) { 34 data_rate=new SpinBox(GetGroupBox()->NewRow(),"data rate"," Hz",1,100,1,50); 34 SimuCamera::SimuCamera(const FrameworkManager *parent, string name, 35 uint16_t width, uint16_t height, uint8_t channels, 36 uint32_t dev_id, uint8_t priority) 37 : Thread(parent, name, priority), 38 Camera(parent, name, width, height, cvimage::Type::Format::BGR) { 39 data_rate = 40 new SpinBox(GetGroupBox()->NewRow(), "data rate", " Hz", 1, 100, 1, 50); 35 41 36 buf_size=width*height*channels;42 buf_size = width * height * channels; 37 43 38 img=cvCreateImage(cvSize(width,height),IPL_DEPTH_8U,3);39 output->img->imageData=img->imageData;44 img = cvCreateImage(cvSize(width, height), IPL_DEPTH_8U, 3); 45 output->img->imageData = img->imageData; 40 46 41 42 43 shmem=new SharedMem((Thread*)this,dev_name.str().c_str(),buf_size);47 ostringstream dev_name; 48 dev_name << "simu_cam_" << dev_id; 49 shmem = new SharedMem((Thread *)this, dev_name.str().c_str(), buf_size); 44 50 } 45 51 46 SimuCamera::SimuCamera(const IODevice* parent,string name,uint16_t width,uint16_t height,uint8_t channels,uint32_t dev_id) : Thread(parent,name,0),Camera(parent,name) { 47 data_rate=NULL; 52 SimuCamera::SimuCamera(const IODevice *parent, string name, uint16_t width, 53 uint16_t height, uint8_t channels, uint32_t dev_id) 54 : Thread(parent, name, 0), Camera(parent, name) { 55 data_rate = NULL; 48 56 49 ostringstream dev_name; 50 dev_name << "simu_cam_" << dev_id; 51 shmem=new SharedMem((Thread*)this,dev_name.str().c_str(),width*height*channels); 57 ostringstream dev_name; 58 dev_name << "simu_cam_" << dev_id; 59 shmem = new SharedMem((Thread *)this, dev_name.str().c_str(), 60 width * height * channels); 52 61 } 53 62 54 63 SimuCamera::~SimuCamera() { 55 56 64 SafeStop(); 65 Join(); 57 66 } 58 67 59 68 void SimuCamera::Run(void) { 60 if(data_rate==NULL) { 61 Thread::Err("not applicable for simulation part.\n"); 62 return; 69 if (data_rate == NULL) { 70 Thread::Err("not applicable for simulation part.\n"); 71 return; 72 } 73 74 SetPeriodUS((uint32_t)(1000000. / data_rate->Value())); 75 76 while (!ToBeStopped()) { 77 WaitPeriod(); 78 79 if (data_rate->ValueChanged() == true) { 80 SetPeriodUS((uint32_t)(1000000. / data_rate->Value())); 63 81 } 64 82 65 SetPeriodUS((uint32_t)(1000000./data_rate->Value())); 83 output->GetMutex(); 84 shmem->Read((char *)img->imageData, buf_size); // remplacer copie par 85 // échange de pointeur sur 86 // double buffering 87 output->ReleaseMutex(); 66 88 67 while(!ToBeStopped()) { 68 WaitPeriod(); 89 output->SetDataTime(GetTime()); 69 90 70 if(data_rate->ValueChanged()==true) { 71 SetPeriodUS((uint32_t)(1000000./data_rate->Value())); 72 } 73 74 output->GetMutex(); 75 shmem->Read((char*)img->imageData,buf_size); // remplacer copie par échange de pointeur sur double buffering 76 output->ReleaseMutex(); 77 78 output->SetDataTime(GetTime()); 79 80 ProcessUpdate(output); 81 } 91 ProcessUpdate(output); 92 } 82 93 } 83 94 -
trunk/lib/FlairSensorActuator/src/SimuCamera.h
r3 r15 18 18 #include <cxcore.h> 19 19 20 namespace flair 21 { 22 namespace core 23 { 24 class SharedMem; 25 } 26 namespace gui 27 { 28 class SpinBox; 29 } 20 namespace flair { 21 namespace core { 22 class SharedMem; 23 } 24 namespace gui { 25 class SpinBox; 26 } 30 27 } 31 28 32 namespace flair 33 { 34 namespace sensor 35 { 36 /*! \class SimuCamera 37 * 38 * \brief Class for a simulation camera 39 */ 40 class SimuCamera : public core::Thread, public Camera 41 { 42 public: 43 /*! 44 * \brief Constructor 45 * 46 * Construct a SimuCamera. Control part. 47 * 48 * \param parent parent 49 * \param name name 50 * \param width width 51 * \param height height 52 * \param channels number of channels 53 * \param dev_id device id 54 * \param priority priority of the Thread 55 */ 56 SimuCamera(const core::FrameworkManager* parent,std::string name,uint16_t width,uint16_t height,uint8_t channels,uint32_t dev_id,uint8_t priority); 29 namespace flair { 30 namespace sensor { 31 /*! \class SimuCamera 32 * 33 * \brief Class for a simulation camera 34 */ 35 class SimuCamera : public core::Thread, public Camera { 36 public: 37 /*! 38 * \brief Constructor 39 * 40 * Construct a SimuCamera. Control part. 41 * 42 * \param parent parent 43 * \param name name 44 * \param width width 45 * \param height height 46 * \param channels number of channels 47 * \param dev_id device id 48 * \param priority priority of the Thread 49 */ 50 SimuCamera(const core::FrameworkManager *parent, std::string name, 51 uint16_t width, uint16_t height, uint8_t channels, uint32_t dev_id, 52 uint8_t priority); 57 53 58 /*! 59 * \brief Constructor 60 * 61 * Construct a SimuCamera. Simulation part.\n 62 * The Thread of this class should not be run. 63 * 64 * \param parent parent 65 * \param name name 66 * \param width width 67 * \param height height 68 * \param channels number of channels 69 * \param dev_id device id 70 */ 71 SimuCamera(const core::IODevice* parent,std::string name,uint16_t width,uint16_t height,uint8_t channels,uint32_t dev_id); 54 /*! 55 * \brief Constructor 56 * 57 * Construct a SimuCamera. Simulation part.\n 58 * The Thread of this class should not be run. 59 * 60 * \param parent parent 61 * \param name name 62 * \param width width 63 * \param height height 64 * \param channels number of channels 65 * \param dev_id device id 66 */ 67 SimuCamera(const core::IODevice *parent, std::string name, uint16_t width, 68 uint16_t height, uint8_t channels, uint32_t dev_id); 72 69 73 74 75 76 77 70 /*! 71 * \brief Destructor 72 * 73 */ 74 ~SimuCamera(); 78 75 79 80 81 82 83 84 76 protected: 77 /*! 78 * \brief SharedMem to access datas 79 * 80 */ 81 core::SharedMem *shmem; 85 82 86 87 88 89 90 91 92 93 83 private: 84 /*! 85 * \brief Run function 86 * 87 * Reimplemented from Thread. 88 * 89 */ 90 void Run(void); 94 91 95 96 97 98 99 100 101 102 92 /*! 93 * \brief Update using provided datas 94 * 95 * Reimplemented from IODevice. 96 * 97 * \param data data from the parent to process 98 */ 99 void UpdateFrom(const core::io_data *data){}; 103 100 104 105 106 IplImage*img;107 101 gui::SpinBox *data_rate; 102 size_t buf_size; 103 IplImage *img; 104 }; 108 105 } // end namespace sensor 109 106 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/SimuGps.cpp
r3 r15 24 24 using namespace flair::core; 25 25 26 namespace flair 27 { 28 namespace sensor 29 { 26 namespace flair { 27 namespace sensor { 30 28 31 SimuGps::SimuGps(const FrameworkManager* parent,string name,Gps::NMEAFlags_t NMEAFlags,uint8_t priority) : Thread(parent,name,priority), Gps(parent,name,NMEAFlags) 32 { 29 SimuGps::SimuGps(const FrameworkManager *parent, string name, 30 Gps::NMEAFlags_t NMEAFlags, uint8_t priority) 31 : Thread(parent, name, priority), Gps(parent, name, NMEAFlags) {} 32 33 SimuGps::~SimuGps() { 34 SafeStop(); 35 Join(); 33 36 } 34 37 35 SimuGps::~SimuGps() 36 { 37 SafeStop(); 38 Join(); 38 void SimuGps::Run(void) { 39 char response[200] = {0}; 40 int size, result; 41 // double lat=0; 42 SetPeriodMS(500); 43 WarnUponSwitches(true); 44 45 while (!ToBeStopped()) { 46 WaitPeriod(); 47 position->SetCoordinates(49.402313, 2.795463, 0); 48 // lat+=.5; 49 } 50 51 WarnUponSwitches(false); 39 52 } 40 41 void SimuGps::Run(void)42 {43 char response[200] = {0};44 int size,result;45 //double lat=0;46 SetPeriodMS(500);47 WarnUponSwitches(true);48 49 while(!ToBeStopped())50 {51 WaitPeriod();52 position->SetCoordinates(49.402313, 2.795463,0);53 // lat+=.5;54 }55 56 57 WarnUponSwitches(false);58 }59 60 53 61 54 } // end namespace sensor -
trunk/lib/FlairSensorActuator/src/SimuGps.h
r3 r15 17 17 #include <Gps.h> 18 18 19 namespace flair 20 { 21 namespace core 22 { 23 class FrameworkManager; 24 } 19 namespace flair { 20 namespace core { 21 class FrameworkManager; 22 } 25 23 } 26 24 27 namespace flair 28 { 29 namespace sensor 30 { 31 /*! \class SimuGps 32 * 33 * \brief Class for a simulation GPS 34 */ 35 class SimuGps : public core::Thread, public Gps 36 { 37 public: 38 /*! 39 * \brief Constructor 40 * 41 * Construct a Novatel. 42 * 43 * \param parent parent 44 * \param name name 45 * \param NMEAFlags NMEA sentances to enable 46 * \param priority priority of the Thread 47 */ 48 SimuGps(const core::FrameworkManager* parent,std::string name,Gps::NMEAFlags_t NMEAFlags,uint8_t priority); 25 namespace flair { 26 namespace sensor { 27 /*! \class SimuGps 28 * 29 * \brief Class for a simulation GPS 30 */ 31 class SimuGps : public core::Thread, public Gps { 32 public: 33 /*! 34 * \brief Constructor 35 * 36 * Construct a Novatel. 37 * 38 * \param parent parent 39 * \param name name 40 * \param NMEAFlags NMEA sentances to enable 41 * \param priority priority of the Thread 42 */ 43 SimuGps(const core::FrameworkManager *parent, std::string name, 44 Gps::NMEAFlags_t NMEAFlags, uint8_t priority); 49 45 50 51 52 53 54 46 /*! 47 * \brief Destructor 48 * 49 */ 50 ~SimuGps(); 55 51 56 57 58 59 60 61 62 63 64 52 private: 53 /*! 54 * \brief Update using provided datas 55 * 56 * Reimplemented from IODevice. 57 * 58 * \param data data from the parent to process 59 */ 60 void UpdateFrom(const core::io_data *data){}; 65 61 66 67 68 69 70 71 72 73 62 /*! 63 * \brief Run function 64 * 65 * Reimplemented from Thread. 66 * 67 */ 68 void Run(void); 69 }; 74 70 } // end namespace sensor 75 71 } // end namespace framewor -
trunk/lib/FlairSensorActuator/src/SimuImu.cpp
r3 r15 31 31 using namespace flair::gui; 32 32 33 namespace flair { namespace sensor { 33 namespace flair { 34 namespace sensor { 34 35 35 SimuImu::SimuImu(const FrameworkManager* parent,string name,uint32_t dev_id,uint8_t priority) :Imu(parent,name),Thread(parent,name,priority) { 36 data_rate=new SpinBox(GetGroupBox()->NewRow(),"data rate"," Hz",1,500,1,200); 37 ahrsData=new AhrsData((Imu*)this); 36 SimuImu::SimuImu(const FrameworkManager *parent, string name, uint32_t dev_id, 37 uint8_t priority) 38 : Imu(parent, name), Thread(parent, name, priority) { 39 data_rate = 40 new SpinBox(GetGroupBox()->NewRow(), "data rate", " Hz", 1, 500, 1, 200); 41 ahrsData = new AhrsData((Imu *)this); 38 42 39 ostringstream dev_name; 40 dev_name << "simu_imu_" << dev_id; 41 shmem=new SharedMem((Thread*)this,dev_name.str().c_str(),sizeof(imu_states_t)); 43 ostringstream dev_name; 44 dev_name << "simu_imu_" << dev_id; 45 shmem = new SharedMem((Thread *)this, dev_name.str().c_str(), 46 sizeof(imu_states_t)); 42 47 } 43 48 44 SimuImu::SimuImu(const IODevice* parent,string name,uint32_t dev_id) :Imu(parent,name),Thread(parent,name,0) { 45 data_rate=NULL; 49 SimuImu::SimuImu(const IODevice *parent, string name, uint32_t dev_id) 50 : Imu(parent, name), Thread(parent, name, 0) { 51 data_rate = NULL; 46 52 47 ostringstream dev_name; 48 dev_name << "simu_imu_" << dev_id; 49 shmem=new SharedMem((Thread*)this,dev_name.str().c_str(),sizeof(imu_states_t)); 53 ostringstream dev_name; 54 dev_name << "simu_imu_" << dev_id; 55 shmem = new SharedMem((Thread *)this, dev_name.str().c_str(), 56 sizeof(imu_states_t)); 50 57 } 51 58 52 59 SimuImu::~SimuImu() { 53 54 60 SafeStop(); 61 Join(); 55 62 } 56 63 57 64 void SimuImu::UpdateFrom(const io_data *data) { 58 if(data!=NULL) {59 cvmatrix *input=(cvmatrix*)data;60 65 if (data != NULL) { 66 cvmatrix *input = (cvmatrix *)data; 67 imu_states_t state; 61 68 62 63 state.q0=input->ValueNoMutex(0,0);64 state.q1=input->ValueNoMutex(1,0);65 state.q2=input->ValueNoMutex(2,0);66 state.q3=input->ValueNoMutex(3,0);67 state.wx=input->ValueNoMutex(7,0);68 state.wy=input->ValueNoMutex(8,0);69 state.wz=input->ValueNoMutex(9,0);70 69 input->GetMutex(); 70 state.q0 = input->ValueNoMutex(0, 0); 71 state.q1 = input->ValueNoMutex(1, 0); 72 state.q2 = input->ValueNoMutex(2, 0); 73 state.q3 = input->ValueNoMutex(3, 0); 74 state.wx = input->ValueNoMutex(7, 0); 75 state.wy = input->ValueNoMutex(8, 0); 76 state.wz = input->ValueNoMutex(9, 0); 77 input->ReleaseMutex(); 71 78 72 shmem->Write((char*)&state,sizeof(imu_states_t));73 79 shmem->Write((char *)&state, sizeof(imu_states_t)); 80 } 74 81 } 75 82 76 83 void SimuImu::Run(void) { 77 78 ImuData*imuData;79 84 imu_states_t state; 85 ImuData *imuData; 86 GetDatas(&imuData); 80 87 81 if(data_rate==NULL) { 82 Thread::Err("not applicable for simulation part.\n"); 83 return; 88 if (data_rate == NULL) { 89 Thread::Err("not applicable for simulation part.\n"); 90 return; 91 } 92 93 SetPeriodUS((uint32_t)(1000000. / data_rate->Value())); 94 95 while (!ToBeStopped()) { 96 WaitPeriod(); 97 98 if (data_rate->ValueChanged() == true) { 99 SetPeriodUS((uint32_t)(1000000. / data_rate->Value())); 84 100 } 85 101 86 SetPeriodUS((uint32_t)(1000000./data_rate->Value())); 102 shmem->Read((char *)&state, sizeof(imu_states_t)); 103 ahrsData->SetQuaternionAndAngularRates( 104 Quaternion(state.q0, state.q1, state.q2, state.q3), 105 Vector3D(state.wx, state.wy, state.wz)); 87 106 88 while(!ToBeStopped()) {89 WaitPeriod();107 imuData->SetDataTime(GetTime()); 108 ahrsData->SetDataTime(GetTime()); 90 109 91 if(data_rate->ValueChanged()==true) { 92 SetPeriodUS((uint32_t)(1000000./data_rate->Value())); 93 } 94 95 shmem->Read((char*)&state,sizeof(imu_states_t)); 96 ahrsData->SetQuaternionAndAngularRates(Quaternion(state.q0,state.q1,state.q2,state.q3) 97 ,Vector3D(state.wx,state.wy,state.wz)); 98 99 imuData->SetDataTime(GetTime()); 100 ahrsData->SetDataTime(GetTime()); 101 102 UpdateImu(); 103 ProcessUpdate(ahrsData); 104 } 110 UpdateImu(); 111 ProcessUpdate(ahrsData); 112 } 105 113 } 106 114 -
trunk/lib/FlairSensorActuator/src/SimuImu.h
r3 r15 18 18 19 19 namespace flair { 20 namespace core{21 22 23 24 25 26 20 namespace core { 21 class SharedMem; 22 class AhrsData; 23 } 24 namespace gui { 25 class SpinBox; 26 } 27 27 } 28 28 29 namespace flair { namespace sensor { 30 /*! \class SimuImu 31 * 32 * \brief Class for a simulation Imu 33 */ 34 class SimuImu : public Imu, public core::Thread { 35 public: 36 /*! 37 * \brief Constructor 38 * 39 * Construct a SimuImu. Control part. 40 * 41 * \param parent parent 42 * \param name name 43 * \param dev_id device id 44 * \param priority priority of the Thread 45 */ 46 SimuImu(const core::FrameworkManager* parent,std::string name,uint32_t dev_id,uint8_t priority); 29 namespace flair { 30 namespace sensor { 31 /*! \class SimuImu 32 * 33 * \brief Class for a simulation Imu 34 */ 35 class SimuImu : public Imu, public core::Thread { 36 public: 37 /*! 38 * \brief Constructor 39 * 40 * Construct a SimuImu. Control part. 41 * 42 * \param parent parent 43 * \param name name 44 * \param dev_id device id 45 * \param priority priority of the Thread 46 */ 47 SimuImu(const core::FrameworkManager *parent, std::string name, 48 uint32_t dev_id, uint8_t priority); 47 49 48 49 50 51 52 53 54 55 56 57 58 SimuImu(const core::IODevice* parent,std::string name,uint32_t dev_id);50 /*! 51 * \brief Constructor 52 * 53 * Construct a SimuImu. Simulation part.\n 54 * The Thread of this class should not be run. 55 * 56 * \param parent parent 57 * \param name name 58 * \param dev_id device id 59 */ 60 SimuImu(const core::IODevice *parent, std::string name, uint32_t dev_id); 59 61 60 61 62 63 64 62 /*! 63 * \brief Destructor 64 * 65 */ 66 ~SimuImu(); 65 67 66 67 68 69 70 71 72 73 68 private: 69 /*! 70 * \brief Run function 71 * 72 * Reimplemented from Thread. 73 * 74 */ 75 void Run(void); 74 76 75 76 77 78 79 80 81 82 77 /*! 78 * \brief Update using provided datas 79 * 80 * Reimplemented from IODevice. 81 * 82 * \param data data from the parent to process 83 */ 84 void UpdateFrom(const core::io_data *data); 83 85 84 85 86 87 88 89 90 91 92 93 94 95 96 86 typedef struct { 87 float q0; 88 float q1; 89 float q2; 90 float q3; 91 float wx; 92 float wy; 93 float wz; 94 } imu_states_t; 95 gui::SpinBox *data_rate; 96 core::SharedMem *shmem; 97 core::AhrsData *ahrsData; 98 }; 97 99 } // end namespace sensor 98 100 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/SimuLaser.cpp
r3 r15 29 29 using namespace flair::gui; 30 30 31 namespace flair 32 { 33 namespace sensor 34 { 31 namespace flair { 32 namespace sensor { 35 33 36 SimuLaser::SimuLaser(const FrameworkManager* parent,string name,uint32_t dev_id,uint8_t priority) : Thread(parent,name,priority), LaserRangeFinder(parent,name) 37 { 38 data_rate=new SpinBox(GetGroupBox()->NewRow(),"data rate"," Hz",1,500,1,50); 34 SimuLaser::SimuLaser(const FrameworkManager *parent, string name, 35 uint32_t dev_id, uint8_t priority) 36 : Thread(parent, name, priority), LaserRangeFinder(parent, name) { 37 data_rate = 38 new SpinBox(GetGroupBox()->NewRow(), "data rate", " Hz", 1, 500, 1, 50); 39 39 40 ostringstream dev_name; 41 dev_name << "simu_Laser_" << dev_id; 42 shmem=new SharedMem((Thread*)this,dev_name.str().c_str(),360*sizeof(float)); //**** 40 ostringstream dev_name; 41 dev_name << "simu_Laser_" << dev_id; 42 shmem = new SharedMem((Thread *)this, dev_name.str().c_str(), 43 360 * sizeof(float)); //**** 43 44 } 44 45 45 SimuLaser::SimuLaser(const IODevice * parent,string name,uint32_t dev_id) : Thread(parent,name,0), LaserRangeFinder(parent,name)46 {47 data_rate=NULL;46 SimuLaser::SimuLaser(const IODevice *parent, string name, uint32_t dev_id) 47 : Thread(parent, name, 0), LaserRangeFinder(parent, name) { 48 data_rate = NULL; 48 49 49 ostringstream dev_name; 50 dev_name << "simu_Laser_" << dev_id; 51 shmem=new SharedMem((Thread*)this,dev_name.str().c_str(),360*sizeof(float)); 50 ostringstream dev_name; 51 dev_name << "simu_Laser_" << dev_id; 52 shmem = new SharedMem((Thread *)this, dev_name.str().c_str(), 53 360 * sizeof(float)); 52 54 } 53 55 54 SimuLaser::~SimuLaser() 55 { 56 SafeStop(); 57 Join(); 56 SimuLaser::~SimuLaser() { 57 SafeStop(); 58 Join(); 58 59 } 59 60 60 void SimuLaser::Run(void) 61 { 62 float z[360]; 61 void SimuLaser::Run(void) { 62 float z[360]; 63 63 64 if(data_rate==NULL) 65 { 66 Thread::Err("not applicable for simulation part.\n"); 67 return; 64 if (data_rate == NULL) { 65 Thread::Err("not applicable for simulation part.\n"); 66 return; 67 } 68 69 SetPeriodUS((uint32_t)(1000000. / data_rate->Value())); 70 71 while (!ToBeStopped()) { 72 WaitPeriod(); 73 74 shmem->Read((char *)z, 360 * sizeof(float)); 75 76 if (data_rate->ValueChanged() == true) { 77 SetPeriodUS((uint32_t)(1000000. / data_rate->Value())); 68 78 } 69 70 SetPeriodUS((uint32_t)(1000000./data_rate->Value())); 71 72 while(!ToBeStopped()) 73 { 74 WaitPeriod(); 75 76 shmem->Read((char*)z,360*sizeof(float)); 77 78 if(data_rate->ValueChanged()==true) 79 { 80 SetPeriodUS((uint32_t)(1000000./data_rate->Value())); 81 } 82 for(int i=0; i<360; i++) 83 { 84 output->SetValue(i,0,z[i]); //******* 85 } 86 output->SetDataTime(GetTime()); 87 ProcessUpdate(output); 79 for (int i = 0; i < 360; i++) { 80 output->SetValue(i, 0, z[i]); //******* 88 81 } 82 output->SetDataTime(GetTime()); 83 ProcessUpdate(output); 84 } 89 85 } 90 86 -
trunk/lib/FlairSensorActuator/src/SimuLaser.h
r3 r15 17 17 #include <Thread.h> 18 18 19 namespace flair 20 { 21 namespace core 22 { 23 class SharedMem; 24 } 25 namespace gui 26 { 27 class SpinBox; 28 } 19 namespace flair { 20 namespace core { 21 class SharedMem; 22 } 23 namespace gui { 24 class SpinBox; 25 } 29 26 } 30 27 31 namespace flair 32 { 33 namespace sensor 34 { 35 /*! \class SimuUs 36 * 37 * \brief Class for a simulation UsRangeFinder 38 */ 39 class SimuLaser : public core::Thread, public LaserRangeFinder 40 { 41 public: 42 /*! 43 * \brief Constructor 44 * 45 * Construct a SimuUs. Control part. 46 * 47 * \param parent parent 48 * \param name name 49 * \param dev_id device id 50 * \param priority priority of the Thread 51 */ 52 SimuLaser(const core::FrameworkManager* parent,std::string name,uint32_t dev_id,uint8_t priority); 28 namespace flair { 29 namespace sensor { 30 /*! \class SimuUs 31 * 32 * \brief Class for a simulation UsRangeFinder 33 */ 34 class SimuLaser : public core::Thread, public LaserRangeFinder { 35 public: 36 /*! 37 * \brief Constructor 38 * 39 * Construct a SimuUs. Control part. 40 * 41 * \param parent parent 42 * \param name name 43 * \param dev_id device id 44 * \param priority priority of the Thread 45 */ 46 SimuLaser(const core::FrameworkManager *parent, std::string name, 47 uint32_t dev_id, uint8_t priority); 53 48 54 55 56 57 58 59 60 61 62 63 64 SimuLaser(const core::IODevice* parent,std::string name,uint32_t dev_id);49 /*! 50 * \brief Constructor 51 * 52 * Construct a SimuUs. Simulation part.\n 53 * The Thread of this class should not be run. 54 * 55 * \param parent parent 56 * \param name name 57 * \param dev_id device id 58 */ 59 SimuLaser(const core::IODevice *parent, std::string name, uint32_t dev_id); 65 60 66 67 68 69 70 61 /*! 62 * \brief Destructor 63 * 64 */ 65 ~SimuLaser(); 71 66 72 73 74 75 76 77 67 protected: 68 /*! 69 * \brief SharedMem to access datas 70 * 71 */ 72 core::SharedMem *shmem; 78 73 79 80 81 82 83 84 85 86 87 74 private: 75 /*! 76 * \brief Update using provided datas 77 * 78 * Reimplemented from IODevice. 79 * 80 * \param data data from the parent to process 81 */ 82 void UpdateFrom(const core::io_data *data){}; 88 83 89 90 91 92 93 94 95 84 /*! 85 * \brief Run function 86 * 87 * Reimplemented from Thread. 88 * 89 */ 90 void Run(void); 96 91 97 98 92 gui::SpinBox *data_rate; 93 }; 99 94 } // end namespace sensor 100 95 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/SimuUs.cpp
r3 r15 29 29 using namespace flair::gui; 30 30 31 namespace flair 32 { 33 namespace sensor 34 { 31 namespace flair { 32 namespace sensor { 35 33 36 SimuUs::SimuUs(const FrameworkManager* parent,string name,uint32_t dev_id,uint8_t priority) : Thread(parent,name,priority), UsRangeFinder(parent,name) 37 { 38 data_rate=new SpinBox(GetGroupBox()->NewRow(),"data rate"," Hz",1,500,1,50); 34 SimuUs::SimuUs(const FrameworkManager *parent, string name, uint32_t dev_id, 35 uint8_t priority) 36 : Thread(parent, name, priority), UsRangeFinder(parent, name) { 37 data_rate = 38 new SpinBox(GetGroupBox()->NewRow(), "data rate", " Hz", 1, 500, 1, 50); 39 39 40 41 42 shmem=new SharedMem((Thread*)this,dev_name.str().c_str(),sizeof(float));40 ostringstream dev_name; 41 dev_name << "simu_us_" << dev_id; 42 shmem = new SharedMem((Thread *)this, dev_name.str().c_str(), sizeof(float)); 43 43 } 44 44 45 SimuUs::SimuUs(const IODevice * parent,string name,uint32_t dev_id) : Thread(parent,name,0), UsRangeFinder(parent,name)46 {47 data_rate=NULL;45 SimuUs::SimuUs(const IODevice *parent, string name, uint32_t dev_id) 46 : Thread(parent, name, 0), UsRangeFinder(parent, name) { 47 data_rate = NULL; 48 48 49 50 51 shmem=new SharedMem((Thread*)this,dev_name.str().c_str(),sizeof(float));49 ostringstream dev_name; 50 dev_name << "simu_us_" << dev_id; 51 shmem = new SharedMem((Thread *)this, dev_name.str().c_str(), sizeof(float)); 52 52 } 53 53 54 SimuUs::~SimuUs() 55 { 56 SafeStop(); 57 Join(); 54 SimuUs::~SimuUs() { 55 SafeStop(); 56 Join(); 58 57 } 59 58 60 void SimuUs::Run(void) 61 { 62 float z; 59 void SimuUs::Run(void) { 60 float z; 63 61 64 if(data_rate==NULL) 65 { 66 Thread::Err("not applicable for simulation part.\n"); 67 return; 62 if (data_rate == NULL) { 63 Thread::Err("not applicable for simulation part.\n"); 64 return; 65 } 66 67 SetPeriodUS((uint32_t)(1000000. / data_rate->Value())); 68 69 while (!ToBeStopped()) { 70 WaitPeriod(); 71 72 shmem->Read((char *)&z, sizeof(float)); 73 74 if (data_rate->ValueChanged() == true) { 75 SetPeriodUS((uint32_t)(1000000. / data_rate->Value())); 68 76 } 69 77 70 SetPeriodUS((uint32_t)(1000000./data_rate->Value())); 71 72 while(!ToBeStopped()) 73 { 74 WaitPeriod(); 75 76 shmem->Read((char*)&z,sizeof(float)); 77 78 if(data_rate->ValueChanged()==true) 79 { 80 SetPeriodUS((uint32_t)(1000000./data_rate->Value())); 81 } 82 83 output->SetValue(0,0,z); 84 output->SetDataTime(GetTime()); 85 ProcessUpdate(output); 86 } 78 output->SetValue(0, 0, z); 79 output->SetDataTime(GetTime()); 80 ProcessUpdate(output); 81 } 87 82 } 88 83 -
