amiro-os / devices / PowerManagement / main.cpp @ 3aee55de
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#ifndef IN_CCM
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/*
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* @brief Makro to store data in the core coupled memory (ccm).
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* Example:
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* int compute_buffer[128] IN_CCM;
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*
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* @note The ccm is not connected to any bus system.
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*/
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#define IN_CCM __attribute__((section(".ccm"))) __attribute__((aligned(4))) |
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#endif
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#ifndef IN_ETH
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/*
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* @brief Makro to store data in the ethernet memory (eth).
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* Example:
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* int dma_buffer[128] IN_ETH;
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*
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* @note The eth is a dedicated memory block with its own DMA controller.
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*/
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#define IN_ETH __attribute__((section(".eth"))) __attribute__((aligned(4))) |
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#endif
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#define BL_CALLBACK_TABLE_ADDR (0x08000000 + 0x01C0) |
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#define BL_MAGIC_NUMBER ((uint32_t)0xFF669900u) |
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#define SHUTDOWN_NONE 0 |
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#define SHUTDOWN_TRANSPORTATION 1 |
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#define SHUTDOWN_DEEPSLEEP 2 |
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#define SHUTDOWN_HIBERNATE 3 |
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#define SHUTDOWN_RESTART 4 |
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#define SHUTDOWN_HANDLE_REQUEST 5 |
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#include <ch.hpp> |
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#include <shell.h> |
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#include <chprintf.h> |
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#include <wakeup.h> |
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#include <cstdlib> |
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#include <cstring> |
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#include <amiro/util/util.h> |
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#include <global.hpp> |
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#include <exti.hpp> |
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using namespace amiro; |
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using namespace constants::PowerManagement; |
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Global global; |
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struct blVersion_t {
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const uint8_t identifier;
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const uint8_t major;
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const uint8_t minor;
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const uint8_t patch;
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} __attribute__((packed)); |
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void shutdownTimeoutISR(void *arg) { |
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(void) arg;
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} |
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void systemStop() {
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// VirtualTimer shutdownTimeout;
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uint8_t i; |
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// tell all boards that it's time to shut down
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global.robot.broadcastShutdown(); |
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global.userThread.requestTerminate(); |
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global.userThread.wait(); |
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// kill bluetooth
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boardBluetoothSetState(0);
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global.adc1_vsys.requestTerminate(); |
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global.adc1_vsys.wait(); |
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for (i = 0; i < global.vcnl4020.size(); ++i) { |
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global.vcnl4020[i].requestTerminate(); |
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global.vcnl4020[i].wait(); |
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} |
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for (i = 0; i < global.bq27500.size(); ++i) { |
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global.bq27500[i].requestTerminate(); |
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global.bq27500[i].wait(); |
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} |
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for (i = 0; i < global.ina219.size(); ++i) { |
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global.ina219[i].requestTerminate(); |
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global.ina219[i].wait(); |
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} |
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// boardWriteIoPower(0);
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global.mpr121.configure(&global.mpr121_stdby_config); |
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/* cannot shut down touch, b/c we need it to
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* clear any interrupt, so WKUP is not blocked
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*/
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// stop I²C
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for (i = 0; i < global.V_I2C1.size(); ++i) |
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global.V_I2C1[i].stop(); |
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for (i = 0; i < global.V_I2C2.size(); ++i) |
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global.V_I2C2[i].stop(); |
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global.mpr121.requestTerminate(); |
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global.mpr121.wait(); |
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global.HW_I2C2.stop(); |
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global.HW_I2C1.stop(); |
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// stop all threads
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global.robot.terminate(); |
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// // 60 sec timeout
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// palWritePad(GPIOC, GPIOC_SYS_INT_N, PAL_HIGH);
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// chVTSet(&shutdownTimeout, MS2ST(60000), shutdownTimeoutISR, NULL);
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// // wait for all boards to release SYS_INT_N
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// while (palReadPad(GPIOC, GPIOC_SYS_INT_N)!=PAL_HIGH && chVTIsArmedI(&shutdownTimeout)) {
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// BaseThread::sleep(MS2ST(1)); /* must sleep for VT, else it will never fire */
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// }
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// chVTReset(&shutdownTimeout);
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// chprintf((BaseSequentialStream*) &SD1, "Stop\n");
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// boardWriteSystemPower(0);
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// boardWriteLed(1);
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// boardStop(0x00, 0x00);
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// /*
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// * HSI-PLL domain now.
