/devices/PowerManagement/PowerManagement.cpp - AMiRo-OS - Research for Cognitive Interaction

amiro-os / devices / PowerManagement / PowerManagement.cpp @ f3972840

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       #include "ch.hpp"
       #include "hal.h"
       #include "PowerManagement.h"
       #include <amiro/proximity/vcnl4020.hpp>
       #include <global.hpp>
       #include <algorithm>
       #include <chprintf.h>
       using namespace chibios_rt;
       using namespace amiro;
       extern Global global;
       PowerManagement::PowerManagement(CANDriver *can)
           : ControllerAreaNetworkTx(can, CAN::POWER_MANAGEMENT_ID),
             ControllerAreaNetworkRx(can, CAN::POWER_MANAGEMENT_ID),
             bc_counter(0)
+      {
         this->powerStatus.charging_flags.value = 0;
+      }
       msg_t PowerManagement::receiveMessage(CANRxFrame *frame) {
         int deviceId = this->decodeDeviceId(frame);
         switch (deviceId) {
           case CAN::SHELL_REPLY_ID(CAN::POWER_MANAGEMENT_ID):
             if (frame->DLC > 0) {
               sdWrite(&SD1, frame->data8, frame->DLC);
               return RDY_OK;
+            }
             break;
           case CAN::SHELL_QUERY_ID(CAN::POWER_MANAGEMENT_ID):
             if (frame->DLC != 0) {
               global.sercanmux1.convCan2Serial(frame->data8, frame->DLC);
               return RDY_OK;
             } else {
               global.sercanmux1.rcvSwitchCmd(this->decodeBoardId(frame));
               return RDY_OK;
+            }
             break;
           case CAN::CALIBRATE_PROXIMITY_RING:
             // Dont care about the payload but start the calibration
             // TODO Care about the payload. Differ between:
             // 1: Do fresh calibration (Save values to memory and to temporary values)
             // 2: Remove temporary Calibration and get uncalibrated values
             // 3: Load calibration from memory
             this->calibrate();
             break;
           case CAN::ROBOT_ID:
             if (frame->DLC == 1) {
               this->robotId = frame->data8[0];
               return RDY_OK;
+            }
             break;
           default:
             break;
+        }
         return -1;
+      }
       msg_t PowerManagement::updateSensorVal() {
         // update charger status
         this->powerStatus.charging_flags.content.powermanagement_plugged_in = global.ltc4412.isPluggedIn();
         // update fuel gauges values
         const BQ27500::Driver::UpdateData* power[2] {
           &global.bq27500[constants::PowerManagement::BAT_A].getStatus(),
           &global.bq27500[constants::PowerManagement::BAT_B].getStatus()
         };
         this->powerStatus.charging_flags.content.powermanagement_charging = (this->powerStatus.charging_flags.content.powermanagement_plugged_in &&
                                                                              this->powerStatus.charging_flags.content.vsys_higher_than_9V &&
                                                                              power[0]->minutes_to_empty == uint16_t(~0) &&
                                                                              power[1]->minutes_to_empty == uint16_t(~0))?
                                                                              true : false;
         this->powerStatus.charging_flags.content.diwheeldrive_charging = (this->powerStatus.charging_flags.content.diwheeldrive_enable_power_path &&
                                                                           this->powerStatus.charging_flags.content.vsys_higher_than_9V &&
                                                                           power[0]->minutes_to_empty == uint16_t(~0) &&
                                                                           power[1]->minutes_to_empty == uint16_t(~0))?
                                                                           true : false;
         this->powerStatus.state_of_charge = (power[0]->state_of_charge + power[1]->state_of_charge) / 2;
         if (this->powerStatus.charging_flags.content.powermanagement_charging || this->powerStatus.charging_flags.content.diwheeldrive_charging) {
           /*
            * Assumption:
            * When charging there is enough power available to charge both batteries at full rate simultaneously.