trunk/lib/FlairSensorActuator/src/SimuUs.h
r3 r15 17 17 #include <Thread.h> 18 18 19 namespace flair 20 { 21 namespace core 22 { 23 class SharedMem; 24 } 25 namespace gui 26 { 27 class SpinBox; 28 } 19 namespace flair { 20 namespace core { 21 class SharedMem; 22 } 23 namespace gui { 24 class SpinBox; 25 } 29 26 } 30 27 31 namespace flair 32 { 33 namespace sensor 34 { 35 /*! \class SimuUs 36 * 37 * \brief Class for a simulation UsRangeFinder 38 */ 39 class SimuUs : public core::Thread, public UsRangeFinder 40 { 41 public: 42 /*! 43 * \brief Constructor 44 * 45 * Construct a SimuUs. Control part. 46 * 47 * \param parent parent 48 * \param name name 49 * \param dev_id device id 50 * \param priority priority of the Thread 51 */ 52 SimuUs(const core::FrameworkManager* parent,std::string name,uint32_t dev_id,uint8_t priority); 28 namespace flair { 29 namespace sensor { 30 /*! \class SimuUs 31 * 32 * \brief Class for a simulation UsRangeFinder 33 */ 34 class SimuUs : public core::Thread, public UsRangeFinder { 35 public: 36 /*! 37 * \brief Constructor 38 * 39 * Construct a SimuUs. Control part. 40 * 41 * \param parent parent 42 * \param name name 43 * \param dev_id device id 44 * \param priority priority of the Thread 45 */ 46 SimuUs(const core::FrameworkManager *parent, std::string name, 47 uint32_t dev_id, uint8_t priority); 53 48 54 55 56 57 58 59 60 61 62 63 64 SimuUs(const core::IODevice* parent,std::string name,uint32_t dev_id);49 /*! 50 * \brief Constructor 51 * 52 * Construct a SimuUs. Simulation part.\n 53 * The Thread of this class should not be run. 54 * 55 * \param parent parent 56 * \param name name 57 * \param dev_id device id 58 */ 59 SimuUs(const core::IODevice *parent, std::string name, uint32_t dev_id); 65 60 66 67 68 69 70 61 /*! 62 * \brief Destructor 63 * 64 */ 65 ~SimuUs(); 71 66 72 73 74 75 76 77 67 protected: 68 /*! 69 * \brief SharedMem to access datas 70 * 71 */ 72 core::SharedMem *shmem; 78 73 79 80 81 82 83 84 85 86 87 74 private: 75 /*! 76 * \brief Update using provided datas 77 * 78 * Reimplemented from IODevice. 79 * 80 * \param data data from the parent to process 81 */ 82 void UpdateFrom(const core::io_data *data){}; 88 83 89 90 91 92 93 94 95 84 /*! 85 * \brief Run function 86 * 87 * Reimplemented from Thread. 88 * 89 */ 90 void Run(void); 96 91 97 98 92 gui::SpinBox *data_rate; 93 }; 99 94 } // end namespace sensor 100 95 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/Srf08.cpp
r3 r15 30 30 using namespace flair::gui; 31 31 32 namespace flair 33 { 34 namespace sensor 35 { 36 37 Srf08::Srf08(const FrameworkManager* parent,string name,I2cPort* i2cport,uint16_t address,uint8_t priority) : Thread(parent,name,priority), UsRangeFinder(parent,name) 38 { 39 is_init=false; 40 41 //default values 42 //range 46*43+43=2021mm max (2m) 43 //7:gain=118 44 //range=46; 45 //gain=7; 46 47 this->i2cport=i2cport; 48 this->address=address; 49 50 //station sol 51 gain=new SpinBox(GetGroupBox()->NewRow(),"gain:",0,255,1,8); 52 range=new SpinBox(GetGroupBox()->LastRowLastCol(),"range:",0,255,1,46); 53 54 55 SetRange(); 56 SetMaxGain(); 57 } 58 59 Srf08::~Srf08() 60 { 61 SafeStop(); 62 Join(); 63 } 64 65 void Srf08::Run(void) 66 { 67 WarnUponSwitches(true); 68 69 //init srf 32 namespace flair { 33 namespace sensor { 34 35 Srf08::Srf08(const FrameworkManager *parent, string name, I2cPort *i2cport, 36 uint16_t address, uint8_t priority) 37 : Thread(parent, name, priority), UsRangeFinder(parent, name) { 38 is_init = false; 39 40 // default values 41 // range 46*43+43=2021mm max (2m) 42 // 7:gain=118 43 // range=46; 44 // gain=7; 45 46 this->i2cport = i2cport; 47 this->address = address; 48 49 // station sol 50 gain = new SpinBox(GetGroupBox()->NewRow(), "gain:", 0, 255, 1, 8); 51 range = new SpinBox(GetGroupBox()->LastRowLastCol(), "range:", 0, 255, 1, 46); 52 53 SetRange(); 54 SetMaxGain(); 55 } 56 57 Srf08::~Srf08() { 58 SafeStop(); 59 Join(); 60 } 61 62 void Srf08::Run(void) { 63 WarnUponSwitches(true); 64 65 // init srf 66 SendEcho(); 67 68 SetPeriodMS(20); 69 70 while (!ToBeStopped()) { 71 WaitPeriod(); 72 73 if (range->ValueChanged() == true) 74 SetRange(); 75 if (gain->ValueChanged() == true) 76 SetMaxGain(); 77 78 GetEcho(); 70 79 SendEcho(); 71 72 SetPeriodMS(20); 73 74 while(!ToBeStopped()) 75 { 76 WaitPeriod(); 77 78 if(range->ValueChanged()==true) SetRange(); 79 if(gain->ValueChanged()==true) SetMaxGain(); 80 81 GetEcho(); 82 SendEcho(); 80 } 81 82 WarnUponSwitches(false); 83 } 84 85 void Srf08::SendEcho(void) { 86 ssize_t written; 87 uint8_t tx[2]; 88 89 tx[0] = 0; // command register 90 tx[1] = 82; // ranging mode in usec 91 92 i2cport->GetMutex(); 93 94 i2cport->SetSlave(address); 95 written = i2cport->Write(tx, 2); 96 echo_time = GetTime(); 97 98 i2cport->ReleaseMutex(); 99 100 if (written < 0) { 101 Thread::Err("erreur rt_dev_write (%s)\n", strerror(-written)); 102 } else if (written != 2) { 103 Thread::Err("erreur rt_dev_write %i/2\n", written); 104 } 105 } 106 107 void Srf08::GetEcho(void) { 108 float z = 0; 109 ssize_t written, read; 110 uint8_t tx, rx[2]; 111 tx = 2; 112 uint8_t nb_err = 0; 113 114 // si l'us est bloqué, on attend 1ms de plus 115 while (1) { 116 i2cport->GetMutex(); 117 i2cport->SetSlave(address); 118 written = i2cport->Write(&tx, 1); 119 120 if (written < 0) { 121 i2cport->ReleaseMutex(); 122 Thread::Err("erreur rt_dev_write (%s)\n", strerror(-written)); 123 nb_err++; 124 if (nb_err == 20) { 125 Thread::Err("erreur rt_dev_write (%s), too many errors\n", 126 strerror(-written)); 127 return; 128 } 129 SleepMS(1); 130 } else { 131 read = i2cport->Read(rx, 2); 132 i2cport->ReleaseMutex(); 133 // rt_printf("%i %i\n",rx[0],rx[1]); 134 if (read < 0) { 135 if (read != -ETIMEDOUT) 136 Thread::Err("erreur rt_dev_read (%s) %i\n", strerror(-written), read); 137 nb_err++; 138 if (nb_err == 20) { 139 Thread::Err("erreur rt_dev_read (%s), too many errors\n", 140 strerror(-written)); 141 return; 142 } 143 SleepMS(1); 144 } else if (read != 2) { 145 Thread::Err("erreur rt_dev_read %i/2\n", read); 146 return; 147 } else if (read == 2) { 148 break; 149 } 83 150 } 84 85 WarnUponSwitches(false); 86 } 87 88 void Srf08::SendEcho(void) 89 { 90 ssize_t written; 91 uint8_t tx[2]; 92 93 tx[0]=0;//command register 94 tx[1]=82;//ranging mode in usec 95 96 i2cport->GetMutex(); 97 98 i2cport->SetSlave(address); 99 written = i2cport->Write(tx, 2); 100 echo_time=GetTime(); 101 102 i2cport->ReleaseMutex(); 103 104 if(written<0) 105 { 106 Thread::Err("erreur rt_dev_write (%s)\n",strerror(-written)); 151 } 152 153 // if(z!=-1) 154 // revoir ce filtrage!!! 155 { 156 z = 0.000001 * (float)(rx[0] * 256 + rx[1]) * 344 / 157 2; // d=v*t; v=344m/s, t=t usec/2 (aller retour) 158 // if(z>1) rt_printf("%i %i %f\n",rx[0],rx[1],z); 159 // on ne permet pas 2 mesures consecutives + grandes de 10cm 160 if (fabs(z - z_1) > 0.5 && is_init == true) { 161 Printf("z %f (anc %f) %lld\n", z, z_1, echo_time); 162 Printf("a revoir on suppose le sol plan\n"); 163 z = z_1 + (z_1 - z_2); // on suppose que l'on continue a la meme vitesse 107 164 } 108 else if (written != 2) 109 { 110 Thread::Err("erreur rt_dev_write %i/2\n",written); 111 } 112 113 } 114 115 void Srf08::GetEcho(void) 116 { 117 float z=0; 118 ssize_t written,read; 119 uint8_t tx,rx[2]; 120 tx=2; 121 uint8_t nb_err=0; 122 123 //si l'us est bloqué, on attend 1ms de plus 124 while(1) 125 { 126 i2cport->GetMutex(); 127 i2cport->SetSlave(address); 128 written = i2cport->Write(&tx, 1); 129 130 if(written<0) 131 { 132 i2cport->ReleaseMutex(); 133 Thread::Err("erreur rt_dev_write (%s)\n",strerror(-written)); 134 nb_err++; 135 if(nb_err==20) 136 { 137 Thread::Err("erreur rt_dev_write (%s), too many errors\n",strerror(-written)); 138 return; 139 } 140 SleepMS(1); 141 } 142 else 143 { 144 read = i2cport->Read(rx, 2); 145 i2cport->ReleaseMutex(); 146 //rt_printf("%i %i\n",rx[0],rx[1]); 147 if(read<0) 148 { 149 if(read!=-ETIMEDOUT) Thread::Err("erreur rt_dev_read (%s) %i\n",strerror(-written),read); 150 nb_err++; 151 if(nb_err==20) 152 { 153 Thread::Err("erreur rt_dev_read (%s), too many errors\n",strerror(-written)); 154 return; 155 } 156 SleepMS(1); 157 } 158 else if (read != 2) 159 { 160 Thread::Err("erreur rt_dev_read %i/2\n",read); 161 return; 162 } 163 else if(read==2) 164 { 165 break; 166 } 167 } 168 } 169 170 //if(z!=-1) 171 //revoir ce filtrage!!! 172 { 173 z=0.000001*(float)(rx[0]*256+rx[1])*344/2;//d=v*t; v=344m/s, t=t usec/2 (aller retour) 174 //if(z>1) rt_printf("%i %i %f\n",rx[0],rx[1],z); 175 //on ne permet pas 2 mesures consecutives + grandes de 10cm 176 if(fabs(z-z_1)>0.5 && is_init==true) 177 { 178 Printf("z %f (anc %f) %lld\n",z,z_1,echo_time); 179 Printf("a revoir on suppose le sol plan\n"); 180 z=z_1+(z_1-z_2);//on suppose que l'on continue a la meme vitesse 181 } 182 output->SetValue(0,0,z); 183 output->SetDataTime(echo_time+(rx[0]*256+rx[1])*1000); 184 ProcessUpdate(output); 185 z_2=z_1; 186 z_1=z; 187 is_init=true; 188 } 189 } 190 191 192 void Srf08::SetRange(void) 193 { 194 ssize_t written; 195 uint8_t tx[2]; 196 197 tx[0]=2;//range register 198 tx[1]=range->Value();//range*43+43=dist max en mm 199 200 i2cport->GetMutex(); 201 202 i2cport->SetSlave(address); 203 written = i2cport->Write(tx, 2); 204 205 i2cport->ReleaseMutex(); 206 207 if(written<0) 208 { 209 Thread::Err("erreur rt_dev_write (%s)\n",strerror(-written)); 210 } 211 else if (written != 2) 212 { 213 Thread::Err("erreur rt_dev_write %i/2\n",written); 214 } 215 216 } 217 218 void Srf08::SetMaxGain(void) 219 { 220 ssize_t written; 221 uint8_t tx[2]; 222 223 //rt_printf("Srf08::SetMaxGain: %s ->%i\n",IODevice::ObjectName().c_str(),gain->Value()); 224 225 tx[0]=1;//max gain register 226 tx[1]=gain->Value(); 227 228 i2cport->GetMutex(); 229 230 i2cport->SetSlave(address); 231 written = i2cport->Write(tx, 2); 232 233 i2cport->ReleaseMutex(); 234 235 if(written<0) 236 { 237 Thread::Err("erreur write (%s)\n",strerror(-written)); 238 } 239 else if (written != 2) 240 { 241 Thread::Err("erreur write %i/2\n",written); 242 } 165 output->SetValue(0, 0, z); 166 output->SetDataTime(echo_time + (rx[0] * 256 + rx[1]) * 1000); 167 ProcessUpdate(output); 168 z_2 = z_1; 169 z_1 = z; 170 is_init = true; 171 } 172 } 173 174 void Srf08::SetRange(void) { 175 ssize_t written; 176 uint8_t tx[2]; 177 178 tx[0] = 2; // range register 179 tx[1] = range->Value(); // range*43+43=dist max en mm 180 181 i2cport->GetMutex(); 182 183 i2cport->SetSlave(address); 184 written = i2cport->Write(tx, 2); 185 186 i2cport->ReleaseMutex(); 187 188 if (written < 0) { 189 Thread::Err("erreur rt_dev_write (%s)\n", strerror(-written)); 190 } else if (written != 2) { 191 Thread::Err("erreur rt_dev_write %i/2\n", written); 192 } 193 } 194 195 void Srf08::SetMaxGain(void) { 196 ssize_t written; 197 uint8_t tx[2]; 198 199 // rt_printf("Srf08::SetMaxGain: %s 200 // ->%i\n",IODevice::ObjectName().c_str(),gain->Value()); 201 202 tx[0] = 1; // max gain register 203 tx[1] = gain->Value(); 204 205 i2cport->GetMutex(); 206 207 i2cport->SetSlave(address); 208 written = i2cport->Write(tx, 2); 209 210 i2cport->ReleaseMutex(); 211 212 if (written < 0) { 213 Thread::Err("erreur write (%s)\n", strerror(-written)); 214 } else if (written != 2) { 215 Thread::Err("erreur write %i/2\n", written); 216 } 243 217 } 244 218 -
trunk/lib/FlairSensorActuator/src/Srf08.h
r3 r15 17 17 #include <UsRangeFinder.h> 18 18 19 namespace flair 20 { 21 namespace core 22 { 23 class FrameworkManager; 24 class I2cPort; 25 } 26 namespace gui 27 { 28 class SpinBox;; 29 } 19 namespace flair { 20 namespace core { 21 class FrameworkManager; 22 class I2cPort; 23 } 24 namespace gui { 25 class SpinBox; 26 ; 27 } 30 28 } 31 29 32 namespace flair 33 { 34 namespace sensor 35 { 36 /*! \class Srf08 37 * 38 * \brief Class for ultra sonic SRF08 39 */ 40 class Srf08 : public core::Thread, public UsRangeFinder 41 { 30 namespace flair { 31 namespace sensor { 32 /*! \class Srf08 33 * 34 * \brief Class for ultra sonic SRF08 35 */ 36 class Srf08 : public core::Thread, public UsRangeFinder { 42 37 43 public: 44 /*! 45 * \brief Constructor 46 * 47 * Construct a SimuUs. Control part. 48 * 49 * \param parent parent 50 * \param name name 51 * \param i2cport i2c port 52 * \param address i2c slave address 53 * \param priority priority of the Thread 54 */ 55 Srf08(const core::FrameworkManager* parent,std::string name,core::I2cPort* i2cport,uint16_t address,uint8_t priority); 38 public: 39 /*! 40 * \brief Constructor 41 * 42 * Construct a SimuUs. Control part. 43 * 44 * \param parent parent 45 * \param name name 46 * \param i2cport i2c port 47 * \param address i2c slave address 48 * \param priority priority of the Thread 49 */ 50 Srf08(const core::FrameworkManager *parent, std::string name, 51 core::I2cPort *i2cport, uint16_t address, uint8_t priority); 56 52 57 58 59 60 61 53 /*! 54 * \brief Destructor 55 * 56 */ 57 ~Srf08(); 62 58 63 64 65 66 67 68 59 /*! 60 * \brief Set Range 61 * 62 * check datasheet for values 63 */ 64 void SetRange(void); 69 65 70 71 72 73 74 75 66 /*! 67 * \brief Set Max Gain 68 * 69 * check datasheet for values 70 */ 71 void SetMaxGain(void); 76 72 77 78 79 80 81 82 83 84 85 73 private: 74 /*! 75 * \brief Update using provided datas 76 * 77 * Reimplemented from IODevice. 78 * 79 * \param data data from the parent to process 80 */ 81 void UpdateFrom(const core::io_data *data){}; 86 82 87 88 89 90 91 92 93 83 /*! 84 * \brief Run function 85 * 86 * Reimplemented from Thread. 87 * 88 */ 89 void Run(void); 94 90 95 96 91 void SendEcho(void); 92 void GetEcho(void); 97 93 98 99 100 float z_1,z_2;101 gui::SpinBox *gain,*range;102 103 core::I2cPort*i2cport;104 94 bool is_init; 95 core::Time echo_time; 96 float z_1, z_2; 97 gui::SpinBox *gain, *range; 98 uint16_t address; 99 core::I2cPort *i2cport; 100 }; 105 101 } // end namespace sensor 106 102 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/TargetController.cpp
r3 r15 31 31 using std::string; 32 32 33 namespace flair 34 { 35 namespace sensor 36 { 33 namespace flair { 34 namespace sensor { 37 35 38 TargetController::TargetController(const FrameworkManager * parent,string name,uint8_t priority) :39 Thread(parent,name,priority),IODevice(parent,name) {40 main_tab=new Tab(getFrameworkManager()->GetTabWidget(),name);41 TabWidget* tab=new TabWidget(main_tab->NewRow(),name);42 setup_tab=new Tab(tab,"Reglages");43 36 TargetController::TargetController(const FrameworkManager *parent, string name, 37 uint8_t priority) 38 : Thread(parent, name, priority), IODevice(parent, name) { 39 main_tab = new Tab(getFrameworkManager()->GetTabWidget(), name); 40 TabWidget *tab = new TabWidget(main_tab->NewRow(), name); 41 setup_tab = new Tab(tab, "Reglages"); 44 42 } 45 43 46 44 TargetController::~TargetController() { 47 48 45 SafeStop(); 46 Join(); 49 47 } 50 48 51 49 std::string TargetController::GetAxisName(unsigned int axisId) const { 52 return string("axis")+std::to_string(axisId);50 return string("axis") + std::to_string(axisId); 53 51 } 54 52 55 53 std::string TargetController::GetButtonName(unsigned int buttonId) const { 56 return string("button")+std::to_string(buttonId);54 return string("button") + std::to_string(buttonId); 57 55 } 58 56 59 57 bool TargetController::SetLedOn(unsigned int ledId) { 60 if (!IsControllerActionSupported(ControllerAction::SetLedOn)) return false; 61 SwitchLedMessage *msgLed=new SwitchLedMessage(true,ledId); 62 changeStateQueue.push(msgLed); 63 return true; 58 if (!IsControllerActionSupported(ControllerAction::SetLedOn)) 59 return false; 60 SwitchLedMessage *msgLed = new SwitchLedMessage(true, ledId); 61 changeStateQueue.push(msgLed); 62 return true; 64 63 } 65 64 66 65 bool TargetController::SetLedOff(unsigned int ledId) { 67 if (!IsControllerActionSupported(ControllerAction::SetLedOn)) return false; 68 SwitchLedMessage *msgLed=new SwitchLedMessage(false,ledId); 69 changeStateQueue.push(msgLed); 70 return true; 66 if (!IsControllerActionSupported(ControllerAction::SetLedOn)) 67 return false; 68 SwitchLedMessage *msgLed = new SwitchLedMessage(false, ledId); 69 changeStateQueue.push(msgLed); 70 return true; 71 71 } 72 72 73 bool TargetController::Rumble(unsigned int leftForce,unsigned int leftTimeout,unsigned int rightForce,unsigned int rightTimeout) { 74 if (!IsControllerActionSupported(ControllerAction::Rumble)) return false; 75 RumbleMessage *msgRumble=new RumbleMessage(leftForce,leftTimeout,rightForce,rightTimeout); 76 changeStateQueue.push(msgRumble); 77 return true; 73 bool TargetController::Rumble(unsigned int leftForce, unsigned int leftTimeout, 74 unsigned int rightForce, 75 unsigned int rightTimeout) { 76 if (!IsControllerActionSupported(ControllerAction::Rumble)) 77 return false; 78 RumbleMessage *msgRumble = 79 new RumbleMessage(leftForce, leftTimeout, rightForce, rightTimeout); 80 changeStateQueue.push(msgRumble); 81 return true; 78 82 } 79 83 80 bool TargetController::FlashLed(unsigned int ledId,unsigned int onTimeout,unsigned int offTimeout){ 81 if (!IsControllerActionSupported(ControllerAction::FlashLed)) return false; 82 FlashLedMessage *msgFlashLed=new FlashLedMessage(ledId,onTimeout,offTimeout); 83 changeStateQueue.push(msgFlashLed); 84 return true; 84 bool TargetController::FlashLed(unsigned int ledId, unsigned int onTimeout, 85 unsigned int offTimeout) { 86 if (!IsControllerActionSupported(ControllerAction::FlashLed)) 87 return false; 88 FlashLedMessage *msgFlashLed = 89 new FlashLedMessage(ledId, onTimeout, offTimeout); 90 changeStateQueue.push(msgFlashLed); 91 return true; 85 92 } 86 93 87 float TargetController::GetAxisValue(unsigned int axisId) const{ 88 //TODO we'd better throw an exception here 89 if (axis==NULL) return 0; 94 float TargetController::GetAxisValue(unsigned int axisId) const { 95 // TODO we'd better throw an exception here 96 if (axis == NULL) 97 return 0; 90 98 91 92 float axisValue=axis->Value(axisId, 0);93 94 99 axis->GetMutex(); 100 float axisValue = axis->Value(axisId, 0); 101 axis->ReleaseMutex(); 102 return axisValue; 95 103 } 96 104 97 bool TargetController::IsButtonPressed(unsigned int buttonId) const{ 98 //TODO we'd better throw an exception here 99 if (button==NULL) return false; 105 bool TargetController::IsButtonPressed(unsigned int buttonId) const { 106 // TODO we'd better throw an exception here 107 if (button == NULL) 108 return false; 100 109 101 102 bool buttonValue=button->Value(buttonId, 0);103 104 110 button->GetMutex(); 111 bool buttonValue = button->Value(buttonId, 0); 112 button->ReleaseMutex(); 113 return buttonValue; 105 114 } 106 115 107 116 void TargetController::Run() { 108 117 Message *message; 109 118 110 if(getFrameworkManager()->ErrorOccured()||!ControllerInitialization()) { 119 if (getFrameworkManager()->ErrorOccured() || !ControllerInitialization()) { 120 SafeStop(); 121 Thread::Err("An error occured, we don't proceed with the loop.\n"); 122 } else { 123 124 axis = new cvmatrix((IODevice *)this, axisNumber, 1, floatType); 125 button = 126 new cvmatrix((IODevice *)this, buttonNumber, 1, SignedIntegerType(8)); 127 128 while (!ToBeStopped()) { 129 // Thread::Info("Debug: entering acquisition loop\n"); 130 if (getFrameworkManager()->ConnectionLost() == true) 111 131 SafeStop(); 112 Thread::Err("An error occured, we don't proceed with the loop.\n");113 } else {114 132 115 axis=new cvmatrix((IODevice *)this,axisNumber,1,floatType);116 button=new cvmatrix((IODevice *)this,buttonNumber,1,SignedIntegerType(8));133 if (IsDataFrameReady()) { 134 // Thread::Info("Debug: data frame is ready\n"); 117 135 118 while(!ToBeStopped()) { 119 //Thread::Info("Debug: entering acquisition loop\n"); 120 if(getFrameworkManager()->ConnectionLost()==true) SafeStop(); 136 AcquireAxisData(*axis); 137 AcquireButtonData(*button); 121 138 122 if (IsDataFrameReady()) { 123 //Thread::Info("Debug: data frame is ready\n"); 139 // send the data 140 axis->SetDataTime(GetTime()); 141 ProcessUpdate(axis); 124 142 125 AcquireAxisData(*axis); 126 AcquireButtonData(*button); 143 // send pending controller state change request(s) 127 144 128 //send the data 129 axis->SetDataTime(GetTime()); 130 ProcessUpdate(axis); 131 132 //send pending controller state change request(s) 133 134 while(changeStateQueue.size()!=0) { 135 message=changeStateQueue.front(); 136 if (ProcessMessage(message)) { 137 changeStateQueue.pop(); 138 delete message; 139 } 140 } 141 } else { 142 //Thread::Info("Debug: relax...\n"); 143 usleep(20000); //20ms 144 } 145 while (changeStateQueue.size() != 0) { 146 message = changeStateQueue.front(); 147 if (ProcessMessage(message)) { 148 changeStateQueue.pop(); 149 delete message; 150 } 145 151 } 152 } else { 153 // Thread::Info("Debug: relax...\n"); 154 usleep(20000); // 20ms 155 } 146 156 } 157 } 147 158 } 148 159 149 Tab* TargetController::GetTab() const { 150 return setup_tab; 151 } 160 Tab *TargetController::GetTab() const { return setup_tab; } 152 161 153 162 } // end namespace sensor -
trunk/lib/FlairSensorActuator/src/TargetController.h