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// */
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// //chprintf((BaseSequentialStream*) &SD1, "After Stop\n");
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// boardWriteLed(1);
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// while (true)
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// BaseThread::sleep(MS2ST(250));
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return;
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} |
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void systemShutdown() {
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VirtualTimer shutdownTimeout; |
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uint8_t i; |
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// tell all boards that it's time to shut down
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global.robot.broadcastShutdown(); |
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// wait a little to make sure all boards got the message and had time to pull their SYS_PD_N pins down
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BaseThread::sleep(MS2ST(500));
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// stop the user thread
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global.userThread.requestTerminate(); |
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global.userThread.wait(); |
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// kill bluetooth
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boardBluetoothSetState(0);
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// stop all threads
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global.robot.terminate(); |
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global.adc1_vsys.requestTerminate(); |
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global.adc1_vsys.wait(); |
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for (i = 0; i < global.vcnl4020.size(); ++i) { |
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global.vcnl4020[i].requestTerminate(); |
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global.vcnl4020[i].wait(); |
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} |
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for (i = 0; i < global.bq27500.size(); ++i) { |
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global.bq27500[i].requestTerminate(); |
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global.bq27500[i].wait(); |
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} |
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for (i = 0; i < global.ina219.size(); ++i) { |
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global.ina219[i].requestTerminate(); |
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global.ina219[i].wait(); |
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} |
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// 60 sec timeout
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chVTSet(&shutdownTimeout, MS2ST(60000), shutdownTimeoutISR, NULL); |
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// wait for all boards to release SYS_PD_N
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while (!palReadPad(GPIOC, GPIOC_SYS_PD_N) && chVTIsArmedI(&shutdownTimeout))
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BaseThread::sleep(MS2ST(1)); /* must sleep for VT, else it will never fire */ |
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chVTReset(&shutdownTimeout); |
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boardWriteIoPower(0);
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global.mpr121.configure(&global.mpr121_stdby_config); |
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/* cannot shut down touch, b/c we need it to
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* clear any interrupt, so WKUP is not blocked
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*/
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// stop I²C
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for (i = 0; i < global.V_I2C1.size(); ++i) |
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global.V_I2C1[i].stop(); |
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for (i = 0; i < global.V_I2C2.size(); ++i) |
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global.V_I2C2[i].stop(); |
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boardWriteSystemPower(0);
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boardStandby(); |
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} |
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void boardPeripheryCheck(BaseSequentialStream *chp) {
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#ifndef AMIRO_NSELFTEST
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chprintf(chp, "\nCHECK: START\n");