            * Thus, the second battery will not charge faster when the first battery is fully charged.
            */
           this->powerStatus.minutes_remaining = std::max(power[0]->minutes_to_full, power[1]->minutes_to_full);
         } else {
           /*
            * Computation of the remaining discharging time:
            * Take the time until the first of the two batteries is empty and add the remaining time of the second battery but half.
            *        time = min(a,b) + (max(a,b) - min(a,b))/2
            * <=>  2*time = 2*min(a,b) + max(a,b) - min(a,b)
            * <=>  2*time = min(a,b) + max(a,b)
            * <=>  2*time = a + b
            * <=>    time = (a + b)/2
            */
           this->powerStatus.minutes_remaining = (power[0]->minutes_to_empty + power[1]->minutes_to_empty) / 2;
+        }
         this->powerStatus.power_consumption = (power[0]->average_power_mW + power[1]->average_power_mW) / 2;
         // update infrared sensor value
         // Note: The CANRx Value will never be updated in this thread
         for (int idx = 0; idx < 8; idx++)
           this->proximityRingValue[idx] = global.vcnl4020[idx].getProximityScaledWoOffset();
         return 0;
+      }
       void PowerManagement::periodicBroadcast() {
         CANTxFrame frame;
         if (this->bc_counter % 10 == 0) {
           frame.SID = 0;
           this->encodeDeviceId(&frame, CAN::POWER_STATUS_ID);
           frame.data8[0] = this->powerStatus.charging_flags.value;
           frame.data8[1] = this->powerStatus.state_of_charge;
           frame.data16[1] = this->powerStatus.minutes_remaining;
           frame.data16[2] = this->powerStatus.power_consumption;
           frame.DLC = 6;
           this->transmitMessage(&frame);
+        }
         for (int i = 0; i < 8; i++) {
           frame.SID = 0;
           this->encodeDeviceId(&frame, CAN::PROXIMITY_RING_ID(i));
           frame.data16[0] = this->proximityRingValue[i];
           frame.DLC = 2;
           this->transmitMessage(&frame);
           BaseThread::sleep(US2ST(10)); // Use to sleep for 10 CAN cycle (@1Mbit), otherwise the cognition-board might not receive all messagee
+        }
         ++this->bc_counter;
+      }
       void PowerManagement::calibrate() {
         // Stop sending and receiving of values to indicate the calibration phase
       //   eventTimerEvtSource->unregister(&this->eventTimerEvtListener);
       //   rxFullCanEvtSource->unregister(&this->rxFullCanEvtListener);
         this->calibrateProximityRingValues();
         // Start sending and receving of values
       //   eventTimerEvtSource->registerOne(&this->eventTimerEvtListener, CAN::PERIODIC_TIMER_ID);
       //   rxFullCanEvtSource->registerOne(&this->rxFullCanEvtListener, CAN::RECEIVED_ID);
+      }
       void PowerManagement::calibrateProximityRingValues() {
         uint16_t buffer;
         for (uint8_t idx = 0; idx < 8; ++idx) {
           global.vcnl4020[idx].calibrate();
           buffer = global.vcnl4020[idx].getProximityOffset();
           global.memory.setVcnl4020Offset(buffer,idx);
+        }
+      }
       ThreadReference PowerManagement::start(tprio_t PRIO) {
         this->ControllerAreaNetworkRx::start(PRIO + 1);
         this->ControllerAreaNetworkTx::start(PRIO);
         return NULL;
+      }
       types::power_status&
       PowerManagement::getPowerStatus()
+      {
         return this->powerStatus;
+      }
       msg_t PowerManagement::terminate(void) {
         msg_t ret = RDY_OK;
         this->ControllerAreaNetworkTx::requestTerminate();
         ret |= this->ControllerAreaNetworkTx::wait();
         this->ControllerAreaNetworkRx::requestTerminate();
         ret |= this->ControllerAreaNetworkRx::wait();
         return ret;
+      }