r3 r15 25 25 26 26 namespace flair { 27 28 29 30 31 32 33 34 35 36 37 27 namespace core { 28 class FrameworkManager; 29 class cvmatrix; 30 class Socket; 31 class io_data; 32 } 33 namespace gui { 34 class Tab; 35 class TabWidget; 36 class DataPlot1D; 37 } 38 38 } 39 39 40 namespace flair { namespace sensor { 41 enum class ControllerAction; 40 namespace flair { 41 namespace sensor { 42 enum class ControllerAction; 42 43 43 /*! \class TargetController 44 * 45 * \brief Base Class for target side remote controls 46 * 47 */ 48 class TargetController : public core::Thread, public core::IODevice { 49 public: 50 TargetController(const core::FrameworkManager* parent,std::string name,uint8_t priority=0); 51 ~TargetController(); 52 //void DrawUserInterface(); 53 virtual bool IsConnected() const=0; 54 virtual bool IsDataFrameReady()=0; 55 //axis stuff 56 unsigned int GetAxisNumber() const; 57 virtual std::string GetAxisName(unsigned int axisId) const; 58 float GetAxisValue(unsigned int axisId) const;// always in the range [-1.0,1.0] 59 //button stuff 60 unsigned int GetButtonNumber() const; 61 bool IsButtonPressed(unsigned int buttonId) const; 62 virtual std::string GetButtonName(unsigned int axisId) const; 63 //controller state stuff 64 virtual bool IsControllerActionSupported(ControllerAction action) const {return false;}; 65 bool SetLedOn(unsigned int ledId); 66 bool SetLedOff(unsigned int ledId); 67 bool Rumble(unsigned int left_force,unsigned int left_timeout,unsigned int right_force,unsigned int right_timeout); 68 bool FlashLed(unsigned int ledId,unsigned int on_timeout,unsigned int off_timeout); 69 void UpdateFrom(const core::io_data *data){}; //TODO 70 gui::Tab* GetTab(void) const; 44 /*! \class TargetController 45 * 46 * \brief Base Class for target side remote controls 47 * 48 */ 49 class TargetController : public core::Thread, public core::IODevice { 50 public: 51 TargetController(const core::FrameworkManager *parent, std::string name, 52 uint8_t priority = 0); 53 ~TargetController(); 54 // void DrawUserInterface(); 55 virtual bool IsConnected() const = 0; 56 virtual bool IsDataFrameReady() = 0; 57 // axis stuff 58 unsigned int GetAxisNumber() const; 59 virtual std::string GetAxisName(unsigned int axisId) const; 60 float 61 GetAxisValue(unsigned int axisId) const; // always in the range [-1.0,1.0] 62 // button stuff 63 unsigned int GetButtonNumber() const; 64 bool IsButtonPressed(unsigned int buttonId) const; 65 virtual std::string GetButtonName(unsigned int axisId) const; 66 // controller state stuff 67 virtual bool IsControllerActionSupported(ControllerAction action) const { 68 return false; 69 }; 70 bool SetLedOn(unsigned int ledId); 71 bool SetLedOff(unsigned int ledId); 72 bool Rumble(unsigned int left_force, unsigned int left_timeout, 73 unsigned int right_force, unsigned int right_timeout); 74 bool FlashLed(unsigned int ledId, unsigned int on_timeout, 75 unsigned int off_timeout); 76 void UpdateFrom(const core::io_data *data){}; // TODO 77 gui::Tab *GetTab(void) const; 71 78 72 protected: 73 virtual bool ProcessMessage(core::Message *msg)=0; 74 void QueueMessage(core::Message msg); 75 virtual bool ControllerInitialization()=0;// {return true;}; 76 //axis stuff 77 unsigned int axisNumber; 78 core::cvmatrix* axis=NULL; 79 virtual void AcquireAxisData(core::cvmatrix &axis)=0; //responsible for getting the axis data from the hardware 80 uint16_t bitsPerAxis; 81 //button stuff 82 unsigned int buttonNumber; 83 core::cvmatrix* button=NULL; 84 virtual void AcquireButtonData(core::cvmatrix &button)=0; //responsible for getting the button data from the hardware 85 //controller state stuff 86 unsigned int ledNumber; 87 private: 88 void Run(); 89 std::queue<core::Message *> changeStateQueue; 90 flair::gui::Tab* main_tab; 91 flair::gui::Tab* setup_tab; 92 }; 79 protected: 80 virtual bool ProcessMessage(core::Message *msg) = 0; 81 void QueueMessage(core::Message msg); 82 virtual bool ControllerInitialization() = 0; // {return true;}; 83 // axis stuff 84 unsigned int axisNumber; 85 core::cvmatrix *axis = NULL; 86 virtual void AcquireAxisData(core::cvmatrix &axis) = 0; // responsible for 87 // getting the axis 88 // data from the 89 // hardware 90 uint16_t bitsPerAxis; 91 // button stuff 92 unsigned int buttonNumber; 93 core::cvmatrix *button = NULL; 94 virtual void AcquireButtonData(core::cvmatrix &button) = 0; // responsible for 95 // getting the 96 // button data 97 // from the 98 // hardware 99 // controller state stuff 100 unsigned int ledNumber; 93 101 94 }} 102 private: 103 void Run(); 104 std::queue<core::Message *> changeStateQueue; 105 flair::gui::Tab *main_tab; 106 flair::gui::Tab *setup_tab; 107 }; 108 } 109 } 95 110 96 111 #endif // TARGETCONTROLLER_H -
trunk/lib/FlairSensorActuator/src/TargetEthController.cpp
r3 r15 12 12 // 13 13 // purpose: class that gets remote controls through an ethernet connection. 14 // Typical use case: a remote control is plugged in a workstation and sends remote control 14 // Typical use case: a remote control is plugged in a workstation 15 // and sends remote control 15 16 // data to a distant target (this class) through Wifi// 16 17 // … … 32 33 using std::string; 33 34 34 namespace flair 35 { 36 namespace sensor 37 { 38 39 TargetEthController::TargetEthController(const FrameworkManager* parent,string name,uint16_t _port,uint8_t priority) : 40 TargetController(parent,name,priority),listeningPort(_port),receiveCurrentPosition(0) { 41 const bool blocking=true; 42 listeningSocket=new TcpSocket(parent,"TEC_listening_socket",blocking,blocking); 43 dataSocket=new Socket(parent,"TEC_data_socket",_port+1); //receiving side 35 namespace flair { 36 namespace sensor { 37 38 TargetEthController::TargetEthController(const FrameworkManager *parent, 39 string name, uint16_t _port, 40 uint8_t priority) 41 : TargetController(parent, name, priority), listeningPort(_port), 42 receiveCurrentPosition(0) { 43 const bool blocking = true; 44 listeningSocket = 45 new TcpSocket(parent, "TEC_listening_socket", blocking, blocking); 46 dataSocket = 47 new Socket(parent, "TEC_data_socket", _port + 1); // receiving side 44 48 } 45 49 46 50 TargetEthController::~TargetEthController() { 47 //We are (currently) the server side. We must ask the client side to initiate tcp connexion closing to avoid the server socket 48 //to get stuck in TIME_WAIT state 49 Message msg(32); 50 if (controlSocket) { 51 Message cancelAcquisition(sizeof(ControllerAction)); 52 ControllerAction exit=ControllerAction::Exit; 53 memcpy(cancelAcquisition.buffer,&exit,sizeof(ControllerAction)); 54 controlSocket->SendMessage(cancelAcquisition.buffer,cancelAcquisition.bufferSize); 55 //We don't expect any more data from the client, we're just waiting for the socket to be closed by the client 56 controlSocket->RecvMessage(msg.buffer,msg.bufferSize); 57 } 58 59 //TargetController calls TargetEthController methods in its run 60 //we must stop the thread now 61 SafeStop(); 62 Join(); 51 // We are (currently) the server side. We must ask the client side to initiate 52 // tcp connexion closing to avoid the server socket 53 // to get stuck in TIME_WAIT state 54 Message msg(32); 55 if (controlSocket) { 56 Message cancelAcquisition(sizeof(ControllerAction)); 57 ControllerAction exit = ControllerAction::Exit; 58 memcpy(cancelAcquisition.buffer, &exit, sizeof(ControllerAction)); 59 controlSocket->SendMessage(cancelAcquisition.buffer, 60 cancelAcquisition.bufferSize); 61 // We don't expect any more data from the client, we're just waiting for the 62 // socket to be closed by the client 63 controlSocket->RecvMessage(msg.buffer, msg.bufferSize); 64 } 65 66 // TargetController calls TargetEthController methods in its run 67 // we must stop the thread now 68 SafeStop(); 69 Join(); 63 70 } 64 71 65 72 bool TargetEthController::IsConnected() const { 66 //TODO 67 } 68 69 bool TargetEthController::IsDataFrameReady(){ 70 //read up to the last data 71 ssize_t received; 72 size_t bytesToReceive=dataFrameSize-receiveCurrentPosition; 73 bool fullDatagramReceived=false; 74 75 do { 76 received=dataSocket->RecvMessage(receiveFrameBuffer+receiveCurrentPosition,bytesToReceive,TIME_NONBLOCK); 77 if (received>0) { 78 bytesToReceive-=received; 79 if (bytesToReceive==0) { 80 //a full datagram has been read in receiveFrameBuffer 81 fullDatagramReceived=true; 82 receiveCurrentPosition=0; 83 //we swap the data and reception buffers to avoid copy 84 char *swapFrameBuffer=dataFrameBuffer; 85 dataFrameBuffer=receiveFrameBuffer; 86 receiveFrameBuffer=swapFrameBuffer; 87 } 88 } 89 } while (!received<0); 90 91 return fullDatagramReceived; 92 } 93 94 uint8_t TargetEthController::getByteOrNull(char *buffer,int byte,size_t bufferSize) { 95 if (byte<bufferSize) return buffer[byte]; 96 else return 0; 97 } 98 99 uint32_t TargetEthController::charBufferToUint32(char *buffer, size_t bufferSize) { 100 union { 101 uint32_t int32; 102 char byte[4]; 103 } bitField; 104 if (!IsBigEndian()) { 105 bitField.byte[0]=getByteOrNull(buffer,3,bufferSize); 106 bitField.byte[1]=getByteOrNull(buffer,2,bufferSize); 107 bitField.byte[2]=getByteOrNull(buffer,1,bufferSize); 108 bitField.byte[3]=getByteOrNull(buffer,0,bufferSize); 109 } else { 110 bitField.byte[0]=getByteOrNull(buffer,0,bufferSize); 111 bitField.byte[1]=getByteOrNull(buffer,1,bufferSize); 112 bitField.byte[2]=getByteOrNull(buffer,2,bufferSize); 113 bitField.byte[3]=getByteOrNull(buffer,3,bufferSize); 114 } 115 return bitField.int32; 116 } 117 118 //read _up_to_16_bits_ in a buffer 119 uint16_t TargetEthController::readBits(uint8_t offsetInBits,uint8_t valueSizeInBits,char *buffer,size_t bufferSize) { 120 //parameters check 121 if (valueSizeInBits>16) throw std::range_error("bitfield should be at max 16bits wide"); 122 size_t minBufferSize=(offsetInBits+valueSizeInBits)/8; 123 if ((offsetInBits+valueSizeInBits)%8!=0) minBufferSize++; 124 if (bufferSize<minBufferSize) throw std::range_error("buffer too small"); 125 //skip first bytes 126 size_t bytesToSkip=offsetInBits/8; 127 buffer+=bytesToSkip; 128 bufferSize-=bytesToSkip; 129 offsetInBits-=bytesToSkip*8; 130 //take care of endianness 131 uint32_t value=charBufferToUint32(buffer,bufferSize); 132 value>>=32-offsetInBits-valueSizeInBits; 133 value&=(1<<valueSizeInBits)-1; 134 return (uint16_t)value; 73 // TODO 74 } 75 76 bool TargetEthController::IsDataFrameReady() { 77 // read up to the last data 78 ssize_t received; 79 size_t bytesToReceive = dataFrameSize - receiveCurrentPosition; 80 bool fullDatagramReceived = false; 81 82 do { 83 received = 84 dataSocket->RecvMessage(receiveFrameBuffer + receiveCurrentPosition, 85 bytesToReceive, TIME_NONBLOCK); 86 if (received > 0) { 87 bytesToReceive -= received; 88 if (bytesToReceive == 0) { 89 // a full datagram has been read in receiveFrameBuffer 90 fullDatagramReceived = true; 91 receiveCurrentPosition = 0; 92 // we swap the data and reception buffers to avoid copy 93 char *swapFrameBuffer = dataFrameBuffer; 94 dataFrameBuffer = receiveFrameBuffer; 95 receiveFrameBuffer = swapFrameBuffer; 96 } 97 } 98 } while (!received < 0); 99 100 return fullDatagramReceived; 101 } 102 103 uint8_t TargetEthController::getByteOrNull(char *buffer, int byte, 104 size_t bufferSize) { 105 if (byte < bufferSize) 106 return buffer[byte]; 107 else 108 return 0; 109 } 110 111 uint32_t TargetEthController::charBufferToUint32(char *buffer, 112 size_t bufferSize) { 113 union { 114 uint32_t int32; 115 char byte[4]; 116 } bitField; 117 if (!IsBigEndian()) { 118 bitField.byte[0] = getByteOrNull(buffer, 3, bufferSize); 119 bitField.byte[1] = getByteOrNull(buffer, 2, bufferSize); 120 bitField.byte[2] = getByteOrNull(buffer, 1, bufferSize); 121 bitField.byte[3] = getByteOrNull(buffer, 0, bufferSize); 122 } else { 123 bitField.byte[0] = getByteOrNull(buffer, 0, bufferSize); 124 bitField.byte[1] = getByteOrNull(buffer, 1, bufferSize); 125 bitField.byte[2] = getByteOrNull(buffer, 2, bufferSize); 126 bitField.byte[3] = getByteOrNull(buffer, 3, bufferSize); 127 } 128 return bitField.int32; 129 } 130 131 // read _up_to_16_bits_ in a buffer 132 uint16_t TargetEthController::readBits(uint8_t offsetInBits, 133 uint8_t valueSizeInBits, char *buffer, 134 size_t bufferSize) { 135 // parameters check 136 if (valueSizeInBits > 16) 137 throw std::range_error("bitfield should be at max 16bits wide"); 138 size_t minBufferSize = (offsetInBits + valueSizeInBits) / 8; 139 if ((offsetInBits + valueSizeInBits) % 8 != 0) 140 minBufferSize++; 141 if (bufferSize < minBufferSize) 142 throw std::range_error("buffer too small"); 143 // skip first bytes 144 size_t bytesToSkip = offsetInBits / 8; 145 buffer += bytesToSkip; 146 bufferSize -= bytesToSkip; 147 offsetInBits -= bytesToSkip * 8; 148 // take care of endianness 149 uint32_t value = charBufferToUint32(buffer, bufferSize); 150 value >>= 32 - offsetInBits - valueSizeInBits; 151 value &= (1 << valueSizeInBits) - 1; 152 return (uint16_t)value; 135 153 } 136 154 137 155 void TargetEthController::AcquireAxisData(core::cvmatrix &axis) { 138 axis.GetMutex(); 139 //char testFrameBuffer[3]={(char)0x09,(char)0x59,(char)0xB8}; 140 for (unsigned int i=0;i<axisNumber;i++) { 141 uint16_t rawAxisValue=readBits(i*bitsPerAxis,bitsPerAxis,dataFrameBuffer,dataFrameSize); 142 // uint16_t rawAxisValue=readBits(i*bitsPerAxis,bitsPerAxis,testFrameBuffer); 143 uint16_t scale=1<<(bitsPerAxis-1); 144 //Thread::Info("RawAxisValue=%d, scale=%d => scaled rawValue=%d, float value)%f\n",rawAxisValue,scale,rawAxisValue-scale,(rawAxisValue-scale)/(float)scale); 145 axis.SetValueNoMutex(i,0,(rawAxisValue-scale)/(float)scale); 146 } 147 axis.ReleaseMutex(); 156 axis.GetMutex(); 157 // char testFrameBuffer[3]={(char)0x09,(char)0x59,(char)0xB8}; 158 for (unsigned int i = 0; i < axisNumber; i++) { 159 uint16_t rawAxisValue = 160 readBits(i * bitsPerAxis, bitsPerAxis, dataFrameBuffer, dataFrameSize); 161 // uint16_t 162 // rawAxisValue=readBits(i*bitsPerAxis,bitsPerAxis,testFrameBuffer); 163 uint16_t scale = 1 << (bitsPerAxis - 1); 164 // Thread::Info("RawAxisValue=%d, scale=%d => scaled rawValue=%d, float 165 // value)%f\n",rawAxisValue,scale,rawAxisValue-scale,(rawAxisValue-scale)/(float)scale); 166 axis.SetValueNoMutex(i, 0, (rawAxisValue - scale) / (float)scale); 167 } 168 axis.ReleaseMutex(); 148 169 } 149 170 150 171 void TargetEthController::AcquireButtonData(core::cvmatrix &button) { 151 uint8_t buttonValue; 152 int currentButton=0; 153 button.GetMutex(); 154 /* 155 for (unsigned int i=0;i<buttonNumber;i++) { 156 memcpy(&buttonValue,buttonOffset+i*sizeof(bool),sizeof(bool)); 157 dataSocket->NetworkToHost((char*)&buttonValue,sizeof(bool)); 158 button.SetValueNoMutex(i,0,buttonValue); 159 // if (buttonValue) Thread::Info("Debug: button '%s' pressed\n", GetButtonName(i).c_str()); 160 }*/ 161 for (unsigned int i=0;i<buttonNumber/8;i++) { 162 memcpy(&buttonValue,dataFrameBuffer+buttonOffset+i*sizeof(uint8_t),sizeof(uint8_t)); 163 // dataSocket->NetworkToHost((char*)&buttonValue,sizeof(uint8_t)); 164 for(unsigned int j=0;j<8;j++) { 165 button.SetValueNoMutex(currentButton,0,(buttonValue>>j)&0x01); 166 currentButton++; 167 } 168 } 169 button.ReleaseMutex(); 170 } 171 172 string TargetEthController::GetAxisName(unsigned int axisId) const{ 173 //TODO: should throw an exception if axisName==NULL or axisId>axisNumber 174 return axisName[axisId]; 175 } 176 177 string TargetEthController::GetButtonName(unsigned int buttonId) const{ 178 //TODO: should throw an exception if buttonName==NULL or buttonId>buttonNumber 179 return buttonName[buttonId]; 172 uint8_t buttonValue; 173 int currentButton = 0; 174 button.GetMutex(); 175 /* 176 for (unsigned int i=0;i<buttonNumber;i++) { 177 memcpy(&buttonValue,buttonOffset+i*sizeof(bool),sizeof(bool)); 178 dataSocket->NetworkToHost((char*)&buttonValue,sizeof(bool)); 179 button.SetValueNoMutex(i,0,buttonValue); 180 // if (buttonValue) Thread::Info("Debug: button '%s' pressed\n", 181 GetButtonName(i).c_str()); 182 }*/ 183 for (unsigned int i = 0; i < buttonNumber / 8; i++) { 184 memcpy(&buttonValue, dataFrameBuffer + buttonOffset + i * sizeof(uint8_t), 185 sizeof(uint8_t)); 186 // dataSocket->NetworkToHost((char*)&buttonValue,sizeof(uint8_t)); 187 for (unsigned int j = 0; j < 8; j++) { 188 button.SetValueNoMutex(currentButton, 0, (buttonValue >> j) & 0x01); 189 currentButton++; 190 } 191 } 192 button.ReleaseMutex(); 193 } 194 195 string TargetEthController::GetAxisName(unsigned int axisId) const { 196 // TODO: should throw an exception if axisName==NULL or axisId>axisNumber 197 return axisName[axisId]; 198 } 199 200 string TargetEthController::GetButtonName(unsigned int buttonId) const { 201 // TODO: should throw an exception if buttonName==NULL or 202 // buttonId>buttonNumber 203 return buttonName[buttonId]; 180 204 } 181 205 182 206 bool TargetEthController::ProcessMessage(Message *msg) { 183 return !(controlSocket->SendMessage(msg->buffer,msg->bufferSize,0)<0); 184 } 185 186 bool TargetEthController::IsControllerActionSupported(ControllerAction action) const { 187 //TODO: here we should ask the remote side (host). Probably through the control socket 188 switch(action) { 189 case ControllerAction::SetLedOn: 190 return true; 191 case ControllerAction::SetLedOff: 192 return true; 193 case ControllerAction::Rumble: 194 return true; 195 case ControllerAction::FlashLed: 196 return true; 197 default: 207 return !(controlSocket->SendMessage(msg->buffer, msg->bufferSize, 0) < 0); 208 } 209 210 bool TargetEthController::IsControllerActionSupported( 211 ControllerAction action) const { 212 // TODO: here we should ask the remote side (host). Probably through the 213 // control socket 214 switch (action) { 215 case ControllerAction::SetLedOn: 216 return true; 217 case ControllerAction::SetLedOff: 218 return true; 219 case ControllerAction::Rumble: 220 return true; 221 case ControllerAction::FlashLed: 222 return true; 223 default: 224 return false; 225 } 226 } 227 228 bool TargetEthController::ControllerInitialization() { 229 char message[1024]; 230 ssize_t received; 231 bool connected = false; 232 bool mustReadMore; 233 234 listeningSocket->Listen(listeningPort); 235 Thread::Info("Debug: Listening to port %d\n", listeningPort); 236 // accept incoming connection 237 bool connectionAccepted = false; 238 while (!connectionAccepted) { 239 controlSocket = listeningSocket->Accept(10); 240 if (controlSocket == nullptr) { 241 // Timeout (or error btw) 242 if (ToBeStopped()) 198 243 return false; 199 } 200 } 201 202 bool TargetEthController::ControllerInitialization() { 203 char message[1024]; 204 ssize_t received; 205 bool connected=false; 206 bool mustReadMore; 207 208 listeningSocket->Listen(listeningPort); 209 Thread::Info("Debug: Listening to port %d\n",listeningPort); 210 //accept incoming connection 211 bool connectionAccepted=false; 212 while (!connectionAccepted) { 213 controlSocket=listeningSocket->Accept(10); 214 if (controlSocket==nullptr) { 215 //Timeout (or error btw) 216 if (ToBeStopped()) return false; 217 } else connectionAccepted=true; 218 } 219 Thread::Info("Debug: Connexion accepted\n"); 220 221 //get axis stuff 222 bool axisNumberRead=false; 223 while (!axisNumberRead) { 224 try { 225 axisNumber=controlSocket->ReadUInt32(10); 226 //Thread::Info("Debug: axisNumber %d\n", axisNumber); 227 axisNumberRead=true; 228 } 229 catch (std::runtime_error e) { 230 //timeout 231 if (ToBeStopped()) return false; 232 } 233 } 234 bool bitsPerAxisRead=false; 235 while (!bitsPerAxisRead) { 236 try { 237 bitsPerAxis=controlSocket->ReadUInt32(10); 238 //Thread::Info("Debug: bits per axis %d\n", bitsPerAxis); 239 bitsPerAxisRead=true; 240 } 241 catch (std::runtime_error e) { 242 //timeout 243 if (ToBeStopped()) return false; 244 } 245 } 246 axisName=new string[axisNumber]; 247 for (unsigned int i=0;i<axisNumber;i++) { 248 //read string size 249 int stringSize; 250 bool stringSizeRead=false; 251 while (!stringSizeRead) { 252 try { 253 stringSize=controlSocket->ReadUInt32(10); 254 stringSizeRead=true; 255 } 256 catch (std::runtime_error e) { 257 //timeout 258 if (ToBeStopped()) return false; 259 } 260 } 261 //read string 262 bool axisNameRead=false; 263 while (!axisNameRead) { 264 try { 265 axisName[i]=controlSocket->ReadString(stringSize,10); 266 axisNameRead=true; 267 } 268 catch (std::runtime_error e) { 269 //timeout 270 if (ToBeStopped()) return false; 271 } 272 } 273 //Thread::Info("Debug: axisName for axis %d %s\n", i, axisName[i].c_str()); 274 } 275 276 //get button stuff 277 bool buttonNumberRead=false; 278 while (!buttonNumberRead) { 279 try { 280 buttonNumber=controlSocket->ReadUInt32(10); 281 buttonNumberRead=true; 282 } 283 catch (std::runtime_error e) { 284 //timeout 285 if (ToBeStopped()) return false; 286 } 287 } 288 //Thread::Info("Debug: buttonNumber %d\n", buttonNumber); 289 buttonName=new string[buttonNumber]; 290 for (unsigned int i=0;i<buttonNumber;i++) { 291 //read string size 292 int stringSize; 293 bool stringSizeRead=false; 294 while (!stringSizeRead) { 295 try { 296 stringSize=controlSocket->ReadUInt32(10); 297 stringSizeRead=true; 298 } 299 catch (std::runtime_error e) { 300 //timeout 301 if (ToBeStopped()) return false; 302 } 303 } 304 //read string 305 bool buttonNameRead=false; 306 while (!buttonNameRead) { 307 try { 308 buttonName[i]=controlSocket->ReadString(stringSize,10); 309 buttonNameRead=true; 310 } 311 catch (std::runtime_error e) { 312 //timeout 313 if (ToBeStopped()) return false; 314 } 315 } 316 //Thread::Info("Debug: buttonName for button %d %s\n", i, buttonName[i].c_str()); 317 } 318 319 // dataFrameSize=axisNumber*sizeof(float)+buttonNumber/8*sizeof(uint8_t); 320 buttonOffset=(axisNumber*bitsPerAxis)/8; 321 if ((axisNumber*bitsPerAxis)%8!=0) buttonOffset++; 322 dataFrameSize=buttonOffset+(buttonNumber/8)*sizeof(uint8_t); 323 if ((buttonNumber%8)!=0) dataFrameSize++; 324 dataFrameBuffer=new char[dataFrameSize]; 325 receiveFrameBuffer=new char[dataFrameSize]; 326 327 Thread::Info("Controller connected with host side\n"); 328 if(buttonNumber%8!=0) Thread::Err("Button number is not multiple of 8\n"); 329 return true; 244 } else 245 connectionAccepted = true; 246 } 247 Thread::Info("Debug: Connexion accepted\n"); 248 249 // get axis stuff 250 bool axisNumberRead = false; 251 while (!axisNumberRead) { 252 try { 253 axisNumber = controlSocket->ReadUInt32(10); 254 // Thread::Info("Debug: axisNumber %d\n", axisNumber); 255 axisNumberRead = true; 256 } catch (std::runtime_error e) { 257 // timeout 258 if (ToBeStopped()) 259 return false; 260 } 261 } 262 bool bitsPerAxisRead = false; 263 while (!bitsPerAxisRead) { 264 try { 265 bitsPerAxis = controlSocket->ReadUInt32(10); 266 // Thread::Info("Debug: bits per axis %d\n", bitsPerAxis); 267 bitsPerAxisRead = true; 268 } catch (std::runtime_error e) { 269 // timeout 270 if (ToBeStopped()) 271 return false; 272 } 273 } 274 axisName = new string[axisNumber]; 275 for (unsigned int i = 0; i < axisNumber; i++) { 276 // read string size 277 int stringSize; 278 bool stringSizeRead = false; 279 while (!stringSizeRead) { 280 try { 281 stringSize = controlSocket->ReadUInt32(10); 282 stringSizeRead = true; 283 } catch (std::runtime_error e) { 284 // timeout 285 if (ToBeStopped()) 286 return false; 287 } 288 } 289 // read string 290 bool axisNameRead = false; 291 while (!axisNameRead) { 292 try { 293 axisName[i] = controlSocket->ReadString(stringSize, 10); 294 axisNameRead = true; 295 } catch (std::runtime_error e) { 296 // timeout 297 if (ToBeStopped()) 298 return false; 299 } 300 } 301 // Thread::Info("Debug: axisName for axis %d %s\n", i, axisName[i].c_str()); 302 } 303 304 // get button stuff 305 bool buttonNumberRead = false; 306 while (!buttonNumberRead) { 307 try { 308 buttonNumber = controlSocket->ReadUInt32(10); 309 buttonNumberRead = true; 310 } catch (std::runtime_error e) { 311 // timeout 312 if (ToBeStopped()) 313 return false; 314 } 315 } 316 // Thread::Info("Debug: buttonNumber %d\n", buttonNumber); 317 buttonName = new string[buttonNumber]; 318 for (unsigned int i = 0; i < buttonNumber; i++) { 319 // read string size 320 int stringSize; 321 bool stringSizeRead = false; 322 while (!stringSizeRead) { 323 try { 324 stringSize = controlSocket->ReadUInt32(10); 325 stringSizeRead = true; 326 } catch (std::runtime_error e) { 327 // timeout 328 if (ToBeStopped()) 329 return false; 330 } 331 } 332 // read string 333 bool buttonNameRead = false; 334 while (!buttonNameRead) { 335 try { 336 buttonName[i] = controlSocket->ReadString(stringSize, 10); 337 buttonNameRead = true; 338 } catch (std::runtime_error e) { 339 // timeout 340 if (ToBeStopped()) 341 return false; 342 } 343 } 344 // Thread::Info("Debug: buttonName for button %d %s\n", i, 345 // buttonName[i].c_str()); 346 } 347 348 // dataFrameSize=axisNumber*sizeof(float)+buttonNumber/8*sizeof(uint8_t); 349 buttonOffset = (axisNumber * bitsPerAxis) / 8; 350 if ((axisNumber * bitsPerAxis) % 8 != 0) 351 buttonOffset++; 352 dataFrameSize = buttonOffset + (buttonNumber / 8) * sizeof(uint8_t); 353 if ((buttonNumber % 8) != 0) 354 dataFrameSize++; 355 dataFrameBuffer = new char[dataFrameSize]; 356 receiveFrameBuffer = new char[dataFrameSize]; 357 358 Thread::Info("Controller connected with host side\n"); 359 if (buttonNumber % 8 != 0) 360 Thread::Err("Button number is not multiple of 8\n"); 361 return true; 330 362 } 331 363 -