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msg_t result = 0;
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// Check the proximitysensors
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for (uint8_t i = 0; i < global.vcnl4020.size(); i++) { |
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result = global.vcnl4020[i].getCheck(); |
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if (result == global.vcnl4020[i].CHECK_OK)
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chprintf(chp, "VCNL4020: %d OK\n", i);
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else
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chprintf(chp, "VCNL4020: %d FAIL\n", i);
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} |
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chprintf(chp, "----------------------------------------\n");
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// check the PowerPath controller
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chprintf(chp, "\n");
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if (global.ltc4412.isPluggedIn())
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chprintf(chp, "LTC4412: plugged in\n");
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else
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chprintf(chp, "LTC4412: not plugged in\n");
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chprintf(chp, "----------------------------------------\n");
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// Check the eeprom
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result = global.memory.getCheck(); |
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if ( result != global.memory.OK)
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chprintf(chp, "Memory Structure: FAIL\n");
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else
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chprintf(chp, "Memory Structure: OK\n");
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chprintf(chp, "----------------------------------------\n");
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// Check the power monitors
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INA219::BusVoltage bus_voltage; |
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chprintf(chp, "\n");
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chprintf(chp, "INA219:\n");
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chprintf(chp, "\tVDD (3.3V):\n");
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uint8_t result_ina219_vdd = global.ina219[INA_VDD].selftest(); |
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chprintf(chp, "->\t");
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if (result_ina219_vdd == BaseSensor<>::NOT_IMPLEMENTED)
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chprintf(chp, "not implemented");
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else if (result_ina219_vdd != INA219::Driver::ST_OK) |
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chprintf(chp, "FAIL (error code 0x%02X)", result_ina219_vdd);
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else
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chprintf(chp, "OK");
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chprintf(chp, "\n\n");
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chprintf(chp, "\tVIO1.8:\n");
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uint8_t result_ina219_vio18 = global.ina219[INA_VIO18].selftest(); |
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chprintf(chp, "->\t");
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if (result_ina219_vio18 == BaseSensor<>::NOT_IMPLEMENTED)
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chprintf(chp, "not implemented");
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else if (result_ina219_vio18 != INA219::Driver::ST_OK) |
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chprintf(chp, "FAIL (error code 0x%02X)", result_ina219_vio18);
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else
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chprintf(chp, "OK");
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chprintf(chp, "\n\n");
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chprintf(chp, "\tVIO3.3:\n");
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uint8_t result_ina219_vio33 = global.ina219[INA_VIO33].selftest(); |
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chprintf(chp, "->\t");
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if (result_ina219_vio33 == BaseSensor<>::NOT_IMPLEMENTED)
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chprintf(chp, "not implemented");
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else if (result_ina219_vio33 != INA219::Driver::ST_OK) |
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chprintf(chp, "FAIL (error code 0x%02X)", result_ina219_vio33);
