//#include "ti/driverlib/dl_wwdt.h" #include "ti/driverlib/m0p/dl_core.h" #include "ti_msp_dl_config.h" #include "src/pi/i2c_pi_target.h" #include "src/controller/controller.h" #include "ti/driverlib/dl_i2c.h" #include "src/battery_data/battery.h" #include "src/cc_cv_charging.h" #include #include "src/battery_data/battery.h" #include "mock_setup.h" //define the varibales: volatile bool mcuSendCommand = false; volatile bool picommandPending = false; volatile bool watchdog_triggered= false; // Interrupt for I2C instance -> MCU to Target void I2C_1_INST_IRQHandler(void) { switch (DL_I2C_getPendingInterrupt(I2C_1_INST)) { case DL_I2C_IIDX_CONTROLLER_START: break; case DL_I2C_IIDX_CONTROLLER_RXFIFO_TRIGGER: mcuSendCommand= true; while(DL_I2C_isControllerRXFIFOEmpty(I2C_1_INST) != true) { if(rxPacket.rxCount < rxPacket.rxLen){ //Get byte from the I2C RX FIFO of the target rxPacket.rxBuffer[rxPacket.rxCount]= DL_I2C_receiveControllerData(I2C_1_INST); rxPacket.rxCount++; }else{ DL_I2C_receiveControllerData(I2C_1_INST); } } if(rxPacket.rxCount >= rxPacket.rxLen){ rxPacket.rxComplete= true; } break; case DL_I2C_IIDX_CONTROLLER_TXFIFO_TRIGGER: /* Fill TX FIFO with bytes to send */ mcuSendCommand = true; txPacket.txComplete= true; break; case DL_I2C_IIDX_CONTROLLER_STOP: mcuSendCommand = true; rxPacket.rxComplete= true; break; case DL_I2C_IIDX_CONTROLLER_ARBITRATION_LOST: case DL_I2C_IIDX_CONTROLLER_NACK: break; default: break; } } void I2C_0_INST_IRQHandler(void) { switch (DL_I2C_getPendingInterrupt(I2C_0_INST)) { case DL_I2C_IIDX_TARGET_START: DL_I2C_flushTargetTXFIFO(I2C_0_INST); break; case DL_I2C_IIDX_TARGET_RXFIFO_TRIGGER: if (DL_I2C_isTargetRXFIFOEmpty(I2C_0_INST)) { return; } picommandPending = true; break; case DL_I2C_IIDX_TARGET_TXFIFO_TRIGGER: /* Fill TX FIFO with bytes to send */ picommandPending = true; break; case DL_I2C_IIDX_TARGET_STOP: picommandPending = true; //DL_I2C_flushTargetTXFIFO(I2C_0_INST); //DL_I2C_flushTargetRXFIFO(I2C_0_INST); break; case DL_I2C_IIDX_TARGET_ARBITRATION_LOST: break; default: break; } } int main(void) { SYSCFG_DL_init(); Battery_Init(); //dynamic addressing function call for Pi dynamic_gpio_addressing(); //Interrupt routine for Pi NVIC_EnableIRQ(I2C_0_INST_INT_IRQN); //Interrupt for target mcu //NVIC_EnableIRQ(I2C_1_INST_INT_IRQN); bool was_true = false; while(1) { if(picommandPending) { printf("Pi Interrupt Triggered.\n"); pi_i2c_mcu(); picommandPending = false; } /*if(mcuSendCommand){ printf("MCU Interrupt Triggered.\n"); mcuSendCommand = false; }*/ for(uint8_t slot_id= 0; slot_id< NUM_SLOTS; slot_id++){ //Reading the battery measurement: printf("mainloop slot?\n"); /*if (!was_true) { printf("executing?\n"); was_true = controller_GetBatteryMeasurement(slot_id); printf("true? %d\n", was_true); }*/ //Reading battery state: Battery_StateCondition(slot_id); //Reading Charging state condition CC_CV_ControlCharging(slot_id, 50); printf("Battery Charging State: %u\n", battery_data[slot_id].battery_charging_state); printf("Battery Limit Received: %u\n", battery_data[slot_id].batteryLimitReceived); printf("STATUS ***Reading Battery Measurement for Slot ID %u:: Battery State: %u, Voltage: %u, Current: %u, Temperature: %u, Slot state: %u***\n", slot_id, battery_data[slot_id].battery_state, battery_data[slot_id].battery_measurement.voltage, battery_data[slot_id].battery_measurement.current, battery_data[slot_id].battery_measurement.temperature, battery_data[slot_id].battery_measurement.slot_state); //If target received battery limits from Pi then start charging: if(battery_data[slot_id].batteryLimitReceived){ printf("Battery Limits: Slot: %d, Max Voltage:%u, Min Voltage:%u, " "Cutoff Current: %u, Capacitance:%u, Charge Fraction:%u, Cycle Number: %u\n", slot_id, battery_data[slot_id].max_voltage, battery_data[slot_id].min_voltage, battery_data[slot_id].cut_off_current, battery_data[slot_id].capacitance, battery_data[slot_id].charge_fraction, battery_data[slot_id].cycle_number); } delay_cycles(MEASUREMENT_CHECK_INTERVAL); } } }