trunk/lib/FlairSensorActuator/src/TargetEthController.h
r3 r15 12 12 // 13 13 // purpose: class that gets remote controls through an ethernet connection. 14 // Typical use case: a remote control is plugged in a workstation and sends remote control 14 // Typical use case: a remote control is plugged in a workstation 15 // and sends remote control 15 16 // data to a distant target (this class) through Wifi 16 17 // … … 24 25 25 26 namespace flair { 26 27 28 29 30 31 32 33 34 35 36 27 namespace core { 28 class FrameworkManager; 29 class cvmatrix; 30 class TcpSocket; 31 class Socket; 32 } 33 namespace gui { 34 class Tab; 35 class TabWidget; 36 class DataPlot1D; 37 } 37 38 } 38 39 39 namespace flair { namespace sensor { 40 /*! \class TargetController 41 * 42 * \brief Base Class for target side remote controls 43 * 44 */ 45 class TargetEthController : public TargetController { 46 public: 47 TargetEthController(const core::FrameworkManager* parent,std::string name,uint16_t port,uint8_t priority=0); 48 ~TargetEthController(); 49 //void DrawUserInterface(); 50 protected: 51 bool IsConnected() const; 52 //axis stuff 53 std::string GetAxisName(unsigned int axisId) const; 54 //button stuff 55 std::string GetButtonName(unsigned int axisId) const; 56 //controller state stuff 57 bool ProcessMessage(core::Message *msg); 58 bool IsControllerActionSupported(ControllerAction action) const; 40 namespace flair { 41 namespace sensor { 42 /*! \class TargetController 43 * 44 * \brief Base Class for target side remote controls 45 * 46 */ 47 class TargetEthController : public TargetController { 48 public: 49 TargetEthController(const core::FrameworkManager *parent, std::string name, 50 uint16_t port, uint8_t priority = 0); 51 ~TargetEthController(); 52 // void DrawUserInterface(); 53 protected: 54 bool IsConnected() const; 55 // axis stuff 56 std::string GetAxisName(unsigned int axisId) const; 57 // button stuff 58 std::string GetButtonName(unsigned int axisId) const; 59 // controller state stuff 60 bool ProcessMessage(core::Message *msg); 61 bool IsControllerActionSupported(ControllerAction action) const; 59 62 60 bool IsDataFrameReady(); 61 void AcquireAxisData(core::cvmatrix &axis); //responsible for getting the axis data from the hardware 62 void AcquireButtonData(core::cvmatrix &button); //responsible for getting the button data from the hardware 63 bool IsDataFrameReady(); 64 void AcquireAxisData(core::cvmatrix &axis); // responsible for getting the 65 // axis data from the hardware 66 void AcquireButtonData(core::cvmatrix &button); // responsible for getting the 67 // button data from the 68 // hardware 63 69 64 70 bool ControllerInitialization(); 65 71 66 private: 67 uint16_t readBits(uint8_t offsetInBits,uint8_t valueSizeInBits,char *buffer,size_t bufferSize); 68 uint8_t getByteOrNull(char *buffer,int byte,size_t bufferSize); 69 uint32_t charBufferToUint32(char *buffer, size_t bufferSize); 70 core::TcpSocket *listeningSocket; 71 int listeningPort; 72 core::TcpSocket *controlSocket=NULL; 73 core::Socket *dataSocket; 74 std::string *axisName=NULL; 75 std::string *buttonName=NULL; 76 size_t dataFrameSize; 77 char *dataFrameBuffer; 78 char *receiveFrameBuffer; 79 size_t receiveCurrentPosition; 80 uint8_t buttonOffset; 81 }; 82 83 }} 72 private: 73 uint16_t readBits(uint8_t offsetInBits, uint8_t valueSizeInBits, char *buffer, 74 size_t bufferSize); 75 uint8_t getByteOrNull(char *buffer, int byte, size_t bufferSize); 76 uint32_t charBufferToUint32(char *buffer, size_t bufferSize); 77 core::TcpSocket *listeningSocket; 78 int listeningPort; 79 core::TcpSocket *controlSocket = NULL; 80 core::Socket *dataSocket; 81 std::string *axisName = NULL; 82 std::string *buttonName = NULL; 83 size_t dataFrameSize; 84 char *dataFrameBuffer; 85 char *receiveFrameBuffer; 86 size_t receiveCurrentPosition; 87 uint8_t buttonOffset; 88 }; 89 } 90 } 84 91 85 92 #endif // TARGETCONTROLLER_H -
trunk/lib/FlairSensorActuator/src/UsRangeFinder.cpp
r3 r15 29 29 using namespace flair::gui; 30 30 31 namespace flair 32 { 33 namespace sensor 34 { 31 namespace flair { 32 namespace sensor { 35 33 36 UsRangeFinder::UsRangeFinder(const FrameworkManager * parent,string name) : IODevice(parent,name)37 {38 plot_tab=NULL;34 UsRangeFinder::UsRangeFinder(const FrameworkManager *parent, string name) 35 : IODevice(parent, name) { 36 plot_tab = NULL; 39 37 40 cvmatrix_descriptor* desc=new cvmatrix_descriptor(1,1);41 desc->SetElementName(0,0,name);42 output=new cvmatrix(this,desc,floatType);43 38 cvmatrix_descriptor *desc = new cvmatrix_descriptor(1, 1); 39 desc->SetElementName(0, 0, name); 40 output = new cvmatrix(this, desc, floatType); 41 AddDataToLog(output); 44 42 45 //station sol46 main_tab=new Tab(parent->GetTabWidget(),name);47 tab=new TabWidget(main_tab->NewRow(),name);48 sensor_tab=new Tab(tab,"Reglages");49 setup_groupbox=new GroupBox(sensor_tab->NewRow(),name);43 // station sol 44 main_tab = new Tab(parent->GetTabWidget(), name); 45 tab = new TabWidget(main_tab->NewRow(), name); 46 sensor_tab = new Tab(tab, "Reglages"); 47 setup_groupbox = new GroupBox(sensor_tab->NewRow(), name); 50 48 } 51 49 52 UsRangeFinder::UsRangeFinder(const IODevice * parent,std::string name) : IODevice(parent,name)53 {54 plot_tab=NULL;55 main_tab=NULL;56 tab=NULL;57 sensor_tab=NULL;58 setup_groupbox=NULL;50 UsRangeFinder::UsRangeFinder(const IODevice *parent, std::string name) 51 : IODevice(parent, name) { 52 plot_tab = NULL; 53 main_tab = NULL; 54 tab = NULL; 55 sensor_tab = NULL; 56 setup_groupbox = NULL; 59 57 60 output=NULL;58 output = NULL; 61 59 } 62 60 63 UsRangeFinder::~UsRangeFinder() 64 { 65 if(main_tab!=NULL)delete main_tab;61 UsRangeFinder::~UsRangeFinder() { 62 if (main_tab != NULL) 63 delete main_tab; 66 64 } 67 65 68 GroupBox* UsRangeFinder::GetGroupBox(void) const 69 { 70 return setup_groupbox; 66 GroupBox *UsRangeFinder::GetGroupBox(void) const { return setup_groupbox; } 67 68 Layout *UsRangeFinder::GetLayout(void) const { return sensor_tab; } 69 70 DataPlot1D *UsRangeFinder::GetPlot(void) const { return plot; } 71 72 Tab *UsRangeFinder::GetPlotTab(void) const { return plot_tab; } 73 74 void UsRangeFinder::UseDefaultPlot(void) { 75 if (tab == NULL) { 76 Err("not applicable for simulation part.\n"); 77 return; 78 } 79 80 plot_tab = new Tab(tab, "Mesures"); 81 plot = new DataPlot1D(plot_tab->NewRow(), ObjectName(), 0, 2); 82 plot->AddCurve(output->Element(0)); 71 83 } 72 84 73 Layout* UsRangeFinder::GetLayout(void) const 74 { 75 return sensor_tab; 85 void UsRangeFinder::LockUserInterface(void) const { 86 setup_groupbox->setEnabled(false); 76 87 } 77 88 78 DataPlot1D* UsRangeFinder::GetPlot(void) const 79 { 80 return plot; 89 void UsRangeFinder::UnlockUserInterface(void) const { 90 setup_groupbox->setEnabled(true); 81 91 } 82 92 83 Tab* UsRangeFinder::GetPlotTab(void) const 84 { 85 return plot_tab; 86 } 87 88 void UsRangeFinder::UseDefaultPlot(void) 89 { 90 if(tab==NULL) 91 { 92 Err("not applicable for simulation part.\n"); 93 return; 94 } 95 96 plot_tab=new Tab(tab,"Mesures"); 97 plot=new DataPlot1D(plot_tab->NewRow(),ObjectName(),0,2); 98 plot->AddCurve(output->Element(0)); 99 } 100 101 void UsRangeFinder::LockUserInterface(void) const 102 { 103 setup_groupbox->setEnabled(false); 104 } 105 106 void UsRangeFinder::UnlockUserInterface(void) const 107 { 108 setup_groupbox->setEnabled(true); 109 } 110 111 float UsRangeFinder::Value(void) const 112 { 113 return output->Value(0,0); 114 } 93 float UsRangeFinder::Value(void) const { return output->Value(0, 0); } 115 94 116 95 } // end namespace sensor -
trunk/lib/FlairSensorActuator/src/UsRangeFinder.h
r3 r15 16 16 #include <IODevice.h> 17 17 18 namespace flair 19 { 20 namespace core 21 { 22 class cvmatrix; 23 } 24 namespace gui 25 { 26 class Tab; 27 class TabWidget; 28 class GroupBox; 29 class Layout; 30 class DataPlot1D; 31 } 18 namespace flair { 19 namespace core { 20 class cvmatrix; 21 } 22 namespace gui { 23 class Tab; 24 class TabWidget; 25 class GroupBox; 26 class Layout; 27 class DataPlot1D; 28 } 32 29 } 33 30 34 namespace flair 35 { 36 namespace sensor 37 { 38 /*! \class UsRangeFinder 39 * 40 * \brief Base class for UsRangeFinder 41 * 42 * Use this class to define a custom UsRangeFinder. 43 * 44 */ 45 class UsRangeFinder : public core::IODevice 46 { 47 public: 48 /*! 49 * \brief Constructor 50 * 51 * Construct a UsRangeFinder. Control part. 52 * 53 * \param parent parent 54 * \param name name 55 */ 56 UsRangeFinder(const core::FrameworkManager* parent,std::string name); 31 namespace flair { 32 namespace sensor { 33 /*! \class UsRangeFinder 34 * 35 * \brief Base class for UsRangeFinder 36 * 37 * Use this class to define a custom UsRangeFinder. 38 * 39 */ 40 class UsRangeFinder : public core::IODevice { 41 public: 42 /*! 43 * \brief Constructor 44 * 45 * Construct a UsRangeFinder. Control part. 46 * 47 * \param parent parent 48 * \param name name 49 */ 50 UsRangeFinder(const core::FrameworkManager *parent, std::string name); 57 51 58 59 60 61 62 63 64 65 66 UsRangeFinder(const core::IODevice* parent,std::string name);52 /*! 53 * \brief Constructor 54 * 55 * Construct a UsRangeFinder. Simulation part. 56 * 57 * \param parent parent 58 * \param name name 59 */ 60 UsRangeFinder(const core::IODevice *parent, std::string name); 67 61 68 69 70 71 72 62 /*! 63 * \brief Destructor 64 * 65 */ 66 ~UsRangeFinder(); 73 67 74 75 76 77 78 68 /*! 69 * \brief Lock user interface 70 * 71 */ 72 void LockUserInterface(void) const; 79 73 80 81 82 83 84 74 /*! 75 * \brief Unlock user interface 76 * 77 */ 78 void UnlockUserInterface(void) const; 85 79 86 87 88 89 90 91 80 /*! 81 * \brief Use default plot 82 * 83 * Should no be used for the simulation part. 84 */ 85 void UseDefaultPlot(void); 92 86 93 94 95 96 97 98 gui::DataPlot1D*GetPlot(void) const;87 /*! 88 * \brief Plot 89 * 90 * \return DataPlot1D 91 */ 92 gui::DataPlot1D *GetPlot(void) const; 99 93 100 101 102 103 104 105 gui::Layout*GetLayout(void) const;94 /*! 95 * \brief Setup Layout 96 * 97 * \return a Layout available 98 */ 99 gui::Layout *GetLayout(void) const; 106 100 107 108 109 110 111 112 gui::Tab*GetPlotTab(void) const;101 /*! 102 * \brief Plot tab 103 * 104 * \return plot Tab 105 */ 106 gui::Tab *GetPlotTab(void) const; 113 107 114 115 116 117 118 119 108 /*! 109 * \brief Value 110 * 111 * \return output value 112 */ 113 float Value(void) const; 120 114 121 122 123 124 125 126 127 115 protected: 116 /*! 117 * \brief Output matrix 118 * 119 * \return output matrix 120 */ 121 core::cvmatrix *output; 128 122 129 130 131 132 133 134 gui::GroupBox*GetGroupBox(void) const;123 /*! 124 * \brief Setup GroupBox 125 * 126 * \return a GroupBox available 127 */ 128 gui::GroupBox *GetGroupBox(void) const; 135 129 136 137 138 139 140 141 142 143 144 130 private: 131 /*! 132 * \brief Update using provided datas 133 * 134 * Reimplemented from IODevice. 135 * 136 * \param data data from the parent to process 137 */ 138 void UpdateFrom(const core::io_data *data){}; 145 139 146 gui::Tab*main_tab;147 148 gui::GroupBox*setup_groupbox;149 gui::Tab*sensor_tab;150 gui::DataPlot1D*plot;151 gui::Tab*plot_tab;152 140 gui::Tab *main_tab; 141 gui::TabWidget *tab; 142 gui::GroupBox *setup_groupbox; 143 gui::Tab *sensor_tab; 144 gui::DataPlot1D *plot; 145 gui::Tab *plot_tab; 146 }; 153 147 } // end namespace sensor 154 148 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/V4LCamera.cpp
r3 r15 30 30 using namespace flair::gui; 31 31 32 namespace flair 33 { 34 namespace sensor 35 { 32 namespace flair { 33 namespace sensor { 36 34 37 V4LCamera::V4LCamera(const FrameworkManager* parent,string name,uint8_t camera_index,uint16_t width,uint16_t height,cvimage::Type::Format format,uint8_t priority) : Thread(parent,name,priority), Camera(parent,name,width,height,format) 38 { 39 capture = cvCaptureFromCAM(camera_index);//a mettre apres l'init dsp 35 V4LCamera::V4LCamera(const FrameworkManager *parent, string name, 36 uint8_t camera_index, uint16_t width, uint16_t height, 37 cvimage::Type::Format format, uint8_t priority) 38 : Thread(parent, name, priority), 39 Camera(parent, name, width, height, format) { 40 capture = cvCaptureFromCAM(camera_index); // a mettre apres l'init dsp 40 41 41 if(capture<0) Thread::Err("cvCaptureFromCAM error\n"); 42 if (capture < 0) 43 Thread::Err("cvCaptureFromCAM error\n"); 42 44 43 if(cvSetCaptureProperty(capture,CV_CAP_PROP_FRAME_WIDTH,width)<0) Thread::Err("cvSetCaptureProperty error\n"); 44 if(cvSetCaptureProperty(capture,CV_CAP_PROP_FRAME_HEIGHT,height)<0) Thread::Err("cvSetCaptureProperty error\n"); 45 if (cvSetCaptureProperty(capture, CV_CAP_PROP_FRAME_WIDTH, width) < 0) 46 Thread::Err("cvSetCaptureProperty error\n"); 47 if (cvSetCaptureProperty(capture, CV_CAP_PROP_FRAME_HEIGHT, height) < 0) 48 Thread::Err("cvSetCaptureProperty error\n"); 45 49 46 if(format==cvimage::Type::Format::UYVY) 47 { 48 if(cvSetCaptureProperty(capture,CV_CAP_PROP_FORMAT,V4L2_PIX_FMT_UYVY)<0) Thread::Err("cvSetCaptureProperty error\n"); 49 } 50 else if(format==cvimage::Type::Format::YUYV) 51 { 52 if(cvSetCaptureProperty(capture,CV_CAP_PROP_FORMAT,V4L2_PIX_FMT_YUYV)<0) Thread::Err("cvSetCaptureProperty error\n"); 53 } 54 else 55 { 56 Thread::Err("format not supported\n"); 50 if (format == cvimage::Type::Format::UYVY) { 51 if (cvSetCaptureProperty(capture, CV_CAP_PROP_FORMAT, V4L2_PIX_FMT_UYVY) < 52 0) 53 Thread::Err("cvSetCaptureProperty error\n"); 54 } else if (format == cvimage::Type::Format::YUYV) { 55 if (cvSetCaptureProperty(capture, CV_CAP_PROP_FORMAT, V4L2_PIX_FMT_YUYV) < 56 0) 57 Thread::Err("cvSetCaptureProperty error\n"); 58 } else { 59 Thread::Err("format not supported\n"); 60 } 61 62 // station sol 63 gain = new DoubleSpinBox(GetGroupBox()->NewRow(), "gain:", 0, 1, 0.1); 64 exposure = new DoubleSpinBox(GetGroupBox()->LastRowLastCol(), "exposure:", 0, 65 1, 0.1); 66 bright = 67 new DoubleSpinBox(GetGroupBox()->LastRowLastCol(), "bright:", 0, 1, 0.1); 68 contrast = new DoubleSpinBox(GetGroupBox()->LastRowLastCol(), "contrast:", 0, 69 1, 0.1); 70 hue = new DoubleSpinBox(GetGroupBox()->LastRowLastCol(), "hue:", 0, 1, 0.1); 71 sharpness = new DoubleSpinBox(GetGroupBox()->LastRowLastCol(), "sharpness:", 72 0, 1, 0.1); 73 sat = new DoubleSpinBox(GetGroupBox()->LastRowLastCol(), "saturation:", 0, 1, 74 0.1); 75 autogain = new CheckBox(GetGroupBox()->NewRow(), "autogain:"); 76 autoexposure = new CheckBox(GetGroupBox()->LastRowLastCol(), "autoexposure:"); 77 awb = new CheckBox(GetGroupBox()->LastRowLastCol(), "awb:"); 78 fps = new Label(GetGroupBox()->NewRow(), "fps"); 79 } 80 81 V4LCamera::~V4LCamera() { 82 SafeStop(); 83 Join(); 84 } 85 86 void V4LCamera::Run(void) { 87 Time cam_time, new_time, fpsNow, fpsPrev; 88 IplImage *img; // raw image 89 int fpsCounter = 0; 90 91 // init image old 92 if (!cvGrabFrame(capture)) { 93 Printf("Could not grab a frame\n"); 94 } 95 cam_time = GetTime(); 96 fpsPrev = cam_time; 97 98 while (!ToBeStopped()) { 99 // fps counter 100 fpsCounter++; 101 if (fpsCounter == 100) { 102 fpsNow = GetTime(); 103 fps->SetText("fps: %.1f", 104 fpsCounter / ((float)(fpsNow - fpsPrev) / 1000000000.)); 105 fpsCounter = 0; 106 fpsPrev = fpsNow; 57 107 } 58 108 59 //station sol 60 gain=new DoubleSpinBox(GetGroupBox()->NewRow(),"gain:",0,1,0.1); 61 exposure=new DoubleSpinBox(GetGroupBox()->LastRowLastCol(),"exposure:",0,1,0.1); 62 bright=new DoubleSpinBox(GetGroupBox()->LastRowLastCol(),"bright:",0,1,0.1); 63 contrast=new DoubleSpinBox(GetGroupBox()->LastRowLastCol(),"contrast:",0,1,0.1); 64 hue=new DoubleSpinBox(GetGroupBox()->LastRowLastCol(),"hue:",0,1,0.1); 65 sharpness=new DoubleSpinBox(GetGroupBox()->LastRowLastCol(),"sharpness:",0,1,0.1); 66 sat=new DoubleSpinBox(GetGroupBox()->LastRowLastCol(),"saturation:",0,1,0.1); 67 autogain=new CheckBox(GetGroupBox()->NewRow(),"autogain:"); 68 autoexposure=new CheckBox(GetGroupBox()->LastRowLastCol(),"autoexposure:"); 69 awb=new CheckBox(GetGroupBox()->LastRowLastCol(),"awb:"); 70 fps=new Label(GetGroupBox()->NewRow(),"fps"); 109 // cam properties 110 if (gain->ValueChanged() == true && autogain->Value() == false) 111 SetGain(gain->Value()); 112 if (exposure->ValueChanged() == true && autoexposure->Value() == false) 113 SetExposure(exposure->Value()); 114 if (bright->ValueChanged() == true) 115 SetBrightness(bright->Value()); 116 if (sat->ValueChanged() == true) 117 SetSaturation(sat->Value()); 118 if (contrast->ValueChanged() == true) 119 SetContrast(contrast->Value()); 120 if (hue->ValueChanged() == true) 121 SetHue(hue->Value()); 122 if (sharpness->ValueChanged() == true) 123 cvSetCaptureProperty(capture, CV_CAP_PROP_SHARPNESS, sharpness->Value()); 124 if (autogain->ValueChanged() == true) { 125 if (autogain->Value() == true) { 126 gain->setEnabled(false); 127 } else { 128 gain->setEnabled(true); 129 SetGain(gain->Value()); 130 } 131 SetAutoGain(autogain->Value()); 132 } 133 if (autoexposure->ValueChanged() == true) { 134 if (autoexposure->Value() == true) { 135 exposure->setEnabled(false); 136 } else { 137 exposure->setEnabled(true); 138 SetExposure(exposure->Value()); 139 } 140 SetAutoExposure(autoexposure->Value()); 141 } 142 if (awb->ValueChanged() == true) 143 cvSetCaptureProperty(capture, CV_CAP_PROP_AWB, awb->Value()); 144 145 // cam pictures 146 img = cvRetrieveRawFrame(capture); 147 if (!cvGrabFrame(capture)) { 148 Printf("Could not grab a frame\n"); 149 } 150 new_time = GetTime(); 151 152 output->GetMutex(); 153 output->img->imageData = img->imageData; 154 output->ReleaseMutex(); 155 156 output->SetDataTime(cam_time); 157 ProcessUpdate(output); 158 159 cam_time = new_time; 160 } 161 162 cvReleaseCapture(&capture); 71 163 } 72 164 73 V4LCamera::~V4LCamera() 74 { 75 SafeStop(); 76 Join(); 165 void V4LCamera::SetAutoGain(bool value) { 166 cvSetCaptureProperty(capture, CV_CAP_PROP_AUTOGAIN, value); 77 167 } 78 168 79 void V4LCamera::Run(void) 80 { 81 Time cam_time,new_time,fpsNow,fpsPrev; 82 IplImage* img;//raw image 83 int fpsCounter=0; 84 85 //init image old 86 if(!cvGrabFrame(capture)) 87 { 88 Printf("Could not grab a frame\n"); 89 } 90 cam_time=GetTime(); 91 fpsPrev = cam_time; 92 93 while(!ToBeStopped()) 94 { 95 //fps counter 96 fpsCounter++; 97 if(fpsCounter==100) { 98 fpsNow = GetTime(); 99 fps->SetText("fps: %.1f",fpsCounter/((float)(fpsNow - fpsPrev)/1000000000.)); 100 fpsCounter=0; 101 fpsPrev=fpsNow; 102 } 103 104 //cam properties 105 if(gain->ValueChanged()==true && autogain->Value()==false) SetGain(gain->Value()); 106 if(exposure->ValueChanged()==true && autoexposure->Value()==false) SetExposure(exposure->Value()); 107 if(bright->ValueChanged()==true) SetBrightness(bright->Value()); 108 if(sat->ValueChanged()==true) SetSaturation(sat->Value()); 109 if(contrast->ValueChanged()==true) SetContrast(contrast->Value()); 110 if(hue->ValueChanged()==true) SetHue(hue->Value()); 111 if(sharpness->ValueChanged()==true) cvSetCaptureProperty(capture,CV_CAP_PROP_SHARPNESS,sharpness->Value()); 112 if(autogain->ValueChanged()==true) 113 { 114 if(autogain->Value()==true) 115 { 116 gain->setEnabled(false); 117 } 118 else 119 { 120 gain->setEnabled(true); 121 SetGain(gain->Value()); 122 } 123 SetAutoGain(autogain->Value()); 124 } 125 if(autoexposure->ValueChanged()==true) 126 { 127 if(autoexposure->Value()==true) 128 { 129 exposure->setEnabled(false); 130 } 131 else 132 { 133 exposure->setEnabled(true); 134 SetExposure(exposure->Value()); 135 } 136 SetAutoExposure(autoexposure->Value()); 137 } 138 if(awb->ValueChanged()==true) cvSetCaptureProperty(capture,CV_CAP_PROP_AWB,awb->Value()); 139 140 141 //cam pictures 142 img=cvRetrieveRawFrame(capture); 143 if(!cvGrabFrame(capture)) 144 { 145 Printf("Could not grab a frame\n"); 146 } 147 new_time=GetTime(); 148 149 output->GetMutex(); 150 output->img->imageData=img->imageData; 151 output->ReleaseMutex(); 152 153 output->SetDataTime(cam_time); 154 ProcessUpdate(output); 155 156 cam_time=new_time; 157 } 158 159 cvReleaseCapture(&capture); 169 void V4LCamera::SetAutoExposure(bool value) { 170 Thread::Warn("not implemented in opencv\n"); 160 171 } 161 172 162 void V4LCamera::SetAutoGain(bool value) 163 { 164 cvSetCaptureProperty(capture,CV_CAP_PROP_AUTOGAIN,value); 173 void V4LCamera::SetGain(float value) { 174 cvSetCaptureProperty(capture, CV_CAP_PROP_GAIN, value); 165 175 } 166 176 167 void V4LCamera::SetAutoExposure(bool value) 168 { 169 Thread::Warn("not implemented in opencv\n"); 177 void V4LCamera::SetExposure(float value) { 178 cvSetCaptureProperty(capture, CV_CAP_PROP_EXPOSURE, value); 170 179 } 171 180 172 void V4LCamera::SetGain(float value) 173 { 174 cvSetCaptureProperty(capture,CV_CAP_PROP_GAIN,value); 181 void V4LCamera::SetBrightness(float value) { 182 cvSetCaptureProperty(capture, CV_CAP_PROP_BRIGHTNESS, value); 175 183 } 176 184 177 void V4LCamera::SetExposure(float value) 178 { 179 cvSetCaptureProperty(capture,CV_CAP_PROP_EXPOSURE,value); 185 void V4LCamera::SetSaturation(float value) { 186 cvSetCaptureProperty(capture, CV_CAP_PROP_SATURATION, value); 180 187 } 181 188 182 void V4LCamera::SetBrightness(float value) 183 { 184 cvSetCaptureProperty(capture,CV_CAP_PROP_BRIGHTNESS,value); 189 void V4LCamera::SetHue(float value) { 190 cvSetCaptureProperty(capture, CV_CAP_PROP_HUE, value); 185 191 } 186 192 187 void V4LCamera::SetSaturation(float value) 188 { 189 cvSetCaptureProperty(capture,CV_CAP_PROP_SATURATION,value); 190 } 191 192 void V4LCamera::SetHue(float value) 193 { 194 cvSetCaptureProperty(capture,CV_CAP_PROP_HUE,value); 195 } 196 197 void V4LCamera::SetContrast(float value) 198 { 199 cvSetCaptureProperty(capture,CV_CAP_PROP_CONTRAST,value); 193 void V4LCamera::SetContrast(float value) { 194 cvSetCaptureProperty(capture, CV_CAP_PROP_CONTRAST, value); 200 195 } 201 196 -