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else
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chprintf(chp, "OK");
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chprintf(chp, "\n\n");
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chprintf(chp, "\tVIO4.2:\n");
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uint8_t result_ina219_vio42 = global.ina219[INA_VIO42].selftest(); |
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chprintf(chp, "->\t");
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if (result_ina219_vio42 == BaseSensor<>::NOT_IMPLEMENTED)
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chprintf(chp, "not implemented");
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else if (result_ina219_vio42 != INA219::Driver::ST_OK) |
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chprintf(chp, "FAIL (error code 0x%02X)", result_ina219_vio42);
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else
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chprintf(chp, "OK");
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bus_voltage = global.ina219[INA_VIO42].readBusVoltage(); |
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chprintf(chp, "\n\n");
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chprintf(chp, "\tVIO5.0:\n");
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uint8_t result_ina219_vio50 = global.ina219[INA_VIO50].selftest(); |
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chprintf(chp, "->\t");
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if (result_ina219_vio50 == BaseSensor<>::NOT_IMPLEMENTED)
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chprintf(chp, "not implemented");
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else if (result_ina219_vio50 != INA219::Driver::ST_OK) |
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chprintf(chp, "FAIL (error code 0x%02X)", result_ina219_vio50);
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else
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chprintf(chp, "OK");
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chprintf(chp, "\n\n");
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result = result_ina219_vdd | result_ina219_vio18 | result_ina219_vio33 | result_ina219_vio42 | result_ina219_vio50; |
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if (result == BaseSensor<>::NOT_IMPLEMENTED)
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chprintf(chp, "->\tINA219: not implemented\n");
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else
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chprintf(chp, "->\tINA219: %s\n", (result != INA219::Driver::ST_OK)? "FAIL" : "OK"); |
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chprintf(chp, "----------------------------------------\n");
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// check the fuel gauges
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chprintf(chp, "\n");
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chprintf(chp, "BQ27500:\n");
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chprintf(chp, "\tP7:\n");
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msg_t result_bq27500_p7 = global.bq27500[BAT_P7].selftest(); |
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chprintf(chp, "->\tP7: ");
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if (result == BaseSensor<>::NOT_IMPLEMENTED)
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chprintf(chp, "not implemented");
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else if (result_bq27500_p7 == BQ27500::Driver::ST_ABORT_NO_BAT) |
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chprintf(chp, "ABORT (no battery detected)");
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else if (result_bq27500_p7 != BQ27500::Driver::ST_OK) |
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chprintf(chp, "FAIL (error code 0x%02X)", result);
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else
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chprintf(chp, "OK");
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chprintf(chp, "\n\n");
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chprintf(chp, "\tP8:\n");
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msg_t result_bq27500_p8 = global.bq27500[BAT_P8].selftest(); |
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chprintf(chp, "->\tP8: ");
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if (result == BaseSensor<>::NOT_IMPLEMENTED)
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chprintf(chp, "not implemented");
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else if (result_bq27500_p8 == BQ27500::Driver::ST_ABORT_NO_BAT) |
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chprintf(chp, "ABORT (no battery detected)");
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else if (result_bq27500_p8 != BQ27500::Driver::ST_OK) |
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chprintf(chp, "FAIL (error code 0x%02X)", result);
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else
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chprintf(chp, "OK");
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chprintf(chp, "\n");
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result = result_bq27500_p7 | result_bq27500_p8; |
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if (result == BaseSensor<>::NOT_IMPLEMENTED)
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chprintf(chp, "\n->\tBQ27500: not implemented\n");
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else
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chprintf(chp, "\n->\tBQ27500: %s\n", (result != BQ27500::Driver::ST_OK)? "FAIL" : "OK"); |
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chprintf(chp, "----------------------------------------\n");
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// check the chargers
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chprintf(chp, "\n");
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chprintf(chp, "BQ24103A:\n");
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if (!global.ltc4412.isPluggedIn())
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chprintf(chp, "This test is skipped. Rerun when plugged in.\n");
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else {
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bool status1, status2, status3;
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chprintf(chp, "\tP7:\n");
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bool status_p7 = global.bq27500[BAT_P7].isBatteryGood();
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chprintf(chp, "Battery good: %s\n", (status_p7? "yes" : "no")); |
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if (!status_p7) {
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chprintf(chp, "-> Rerun test with (another) battery!\n");
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status_p7 = true;
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} else {
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status1 = global.bq24103a[BAT_P7]->isCharging(); |
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chprintf(chp, "status:%scharging\n", (status1? " " : " not ")); |
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chprintf(chp, "%sabling charger...\n", (status1? "dis" : "en")); |
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global.bq24103a[BAT_P7]->enable(!status1); |
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BaseThread::sleep(MS2ST(1500));
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status2 = global.bq24103a[BAT_P7]->isCharging(); |
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chprintf(chp, "status:%scharging\n", (status2? " " : " not ")); |
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chprintf(chp, "%sabling charger...\n", (!status1? "dis" : "en")); |
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global.bq24103a[BAT_P7]->enable(status1); |
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BaseThread::sleep(MS2ST(1500));
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status3 = global.bq24103a[BAT_P7]->isCharging(); |
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chprintf(chp, "status:%scharging\n", (status3? " " : " not ")); |
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status_p7 = status2 != status1 && status3 == status1; |
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chprintf(chp, "->\t");
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if (status_p7) {
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chprintf(chp, "OK");
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} else {
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chprintf(chp, "FAIL");
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} |
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chprintf(chp, "\n");
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} |
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chprintf(chp, "\n");
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chprintf(chp, "\tP8:\n");
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bool status_p8 = global.bq27500[BAT_P8].isBatteryGood();
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chprintf(chp, "Battery good: %s\n", (status_p8? "yes" : "no")); |
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if (!status_p8) {
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chprintf(chp, "-> Rerun test with (another) battery!\n");
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status_p8 = true;
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} else {