trunk/lib/FlairSensorActuator/src/V4LCamera.h
r3 r15 18 18 #include <highgui.h> 19 19 20 namespace flair 21 { 22 namespace core 23 { 24 class cvimage; 25 class FrameworkManager; 26 } 27 namespace gui 28 { 29 class GridLayout; 30 class DoubleSpinBox; 31 class CheckBox; 32 class Label; 33 } 20 namespace flair { 21 namespace core { 22 class cvimage; 23 class FrameworkManager; 24 } 25 namespace gui { 26 class GridLayout; 27 class DoubleSpinBox; 28 class CheckBox; 29 class Label; 30 } 34 31 } 35 32 36 namespace flair 37 { 38 namespace sensor 39 { 40 /*! \class V4LCamera 41 * 42 * \brief Base class for V4l camera 43 */ 44 class V4LCamera : public core::Thread, public Camera 45 { 46 public: 47 /*! 48 * \brief Constructor 49 * 50 * Construct a Camera. 51 * 52 * \param parent parent 53 * \param name name 54 * \param camera_index camera index 55 * \param width width 56 * \param height height 57 * \param format image format 58 * \param priority priority of the Thread 59 */ 60 V4LCamera(const core::FrameworkManager* parent,std::string name,uint8_t camera_index,uint16_t width,uint16_t height,core::cvimage::Type::Format format,uint8_t priority); 33 namespace flair { 34 namespace sensor { 35 /*! \class V4LCamera 36 * 37 * \brief Base class for V4l camera 38 */ 39 class V4LCamera : public core::Thread, public Camera { 40 public: 41 /*! 42 * \brief Constructor 43 * 44 * Construct a Camera. 45 * 46 * \param parent parent 47 * \param name name 48 * \param camera_index camera index 49 * \param width width 50 * \param height height 51 * \param format image format 52 * \param priority priority of the Thread 53 */ 54 V4LCamera(const core::FrameworkManager *parent, std::string name, 55 uint8_t camera_index, uint16_t width, uint16_t height, 56 core::cvimage::Type::Format format, uint8_t priority); 61 57 62 63 64 65 66 58 /*! 59 * \brief Destructor 60 * 61 */ 62 ~V4LCamera(); 67 63 68 69 70 71 72 73 74 64 protected: 65 /*! 66 * \brief Set Gain 67 * 68 * \param value value between 0 and 1 69 */ 70 virtual void SetGain(float value); 75 71 76 77 78 79 80 81 72 /*! 73 * \brief Set Auto Gain 74 * 75 * \param value value 76 */ 77 virtual void SetAutoGain(bool value); 82 78 83 84 85 86 87 88 79 /*! 80 * \brief Set Exposure 81 * 82 * \param value value between 0 and 1 83 */ 84 virtual void SetExposure(float value); 89 85 90 91 92 93 94 95 86 /*! 87 * \brief Set Auto Exposure 88 * 89 * \param value value 90 */ 91 virtual void SetAutoExposure(bool value); 96 92 97 98 99 100 101 102 93 /*! 94 * \brief Set Brightness 95 * 96 * \param value value between 0 and 1 97 */ 98 virtual void SetBrightness(float value); 103 99 104 105 106 107 108 109 100 /*! 101 * \brief Set Saturation 102 * 103 * \param value value between 0 and 1 104 */ 105 virtual void SetSaturation(float value); 110 106 111 112 113 114 115 116 107 /*! 108 * \brief Set Hue 109 * 110 * \param value value between 0 and 1 111 */ 112 virtual void SetHue(float value); 117 113 118 119 120 121 122 123 114 /*! 115 * \brief Set Contrast 116 * 117 * \param value value between 0 and 1 118 */ 119 virtual void SetContrast(float value); 124 120 125 126 127 128 129 130 131 132 133 121 private: 122 /*! 123 * \brief Update using provided datas 124 * 125 * Reimplemented from IODevice. 126 * 127 * \param data data from the parent to process 128 */ 129 void UpdateFrom(const core::io_data *data){}; 134 130 135 136 137 138 139 140 141 131 /*! 132 * \brief Run function 133 * 134 * Reimplemented from Thread. 135 * 136 */ 137 void Run(void); 142 138 143 CvCapture*capture;139 CvCapture *capture; 144 140 145 gui::Tab* sensor_tab; 146 gui::DoubleSpinBox *bright,*exposure,*gain,*contrast,*hue,*sharpness,*sat; 147 gui::CheckBox *autogain,*awb,*autoexposure; 148 gui::Label *fps; 149 }; 141 gui::Tab *sensor_tab; 142 gui::DoubleSpinBox *bright, *exposure, *gain, *contrast, *hue, *sharpness, 143 *sat; 144 gui::CheckBox *autogain, *awb, *autoexposure; 145 gui::Label *fps; 146 }; 150 147 } // end namespace sensor 151 148 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/VrpnClient.cpp
r3 r15 26 26 using namespace flair::gui; 27 27 28 namespace flair 29 { 30 namespace sensor 31 { 28 namespace flair { 29 namespace sensor { 32 30 33 VrpnClient::VrpnClient(const FrameworkManager* parent,string name,string address,uint16_t us_period,uint8_t priority): Thread(parent,name,priority) 34 { 35 pimpl_=new VrpnClient_impl(this,name,address,us_period); 31 VrpnClient::VrpnClient(const FrameworkManager *parent, string name, 32 string address, uint16_t us_period, uint8_t priority) 33 : Thread(parent, name, priority) { 34 pimpl_ = new VrpnClient_impl(this, name, address, us_period); 36 35 } 37 36 38 VrpnClient::VrpnClient(const FrameworkManager* parent,string name,SerialPort* serialport,uint16_t us_period,uint8_t priority): Thread(parent,name,priority) 39 { 40 pimpl_=new VrpnClient_impl(this,name,serialport,us_period); 37 VrpnClient::VrpnClient(const FrameworkManager *parent, string name, 38 SerialPort *serialport, uint16_t us_period, 39 uint8_t priority) 40 : Thread(parent, name, priority) { 41 pimpl_ = new VrpnClient_impl(this, name, serialport, us_period); 41 42 } 42 43 43 VrpnClient::~VrpnClient() 44 { 45 SafeStop(); 46 Join(); 44 VrpnClient::~VrpnClient() { 45 SafeStop(); 46 Join(); 47 47 48 48 delete pimpl_; 49 49 } 50 50 51 Layout* VrpnClient::GetLayout(void) const 52 { 53 return (Layout*)(pimpl_->setup_tab); 51 Layout *VrpnClient::GetLayout(void) const { 52 return (Layout *)(pimpl_->setup_tab); 54 53 } 55 54 56 TabWidget* VrpnClient::GetTabWidget(void) const 57 { 58 return pimpl_->tab; 59 } 55 TabWidget *VrpnClient::GetTabWidget(void) const { return pimpl_->tab; } 60 56 61 bool VrpnClient::UseXbee(void) const 62 { 63 return pimpl_->UseXbee(); 64 } 57 bool VrpnClient::UseXbee(void) const { return pimpl_->UseXbee(); } 65 58 66 void VrpnClient::Run(void) 67 { 68 pimpl_->Run(); 69 } 59 void VrpnClient::Run(void) { pimpl_->Run(); } 70 60 71 61 } // end namespace sensor -
trunk/lib/FlairSensorActuator/src/VrpnClient.h
r3 r15 6 6 * \file VrpnClient.h 7 7 * \brief Class to connect to a Vrpn server 8 * \author César Richard, Guillaume Sanahuja, Copyright Heudiasyc UMR UTC/CNRS 7253 8 * \author César Richard, Guillaume Sanahuja, Copyright Heudiasyc UMR UTC/CNRS 9 * 7253 9 10 * \date 2013/04/03 10 11 * \version 4.0 … … 16 17 #include <Thread.h> 17 18 18 namespace flair 19 { 20 namespace core 21 { 22 class FrameworkManager; 23 class SerialPort; 24 } 25 namespace gui 26 { 27 class TabWidget; 28 class Layout; 29 } 19 namespace flair { 20 namespace core { 21 class FrameworkManager; 22 class SerialPort; 23 } 24 namespace gui { 25 class TabWidget; 26 class Layout; 27 } 30 28 } 31 29 … … 33 31 class VrpnObject_impl; 34 32 35 namespace flair 36 { 37 namespace sensor 38 { 39 /*! \class VrpnClient 40 * 41 * \brief Class to connect to a Vrpn server 42 */ 43 class VrpnClient:public core::Thread 44 { 45 friend class ::VrpnObject_impl; 33 namespace flair { 34 namespace sensor { 35 /*! \class VrpnClient 36 * 37 * \brief Class to connect to a Vrpn server 38 */ 39 class VrpnClient : public core::Thread { 40 friend class ::VrpnObject_impl; 46 41 47 public: 48 /*! 49 * \brief Constructor 50 * 51 * Construct a VrpnClient. Connection is done by IP. 52 * 53 * \param parent parent 54 * \param name name 55 * \param address server address 56 * \param us_period Thread period in us 57 * \param priority priority of the Thread 58 */ 59 VrpnClient(const core::FrameworkManager* parent,std::string name,std::string address,uint16_t us_period,uint8_t priority); 42 public: 43 /*! 44 * \brief Constructor 45 * 46 * Construct a VrpnClient. Connection is done by IP. 47 * 48 * \param parent parent 49 * \param name name 50 * \param address server address 51 * \param us_period Thread period in us 52 * \param priority priority of the Thread 53 */ 54 VrpnClient(const core::FrameworkManager *parent, std::string name, 55 std::string address, uint16_t us_period, uint8_t priority); 60 56 61 /*! 62 * \brief Constructor 63 * 64 * Construct a VrpnClient. Connection is done by XBee modem. 65 * 66 * \param parent parent 67 * \param name name 68 * \param serialport SerialPort for XBee modem 69 * \param us_period Xbee RX timeout in us 70 * \param priority priority of the Thread 71 */ 72 VrpnClient(const core::FrameworkManager* parent,std::string name,core::SerialPort* serialport,uint16_t us_period,uint8_t priority); 57 /*! 58 * \brief Constructor 59 * 60 * Construct a VrpnClient. Connection is done by XBee modem. 61 * 62 * \param parent parent 63 * \param name name 64 * \param serialport SerialPort for XBee modem 65 * \param us_period Xbee RX timeout in us 66 * \param priority priority of the Thread 67 */ 68 VrpnClient(const core::FrameworkManager *parent, std::string name, 69 core::SerialPort *serialport, uint16_t us_period, 70 uint8_t priority); 73 71 74 75 76 77 78 72 /*! 73 * \brief Destructor 74 * 75 */ 76 ~VrpnClient(); 79 77 80 81 82 83 84 85 gui::Layout*GetLayout(void) const;78 /*! 79 * \brief Setup Layout 80 * 81 * \return a Layout available 82 */ 83 gui::Layout *GetLayout(void) const; 86 84 87 88 89 90 91 92 gui::TabWidget*GetTabWidget(void) const;85 /*! 86 * \brief Setup Tab 87 * 88 * \return a Tab available 89 */ 90 gui::TabWidget *GetTabWidget(void) const; 93 91 94 95 96 97 98 99 92 /*! 93 * \brief Is XBee used? 94 * 95 * \return true if connection is based on XBee modem 96 */ 97 bool UseXbee(void) const; 100 98 101 102 103 104 105 106 107 108 99 private: 100 /*! 101 * \brief Run function 102 * 103 * Reimplemented from Thread. 104 * 105 */ 106 void Run(void); 109 107 110 class VrpnClient_impl*pimpl_;111 108 class VrpnClient_impl *pimpl_; 109 }; 112 110 } // end namespace sensor 113 111 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/VrpnClient_impl.cpp
r3 r15 41 41 using namespace flair::sensor; 42 42 43 VrpnClient_impl::VrpnClient_impl(VrpnClient* self,std::string name,std::string address,uint16_t us_period) 44 { 45 this->us_period=us_period; 46 this->self=self; 47 serialport=NULL; 48 49 mutex=new Mutex(self,name); 50 51 connection = vrpn_get_connection_by_name(address.c_str()); 52 53 //station sol 54 main_tab=new Tab(getFrameworkManager()->GetTabWidget(),name); 55 tab=new TabWidget(main_tab->NewRow(),name); 56 setup_tab=new Tab(tab,"Reglages"); 57 58 rotation_1=new OneAxisRotation(setup_tab->NewRow(),"post rotation 1"); 59 rotation_2=new OneAxisRotation(setup_tab->NewRow(),"post rotation 2"); 60 } 61 62 VrpnClient_impl::VrpnClient_impl(VrpnClient* self,std::string name,SerialPort* serialport,uint16_t us_period) 63 { 64 this->us_period=us_period; 65 this->self=self; 66 this->serialport=serialport; 67 connection=NULL; 68 mutex=new Mutex(self,name); 69 70 serialport->SetBaudrate(111111); 71 serialport->SetRxTimeout(us_period*1000); 72 73 //station sol 74 main_tab=new Tab(getFrameworkManager()->GetTabWidget(),name); 75 tab=new TabWidget(main_tab->NewRow(),name); 76 setup_tab=new Tab(tab,"Reglages"); 77 78 rotation_1=new OneAxisRotation(setup_tab->NewRow(),"post rotation 1"); 79 rotation_2=new OneAxisRotation(setup_tab->NewRow(),"post rotation 2"); 80 } 81 82 VrpnClient_impl::~VrpnClient_impl() 83 { 84 if(!UseXbee()) 85 { 86 //on fait une copie car le delete touche a xbee_objects_copy via RemoveTrackable 87 vector<VrpnObject*> trackables_copy=trackables; 88 for(unsigned int i=0;i<trackables_copy.size();i++) delete trackables_copy.at(i); 89 //trackables.clear(); 43 VrpnClient_impl::VrpnClient_impl(VrpnClient *self, std::string name, 44 std::string address, uint16_t us_period) { 45 this->us_period = us_period; 46 this->self = self; 47 serialport = NULL; 48 49 mutex = new Mutex(self, name); 50 51 connection = vrpn_get_connection_by_name(address.c_str()); 52 53 // station sol 54 main_tab = new Tab(getFrameworkManager()->GetTabWidget(), name); 55 tab = new TabWidget(main_tab->NewRow(), name); 56 setup_tab = new Tab(tab, "Reglages"); 57 58 rotation_1 = new OneAxisRotation(setup_tab->NewRow(), "post rotation 1"); 59 rotation_2 = new OneAxisRotation(setup_tab->NewRow(), "post rotation 2"); 60 } 61 62 VrpnClient_impl::VrpnClient_impl(VrpnClient *self, std::string name, 63 SerialPort *serialport, uint16_t us_period) { 64 this->us_period = us_period; 65 this->self = self; 66 this->serialport = serialport; 67 connection = NULL; 68 mutex = new Mutex(self, name); 69 70 serialport->SetBaudrate(111111); 71 serialport->SetRxTimeout(us_period * 1000); 72 73 // station sol 74 main_tab = new Tab(getFrameworkManager()->GetTabWidget(), name); 75 tab = new TabWidget(main_tab->NewRow(), name); 76 setup_tab = new Tab(tab, "Reglages"); 77 78 rotation_1 = new OneAxisRotation(setup_tab->NewRow(), "post rotation 1"); 79 rotation_2 = new OneAxisRotation(setup_tab->NewRow(), "post rotation 2"); 80 } 81 82 VrpnClient_impl::~VrpnClient_impl() { 83 if (!UseXbee()) { 84 // on fait une copie car le delete touche a xbee_objects_copy via 85 // RemoveTrackable 86 vector<VrpnObject *> trackables_copy = trackables; 87 for (unsigned int i = 0; i < trackables_copy.size(); i++) 88 delete trackables_copy.at(i); 89 // trackables.clear(); 90 } else { 91 // on fait une copie car le delete touche a xbee_objects_copy via 92 // RemoveTrackable 93 vector<xbee_object> xbee_objects_copy = xbee_objects; 94 for (unsigned int i = 0; i < xbee_objects_copy.size(); i++) 95 delete xbee_objects_copy.at(i).vrpnobject->self; 96 } 97 98 delete main_tab; 99 100 if (!UseXbee()) { 101 // it will automatically delete connection 102 connection->removeReference(); 103 } 104 } 105 106 void VrpnClient_impl::ComputeRotations(Vector3D &point) { 107 rotation_1->ComputeRotation(point); 108 rotation_2->ComputeRotation(point); 109 } 110 111 void VrpnClient_impl::ComputeRotations(Quaternion &quat) { 112 rotation_1->ComputeRotation(quat); 113 rotation_2->ComputeRotation(quat); 114 } 115 116 void VrpnClient_impl::AddTrackable(VrpnObject *obj) { 117 mutex->GetMutex(); 118 trackables.push_back(obj); 119 mutex->ReleaseMutex(); 120 } 121 122 void VrpnClient_impl::RemoveTrackable(VrpnObject *obj) { 123 mutex->GetMutex(); 124 for (vector<VrpnObject *>::iterator it = trackables.begin(); 125 it < trackables.end(); it++) { 126 if (*it == obj) { 127 trackables.erase(it); 128 break; 90 129 } 91 else 92 { 93 //on fait une copie car le delete touche a xbee_objects_copy via RemoveTrackable 94 vector<xbee_object> xbee_objects_copy=xbee_objects; 95 for(unsigned int i=0;i<xbee_objects_copy.size();i++) delete xbee_objects_copy.at(i).vrpnobject->self; 130 } 131 mutex->ReleaseMutex(); 132 } 133 134 void VrpnClient_impl::AddTrackable(VrpnObject_impl *obj, uint8_t id) { 135 xbee_object tmp; 136 tmp.vrpnobject = obj; 137 tmp.id = id; 138 mutex->GetMutex(); 139 xbee_objects.push_back(tmp); 140 mutex->ReleaseMutex(); 141 } 142 143 void VrpnClient_impl::RemoveTrackable(VrpnObject_impl *obj) { 144 mutex->GetMutex(); 145 for (vector<xbee_object>::iterator it = xbee_objects.begin(); 146 it < xbee_objects.end(); it++) { 147 if ((*it).vrpnobject == obj) { 148 xbee_objects.erase(it); 149 break; 96 150 } 97 98 delete main_tab; 99 100 if(!UseXbee()) 101 { 102 //it will automatically delete connection 103 connection->removeReference(); 151 } 152 mutex->ReleaseMutex(); 153 } 154 155 bool VrpnClient_impl::UseXbee(void) { 156 if (connection == NULL) { 157 return true; 158 } else { 159 return false; 160 } 161 } 162 163 void VrpnClient_impl::Run(void) { 164 while (!self->ToBeStopped()) { 165 if (UseXbee()) { 166 ssize_t read = 0; 167 uint8_t response[38] = {0}; 168 169 read = serialport->Read(response, sizeof(response)); 170 if (read > 0 && read != sizeof(response)) 171 read += serialport->Read(&response[read], sizeof(response) - read); 172 // int temps=(float)self->GetTime()/(1000*1000); 173 // self->Printf("%i %i %i\n",temps-last,temps,last); 174 // last=temps; 175 if (read < 0) { 176 // self->Warn("erreur rt_dev_read (%s)\n",strerror(-read)); 177 } else if (read != sizeof(response)) { 178 self->Warn("erreur rt_dev_read %i/%i\n", read, sizeof(response)); 179 } else { 180 // for(ssize_t i=0;i<read;i++) printf("%x ",response[i]); 181 // printf("\n"); 182 uint8_t checksum = 0; 183 for (ssize_t i = 3; i < read; i++) 184 checksum += response[i]; 185 if (checksum != 255) { 186 self->Err("checksum error\n"); 187 } else { 188 vrpn_TRACKERCB t; 189 float pos[3]; 190 float quat[4]; 191 uint8_t id = response[8]; 192 193 mutex->GetMutex(); 194 if (id < xbee_objects.size()) { 195 memcpy(pos, &response[9], sizeof(pos)); 196 memcpy(quat, &response[9] + sizeof(pos), sizeof(quat)); 197 for (int i = 0; i < 3; i++) 198 t.pos[i] = pos[i]; 199 for (int i = 0; i < 4; i++) 200 t.quat[i] = quat[i]; 201 if (fabs(pos[0] > 10) || fabs(pos[1] > 10) || fabs(pos[2] > 10)) { 202 printf("prob pos %f %f %f\n", pos[0], pos[1], pos[2]); 203 } else { 204 // self->Printf("%i %f %f %f 205 // %f\n",id,pos[0],pos[1],pos[2],(float)self->GetTime()/(1000*1000)); 206 VrpnObject_impl::handle_pos(xbee_objects.at(id).vrpnobject, t); 207 } 208 } 209 mutex->ReleaseMutex(); 210 } 211 } 212 } else { 213 connection->mainloop(); 214 mutex->GetMutex(); 215 for (unsigned int i = 0; i < trackables.size(); i++) 216 trackables.at(i)->mainloop(); 217 mutex->ReleaseMutex(); 218 219 self->SleepUS(us_period); 104 220 } 105 } 106 107 void VrpnClient_impl::ComputeRotations(Vector3D& point) 108 { 109 rotation_1->ComputeRotation(point); 110 rotation_2->ComputeRotation(point); 111 } 112 113 void VrpnClient_impl::ComputeRotations(Quaternion& quat) 114 { 115 rotation_1->ComputeRotation(quat); 116 rotation_2->ComputeRotation(quat); 117 } 118 119 void VrpnClient_impl::AddTrackable(VrpnObject* obj) 120 { 121 mutex->GetMutex(); 122 trackables.push_back(obj); 123 mutex->ReleaseMutex(); 124 } 125 126 void VrpnClient_impl::RemoveTrackable(VrpnObject* obj) 127 { 128 mutex->GetMutex(); 129 for(vector<VrpnObject*>::iterator it=trackables.begin() ; it < trackables.end(); it++ ) 130 { 131 if(*it==obj) 132 { 133 trackables.erase (it); 134 break; 135 } 136 } 137 mutex->ReleaseMutex(); 138 } 139 140 void VrpnClient_impl::AddTrackable(VrpnObject_impl* obj,uint8_t id) 141 { 142 xbee_object tmp; 143 tmp.vrpnobject=obj; 144 tmp.id=id; 145 mutex->GetMutex(); 146 xbee_objects.push_back(tmp); 147 mutex->ReleaseMutex(); 148 } 149 150 void VrpnClient_impl::RemoveTrackable(VrpnObject_impl* obj) 151 { 152 mutex->GetMutex(); 153 for(vector<xbee_object>::iterator it=xbee_objects.begin() ; it < xbee_objects.end(); it++ ) 154 { 155 if((*it).vrpnobject==obj) 156 { 157 xbee_objects.erase (it); 158 break; 159 } 160 } 161 mutex->ReleaseMutex(); 162 } 163 164 bool VrpnClient_impl::UseXbee(void) 165 { 166 if(connection==NULL) 167 { 168 return true; 169 } 170 else 171 { 172 return false; 173 } 174 } 175 176 void VrpnClient_impl::Run(void) 177 { 178 while(!self->ToBeStopped()) 179 { 180 if(UseXbee()) 181 { 182 ssize_t read = 0; 183 uint8_t response[38] = {0}; 184 185 read = serialport->Read(response,sizeof(response)); 186 if(read>0 && read!=sizeof(response)) read += serialport->Read(&response[read],sizeof(response)-read); 187 //int temps=(float)self->GetTime()/(1000*1000); 188 //self->Printf("%i %i %i\n",temps-last,temps,last); 189 //last=temps; 190 if(read<0) 191 { 192 //self->Warn("erreur rt_dev_read (%s)\n",strerror(-read)); 193 } 194 else if (read != sizeof(response)) 195 { 196 self->Warn("erreur rt_dev_read %i/%i\n",read,sizeof(response)); 197 } 198 else 199 { 200 //for(ssize_t i=0;i<read;i++) printf("%x ",response[i]); 201 //printf("\n"); 202 uint8_t checksum=0; 203 for(ssize_t i=3;i<read;i++) checksum+=response[i]; 204 if(checksum!=255) 205 { 206 self->Err("checksum error\n"); 207 } 208 else 209 { 210 vrpn_TRACKERCB t; 211 float pos[3]; 212 float quat[4]; 213 uint8_t id=response[8]; 214 215 mutex->GetMutex(); 216 if(id<xbee_objects.size()) 217 { 218 memcpy(pos,&response[9],sizeof(pos)); 219 memcpy(quat,&response[9]+sizeof(pos),sizeof(quat)); 220 for(int i=0;i<3;i++) t.pos[i]=pos[i]; 221 for(int i=0;i<4;i++) t.quat[i]=quat[i]; 222 if(fabs(pos[0]>10) || fabs(pos[1]>10) || fabs(pos[2]>10)) 223 { 224 printf("prob pos %f %f %f\n",pos[0],pos[1],pos[2]); 225 } 226 else 227 { 228 //self->Printf("%i %f %f %f %f\n",id,pos[0],pos[1],pos[2],(float)self->GetTime()/(1000*1000)); 229 VrpnObject_impl::handle_pos(xbee_objects.at(id).vrpnobject,t); 230 } 231 } 232 mutex->ReleaseMutex(); 233 } 234 } 235 } 236 else 237 { 238 connection->mainloop(); 239 mutex->GetMutex(); 240 for(unsigned int i=0;i<trackables.size();i++) trackables.at(i)->mainloop(); 241 mutex->ReleaseMutex(); 242 243 self->SleepUS(us_period); 244 } 245 } 246 } 221 } 222 } -
trunk/lib/FlairSensorActuator/src/VrpnObject.cpp
r3 r15 27 27 using namespace flair::gui; 28 28 29 namespace flair 30 { 31 namespace sensor 32 { 29 namespace flair { 30 namespace sensor { 33 31 34 VrpnObject::VrpnObject(const VrpnClient *parent,string name,const TabWidget* tab): IODevice(parent,name) 35 { 36 pimpl_=new VrpnObject_impl(this,parent,name,-1,tab); 37 AddDataToLog(pimpl_->output); 32 VrpnObject::VrpnObject(const VrpnClient *parent, string name, 33 const TabWidget *tab) 34 : IODevice(parent, name) { 35 pimpl_ = new VrpnObject_impl(this, parent, name, -1, tab); 36 AddDataToLog(pimpl_->output); 38 37 } 39 38 40 VrpnObject::VrpnObject(const VrpnClient *parent,string name,uint8_t id,const TabWidget* tab): IODevice(parent,name) 41 { 42 Warn("Creation of object %s with id %i\n",name.c_str(),id); 43 pimpl_=new VrpnObject_impl(this,parent,name,id,tab); 44 AddDataToLog(pimpl_->output); 39 VrpnObject::VrpnObject(const VrpnClient *parent, string name, uint8_t id, 40 const TabWidget *tab) 41 : IODevice(parent, name) { 42 Warn("Creation of object %s with id %i\n", name.c_str(), id); 43 pimpl_ = new VrpnObject_impl(this, parent, name, id, tab); 44 AddDataToLog(pimpl_->output); 45 45 } 46 46 47 VrpnObject::~VrpnObject(void) 48 { 49 delete pimpl_; 47 VrpnObject::~VrpnObject(void) { delete pimpl_; } 48 49 cvmatrix *VrpnObject::Output(void) const { return pimpl_->output; } 50 51 cvmatrix *VrpnObject::State(void) const { return pimpl_->state; } 52 53 Tab *VrpnObject::GetPlotTab(void) const { return pimpl_->plot_tab; } 54 55 DataPlot1D *VrpnObject::xPlot(void) const { return pimpl_->x_plot; } 56 57 DataPlot1D *VrpnObject::yPlot(void) const { return pimpl_->y_plot; } 58 59 DataPlot1D *VrpnObject::zPlot(void) const { return pimpl_->z_plot; } 60 61 Time VrpnObject::GetLastPacketTime(void) const { 62 return pimpl_->output->DataTime(); 50 63 } 51 64 52 cvmatrix *VrpnObject::Output(void) const 53 { 54 return pimpl_->output; 65 bool VrpnObject::IsTracked(unsigned int timeout_ms) const { 66 return pimpl_->IsTracked(timeout_ms); 55 67 } 56 68 57 cvmatrix *VrpnObject::State(void) const 58 { 59 return pimpl_->state; 69 void VrpnObject::GetEuler(Euler &euler) const { pimpl_->GetEuler(euler); } 70 71 void VrpnObject::GetQuaternion(Quaternion &quaternion) const { 72 pimpl_->GetQuaternion(quaternion); 60 73 } 61 74 62 Tab* VrpnObject::GetPlotTab(void) const 63 { 64 return pimpl_->plot_tab; 75 void VrpnObject::GetPosition(Vector3D &point) const { 76 pimpl_->GetPosition(point); 65 77 } 66 78 67 DataPlot1D* VrpnObject::xPlot(void) const 68 { 69 return pimpl_->x_plot; 70 } 71 72 DataPlot1D* VrpnObject::yPlot(void) const 73 { 74 return pimpl_->y_plot; 75 } 76 77 DataPlot1D* VrpnObject::zPlot(void) const 78 { 79 return pimpl_->z_plot; 80 } 81 82 Time VrpnObject::GetLastPacketTime(void) const 83 { 84 return pimpl_->output->DataTime(); 85 } 86 87 bool VrpnObject::IsTracked(unsigned int timeout_ms) const 88 { 89 return pimpl_->IsTracked(timeout_ms); 90 } 91 92 void VrpnObject::GetEuler(Euler &euler) const 93 { 94 pimpl_->GetEuler(euler); 95 } 96 97 void VrpnObject::GetQuaternion(Quaternion &quaternion) const { 98 pimpl_->GetQuaternion(quaternion); 99 } 100 101 void VrpnObject::GetPosition(Vector3D &point) const 102 { 103 pimpl_->GetPosition(point); 104 } 105 106 void VrpnObject::mainloop(void) 107 { 108 pimpl_->mainloop(); 109 } 79 void VrpnObject::mainloop(void) { pimpl_->mainloop(); } 110 80 111 81 } // end namespace sensor -