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status1 = global.bq24103a[BAT_P8]->isCharging(); |
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chprintf(chp, "status:%scharging\n", (status1? " " : " not ")); |
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chprintf(chp, "%sabling charger...\n", (status1? "dis" : "en")); |
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global.bq24103a[BAT_P8]->enable(!status1); |
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BaseThread::sleep(MS2ST(1500));
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status2 = global.bq24103a[BAT_P8]->isCharging(); |
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chprintf(chp, "status:%scharging\n", (status2? " " : " not ")); |
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chprintf(chp, "%sabling charger...\n", (!status1? "dis" : "en")); |
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global.bq24103a[BAT_P8]->enable(status1); |
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BaseThread::sleep(MS2ST(1500));
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status3 = global.bq24103a[BAT_P8]->isCharging(); |
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chprintf(chp, "status:%scharging\n", (status3? " " : "not ")); |
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status_p8 = status2 != status1 && status3 == status1; |
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chprintf(chp, "->\t");
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if (status_p8)
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chprintf(chp, "OK");
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else
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chprintf(chp, "FAIL");
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chprintf(chp, "\n");
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} |
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chprintf(chp, "\n");
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chprintf(chp, "->\tBQ24103A: ");
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if (status_p7 && status_p8)
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chprintf(chp, "OK");
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else
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chprintf(chp, "FAIL");
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chprintf(chp, "\n");
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} |
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chprintf(chp, "----------------------------------------\n");
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// check Bluetooth (TODO: move this check to driver)
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chprintf(chp, "\n");
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chprintf(chp, "WT12-A-AI:\n");
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chprintf(chp, "testing for MUX mode:\t");
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if (global.wt12.bluetoothIsMuxMode()) {
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chprintf(chp, "PASSED\n");
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} else {
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chprintf(chp, "FAILED -> setting MUX mode now\n");
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/* initialise the WT-12 bluetooth chip on AMIRO (Please, run this processes once) */
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global.wt12.bluetoothSendCommand("SET BT AUTH *");
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global.wt12.bluetoothSendCommand("SET BT PAIR *");
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global.wt12.bluetoothSendCommand("SET BT SSP 3 0");
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global.wt12.bluetoothEnableMux(); |
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global.wt12.bluetoothReset(); |
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} |
430 |
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global.wt12.bluetoothSendCommand("TEMP");
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global.wt12.bluetoothSendCommand("SET");
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chprintf(chp, "----------------------------------------\n");
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|
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// check the buzzer
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chprintf(chp, "\n");
|
438 |
chprintf(chp, "PKLCS1212E4001:\n");
|
439 |
chprintf(chp, "you should hear the buzzer for one second...\n");
|
440 |
pwmEnableChannel(&PWMD3, 1, 50); |
441 |
BaseThread::sleep(MS2ST(1000));
|
442 |
pwmDisableChannel(&PWMD3, 1);
|
443 |
chprintf(chp, "----------------------------------------\n");
|
444 |
|
445 |
chprintf(chp, "CHECK: FINISH\n");
|
446 |
#endif
|
447 |
|
448 |
return;
|
449 |
} |
450 |
|
451 |
void shellRequestShutdown(BaseSequentialStream* chp, int __unused argc, char __unused *argv[]) { |
452 |
|
453 |
chprintf(chp, "shellRequestShutdown\n");
|
454 |
|
455 |
/* if no argument was given, print some help text */
|
456 |
if (argc == 0 || strcmp(argv[0],"help") == 0) { |
457 |
chprintf(chp, "\tUSAGE:\n");
|
458 |
chprintf(chp, "> shutdown <type>\n");
|
459 |
chprintf(chp, "\n");
|
460 |
chprintf(chp, "\ttype\n");
|
461 |
chprintf(chp, "The type of shutdown to perform.\n");
|
462 |
chprintf(chp, "Choose one of the following types:\n");
|
463 |
chprintf(chp, " transportation - Ultra low-power mode with all wakeups disabled.\n");
|
464 |
chprintf(chp, " The robot can not be charged.\n");
|
465 |
chprintf(chp, " deepsleep - Ultra low-power mode with several wakeups enabled.\n");
|
466 |
chprintf(chp, " The robot can only be charged via the power plug.\n");
|
467 |
chprintf(chp, " hibernate - Medium low-power mode, but with full charging capabilities.\n");
|
468 |
chprintf(chp, " restart - Performs a system restart.\n");
|
469 |
chprintf(chp, "Alternatively, you can use the shortcuts 't', 'd', 'h', and 'r' respectively.");
|
470 |
chprintf(chp, "\n");
|
471 |
return;
|
472 |
} |
473 |
|
474 |
if (strcmp(argv[0],"transportation") == 0 || strcmp(argv[0],"t") == 0) { |
475 |
shutdown_now = SHUTDOWN_TRANSPORTATION; |
476 |
chprintf(chp, "shutdown to transportation mode initialized\n");
|
477 |
} else if (strcmp(argv[0],"deepsleep") == 0 || strcmp(argv[0],"d") == 0) { |
478 |
shutdown_now = SHUTDOWN_DEEPSLEEP; |
479 |
chprintf(chp, "shutdown to deepsleep mode initialized\n");
|
480 |
} else if (strcmp(argv[0],"hibernate") == 0 || strcmp(argv[0],"h") == 0) { |
481 |
shutdown_now = SHUTDOWN_HIBERNATE; |
482 |
chprintf(chp, "shutdown to hibernate mode initialized\n");
|
483 |
} else if (strcmp(argv[0],"restart") == 0 || strcmp(argv[0],"r") == 0) { |
484 |
chprintf(chp, "restart initialized\n");
|
485 |
shutdown_now = SHUTDOWN_RESTART; |
486 |
} else {
|
487 |
chprintf(chp, "ERROR: unknown argument!\n");
|
488 |
shutdown_now = SHUTDOWN_NONE; |
489 |
} |
490 |
|
491 |
return;
|
492 |
} |
493 |
|
494 |
void shellRequestResetMemory(BaseSequentialStream *chp, int __unused argc, char __unused *argv[]) { |
495 |
chprintf(chp, "shellRequestInitMemory\n");
|
496 |
|
497 |
msg_t res = global.memory.resetMemory(); |
498 |
|
499 |
if ( res != global.memory.OK)
|
500 |
chprintf(chp, "Memory Init: FAIL\n");
|
501 |
else
|
502 |
chprintf(chp, "Memory Init: OK\n");
|
503 |
} |
504 |
|
505 |
void shellRequestGetBoardId(BaseSequentialStream *chp, int __unused argc, char __unused *argv[]) { |
506 |
chprintf(chp, "shellRequestGetBoardId\n");
|
507 |
|
508 |
uint8_t id = 0xFFu;
|
509 |
msg_t res = global.memory.getBoardId(&id); |
510 |
if (res != global.memory.OK)
|
511 |
chprintf(chp, "Get Board ID: FAIL\n");
|
512 |
else
|
513 |
chprintf(chp, "Get Board ID: %u\n", id);
|
514 |
} |
515 |
|
516 |
void shellRequestSetBoardId(BaseSequentialStream *chp, int argc, char *argv[]) { |
517 |
chprintf(chp, "shellRequestSetBoardId\n");
|
518 |
|
519 |
if (argc == 0) { |
520 |
chprintf(chp, "Usage: %s\n","set_board_id <idx>"); |
521 |
} else {
|
522 |
msg_t res = global.memory.setBoardId(atoi(argv[0]));
|
523 |
if (res != global.memory.OK)
|
524 |
chprintf(chp, "Set Board ID: FAIL\n");
|
525 |
else
|
526 |
chprintf(chp, "Set Board ID: OK\n");
|
527 |
} |
528 |
|
529 |
} |
530 |
|
531 |
void shellRequestGetMemoryData(BaseSequentialStream *chp, int argc, char *argv[]) { |
532 |
enum Type {HEX, U8, U16, U32, S8, S16, S32};
|
533 |
|
534 |
chprintf(chp, "shellRequestReadData\n");
|
535 |
|
536 |
if (argc < 2 || strcmp(argv[0],"help") == 0) |
537 |
{ |
538 |
chprintf(chp, "Usage: %s\n","get_memory_data <type> <start> [<count>]"); |
539 |
chprintf(chp, "\n");
|
540 |
chprintf(chp, "\ttype\n");
|
541 |
chprintf(chp, "The data type as which to interpret the data.\n");
|
542 |
chprintf(chp, "Choose one of the following types:\n");
|
543 |
chprintf(chp, " hex - one byte as hexadecimal value\n");
|
544 |
chprintf(chp, " u8 - unsigned integer (8 bit)\n");
|
545 |
chprintf(chp, " u16 - unsigned integer (16 bit)\n");
|
546 |
chprintf(chp, " u32 - unsigned integer (32 bit)\n");
|
547 |
chprintf(chp, " s8 - signed integer (8 bit)\n");
|
548 |
chprintf(chp, " s16 - signed integer (16 bit)\n");
|
549 |
chprintf(chp, " s32 - signed integer (32 bit)\n");
|
550 |
chprintf(chp, "\tstart\n");
|
551 |
chprintf(chp, "The first byte to read from the memory.\n");
|
552 |
chprintf(chp, "\tcount [default = 1]\n");
|
553 |
chprintf(chp, "The number of elements to read.\n");
|
554 |
chprintf(chp, "\n");
|
555 |
chprintf(chp, "\tNOTE\n");
|
556 |
chprintf(chp, "Type conversions of this function might fail.\n");
|
557 |
chprintf(chp, "If so, use type=hex and convert by hand.\n");
|
558 |
chprintf(chp, "\n");
|
559 |
return;
|
560 |
} |
561 |
|
562 |
uint8_t type_size = 0;
|
563 |
Type type = HEX; |