trunk/lib/FlairSensorActuator/src/VrpnObject.h
r3 r15 6 6 * \file VrpnObject.h 7 7 * \brief Class for VRPN object 8 * \author César Richard, Guillaume Sanahuja, Copyright Heudiasyc UMR UTC/CNRS 7253 8 * \author César Richard, Guillaume Sanahuja, Copyright Heudiasyc UMR UTC/CNRS 9 * 7253 9 10 * \date 2013/04/03 10 11 * \version 4.0 … … 17 18 #include <stdint.h> 18 19 19 namespace flair 20 { 21 namespace core 22 { 23 class cvmatrix; 24 class Vector3D; 25 class Euler; 26 class Quaternion; 27 } 28 namespace gui 29 { 30 class TabWidget; 31 class Tab; 32 class DataPlot1D; 33 } 20 namespace flair { 21 namespace core { 22 class cvmatrix; 23 class Vector3D; 24 class Euler; 25 class Quaternion; 26 } 27 namespace gui { 28 class TabWidget; 29 class Tab; 30 class DataPlot1D; 31 } 34 32 } 35 33 … … 37 35 class VrpnClient_impl; 38 36 39 namespace flair 40 { 41 namespace sensor 42 { 43 class VrpnClient; 37 namespace flair { 38 namespace sensor { 39 class VrpnClient; 44 40 45 /*! \class VrpnObject 46 * 47 * \brief Class for VRPN object 48 */ 49 class VrpnObject: public core::IODevice 50 { 51 friend class ::VrpnObject_impl; 52 friend class ::VrpnClient_impl; 41 /*! \class VrpnObject 42 * 43 * \brief Class for VRPN object 44 */ 45 class VrpnObject : public core::IODevice { 46 friend class ::VrpnObject_impl; 47 friend class ::VrpnClient_impl; 53 48 54 public: 55 /*! 56 * \brief Constructor 57 * 58 * Construct a VrpnObject. Connection is done by IP. 59 * 60 * \param parent parent 61 * \param name VRPN object name, should be the same as defined in the server 62 * \param tab Tab for the user interface 63 */ 64 VrpnObject(const VrpnClient *parent,std::string name,const gui::TabWidget* tab); 49 public: 50 /*! 51 * \brief Constructor 52 * 53 * Construct a VrpnObject. Connection is done by IP. 54 * 55 * \param parent parent 56 * \param name VRPN object name, should be the same as defined in the server 57 * \param tab Tab for the user interface 58 */ 59 VrpnObject(const VrpnClient *parent, std::string name, 60 const gui::TabWidget *tab); 65 61 66 /*! 67 * \brief Constructor 68 * 69 * Construct a VrpnObject. Connection is done by IP. 70 * 71 * \param parent parent 72 * \param name name 73 * \param id VRPN object id, should be the same as defined in the server 74 * \param tab Tab for the user interface 75 */ 76 VrpnObject(const VrpnClient *parent,std::string name,uint8_t id,const gui::TabWidget* tab); 62 /*! 63 * \brief Constructor 64 * 65 * Construct a VrpnObject. Connection is done by IP. 66 * 67 * \param parent parent 68 * \param name name 69 * \param id VRPN object id, should be the same as defined in the server 70 * \param tab Tab for the user interface 71 */ 72 VrpnObject(const VrpnClient *parent, std::string name, uint8_t id, 73 const gui::TabWidget *tab); 77 74 78 79 80 81 82 75 /*! 76 * \brief Destructor 77 * 78 */ 79 ~VrpnObject(void); 83 80 84 85 86 87 88 89 gui::Tab*GetPlotTab(void) const;81 /*! 82 * \brief Plot tab 83 * 84 * \return plot Tab 85 */ 86 gui::Tab *GetPlotTab(void) const; 90 87 91 92 93 94 95 96 88 /*! 89 * \brief Get Last Packet Time 90 * 91 * \return Time of last received packe 92 */ 93 core::Time GetLastPacketTime(void) const; 97 94 98 99 100 101 102 103 104 95 /*! 96 * \brief Is object tracked? 97 * 98 * \param timeout_ms timeout 99 * \return true if object is tracked during timeout_ms time 100 */ 101 bool IsTracked(unsigned int timeout_ms) const; 105 102 106 107 108 109 110 111 103 /*! 104 * \brief Get Euler angles 105 * 106 * \param euler output datas 107 */ 108 void GetEuler(core::Euler &euler) const; 112 109 113 114 115 116 117 118 119 120 121 122 123 124 110 /*! 111 * \brief Get Quaternion 112 * 113 * \param quaternion output datas 114 */ 115 void GetQuaternion(core::Quaternion &quaternion) const; 116 /*! 117 * \brief Get Position 118 * 119 * \param point output datas 120 */ 121 void GetPosition(core::Vector3D &point) const; 125 122 126 127 128 129 130 131 132 133 134 135 136 137 138 139 123 /*! 124 * \brief Output matrix 125 * 126 * Matrix is of type float and as follows: \n 127 * (0,0) roll (rad) \n 128 * (1,0) pitch (rad) \n 129 * (2,0) yaw (rad) \n 130 * (3,0) x \n 131 * (4,0) y \n 132 * (5,0) z \n 133 * 134 * \return Output metrix 135 */ 136 core::cvmatrix *Output(void) const; 140 137 141 142 143 144 145 146 147 148 149 150 151 138 /*! 139 * \brief State matrix 140 * 141 * Matrix is of type float and as follows: \n 142 * (0,0) roll (deg) \n 143 * (1,0) pitch (deg) \n 144 * (2,0) yaw (deg) \n 145 * 146 * \return State metrix 147 */ 148 core::cvmatrix *State(void) const; 152 149 153 154 155 156 157 158 gui::DataPlot1D*xPlot(void) const;150 /*! 151 * \brief x plot 152 * 153 * \return x plot 154 */ 155 gui::DataPlot1D *xPlot(void) const; 159 156 160 161 162 163 164 165 gui::DataPlot1D*yPlot(void) const;157 /*! 158 * \brief y plot 159 * 160 * \return y plot 161 */ 162 gui::DataPlot1D *yPlot(void) const; 166 163 167 168 169 170 171 172 gui::DataPlot1D*zPlot(void) const;164 /*! 165 * \brief z plot 166 * 167 * \return z plot 168 */ 169 gui::DataPlot1D *zPlot(void) const; 173 170 174 175 176 177 178 179 180 181 182 171 private: 172 /*! 173 * \brief Update using provided datas 174 * 175 * Reimplemented from IODevice. 176 * 177 * \param data data from the parent to process 178 */ 179 void UpdateFrom(const core::io_data *data){}; 183 180 184 185 class VrpnObject_impl*pimpl_;186 181 void mainloop(void); 182 class VrpnObject_impl *pimpl_; 183 }; 187 184 } // end namespace sensor 188 185 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/VrpnObject_impl.cpp
r3 r15 39 39 using namespace flair::sensor; 40 40 41 VrpnObject_impl::VrpnObject_impl(VrpnObject * self,const VrpnClient *parent,string name, int id,const TabWidget* tab)42 {43 this->parent=parent;44 this->self=self;41 VrpnObject_impl::VrpnObject_impl(VrpnObject *self, const VrpnClient *parent, 42 string name, int id, const TabWidget *tab) { 43 this->parent = parent; 44 this->self = self; 45 45 46 if(id==-1 && parent->UseXbee()) 47 { 48 self->Err("erreur aucun identifiant specifie pour la connexion Xbee\n"); 49 } 50 if(id!=-1 && !parent->UseXbee()) 51 { 52 self->Warn("identifiant pour la connexion Xbee ignore car pas en mode Xbee\n"); 53 } 46 if (id == -1 && parent->UseXbee()) { 47 self->Err("erreur aucun identifiant specifie pour la connexion Xbee\n"); 48 } 49 if (id != -1 && !parent->UseXbee()) { 50 self->Warn( 51 "identifiant pour la connexion Xbee ignore car pas en mode Xbee\n"); 52 } 54 53 55 if(parent->UseXbee()) 56 { 57 parent->pimpl_->AddTrackable(this,id); 58 tracker=NULL; 59 } 60 else 61 { 62 parent->pimpl_->AddTrackable(self); 63 tracker = new vrpn_Tracker_Remote(name.c_str(), parent->pimpl_->connection); 64 tracker->register_change_handler(this,handle_pos); 65 tracker->shutup=true; 66 } 54 if (parent->UseXbee()) { 55 parent->pimpl_->AddTrackable(this, id); 56 tracker = NULL; 57 } else { 58 parent->pimpl_->AddTrackable(self); 59 tracker = new vrpn_Tracker_Remote(name.c_str(), parent->pimpl_->connection); 60 tracker->register_change_handler(this, handle_pos); 61 tracker->shutup = true; 62 } 67 63 68 //state69 cvmatrix_descriptor* desc=new cvmatrix_descriptor(6,1);70 desc->SetElementName(0,0,"roll");71 desc->SetElementName(1,0,"pitch");72 desc->SetElementName(2,0,"yaw");73 desc->SetElementName(3,0,"x");74 desc->SetElementName(4,0,"y");75 desc->SetElementName(5,0,"z");76 output=new cvmatrix(self,desc,floatType);64 // state 65 cvmatrix_descriptor *desc = new cvmatrix_descriptor(6, 1); 66 desc->SetElementName(0, 0, "roll"); 67 desc->SetElementName(1, 0, "pitch"); 68 desc->SetElementName(2, 0, "yaw"); 69 desc->SetElementName(3, 0, "x"); 70 desc->SetElementName(4, 0, "y"); 71 desc->SetElementName(5, 0, "z"); 72 output = new cvmatrix(self, desc, floatType); 77 73 78 desc=new cvmatrix_descriptor(3,1);79 desc->SetElementName(0,0,"roll");80 desc->SetElementName(1,0,"pitch");81 desc->SetElementName(2,0,"yaw");82 state=new cvmatrix(self,desc,floatType);74 desc = new cvmatrix_descriptor(3, 1); 75 desc->SetElementName(0, 0, "roll"); 76 desc->SetElementName(1, 0, "pitch"); 77 desc->SetElementName(2, 0, "yaw"); 78 state = new cvmatrix(self, desc, floatType); 83 79 84 //ui85 plot_tab=new Tab(tab,"Mesures "+ name);86 x_plot=new DataPlot1D(plot_tab->NewRow(),"x",-10,10);87 88 y_plot=new DataPlot1D(plot_tab->LastRowLastCol(),"y",-10,10);89 90 z_plot=new DataPlot1D(plot_tab->LastRowLastCol(),"z",-2,0);91 80 // ui 81 plot_tab = new Tab(tab, "Mesures " + name); 82 x_plot = new DataPlot1D(plot_tab->NewRow(), "x", -10, 10); 83 x_plot->AddCurve(output->Element(3)); 84 y_plot = new DataPlot1D(plot_tab->LastRowLastCol(), "y", -10, 10); 85 y_plot->AddCurve(output->Element(4)); 86 z_plot = new DataPlot1D(plot_tab->LastRowLastCol(), "z", -2, 0); 87 z_plot->AddCurve(output->Element(5)); 92 88 } 93 89 94 VrpnObject_impl::~VrpnObject_impl(void) 95 { 96 if(tracker!=NULL)//normal 97 { 98 parent->pimpl_->RemoveTrackable(self); 99 tracker->unregister_change_handler(this,handle_pos); 100 delete tracker; 101 } 102 else//xbee 103 { 104 parent->pimpl_->RemoveTrackable(this); 105 } 106 delete plot_tab; 90 VrpnObject_impl::~VrpnObject_impl(void) { 91 if (tracker != NULL) // normal 92 { 93 parent->pimpl_->RemoveTrackable(self); 94 tracker->unregister_change_handler(this, handle_pos); 95 delete tracker; 96 } else // xbee 97 { 98 parent->pimpl_->RemoveTrackable(this); 99 } 100 delete plot_tab; 107 101 } 108 102 109 void VrpnObject_impl::mainloop(void) 110 { 111 tracker->mainloop(); 103 void VrpnObject_impl::mainloop(void) { tracker->mainloop(); } 104 105 bool VrpnObject_impl::IsTracked(unsigned int timeout_ms) { 106 output->GetMutex(); 107 Time a = GetTime(); 108 Time dt = a - output->DataTime(); 109 output->ReleaseMutex(); 110 111 if (dt > (Time)(timeout_ms * 1000000)) { 112 // self->Printf("%lld %lld %lld 113 // %lld\n",a,output->DataTime(),dt,(Time)(timeout_ms*1000000)); 114 return false; 115 } else { 116 return true; 117 } 112 118 } 113 119 114 bool VrpnObject_impl::IsTracked(unsigned int timeout_ms) 115 { 116 output->GetMutex(); 117 Time a=GetTime(); 118 Time dt=a-output->DataTime(); 119 output->ReleaseMutex(); 120 121 if(dt>(Time)(timeout_ms*1000000)) 122 { 123 //self->Printf("%lld %lld %lld %lld\n",a,output->DataTime(),dt,(Time)(timeout_ms*1000000)); 124 return false; 125 } 126 else 127 { 128 return true; 129 } 130 } 131 132 void VrpnObject_impl::GetEuler(Euler &euler) 133 { 134 output->GetMutex(); 135 euler.roll=output->ValueNoMutex(0,0); 136 euler.pitch=output->ValueNoMutex(1,0); 137 euler.yaw=output->ValueNoMutex(2,0); 138 output->ReleaseMutex(); 120 void VrpnObject_impl::GetEuler(Euler &euler) { 121 output->GetMutex(); 122 euler.roll = output->ValueNoMutex(0, 0); 123 euler.pitch = output->ValueNoMutex(1, 0); 124 euler.yaw = output->ValueNoMutex(2, 0); 125 output->ReleaseMutex(); 139 126 } 140 127 141 128 void VrpnObject_impl::GetQuaternion(Quaternion &quaternion) { 142 143 quaternion.q0=this->quaternion.q0;144 quaternion.q1=this->quaternion.q1;145 quaternion.q2=this->quaternion.q2;146 quaternion.q3=this->quaternion.q3;147 129 output->GetMutex(); 130 quaternion.q0 = this->quaternion.q0; 131 quaternion.q1 = this->quaternion.q1; 132 quaternion.q2 = this->quaternion.q2; 133 quaternion.q3 = this->quaternion.q3; 134 output->ReleaseMutex(); 148 135 } 149 136 150 void VrpnObject_impl::GetPosition(Vector3D &point) 151 { 152 output->GetMutex(); 153 point.x=output->ValueNoMutex(3,0); 154 point.y=output->ValueNoMutex(4,0); 155 point.z=output->ValueNoMutex(5,0); 156 output->ReleaseMutex(); 137 void VrpnObject_impl::GetPosition(Vector3D &point) { 138 output->GetMutex(); 139 point.x = output->ValueNoMutex(3, 0); 140 point.y = output->ValueNoMutex(4, 0); 141 point.z = output->ValueNoMutex(5, 0); 142 output->ReleaseMutex(); 157 143 } 158 144 159 void VRPN_CALLBACK VrpnObject_impl::handle_pos(void *userdata, const vrpn_TRACKERCB t)160 {161 bool is_nan=false;162 VrpnObject_impl* caller= reinterpret_cast<VrpnObject_impl*>(userdata);163 Time time=GetTime();145 void VRPN_CALLBACK 146 VrpnObject_impl::handle_pos(void *userdata, const vrpn_TRACKERCB t) { 147 bool is_nan = false; 148 VrpnObject_impl *caller = reinterpret_cast<VrpnObject_impl *>(userdata); 149 Time time = GetTime(); 164 150 165 //check if something is nan 166 for(int i=0;i<3;i++) 167 { 168 if(isnan(t.pos[i])==true) is_nan=true; 169 } 170 for(int i=0;i<4;i++) 171 { 172 if(isnan(t.quat[i])==true) is_nan=true; 173 } 174 if(is_nan==true) 175 { 176 caller->self->Warn("data is nan, skipping it (time %lld)\n",time); 177 return; 178 } 151 // check if something is nan 152 for (int i = 0; i < 3; i++) { 153 if (isnan(t.pos[i]) == true) 154 is_nan = true; 155 } 156 for (int i = 0; i < 4; i++) { 157 if (isnan(t.quat[i]) == true) 158 is_nan = true; 159 } 160 if (is_nan == true) { 161 caller->self->Warn("data is nan, skipping it (time %lld)\n", time); 162 return; 163 } 179 164 180 //on prend une fois pour toute le mutex et on fait des accès directs181 165 // on prend une fois pour toute le mutex et on fait des accès directs 166 caller->output->GetMutex(); 182 167 183 //warning: t.quat is defined as (qx,qy,qz,qw), which is different from flair::core::Quaternion 184 caller->quaternion.q0=t.quat[3]; 185 caller->quaternion.q1=t.quat[0]; 186 caller->quaternion.q2=t.quat[1]; 187 caller->quaternion.q3=t.quat[2]; 188 Vector3D pos((float)t.pos[0],(float)t.pos[1],(float)t.pos[2]); 168 // warning: t.quat is defined as (qx,qy,qz,qw), which is different from 169 // flair::core::Quaternion 170 caller->quaternion.q0 = t.quat[3]; 171 caller->quaternion.q1 = t.quat[0]; 172 caller->quaternion.q2 = t.quat[1]; 173 caller->quaternion.q3 = t.quat[2]; 174 Vector3D pos((float)t.pos[0], (float)t.pos[1], (float)t.pos[2]); 189 175 190 //on effectue les rotation191 192 176 // on effectue les rotation 177 caller->parent->pimpl_->ComputeRotations(pos); 178 caller->parent->pimpl_->ComputeRotations(caller->quaternion); 193 179 194 195 196 caller->output->SetValueNoMutex( 0, 0,euler.roll);197 caller->output->SetValueNoMutex( 1, 0,euler.pitch);198 caller->output->SetValueNoMutex( 2, 0,euler.yaw);199 caller->output->SetValueNoMutex( 3, 0,pos.x);200 caller->output->SetValueNoMutex( 4, 0,pos.y);201 caller->output->SetValueNoMutex( 5, 0,pos.z);180 Euler euler; 181 caller->quaternion.ToEuler(euler); 182 caller->output->SetValueNoMutex(0, 0, euler.roll); 183 caller->output->SetValueNoMutex(1, 0, euler.pitch); 184 caller->output->SetValueNoMutex(2, 0, euler.yaw); 185 caller->output->SetValueNoMutex(3, 0, pos.x); 186 caller->output->SetValueNoMutex(4, 0, pos.y); 187 caller->output->SetValueNoMutex(5, 0, pos.z); 202 188 203 204 189 caller->output->SetDataTime(time); 190 caller->output->ReleaseMutex(); 205 191 206 207 caller->state->SetValueNoMutex( 0, 0,Euler::ToDegree(euler.roll));208 caller->state->SetValueNoMutex( 1, 0,Euler::ToDegree(euler.pitch));209 caller->state->SetValueNoMutex(2, 0,Euler::ToDegree(euler.yaw));210 192 caller->state->GetMutex(); 193 caller->state->SetValueNoMutex(0, 0, Euler::ToDegree(euler.roll)); 194 caller->state->SetValueNoMutex(1, 0, Euler::ToDegree(euler.pitch)); 195 caller->state->SetValueNoMutex(2, 0, Euler::ToDegree(euler.yaw)); 196 caller->state->ReleaseMutex(); 211 197 212 198 caller->self->ProcessUpdate(caller->output); 213 199 } 214 -
trunk/lib/FlairSensorActuator/src/XBldc.cpp
r3 r15 23 23 using namespace flair::gui; 24 24 25 namespace flair 26 { 27 namespace actuator 28 { 25 namespace flair { 26 namespace actuator { 29 27 30 XBldc::XBldc(const IODevice* parent,Layout* layout,string name,I2cPort* i2cport) : Bldc(parent,layout,name,4) { 31 pimpl_=new XBldc_impl(this,i2cport); 28 XBldc::XBldc(const IODevice *parent, Layout *layout, string name, 29 I2cPort *i2cport) 30 : Bldc(parent, layout, name, 4) { 31 pimpl_ = new XBldc_impl(this, i2cport); 32 32 } 33 33 34 XBldc::~XBldc() { 35 delete pimpl_; 36 } 34 XBldc::~XBldc() { delete pimpl_; } 37 35 38 void XBldc::SetMotors(float* value) { 39 pimpl_->SetMotors(value); 40 } 36 void XBldc::SetMotors(float *value) { pimpl_->SetMotors(value); } 41 37 42 38 } // end namespace actuator -
trunk/lib/FlairSensorActuator/src/XBldc.h
r3 r15 16 16 #include "Bldc.h" 17 17 18 namespace flair 19 { 20 namespace core 21 { 22 class IODevice; 23 class I2cPort; 24 } 25 namespace gui 26 { 27 class Layout; 28 } 18 namespace flair { 19 namespace core { 20 class IODevice; 21 class I2cPort; 22 } 23 namespace gui { 24 class Layout; 25 } 29 26 } 30 27 31 28 class XBldc_impl; 32 29 33 namespace flair 34 { 35 namespace actuator 36 { 37 /*! \class XBldc 38 * 39 * \brief Class for Xufo Bldc 40 */ 41 class XBldc : public Bldc 42 { 43 public: 44 /*! 45 * \brief Constructor 46 * 47 * Construct a XBldc. 48 * 49 * \param parent parent 50 * \param layout layout 51 * \param name name 52 * \param i2cport i2cport 53 */ 54 XBldc(const core::IODevice* parent,gui::Layout* layout,std::string name,core::I2cPort* i2cport); 30 namespace flair { 31 namespace actuator { 32 /*! \class XBldc 33 * 34 * \brief Class for Xufo Bldc 35 */ 36 class XBldc : public Bldc { 37 public: 38 /*! 39 * \brief Constructor 40 * 41 * Construct a XBldc. 42 * 43 * \param parent parent 44 * \param layout layout 45 * \param name name 46 * \param i2cport i2cport 47 */ 48 XBldc(const core::IODevice *parent, gui::Layout *layout, std::string name, 49 core::I2cPort *i2cport); 55 50 56 57 58 59 60 51 /*! 52 * \brief Destructor 53 * 54 */ 55 ~XBldc(); 61 56 62 63 64 65 66 67 68 69 bool HasSpeedMeasurement(void) const{return false;};57 /*! 58 * \brief Has speed measurement 59 * 60 * Reimplemented from Bldc. \n 61 * 62 * \return true if it has speed measurement 63 */ 64 bool HasSpeedMeasurement(void) const { return false; }; 70 65 71 72 73 74 75 76 77 78 bool HasCurrentMeasurement(void) const{return false;};66 /*! 67 * \brief Has current measurement 68 * 69 * Reimplemented from Bldc. \n 70 * 71 * \return true if it has current measurement 72 */ 73 bool HasCurrentMeasurement(void) const { return false; }; 79 74 80 81 82 83 84 85 86 87 88 89 void SetMotors(float*value);75 private: 76 /*! 77 * \brief Set motors values 78 * 79 * Reimplemented from Bldc. \n 80 * Values size must be the same as MotorsCount() 81 * 82 * \param values motor values 83 */ 84 void SetMotors(float *value); 90 85 91 class XBldc_impl*pimpl_;92 86 class XBldc_impl *pimpl_; 87 }; 93 88 } // end namespace actuator 94 89 } // end namespace flair -
trunk/lib/FlairSensorActuator/src/XBldc_impl.cpp
r3 r15 29 29 using namespace flair::actuator; 30 30 31 XBldc_impl::XBldc_impl(XBldc * self,I2cPort*i2cport) {32 this->self=self;33 this->i2cport=i2cport;31 XBldc_impl::XBldc_impl(XBldc *self, I2cPort *i2cport) { 32 this->self = self; 33 this->i2cport = i2cport; 34 34 35 35 i2cport->SetTxTimeout(5000000); 36 36 } 37 37 38 XBldc_impl::~XBldc_impl() { 39 } 38 XBldc_impl::~XBldc_impl() {} 40 39 41 void XBldc_impl::SetMotors(float *value) {42 40 void XBldc_impl::SetMotors(float *value) { 41 uint8_t tosend_value[5]; 43 42 44 for(int i=0;i<4;i++) tosend_value[i]=(uint8_t)(MAX_VALUE*value[i]); 43 for (int i = 0; i < 4; i++) 44 tosend_value[i] = (uint8_t)(MAX_VALUE * value[i]); 45 45 46 ssize_t written; 47 tosend_value[4]=0xaa; 48 for(int i=0;i<4;i++) tosend_value[4]+=tosend_value[i]; 49 self->Err("please verify motors adresses\n"); 50 //todo faire la procedure changement addresse par la station sol 51 /* 52 i2cport->GetMutex(); 53 i2cport->SetSlave(BASE_ADDRESS); 46 ssize_t written; 47 tosend_value[4] = 0xaa; 48 for (int i = 0; i < 4; i++) 49 tosend_value[4] += tosend_value[i]; 50 self->Err("please verify motors adresses\n"); 51 // todo faire la procedure changement addresse par la station sol 52 /* 53 i2cport->GetMutex(); 54 i2cport->SetSlave(BASE_ADDRESS); 54 55 55 written =i2cport->Write(tosend_value, sizeof(tosend_value));56 if(written<0)57 {58 self->Err("rt_dev_write error (%s)\n",strerror(-written));59 }60 else if (written != sizeof(tosend_value))61 {62 self->Err("rt_dev_write error %i/%i\n",written,sizeof(tosend_value));63 }56 written =i2cport->Write(tosend_value, sizeof(tosend_value)); 57 if(written<0) 58 { 59 self->Err("rt_dev_write error (%s)\n",strerror(-written)); 60 } 61 else if (written != sizeof(tosend_value)) 62 { 63 self->Err("rt_dev_write error %i/%i\n",written,sizeof(tosend_value)); 64 } 64 65 65 i2cport->ReleaseMutex();*/ 66 66 i2cport->ReleaseMutex();*/ 67 67 } 68 68 /* … … 94 94 */ 95 95 void XBldc_impl::ChangeDirection(uint8_t moteur) { 96 97 96 unsigned char tx[4]; 97 ssize_t written; 98 98 99 tx[0]=254;100 tx[1]=moteur;101 tx[2]=0;102 tx[3]=234+moteur;99 tx[0] = 254; 100 tx[1] = moteur; 101 tx[2] = 0; 102 tx[3] = 234 + moteur; 103 103 104 105 104 i2cport->GetMutex(); 105 i2cport->SetSlave(BASE_ADDRESS); 106 106 107 written =i2cport->Write(tx, sizeof(tx));108 if(written<0) {109 self->Err("rt_dev_write (%s) error\n",strerror(-written));110 111 self->Err("rt_dev_write %i/%i error\n",written,sizeof(tx));112 107 written = i2cport->Write(tx, sizeof(tx)); 108 if (written < 0) { 109 self->Err("rt_dev_write (%s) error\n", strerror(-written)); 110 } else if (written != sizeof(tx)) { 111 self->Err("rt_dev_write %i/%i error\n", written, sizeof(tx)); 112 } 113 113 114 114 i2cport->ReleaseMutex(); 115 115 } 116 116 117 void XBldc_impl::ChangeAdress(uint8_t old_add, uint8_t new_add) {118 119 117 void XBldc_impl::ChangeAdress(uint8_t old_add, uint8_t new_add) { 118 unsigned char tx[4]; 119 ssize_t written; 120 120 121 tx[0]=250;122 tx[1]=old_add;123 tx[2]=new_add;124 tx[3]=230+old_add+new_add;121 tx[0] = 250; 122 tx[1] = old_add; 123 tx[2] = new_add; 124 tx[3] = 230 + old_add + new_add; 125 125 126 127 126 i2cport->GetMutex(); 127 i2cport->SetSlave(BASE_ADDRESS); 128 128 129 written =i2cport->Write(tx, sizeof(tx));130 if(written<0) {131 self->Err("rt_dev_write error (%s)\n",strerror(-written));132 133 self->Err("rt_dev_write error %i/%i\n",written,sizeof(tx));134 129 written = i2cport->Write(tx, sizeof(tx)); 130 if (written < 0) { 131 self->Err("rt_dev_write error (%s)\n", strerror(-written)); 132 } else if (written != sizeof(tx)) { 133 self->Err("rt_dev_write error %i/%i\n", written, sizeof(tx)); 134 } 135 135 136 136 i2cport->ReleaseMutex(); 137 137 } 138 138 139 uint8_t XBldc_impl::Sat(float value, uint8_t min,uint8_t max) {140 uint8_t sat_value =(uint8_t)value;139 uint8_t XBldc_impl::Sat(float value, uint8_t min, uint8_t max) { 140 uint8_t sat_value = (uint8_t)value; 141 141 142 if(value>((float)sat_value+0.5)) sat_value++; 142 if (value > ((float)sat_value + 0.5)) 143 sat_value++; 143 144 144 if(value<(float)min) sat_value=min; 145 if(value>(float)max) sat_value=max; 145 if (value < (float)min) 146 sat_value = min; 147 if (value > (float)max) 148 sat_value = max; 146 149 147 150 return sat_value; -
trunk/lib/FlairSensorActuator/src/geodesie.cpp
r3 r15 8 8 9 9 #ifdef _MSC_VER 10 # pragma warning(disable:4244)10 #pragma warning(disable : 4244) 11 11 #endif //_MSC_VER 12 12 13 13 namespace Geodesie { 14 14 /// //////////////////////////////////////////////////////////////////// 15 Matrice::Matrice(const Matrice & A) { 16 c0_l0=A.c0_l0;c1_l0=A.c1_l0;c2_l0=A.c2_l0; 17 c0_l1=A.c0_l1;c1_l1=A.c1_l1;c2_l1=A.c2_l1; 18 c0_l2=A.c0_l2;c1_l2=A.c1_l2;c2_l2=A.c2_l2; 15 Matrice::Matrice(const Matrice &A) { 16 c0_l0 = A.c0_l0; 17 c1_l0 = A.c1_l0; 18 c2_l0 = A.c2_l0; 19 c0_l1 = A.c0_l1; 20 c1_l1 = A.c1_l1; 21 c2_l1 = A.c2_l1; 22 c0_l2 = A.c0_l2; 23 c1_l2 = A.c1_l2; 24 c2_l2 = A.c2_l2; 19 25 } 20 26 /// //////////////////////////////////////////////////////////////////// 21 27 Matrice::Matrice() { 22 c0_l0=0.0;c1_l0=0.0;c2_l0=0.0; 23 c0_l1=0.0;c1_l1=0.0;c2_l1=0.0; 24 c0_l2=0.0;c1_l2=0.0;c2_l2=0.0; 25 } 26 /// //////////////////////////////////////////////////////////////////// 27 void Matrice::Apply(double v0,double v1,double v2, double& Mv0,double& Mv1,double& Mv2) { 28 Mv0 = c0_l0*v0 + c1_l0*v1 + c2_l0*v2; 29 Mv1 = c0_l1*v0 + c1_l1*v1 + c2_l1*v2; 30 Mv2 = c0_l2*v0 + c1_l2*v1 + c2_l2*v2; 28 c0_l0 = 0.0; 29 c1_l0 = 0.0; 30 c2_l0 = 0.0; 31 c0_l1 = 0.0; 32 c1_l1 = 0.0; 33 c2_l1 = 0.0; 34 c0_l2 = 0.0; 35 c1_l2 = 0.0; 36 c2_l2 = 0.0; 37 } 38 /// //////////////////////////////////////////////////////////////////// 39 void Matrice::Apply(double v0, double v1, double v2, double &Mv0, double &Mv1, 40 double &Mv2) { 41 Mv0 = c0_l0 * v0 + c1_l0 * v1 + c2_l0 * v2; 42 Mv1 = c0_l1 * v0 + c1_l1 * v1 + c2_l1 * v2; 43 Mv2 = c0_l2 * v0 + c1_l2 * v1 + c2_l2 * v2; 31 44 } 32 45 /// //////////////////////////////////////////////////////////////////// 33 46 Matrice ProdMat(const Matrice A, const Matrice B) { 34 35 36 out.c0_l0=A.c0_l0 * B.c0_l0 + A.c1_l0 * B.c0_l1 + A.c2_l0 * B.c0_l2;37 out.c1_l0=A.c0_l0 * B.c1_l0 + A.c1_l0 * B.c1_l1 + A.c2_l0 * B.c1_l2;38 out.c2_l0=A.c0_l0 * B.c2_l0 + A.c1_l0 * B.c2_l1 + A.c2_l0 * B.c2_l2;39 40 out.c0_l1=A.c0_l1 * B.c0_l0 + A.c1_l1 * B.c0_l1 + A.c2_l1 * B.c0_l2;41 out.c1_l1=A.c0_l1 * B.c1_l0 + A.c1_l1 * B.c1_l1 + A.c2_l1 * B.c1_l2;42 out.c2_l1=A.c0_l1 * B.c2_l0 + A.c1_l1 * B.c2_l1 + A.c2_l1 * B.c2_l2;43 44 out.c0_l2=A.c0_l2 * B.c0_l0 + A.c1_l2 * B.c0_l1 + A.c2_l2 * B.c0_l2;45 out.c1_l2=A.c0_l2 * B.c1_l0 + A.c1_l2 * B.c1_l1 + A.c2_l2 * B.c1_l2;46 out.c2_l2=A.c0_l2 * B.c2_l0 + A.c1_l2 * B.c2_l1 + A.c2_l2 * B.c2_l2;47 47 Matrice out; 48 49 out.c0_l0 = A.c0_l0 * B.c0_l0 + A.c1_l0 * B.c0_l1 + A.c2_l0 * B.c0_l2; 50 out.c1_l0 = A.c0_l0 * B.c1_l0 + A.c1_l0 * B.c1_l1 + A.c2_l0 * B.c1_l2; 51 out.c2_l0 = A.c0_l0 * B.c2_l0 + A.c1_l0 * B.c2_l1 + A.c2_l0 * B.c2_l2; 52 53 out.c0_l1 = A.c0_l1 * B.c0_l0 + A.c1_l1 * B.c0_l1 + A.c2_l1 * B.c0_l2; 54 out.c1_l1 = A.c0_l1 * B.c1_l0 + A.c1_l1 * B.c1_l1 + A.c2_l1 * B.c1_l2; 55 out.c2_l1 = A.c0_l1 * B.c2_l0 + A.c1_l1 * B.c2_l1 + A.c2_l1 * B.c2_l2; 56 57 out.c0_l2 = A.c0_l2 * B.c0_l0 + A.c1_l2 * B.c0_l1 + A.c2_l2 * B.c0_l2; 58 out.c1_l2 = A.c0_l2 * B.c1_l0 + A.c1_l2 * B.c1_l1 + A.c2_l2 * B.c1_l2; 59 out.c2_l2 = A.c0_l2 * B.c2_l0 + A.c1_l2 * B.c2_l1 + A.c2_l2 * B.c2_l2; 60 return out; 48 61 } 49 62 50 63 /// //////////////////////////////////////////////////////////////////// 51 64 Matrice TransMat(const Matrice A) { 52 Matrice out; 53 out.c0_l0=A.c0_l0 ; out.c1_l0 = A.c0_l1 ; out.c2_l0 = A.c0_l2 ; 54 out.c0_l1=A.c1_l0 ; out.c1_l1 = A.c1_l1 ; out.c2_l1 = A.c1_l2 ; 55 out.c0_l2=A.c2_l0 ; out.c1_l2 = A.c2_l1 ; out.c2_l2 = A.c2_l2 ; 56 return out; 57 } 58 59 /// //////////////////////////////////////////////////////////////////// 60 void Write(const Matrice A,std::ostream& out) { 61 out<< A.c0_l0<<"\t"<< A.c1_l0<<"\t"<< A.c2_l0<<"\n"; 62 out<< A.c0_l1<<"\t"<< A.c1_l1<<"\t"<< A.c2_l1<<"\n"; 63 out<< A.c0_l2<<"\t"<< A.c1_l2<<"\t"<< A.c2_l2<<"\n"; 64 } 65 66 /// //////////////////////////////////////////////////////////////////// 67 Raf98::~Raf98() { 68 m_dvalues.clear(); 69 } 65 Matrice out; 66 out.c0_l0 = A.c0_l0; 67 out.c1_l0 = A.c0_l1; 68 out.c2_l0 = A.c0_l2; 69 out.c0_l1 = A.c1_l0; 70 out.c1_l1 = A.c1_l1; 71 out.c2_l1 = A.c1_l2; 72 out.c0_l2 = A.c2_l0; 73 out.c1_l2 = A.c2_l1; 74 out.c2_l2 = A.c2_l2; 75 return out; 76 } 77 78 /// //////////////////////////////////////////////////////////////////// 79 void Write(const Matrice A, std::ostream &out) { 80 out << A.c0_l0 << "\t" << A.c1_l0 << "\t" << A.c2_l0 << "\n"; 81 out << A.c0_l1 << "\t" << A.c1_l1 << "\t" << A.c2_l1 << "\n"; 82 out << A.c0_l2 << "\t" << A.c1_l2 << "\t" << A.c2_l2 << "\n"; 83 } 84 85 /// //////////////////////////////////////////////////////////////////// 86 Raf98::~Raf98() { m_dvalues.clear(); } 70 87 71 88 //----------------------------------------------------------------------------- 72 bool Raf98::Interpol(double longitude, double latitude, double* Hwgs84) const { 73 *Hwgs84 = 0.0; 74 if (m_dvalues.size()==0) 75 return false; 76 const double longitude_min = -5.5; 77 const double longitude_max = 8.5; 78 if (longitude < longitude_min) 79 return false; 80 if (longitude > longitude_max) 81 return false; 82 83 const double latitude_min = 42; 84 const double latitude_max = 51.5; 85 if (latitude < latitude_min) 86 return false; 87 if (latitude > latitude_max) 88 return false; 89 90 //conversion en position 91 double longPix = (longitude - longitude_min) * 30.; 92 double latPix = (latitude_max - latitude) * 40.; 93 94 double RestCol,RestLig; 95 double ColIni,LigIni; 96 RestCol = modf(longPix,&ColIni); 97 RestLig = modf(latPix,&LigIni); 98 99 100 double Zbd = (1.0-RestCol) * (1.0-RestLig) * LitGrille(ColIni , LigIni ); 101 Zbd += RestCol * (1.0-RestLig) * LitGrille(ColIni+1, LigIni ); 102 Zbd += (1.0-RestCol) * RestLig * LitGrille(ColIni , LigIni+1); 103 Zbd += RestCol * RestLig * LitGrille(ColIni+1, LigIni+1); 104 *Hwgs84 = Zbd; 105 106 107 return true; 108 } 109 /// //////////////////////////////////////////////////////////////////// 110 double Raf98::LitGrille(unsigned int c,unsigned int l) const{ 111 const unsigned int w=421; 112 // const unsigned int h=381; 113 return m_dvalues.at(c+l*w); 114 } 115 /// //////////////////////////////////////////////////////////////////// 116 bool Raf98::Load(const std::string & sin) { 117 std::ifstream in(sin.c_str()); 118 unsigned int w = 421; 119 unsigned int h = 381; 120 121 m_dvalues.reserve(w*h); 122 123 char entete[1024];//sur 3 lignes 124 in.getline(entete,1023); 125 in.getline(entete,1023); 126 in.getline(entete,1023); 127 128 char bidon[1024]; 129 double val; 130 for (unsigned int i=0; i< h; ++i) { 131 for (unsigned int j=0; j< 52; ++j) { 132 for (unsigned int k=0; k< 8; ++k) { 133 in >> val; 134 m_dvalues.push_back( val ); 135 } 136 in.getline(bidon,1023); 137 } 138 for (unsigned int k=0; k< 5; ++k) { 139 in >> val; 140 m_dvalues.push_back( val ); 141 } 142 in.getline(bidon,1023); 143 if (!in.good()) { 144 m_dvalues.clear(); 145 return false; 146 } 89 bool Raf98::Interpol(double longitude, double latitude, double *Hwgs84) const { 90 *Hwgs84 = 0.0; 91 if (m_dvalues.size() == 0) 92 return false; 93 const double longitude_min = -5.5; 94 const double longitude_max = 8.5; 95 if (longitude < longitude_min) 96 return false; 97 if (longitude > longitude_max) 98 return false; 99 100 const double latitude_min = 42; 101 const double latitude_max = 51.5; 102 if (latitude < latitude_min) 103 return false; 104 if (latitude > latitude_max) 105 return false; 106 107 // conversion en position 108 double longPix = (longitude - longitude_min) * 30.; 109 double latPix = (latitude_max - latitude) * 40.; 110 111 double RestCol, RestLig; 112 double ColIni, LigIni; 113 RestCol = modf(longPix, &ColIni); 114 RestLig = modf(latPix, &LigIni); 115 116 double Zbd = (1.0 - RestCol) * (1.0 - RestLig) * LitGrille(ColIni, LigIni); 117 Zbd += RestCol * (1.0 - RestLig) * LitGrille(ColIni + 1, LigIni); 118 Zbd += (1.0 - RestCol) * RestLig * LitGrille(ColIni, LigIni + 1); 119 Zbd += RestCol * RestLig * LitGrille(ColIni + 1, LigIni + 1); 120 *Hwgs84 = Zbd; 121 122 return true; 123 } 124 /// //////////////////////////////////////////////////////////////////// 125 double Raf98::LitGrille(unsigned int c, unsigned int l) const { 126 const unsigned int w = 421; 127 // const unsigned int h=381; 128 return m_dvalues.at(c + l * w); 129 } 130 /// //////////////////////////////////////////////////////////////////// 131 bool Raf98::Load(const std::string &sin) { 132 std::ifstream in(sin.c_str()); 133 unsigned int w = 421; 134 unsigned int h = 381; 135 136 m_dvalues.reserve(w * h); 137 138 char entete[1024]; // sur 3 lignes 139 in.getline(entete, 1023); 140 in.getline(entete, 1023); 141 in.getline(entete, 1023); 142 143 char bidon[1024]; 144 double val; 145 for (unsigned int i = 0; i < h; ++i) { 146 for (unsigned int j = 0; j < 52; ++j) { 147 for (unsigned int k = 0; k < 8; ++k) { 148 in >> val; 149 m_dvalues.push_back(val); 150 } 151 in.getline(bidon, 1023); 147 152 } 148 return in.good(); 153 for (unsigned int k = 0; k < 5; ++k) { 154 in >> val; 155 m_dvalues.push_back(val); 156 } 157 in.getline(bidon, 1023); 158 if (!in.good()) { 159 m_dvalues.clear(); 160 return false; 161 } 162 } 163 return in.good(); 149 164 } 150 165 … … 155 170 156 171 /// //////////////////////////////////////////////////////////////////// 157 //ALGO0001 158 double Geodesie::LatitueIsometrique(double latitude,double e) { 159 double li; 160 li = log(tan(M_PI_4 + latitude/2.)) + e*log( (1-e*sin(latitude))/(1+e*sin(latitude)) )/2; 161 return li; 162 } 163 164 /// //////////////////////////////////////////////////////////////////// 165 //ALGO0002 166 double Geodesie::LatitueIsometrique2Lat(double latitude_iso,double e,double epsilon) { 167 double latitude_i=2*atan(exp(latitude_iso)) - M_PI_2; 168 double latitude_ip1=latitude_i+epsilon*2; 169 while (fabs(latitude_i-latitude_ip1)>epsilon) { 170 latitude_i=latitude_ip1; 171 latitude_ip1=2*atan( 172 exp(e*0.5* 173 log( 174 (1+e*sin(latitude_i))/(1-e*sin(latitude_i)) 175 ) 176 ) 177 *exp(latitude_iso) 178 ) - M_PI_2; 179 } 180 return latitude_ip1; 181 } 182 /// //////////////////////////////////////////////////////////////////// 183 void Geodesie::Geo2ProjLambert( 184 double lambda,double phi, 185 double n, double c,double e, 186 double lambdac,double xs,double ys, 187 double& X,double& Y) 188 { 189 double lat_iso=LatitueIsometrique(phi,e); 190 X=xs+c*exp(-n*lat_iso)*sin(n*(lambda-lambdac)); 191 Y=ys-c*exp(-n*lat_iso)*cos(n*(lambda-lambdac)); 192 } 193 /// //////////////////////////////////////////////////////////////////// 194 //ALGO0004 195 void Geodesie::Proj2GeoLambert( 196 double X,double Y, 197 double n, double c,double e, 198 double lambdac,double xs,double ys, 199 double epsilon, 200 double& lambda,double& phi) 201 { 202 double X_xs=X-xs; 203 double ys_Y=ys-Y; 204 double R=sqrt(X_xs*X_xs+ys_Y*ys_Y); 205 double gamma=atan(X_xs/ys_Y); 206 lambda=lambdac+gamma/n; 207 double lat_iso=-1/n*log(fabs(R/c)); 208 phi=LatitueIsometrique2Lat(lat_iso,e,epsilon); 172 // ALGO0001 173 double Geodesie::LatitueIsometrique(double latitude, double e) { 174 double li; 175 li = log(tan(M_PI_4 + latitude / 2.)) + 176 e * log((1 - e * sin(latitude)) / (1 + e * sin(latitude))) / 2; 177 return li; 178 } 179 180 /// //////////////////////////////////////////////////////////////////// 181 // ALGO0002 182 double Geodesie::LatitueIsometrique2Lat(double latitude_iso, double e, 183 double epsilon) { 184 double latitude_i = 2 * atan(exp(latitude_iso)) - M_PI_2; 185 double latitude_ip1 = latitude_i + epsilon * 2; 186 while (fabs(latitude_i - latitude_ip1) > epsilon) { 187 latitude_i = latitude_ip1; 188 latitude_ip1 = 2 * atan(exp(e * 0.5 * log((1 + e * sin(latitude_i)) / 189 (1 - e * sin(latitude_i)))) * 190 exp(latitude_iso)) - 191 M_PI_2; 192 } 193 return latitude_ip1; 194 } 195 /// //////////////////////////////////////////////////////////////////// 196 void Geodesie::Geo2ProjLambert(double lambda, double phi, double n, double c, 197 double e, double lambdac, double xs, double ys, 198 double &X, double &Y) { 199 double lat_iso = LatitueIsometrique(phi, e); 200 X = xs + c * exp(-n * lat_iso) * sin(n * (lambda - lambdac)); 201 Y = ys - c * exp(-n * lat_iso) * cos(n * (lambda - lambdac)); 202 } 203 /// //////////////////////////////////////////////////////////////////// 204 // ALGO0004 205 void Geodesie::Proj2GeoLambert(double X, double Y, double n, double c, double e, 206 double lambdac, double xs, double ys, 207 double epsilon, double &lambda, double &phi) { 208 double X_xs = X - xs; 209 double ys_Y = ys - Y; 210 double R = sqrt(X_xs * X_xs + ys_Y * ys_Y); 211 double gamma = atan(X_xs / ys_Y); 212 lambda = lambdac + gamma / n; 213 double lat_iso = -1 / n * log(fabs(R / c)); 214 phi = LatitueIsometrique2Lat(lat_iso, e, epsilon); 209 215 } 210 216 /// //////////////////////////////////////////////////////////////////// 211 217 double Geodesie::ConvMerApp(double longitude) { 212 213 214 double conv=-sin(phi0_Lambert93)*(longitude-lambda0_Lambert93);215 returnconv;218 double phi0_Lambert93 = Deg2Rad(46.5); 219 double lambda0_Lambert93 = Deg2Rad(3.0); 220 double conv = -sin(phi0_Lambert93) * (longitude - lambda0_Lambert93); 221 return conv; 216 222 } 217 223 218 224 //////////////////////////////////////////////////////////////////// 219 void Geodesie::Geographique_2_Lambert93(const Raf98& raf98,double lambda,double phi,double he,Matrice in,double& E,double& N,double& h,Matrice& out) { 220 Matrice passage; 221 double conv=Geodesie::ConvMerApp(lambda); 222 double c_=cos(conv); 223 double s_=sin(conv); 224 225 passage.c0_l0 = c_; 226 passage.c0_l1 = s_; 227 passage.c0_l2 = 0.0; 228 229 passage.c1_l0 = -s_; 230 passage.c1_l1 = c_; 231 passage.c1_l2 = 0.0; 232 233 passage.c2_l0 = 0.0; 234 passage.c2_l1 = 0.0; 235 passage.c2_l2 = 1.0; 236 237 out=ProdMat(passage,in); 238 double diff_h; 239 raf98.Interpol(Rad2Deg(lambda),Rad2Deg(phi),&diff_h); 240 h=he-diff_h; 241 242 Geodesie::Geo2ProjLambert( 243 lambda,phi, 244 n_Lambert93,c_Lambert93,e_Lambert93, 245 lambda0_Lambert93,xs_Lambert93,ys_Lambert93, 246 E,N); 225 void Geodesie::Geographique_2_Lambert93(const Raf98 &raf98, double lambda, 226 double phi, double he, Matrice in, 227 double &E, double &N, double &h, 228 Matrice &out) { 229 Matrice passage; 230 double conv = Geodesie::ConvMerApp(lambda); 231 double c_ = cos(conv); 232 double s_ = sin(conv); 233 234 passage.c0_l0 = c_; 235 passage.c0_l1 = s_; 236 passage.c0_l2 = 0.0; 237 238 passage.c1_l0 = -s_; 239 passage.c1_l1 = c_; 240 passage.c1_l2 = 0.0; 241 242 passage.c2_l0 = 0.0; 243 passage.c2_l1 = 0.0; 244 passage.c2_l2 = 1.0; 245 246 out = ProdMat(passage, in); 247 double diff_h; 248 raf98.Interpol(Rad2Deg(lambda), Rad2Deg(phi), &diff_h); 249 h = he - diff_h; 250 251 Geodesie::Geo2ProjLambert(lambda, phi, n_Lambert93, c_Lambert93, e_Lambert93, 252 lambda0_Lambert93, xs_Lambert93, ys_Lambert93, E, 253 N); 247 254 } 248 255 //////////////////////////////////////////////////////////////////////// 249 void Geodesie::Geographique_2_Lambert93(const Raf98 & raf98,double lambda,double phi,double he,double& E,double& N,double& h) {250 Geodesie::Geo2ProjLambert(251 lambda,phi,252 n_Lambert93,c_Lambert93,e_Lambert93,253 lambda0_Lambert93,xs_Lambert93,ys_Lambert93,254 E,N);255 256 257 raf98.Interpol(Rad2Deg(lambda),Rad2Deg(phi),&diff_h);258 h=he-diff_h;256 void Geodesie::Geographique_2_Lambert93(const Raf98 &raf98, double lambda, 257 double phi, double he, double &E, 258 double &N, double &h) { 259 Geodesie::Geo2ProjLambert(lambda, phi, n_Lambert93, c_Lambert93, e_Lambert93, 260 lambda0_Lambert93, xs_Lambert93, ys_Lambert93, E, 261 N); 262 263 double diff_h; 264 raf98.Interpol(Rad2Deg(lambda), Rad2Deg(phi), &diff_h); 265 h = he - diff_h; 259 266 } 260 267 /** 261 Converts Lambert93 coordinates (East, North, Height) into geographical coordinates in radians (Longitude = Rad2Deg(lambda), Latitude = Rad2Deg(phi), Height) 268 Converts Lambert93 coordinates (East, North, Height) into geographical 269 coordinates in radians (Longitude = Rad2Deg(lambda), Latitude = Rad2Deg(phi), 270 Height) 262 271 */ 263 void Geodesie::Lambert93_2_Geographique(const Raf98& raf98,double E,double N,double h,double& lambda,double& phi,double& he) { 264 Geodesie::Proj2GeoLambert( 265 E,N, 266 n_Lambert93,c_Lambert93,e_Lambert93, 267 lambda0_Lambert93,xs_Lambert93,ys_Lambert93, 268 0.0000000000000001, 269 lambda,phi); 270 271 double diff_h; 272 raf98.Interpol(Rad2Deg(lambda),Rad2Deg(phi),&diff_h); 273 he=h+diff_h; 272 void Geodesie::Lambert93_2_Geographique(const Raf98 &raf98, double E, double N, 273 double h, double &lambda, double &phi, 274 double &he) { 275 Geodesie::Proj2GeoLambert(E, N, n_Lambert93, c_Lambert93, e_Lambert93, 276 lambda0_Lambert93, xs_Lambert93, ys_Lambert93, 277 0.0000000000000001, lambda, phi); 278 279 double diff_h; 280 raf98.Interpol(Rad2Deg(lambda), Rad2Deg(phi), &diff_h); 281 he = h + diff_h; 274 282 } 275 283 //////////////////////////////////////////////////////////////////////// 276 void Geodesie::Lambert93_2_Geographique(const Raf98& raf98,double E,double N,double h,Matrice in,double& lambda,double& phi,double& he,Matrice& out) { 277 Geodesie::Proj2GeoLambert( 278 E,N, 279 n_Lambert93,c_Lambert93,e_Lambert93, 280 lambda0_Lambert93,xs_Lambert93,ys_Lambert93, 281 0.0000000000000001, 282 lambda,phi); 283 284 Matrice passage; 285 double conv=Geodesie::ConvMerApp(lambda); 286 double c_=cos(conv); 287 double s_=sin(conv); 288 289 passage.c0_l0 = c_; 290 passage.c0_l1 = -s_; 291 passage.c0_l2 = 0.0; 292 293 passage.c1_l0 = s_; 294 passage.c1_l1 = c_; 295 passage.c1_l2 = 0.0; 296 297 passage.c2_l0 = 0.0; 298 passage.c2_l1 = 0.0; 299 passage.c2_l2 = 1.0; 300 301 out=ProdMat(passage,in); 302 303 double diff_h; 304 raf98.Interpol(Rad2Deg(lambda),Rad2Deg(phi),&diff_h); 305 he=h+diff_h; 284 void Geodesie::Lambert93_2_Geographique(const Raf98 &raf98, double E, double N, 285 double h, Matrice in, double &lambda, 286 double &phi, double &he, Matrice &out) { 287 Geodesie::Proj2GeoLambert(E, N, n_Lambert93, c_Lambert93, e_Lambert93, 288 lambda0_Lambert93, xs_Lambert93, ys_Lambert93, 289 0.0000000000000001, lambda, phi); 290 291 Matrice passage; 292 double conv = Geodesie::ConvMerApp(lambda); 293 double c_ = cos(conv); 294 double s_ = sin(conv); 295 296 passage.c0_l0 = c_; 297 passage.c0_l1 = -s_; 298 passage.c0_l2 = 0.0; 299 300 passage.c1_l0 = s_; 301 passage.c1_l1 = c_; 302 passage.c1_l2 = 0.0; 303 304 passage.c2_l0 = 0.0; 305 passage.c2_l1 = 0.0; 306 passage.c2_l2 = 1.0; 307 308 out = ProdMat(passage, in); 309 310 double diff_h; 311 raf98.Interpol(Rad2Deg(lambda), Rad2Deg(phi), &diff_h); 312 he = h + diff_h; 306 313 } 307 314 308 315 //////////////////////////////////////////////////////////////////////// 309 void Geodesie::Geographique_2_ECEF(double longitude,double latitude,double he,double& x,double& y,double& z) { 310 const double n = GRS_a / sqrt(1.0 - pow(GRS_e,2) * pow(sin(latitude),2)); 311 x = (n + he) * cos(latitude) * cos(longitude); 312 y = (n + he) * cos(latitude) * sin(longitude); 313 z = (n * (1.0 - pow(GRS_e,2)) + he) * sin(latitude); 316 void Geodesie::Geographique_2_ECEF(double longitude, double latitude, double he, 317 double &x, double &y, double &z) { 318 const double n = GRS_a / sqrt(1.0 - pow(GRS_e, 2) * pow(sin(latitude), 2)); 319 x = (n + he) * cos(latitude) * cos(longitude); 320 y = (n + he) * cos(latitude) * sin(longitude); 321 z = (n * (1.0 - pow(GRS_e, 2)) + he) * sin(latitude); 314 322 } 315 323 316 324 //////////////////////////////////////////////////////////////////////// 317 void Geodesie::ECEF_2_ENU(double x,double y,double z,double& e,double& n,double& u,double lon0,double lat0,double he0) { 318 double slat = std::sin(lat0); 319 double clat = std::cos(lat0); 320 double slon = std::sin(lon0); 321 double clon = std::cos(lon0); 322 323 Geodesie::Matrice C; 324 C.c0_l0 = -slon; 325 C.c1_l0 = clon; 326 327 C.c0_l1 = -clon * slat; 328 C.c1_l1 = -slon * slat; 329 C.c2_l1 = clat; 330 331 C.c0_l2 = clon * clat; 332 C.c1_l2 = slon * clat; 333 C.c2_l2 = slat; 334 335 double x0, y0, z0; 336 Geographique_2_ECEF(lon0,lat0,he0, x0,y0,z0); 337 338 x -= x0; 339 y -= y0; 340 z -= z0; 341 342 C.Apply(x,y,z, e,n,u); 343 } 325 void Geodesie::ECEF_2_ENU(double x, double y, double z, double &e, double &n, 326 double &u, double lon0, double lat0, double he0) { 327 double slat = std::sin(lat0); 328 double clat = std::cos(lat0); 329 double slon = std::sin(lon0); 330 double clon = std::cos(lon0); 331 332 Geodesie::Matrice C; 333 C.c0_l0 = -slon; 334 C.c1_l0 = clon; 335 336 C.c0_l1 = -clon * slat; 337 C.c1_l1 = -slon * slat; 338 C.c2_l1 = clat; 339 340 C.c0_l2 = clon * clat; 341 C.c1_l2 = slon * clat; 342 C.c2_l2 = slat; 343 344 double x0, y0, z0; 345 Geographique_2_ECEF(lon0, lat0, he0, x0, y0, z0); 346 347 x -= x0; 348 y -= y0; 349 z -= z0; 350 351 C.Apply(x, y, z, e, n, u); 352 } -
trunk/lib/FlairSensorActuator/src/unexported/AfroBldc_impl.h
r3 r15 16 16 /*********************************************************************/ 17 17 18 19 18 #ifndef AFROBLDC_IMPL_H 20 19 #define AFROBLDC_IMPL_H … … 25 24 #define MAX_MOTORS 8 26 25 27 namespace flair 28 { 29 namespace core 30 { 31 class I2cPort; 32 } 33 namespace gui 34 { 35 class SpinBox; 36 class GroupBox; 37 class Layout; 38 } 39 namespace actuator 40 { 41 class AfroBldc; 42 } 43 namespace sensor 44 { 45 class BatteryMonitor; 46 } 26 namespace flair { 27 namespace core { 28 class I2cPort; 29 } 30 namespace gui { 31 class SpinBox; 32 class GroupBox; 33 class Layout; 34 } 35 namespace actuator { 36 class AfroBldc; 37 } 38 namespace sensor { 39 class BatteryMonitor; 40 } 47 41 } 48 42 49 class AfroBldc_impl 50 { 51 public:52 AfroBldc_impl(flair::actuator::AfroBldc* self,flair::gui::Layout *layout,flair::core::I2cPort*i2cport);53 54 void SetMotors(float*value);43 class AfroBldc_impl { 44 public: 45 AfroBldc_impl(flair::actuator::AfroBldc *self, flair::gui::Layout *layout, 46 flair::core::I2cPort *i2cport); 47 ~AfroBldc_impl(); 48 void SetMotors(float *value); 55 49 56 private: 57 void WriteValue(uint16_t value);//I2cPort mutex must be taken before calling this function 58 int nb_mot; 59 flair::core::I2cPort* i2cport; 60 flair::actuator::AfroBldc* self; 50 private: 51 void WriteValue(uint16_t value); // I2cPort mutex must be taken before calling 52 // this function 53 int nb_mot; 54 flair::core::I2cPort *i2cport; 55 flair::actuator::AfroBldc *self; 61 56 }; 62 57 -
trunk/lib/FlairSensorActuator/src/unexported/BlCtrlV2_impl.h
r3 r15 16 16 /*********************************************************************/ 17 17 18 19 18 #ifndef BLCTRLV2_IMPL_H 20 19 #define BLCTRLV2_IMPL_H … … 25 24 #define MAX_MOTORS 8 26 25 27 namespace flair 28 { 29 namespace core 30 { 31 class I2cPort; 32 } 33 namespace gui 34 { 35 class SpinBox; 36 class GroupBox; 37 class Layout; 38 } 39 namespace actuator 40 { 41 class BlCtrlV2; 42 } 43 namespace sensor 44 { 45 class BatteryMonitor; 46 } 26 namespace flair { 27 namespace core { 28 class I2cPort; 29 } 30 namespace gui { 31 class SpinBox; 32 class GroupBox; 33 class Layout; 34 } 35 namespace actuator { 36 class BlCtrlV2; 37 } 38 namespace sensor { 39 class BatteryMonitor; 40 } 47 41 } 48 42 49 class BlCtrlV2_impl 50 { 51 public:52 BlCtrlV2_impl(flair::actuator::BlCtrlV2* self,flair::gui::Layout *layout,flair::core::I2cPort*i2cport);53 54 void SetMotors(float*value);55 56 43 class BlCtrlV2_impl { 44 public: 45 BlCtrlV2_impl(flair::actuator::BlCtrlV2 *self, flair::gui::Layout *layout, 46 flair::core::I2cPort *i2cport); 47 ~BlCtrlV2_impl(); 48 void SetMotors(float *value); 49 flair::sensor::BatteryMonitor *battery; 50 flair::gui::SpinBox *poles; 57 51 58 private: 59 void WriteValue(uint16_t value);//I2cPort mutex must be taken before calling this function 60 void DetectMotors(void); 61 void GetCurrentSpeedAndVoltage(float ¤t,float &speed,float &voltage);//I2cPort mutex must be taken before calling this function 62 void GetCurrentAndSpeed(float ¤t,float &speed);//I2cPort mutex must be taken before calling this function 63 flair::core::Time last_voltage_time; 64 int nb_mot; 65 flair::core::I2cPort* i2cport; 66 flair::actuator::BlCtrlV2* self; 52 private: 53 void WriteValue(uint16_t value); // I2cPort mutex must be taken before calling 54 // this function 55 void DetectMotors(void); 56 void GetCurrentSpeedAndVoltage(float ¤t, float &speed, 57 float &voltage); // I2cPort mutex must be taken 58 // before calling this 59 // function 60 void GetCurrentAndSpeed( 61 float ¤t, 62 float &speed); // I2cPort mutex must be taken before calling this function 63 flair::core::Time last_voltage_time; 64 int nb_mot; 65 flair::core::I2cPort *i2cport; 66 flair::actuator::BlCtrlV2 *self; 67 67 }; 68 68 -
trunk/lib/FlairSensorActuator/src/unexported/Bldc_impl.h
r3 r15 22 22 #include <stdint.h> 23 23 24 namespace flair 25 { 26 namespace gui 27 { 28 class DoubleSpinBox; 29 class Layout; 30 class Label; 31 class DataPlot1D; 32 class TabWidget; 33 class PushButton; 34 } 35 namespace actuator 36 { 37 class Bldc; 38 } 24 namespace flair { 25 namespace gui { 26 class DoubleSpinBox; 27 class Layout; 28 class Label; 29 class DataPlot1D; 30 class TabWidget; 31 class PushButton; 32 } 33 namespace actuator { 34 class Bldc; 35 } 39 36 } 40 37 41 class Bldc_impl 42 { 43 public:44 Bldc_impl(flair::actuator::Bldc* self,flair::gui::Layout* layout,std::string name,uint8_t motors_count);45 Bldc_impl(flair::actuator::Bldc* self,uint8_t motors_count);//simulation46 47 48 49 50 51 float*power;52 void UseDefaultPlot(flair::gui::TabWidget*tab);53 54 flair::gui::Layout*layout;38 class Bldc_impl { 39 public: 40 Bldc_impl(flair::actuator::Bldc *self, flair::gui::Layout *layout, 41 std::string name, uint8_t motors_count); 42 Bldc_impl(flair::actuator::Bldc *self, uint8_t motors_count); // simulation 43 ~Bldc_impl(); 44 void UpdateFrom(const flair::core::io_data *data); 45 void LockUserInterface(void) const; 46 void UnlockUserInterface(void) const; 47 bool are_enabled; 48 float *power; 49 void UseDefaultPlot(flair::gui::TabWidget *tab); 50 uint8_t motors_count; 51 flair::gui::Layout *layout; 55 52 56 57 58 59 flair::actuator::Bldc*self;60 flair::gui::DoubleSpinBox *min_value,*max_value,*test_value;61 62 63 64 65 66 67 68 int tested_motor;//=-1 if no motor is tested53 private: 54 float *values; 55 float Sat(float value); 56 flair::actuator::Bldc *self; 57 flair::gui::DoubleSpinBox *min_value, *max_value, *test_value; 58 flair::gui::Label *flight_time; 59 flair::gui::DataPlot1D *plots; 60 flair::core::Time flight_start_time; 61 flair::gui::PushButton **button_test; 62 int time_sec; 63 bool is_running; 64 flair::core::Time test_start_time; 65 int tested_motor; //=-1 if no motor is tested 69 66 }; 70 67 -
trunk/lib/FlairSensorActuator/src/unexported/Gx3_25_imu_impl.h
r3 r15 18 18 19 19 namespace flair { 20 21 22 23 24 25 26 27 28 29 30 20 namespace core { 21 class FrameworkManager; 22 class SerialPort; 23 class AhrsData; 24 } 25 namespace gui { 26 class SpinBox; 27 class CheckBox; 28 class PushButton; 29 class Label; 30 } 31 31 } 32 32 … … 38 38 class Gx3_25_imu_impl { 39 39 40 public: 41 Gx3_25_imu_impl(flair::sensor::Gx3_25_imu* self,std::string name,flair::core::SerialPort *serialport,flair::sensor::Gx3_25_imu::Command_t command,flair::gui::GroupBox* setupgroupbox); 42 ~Gx3_25_imu_impl(); 43 void Run(void); 40 public: 41 Gx3_25_imu_impl(flair::sensor::Gx3_25_imu *self, std::string name, 42 flair::core::SerialPort *serialport, 43 flair::sensor::Gx3_25_imu::Command_t command, 44 flair::gui::GroupBox *setupgroupbox); 45 ~Gx3_25_imu_impl(); 46 void Run(void); 44 47 45 46 47 void GetData(uint8_t* buf,ssize_t buf_size,flair::core::Time *time);48 float Dequeue(uint8_t**buf);49 50 51 52 bool CalcChecksum(uint8_t *buf,int size);53 54 55 void RealignUpNorth(bool realign_up,bool realign_north);48 private: 49 void DeviceReset(void); 50 void GetData(uint8_t *buf, ssize_t buf_size, flair::core::Time *time); 51 float Dequeue(uint8_t **buf); 52 void GyrosBias(void); 53 void SamplingSettings(void); 54 void SetBaudrate(int value); 55 bool CalcChecksum(uint8_t *buf, int size); 56 int FirmwareNumber(void); 57 void PrintModelInfo(void); 58 void RealignUpNorth(bool realign_up, bool realign_north); 56 59 57 60 void SetContinuousMode(uint8_t continuous_command); 58 61 59 flair::gui::GroupBox *setupgroupbox; 60 flair::gui::SpinBox *data_rate,*gyro_acc_size,*mag_size,*up_comp,*north_comp; 61 flair::gui::CheckBox *coning,*disable_magn,*disable_north_comp,*disable_grav_comp; 62 flair::gui::PushButton *button_bias; 63 flair::gui::Label *data_rate_label; 62 flair::gui::GroupBox *setupgroupbox; 63 flair::gui::SpinBox *data_rate, *gyro_acc_size, *mag_size, *up_comp, 64 *north_comp; 65 flair::gui::CheckBox *coning, *disable_magn, *disable_north_comp, 66 *disable_grav_comp; 67 flair::gui::PushButton *button_bias; 68 flair::gui::Label *data_rate_label; 64 69 65 66 67 68 70 flair::core::SerialPort *serialport; 71 uint8_t command; 72 flair::sensor::Gx3_25_imu *self; 73 flair::core::AhrsData *ahrsData; 69 74 }; 70 75 -
trunk/lib/FlairSensorActuator/src/unexported/VrpnClient_impl.h
r3 r15 22 22 #include <vector> 23 23 24 namespace flair 25 { 26 namespace core 27 { 28 class OneAxisRotation; 29 class Vector3D; 30 class Quaternion; 31 class Mutex; 32 class SerialPort; 33 } 34 namespace gui 35 { 36 class TabWidget; 37 class Tab; 38 class Layout; 39 } 40 namespace sensor 41 { 42 class VrpnClient; 43 class VrpnObject; 44 } 24 namespace flair { 25 namespace core { 26 class OneAxisRotation; 27 class Vector3D; 28 class Quaternion; 29 class Mutex; 30 class SerialPort; 31 } 32 namespace gui { 33 class TabWidget; 34 class Tab; 35 class Layout; 36 } 37 namespace sensor { 38 class VrpnClient; 39 class VrpnObject; 40 } 45 41 } 46 42 … … 48 44 class vrpn_Connection; 49 45 50 class VrpnClient_impl 51 { 52 public: 53 VrpnClient_impl(flair::sensor::VrpnClient* self,std::string name,std::string address,uint16_t us_period); 54 VrpnClient_impl(flair::sensor::VrpnClient* self,std::string name,flair::core::SerialPort* serialport,uint16_t us_period); 55 ~VrpnClient_impl(); 56 void AddTrackable(flair::sensor::VrpnObject* obj);//normal 57 void RemoveTrackable(flair::sensor::VrpnObject* obj);//normal 58 void AddTrackable(VrpnObject_impl* obj,uint8_t id);//xbee 59 void RemoveTrackable(VrpnObject_impl* obj);//xbee 60 void ComputeRotations(flair::core::Vector3D& point); 61 void ComputeRotations(flair::core::Quaternion& quat); 62 bool UseXbee(void); 63 void Run(void); 64 flair::gui::Tab* setup_tab; 65 flair::gui::TabWidget* tab; 66 vrpn_Connection *connection; 46 class VrpnClient_impl { 47 public: 48 VrpnClient_impl(flair::sensor::VrpnClient *self, std::string name, 49 std::string address, uint16_t us_period); 50 VrpnClient_impl(flair::sensor::VrpnClient *self, std::string name, 51 flair::core::SerialPort *serialport, uint16_t us_period); 52 ~VrpnClient_impl(); 53 void AddTrackable(flair::sensor::VrpnObject *obj); // normal 54 void RemoveTrackable(flair::sensor::VrpnObject *obj); // normal 55 void AddTrackable(VrpnObject_impl *obj, uint8_t id); // xbee 56 void RemoveTrackable(VrpnObject_impl *obj); // xbee 57 void ComputeRotations(flair::core::Vector3D &point); 58 void ComputeRotations(flair::core::Quaternion &quat); 59 bool UseXbee(void); 60 void Run(void); 61 flair::gui::Tab *setup_tab; 62 flair::gui::TabWidget *tab; 63 vrpn_Connection *connection; 67 64 68 69 flair::sensor::VrpnClient*self;70 flair::core::Mutex*mutex;71 72 std::vector<flair::sensor::VrpnObject*> trackables;73 typedef struct xbee_object{74 VrpnObject_impl*vrpnobject;75 76 65 private: 66 flair::sensor::VrpnClient *self; 67 flair::core::Mutex *mutex; 68 uint16_t us_period; 69 std::vector<flair::sensor::VrpnObject *> trackables; 70 typedef struct xbee_object { 71 VrpnObject_impl *vrpnobject; 72 uint8_t id; 73 } xbee_object; 77 74 78 79 flair::gui::Tab*main_tab;80 flair::core::OneAxisRotation *rotation_1,*rotation_2;81 flair::core::SerialPort*serialport;75 std::vector<xbee_object> xbee_objects; 76 flair::gui::Tab *main_tab; 77 flair::core::OneAxisRotation *rotation_1, *rotation_2; 78 flair::core::SerialPort *serialport; 82 79 }; 83 80 -
trunk/lib/FlairSensorActuator/src/unexported/VrpnObject_impl.h
r3 r15 25 25 #include "Quaternion.h" 26 26 27 namespace flair 28 { 29 namespace core 30 { 31 class cvmatrix; 32 class Vector3D; 33 class Euler; 34 } 35 namespace gui 36 { 37 class TabWidget; 38 class Tab; 39 class DataPlot1D; 40 } 41 namespace sensor 42 { 43 class VrpnClient; 44 class VrpnObject; 45 } 27 namespace flair { 28 namespace core { 29 class cvmatrix; 30 class Vector3D; 31 class Euler; 32 } 33 namespace gui { 34 class TabWidget; 35 class Tab; 36 class DataPlot1D; 37 } 38 namespace sensor { 39 class VrpnClient; 40 class VrpnObject; 41 } 46 42 } 47 43 48 class VrpnObject_impl 49 { 50 friend class VrpnClient_impl; 44 class VrpnObject_impl { 45 friend class VrpnClient_impl; 51 46 52 public: 53 VrpnObject_impl(flair::sensor::VrpnObject* self,const flair::sensor::VrpnClient *parent,std::string name,int id,const flair::gui::TabWidget* tab); 54 ~VrpnObject_impl(void); 47 public: 48 VrpnObject_impl(flair::sensor::VrpnObject *self, 49 const flair::sensor::VrpnClient *parent, std::string name, 50 int id, const flair::gui::TabWidget *tab); 51 ~VrpnObject_impl(void); 55 52 56 57 58 59 60 53 void mainloop(void); 54 void GetEuler(flair::core::Euler &euler); 55 void GetQuaternion(flair::core::Quaternion &quaternion); 56 void GetPosition(flair::core::Vector3D &point); 57 bool IsTracked(unsigned int timeout_ms); 61 58 62 flair::gui::Tab*plot_tab;63 flair::gui::DataPlot1D*x_plot;64 flair::gui::DataPlot1D*y_plot;65 flair::gui::DataPlot1D*z_plot;66 flair::core::cvmatrix *output,*state;59 flair::gui::Tab *plot_tab; 60 flair::gui::DataPlot1D *x_plot; 61 flair::gui::DataPlot1D *y_plot; 62 flair::gui::DataPlot1D *z_plot; 63 flair::core::cvmatrix *output, *state; 67 64 68 static voidVRPN_CALLBACK handle_pos(void *userdata, const vrpn_TRACKERCB t);65 static void VRPN_CALLBACK handle_pos(void *userdata, const vrpn_TRACKERCB t); 69 66 70 private: 71 flair::sensor::VrpnObject* self; 72 const flair::sensor::VrpnClient *parent; 73 vrpn_Tracker_Remote* tracker; 74 flair::core::Quaternion quaternion;//todo: quaternion should be included in the output to replace euler angles 75 void Update(void); 67 private: 68 flair::sensor::VrpnObject *self; 69 const flair::sensor::VrpnClient *parent; 70 vrpn_Tracker_Remote *tracker; 71 flair::core::Quaternion quaternion; // todo: quaternion should be included in 72 // the output to replace euler angles 73 void Update(void); 76 74 }; 77 75 -
trunk/lib/FlairSensorActuator/src/unexported/XBldc_impl.h
r3 r15 16 16 /*********************************************************************/ 17 17 18 19 18 #ifndef XBLDC_IMPL_H 20 19 #define XBLDC_IMPL_H … … 23 22 #include <stdint.h> 24 23 25 namespace flair 26 { 27 namespace core 28 { 29 class I2cPort; 30 } 31 namespace actuator 32 { 33 class XBldc; 34 } 24 namespace flair { 25 namespace core { 26 class I2cPort; 27 } 28 namespace actuator { 29 class XBldc; 30 } 35 31 } 36 32 33 class XBldc_impl { 37 34 38 class XBldc_impl 39 { 35 public: 36 XBldc_impl(flair::actuator::XBldc *self, flair::core::I2cPort *i2cport); 37 ~XBldc_impl(); 38 void UpdateFrom(flair::core::io_data *data); 39 void SetMotors(float *value); 40 40 41 public: 42 XBldc_impl(flair::actuator::XBldc* self,flair::core::I2cPort* i2cport); 43 ~XBldc_impl(); 44 void UpdateFrom(flair::core::io_data *data); 45 void SetMotors(float* value); 46 47 private: 48 uint8_t Sat(float value,uint8_t min,uint8_t max); 49 //void StartTest(uint8_t moteur); 50 void ChangeDirection(uint8_t moteur); 51 void ChangeAdress(uint8_t old_add,uint8_t new_add); 52 flair::actuator::XBldc* self; 53 flair::core::I2cPort* i2cport; 41 private: 42 uint8_t Sat(float value, uint8_t min, uint8_t max); 43 // void StartTest(uint8_t moteur); 44 void ChangeDirection(uint8_t moteur); 45 void ChangeAdress(uint8_t old_add, uint8_t new_add); 46 flair::actuator::XBldc *self; 47 flair::core::I2cPort *i2cport; 54 48 }; 55 49 -
trunk/lib/FlairSensorActuator/src/unexported/geodesie.h
r3 r15 13 13 14 14 #ifndef M_PI 15 # 15 #define M_PI 3.14159265358979323846 16 16 #endif 17 17 #ifndef M_PI_2 18 # 18 #define M_PI_2 1.57079632679489661923 19 19 #endif 20 20 #ifndef M_PI_4 21 # 21 #define M_PI_4 0.78539816339744830962 22 22 #endif 23 23 24 24 //////////////////////////////////////////////////////////////////////// 25 25 struct Matrice { 26 Matrice(const Matrice & A); 27 Matrice(); 28 void Apply(double v0, double v1, double v2, double & Mv0, double & Mv1, double & Mv2); 29 double c0_l0;double c1_l0;double c2_l0; 30 double c0_l1;double c1_l1;double c2_l1; 31 double c0_l2;double c1_l2;double c2_l2; 26 Matrice(const Matrice &A); 27 Matrice(); 28 void Apply(double v0, double v1, double v2, double &Mv0, double &Mv1, 29 double &Mv2); 30 double c0_l0; 31 double c1_l0; 32 double c2_l0; 33 double c0_l1; 34 double c1_l1; 35 double c2_l1; 36 double c0_l2; 37 double c1_l2; 38 double c2_l2; 32 39 }; // class 33 40 34 41 Matrice TransMat(const Matrice A); 35 42 36 Matrice ProdMat(const Matrice A, const Matrice B);37 void Write(const Matrice A, std::ostream&out);43 Matrice ProdMat(const Matrice A, const Matrice B); 44 void Write(const Matrice A, std::ostream &out); 38 45 39 46 //////////////////////////////////////////////////////////////////////// 40 47 class Raf98 { 41 private : 42 std::vector<double> m_dvalues; 43 double LitGrille(unsigned int c,unsigned int l) const; 44 public : 45 ~Raf98(); 46 Raf98() {} 47 bool Load(const std::string & s); 48 bool Interpol(double longitude/*deg*/, double latitude/*deg*/, double* Hwgs84) const; 48 private: 49 std::vector<double> m_dvalues; 50 double LitGrille(unsigned int c, unsigned int l) const; 51 52 public: 53 ~Raf98(); 54 Raf98() {} 55 bool Load(const std::string &s); 56 bool Interpol(double longitude /*deg*/, double latitude /*deg*/, 57 double *Hwgs84) const; 49 58 }; // class 50 59 //////////////////////////////////////////////////////////////////////// 51 60 52 61 //////////////////////////////////////////////////////////////////////// 53 inline double Deg2Rad(double deg) { return deg*M_PI/180.0;}54 inline double Rad2Deg(double rad) { return rad*180.0/M_PI;}62 inline double Deg2Rad(double deg) { return deg * M_PI / 180.0; } 63 inline double Rad2Deg(double rad) { return rad * 180.0 / M_PI; } 55 64 //////////////////////////////////////////////////////////////////////// 56 65 57 const double a_Lambert93 =6378137;58 const double f_Lambert93 =1 / 298.257222101;59 const double e_Lambert93 =sqrt(f_Lambert93*(2-f_Lambert93));60 const double lambda0_Lambert93 =Deg2Rad(3.0);//degres61 const double phi0_Lambert93 =Deg2Rad(46.5);62 const double phi1_Lambert93 =Deg2Rad(44.0);63 const double phi2_Lambert93 =Deg2Rad(49.0);//degres64 const double X0_Lambert93 =700000;//65 const double Y0_Lambert93 =6600000;//66 const double a_Lambert93 = 6378137; 67 const double f_Lambert93 = 1 / 298.257222101; 68 const double e_Lambert93 = sqrt(f_Lambert93 * (2 - f_Lambert93)); 69 const double lambda0_Lambert93 = Deg2Rad(3.0); // degres 70 const double phi0_Lambert93 = Deg2Rad(46.5); 71 const double phi1_Lambert93 = Deg2Rad(44.0); 72 const double phi2_Lambert93 = Deg2Rad(49.0); // degres 73 const double X0_Lambert93 = 700000; // 74 const double Y0_Lambert93 = 6600000; // 66 75 const double n_Lambert93 = 0.7256077650; 67 76 const double c_Lambert93 = 11754255.426; … … 70 79 71 80 const double GRS_a = 6378137; 72 const double GRS_f = 1 /298.257222101;73 const double GRS_b = GRS_a *(1-GRS_f);74 const double GRS_e = sqrt((pow(GRS_a, 2) - pow(GRS_b,2)) / pow(GRS_a,2));81 const double GRS_f = 1 / 298.257222101; 82 const double GRS_b = GRS_a * (1 - GRS_f); 83 const double GRS_e = sqrt((pow(GRS_a, 2) - pow(GRS_b, 2)) / pow(GRS_a, 2)); 75 84 76 85 //////////////////////////////////////////////////////////////////////// 77 void Geographique_2_Lambert93(const Raf98& raf98,double lambda,double phi,double he,Matrice in,double& E,double& N,double& h,Matrice& out); 78 void Geographique_2_Lambert93(const Raf98& raf98,double lambda,double phi,double he,double& E,double& N,double& h); 79 void Lambert93_2_Geographique(const Raf98& raf98,double E,double N,double h,double& lambda,double& phi,double& he); 80 void Lambert93_2_Geographique(const Raf98& raf98,double E,double N,double h,Matrice in,double& lambda,double& phi,double& he,Matrice& out); 86 void Geographique_2_Lambert93(const Raf98 &raf98, double lambda, double phi, 87 double he, Matrice in, double &E, double &N, 88 double &h, Matrice &out); 89 void Geographique_2_Lambert93(const Raf98 &raf98, double lambda, double phi, 90 double he, double &E, double &N, double &h); 91 void Lambert93_2_Geographique(const Raf98 &raf98, double E, double N, double h, 92 double &lambda, double &phi, double &he); 93 void Lambert93_2_Geographique(const Raf98 &raf98, double E, double N, double h, 94 Matrice in, double &lambda, double &phi, 95 double &he, Matrice &out); 81 96 /** Convert from geographique to ECEF. 82 97 * @param[in] longitude Longitude in radian. … … 84 99 * @param[in] he Height in meter. 85 100 */ 86 void Geographique_2_ECEF(double longitude, double latitude, double he, double& x, double& y, double& z); 101 void Geographique_2_ECEF(double longitude, double latitude, double he, 102 double &x, double &y, double &z); 87 103 /** Convert from ECEF two ENU. 88 104 * @param[in] lon0 Longitude of the origin in radian. … … 90 106 * @param[in] he0 Height of the origin in radian. 91 107 */ 92 void ECEF_2_ENU(double x,double y,double z,double& e,double& n,double& u,double lon0,double lat0,double he0); 108 void ECEF_2_ENU(double x, double y, double z, double &e, double &n, double &u, 109 double lon0, double lat0, double he0); 93 110 //////////////////////////////////////////////////////////////////////// 94 111 95 // ALGO000196 double LatitueIsometrique(double latitude, double e);97 // ALGO000298 double LatitueIsometrique2Lat(double latitude_iso, double e,double epsilon);112 // ALGO0001 113 double LatitueIsometrique(double latitude, double e); 114 // ALGO0002 115 double LatitueIsometrique2Lat(double latitude_iso, double e, double epsilon); 99 116 100 //ALGO0003 101 void Geo2ProjLambert( 102 double lambda,double phi, 103 double n, double c,double e, 104 double lambdac,double xs,double ys, 105 double& X,double& Y); 106 //ALGO0004 107 void Proj2GeoLambert( 108 double X,double Y, 109 double n, double c,double e, 110 double lambdac,double xs,double ys, 111 double epsilon, 112 double& lambda,double& phi); 117 // ALGO0003 118 void Geo2ProjLambert(double lambda, double phi, double n, double c, double e, 119 double lambdac, double xs, double ys, double &X, 120 double &Y); 121 // ALGO0004 122 void Proj2GeoLambert(double X, double Y, double n, double c, double e, 123 double lambdac, double xs, double ys, double epsilon, 124 double &lambda, double &phi); 113 125 114 126 double ConvMerApp(double longitude); … … 118 130 */ 119 131 template <typename _T1, typename _T2> 120 void cartesianToPolar(const _T1 x, const _T1 y, _T2 & r, _T2 &theta) {121 r = std::sqrt(x*x + y*y);122 132 void cartesianToPolar(const _T1 x, const _T1 y, _T2 &r, _T2 &theta) { 133 r = std::sqrt(x * x + y * y); 134 theta = std::atan2(x, y); 123 135 } 124 136 … … 127 139 */ 128 140 template <typename _T1, typename _T2> 129 void polarToCartesian(const _T1 r, const _T1 theta, _T2 & x, _T2 &y) {130 131 141 void polarToCartesian(const _T1 r, const _T1 theta, _T2 &x, _T2 &y) { 142 x = r * std::cos(theta); 143 y = r * std::sin(theta); 132 144 } 133 145 134 146 /** 135 Converts Cartesian (x, y, z) coordinates to spherical coordinates (r, theta, phi) 147 Converts Cartesian (x, y, z) coordinates to spherical coordinates (r, theta, 148 phi) 136 149 Angles expressed in radians. 137 150 */ 138 151 template <typename _T1, typename _T2> 139 void cartesianToSpherical(const _T1 x, const _T1 y, const _T1 z, _T2 & r, _T2 & theta, _T2 & phi) { 140 r = std::sqrt(x*x + y*y + z*z); 141 theta = std::acos(z / r); 142 phi = std::atan2(y, x); 152 void cartesianToSpherical(const _T1 x, const _T1 y, const _T1 z, _T2 &r, 153 _T2 &theta, _T2 &phi) { 154 r = std::sqrt(x * x + y * y + z * z); 155 theta = std::acos(z / r); 156 phi = std::atan2(y, x); 143 157 } 144 158 145 159 /** 146 Converts spherical coordinates (r, theta, phi) to Cartesian (x, y, z) coordinates. 160 Converts spherical coordinates (r, theta, phi) to Cartesian (x, y, z) 161 coordinates. 147 162 Angles expressed in radians. 148 163 */ 149 164 template <typename _T1, typename _T2> 150 void sphericalToCartesian(const _T1 r, const _T1 theta, const _T1 phi, _T2 & x, _T2 & y, _T2 & z) { 151 x = r * std::sin(theta) * std::cos(phi); 152 y = r * std::sin(theta) * std::sin(phi); 153 z = r * std::cos(theta); 165 void sphericalToCartesian(const _T1 r, const _T1 theta, const _T1 phi, _T2 &x, 166 _T2 &y, _T2 &z) { 167 x = r * std::sin(theta) * std::cos(phi); 168 y = r * std::sin(theta) * std::sin(phi); 169 z = r * std::cos(theta); 154 170 } 155 171
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