564 |
if (strcmp(argv[0],"hex") == 0) { |
565 |
type_size = sizeof(unsigned char); |
566 |
type = HEX; |
567 |
} else if(strcmp(argv[0],"u8") == 0) { |
568 |
type_size = sizeof(uint8_t);
|
569 |
type = U8; |
570 |
} else if(strcmp(argv[0],"u16") == 0) { |
571 |
type_size = sizeof(uint16_t);
|
572 |
type = U16; |
573 |
} else if(strcmp(argv[0],"u32") == 0) { |
574 |
type_size = sizeof(uint32_t);
|
575 |
type = U32; |
576 |
} else if(strcmp(argv[0],"s8") == 0) { |
577 |
type_size = sizeof(int8_t);
|
578 |
type = S8; |
579 |
} else if(strcmp(argv[0],"s16") == 0) { |
580 |
type_size = sizeof(int16_t);
|
581 |
type = S16; |
582 |
} else if(strcmp(argv[0],"s32") == 0) { |
583 |
type_size = sizeof(int32_t);
|
584 |
type = S32; |
585 |
} else {
|
586 |
chprintf(chp, "First argument invalid. Use 'get_memory_data help' for help.\n");
|
587 |
return;
|
588 |
} |
589 |
|
590 |
unsigned int start_byte = atoi(argv[1]); |
591 |
|
592 |
unsigned int num_elements = 1; |
593 |
if (argc >= 3) { |
594 |
num_elements = atoi(argv[2]);
|
595 |
} |
596 |
|
597 |
const size_t eeprom_size = EEPROM::getsize(&global.at24c01);
|
598 |
uint8_t buffer[eeprom_size]; |
599 |
if (start_byte + (type_size * num_elements) > eeprom_size) {
|
600 |
num_elements = (eeprom_size - start_byte) / type_size; |
601 |
chprintf(chp, "Warning: request exceeds eeprom size -> limiting to %u values.\n", num_elements);
|
602 |
} |
603 |
|
604 |
chFileStreamSeek((BaseFileStream*)&global.at24c01, start_byte); |
605 |
uint32_t bytes_read = chSequentialStreamRead((BaseFileStream*)&global.at24c01, buffer, type_size*num_elements); |
606 |
|
607 |
if (bytes_read != type_size*num_elements) {
|
608 |
chprintf(chp, "Warning: %u of %u requested bytes were read.\n", bytes_read, type_size*num_elements);
|
609 |
} |
610 |
|
611 |
for (unsigned int i = 0; i < num_elements; ++i) |
612 |
{ |
613 |
switch (type)
|
614 |
{ |
615 |
case HEX:
|
616 |
chprintf(chp, "%02X ", buffer[i]);
|
617 |
break;
|
618 |
case U8:
|
619 |
chprintf(chp, "%03u ", ((uint8_t*)buffer)[i]);
|
620 |
break;
|
621 |
case U16:
|
622 |
chprintf(chp, "%05u ", ((uint16_t*)buffer)[i]);
|
623 |
break;
|
624 |
case U32:
|
625 |
chprintf(chp, "%010u ", ((uint32_t*)buffer)[i]);
|
626 |
break;
|
627 |
case S8:
|
628 |
chprintf(chp, "%+03d ", ((int8_t*)buffer)[i]);
|
629 |
break;
|
630 |
case S16:
|
631 |
chprintf(chp, "%+05d ", ((int16_t*)buffer)[i]);
|
632 |
break;
|
633 |
case S32:
|
634 |
chprintf(chp, "%+010d ", ((int32_t*)buffer)[i]);
|
635 |
break;
|
636 |
default:
|
637 |
break;
|
638 |
} |
639 |
} |
640 |
chprintf(chp, "\n");
|
641 |
|
642 |
return;
|
643 |
} |
644 |
|
645 |
void shellRequestSetVcnlOffset(BaseSequentialStream *chp, int argc, char *argv[]) { |
646 |
chprintf(chp, "shellRequestSetVcnlOffset\n");
|
647 |
if (argc != 2) { |
648 |
chprintf(chp, "Usage: %s\n","set_vcnl <idx> <offset>"); |
649 |
return;
|
650 |
} |
651 |
|
652 |
uint8_t vcnlIdx = static_cast<uint8_t>(atoi(argv[0])); |
653 |
uint16_t vcnlOffset = static_cast<uint16_t>(atoi(argv[1])); |
654 |
|
655 |
if (vcnlIdx >= global.vcnl4020.size()) {
|
656 |
chprintf((BaseSequentialStream *)&SD1, "Wrong VCNL index: Choose [0 .. %d]\n", global.vcnl4020.size()-1); |
657 |
return;
|
658 |
} |
659 |
|
660 |
msg_t res = global.memory.setVcnl4020Offset(vcnlOffset, vcnlIdx); |
661 |
if (res != global.memory.OK) {
|
662 |
chprintf(chp, "Set Offset: FAIL\n");
|
663 |
} else {
|
664 |
chprintf(chp, "Set Offset: OK\n");
|
665 |
global.vcnl4020[vcnlIdx].setProximityOffset(vcnlOffset); |
666 |
} |
667 |
} |
668 |
|
669 |
void shellRequestResetVcnlOffset(BaseSequentialStream *chp, int argc, char *argv[]) { |
670 |
msg_t res = global.memory.OK; |
671 |
for (uint8_t idx = 0; idx < 8; ++idx) { |
672 |
msg_t r = global.memory.setVcnl4020Offset(0, idx);
|
673 |
if (r == global.memory.OK) {
|
674 |
global.vcnl4020[idx].setProximityOffset(0);
|
675 |
} else {
|
676 |
chprintf(chp, "Reset Offset %u: FAIL\n", idx);
|
677 |
res = r; |
678 |
} |
679 |
} |
680 |
|
681 |
if (res == global.memory.OK) {
|
682 |
chprintf(chp, "Reset Offset: DONE\n");
|
683 |
} |
684 |
|
685 |
return;
|
686 |
} |
687 |
|
688 |
void shellRequestGetVcnlOffset(BaseSequentialStream *chp, int argc, char *argv[]) { |
689 |
chprintf(chp, "shellRequestGetVcnlOffset\n");
|
690 |
if (argc != 1) { |
691 |
chprintf(chp, "Usage: %s\n","get_vcnl_offset <idx>"); |
692 |
return;
|
693 |
} |
694 |
|
695 |
uint8_t vcnlIdx = static_cast<uint8_t>(atoi(argv[0])); |
696 |
|
697 |
if (vcnlIdx >= global.vcnl4020.size()) {
|
698 |
chprintf((BaseSequentialStream *)&SD1, "Wrong VCNL index: Choose [0 .. %d]\n", global.vcnl4020.size()-1); |
699 |
return;
|
700 |
} |
701 |
|
702 |
uint16_t vcnlOffset; |
703 |
msg_t res = global.memory.getVcnl4020Offset(&vcnlOffset, vcnlIdx); |
704 |
if (res != global.memory.OK) {
|
705 |
chprintf(chp, "Get Offset: FAIL\n");
|
706 |
} else {
|
707 |
chprintf(chp, "Get Offset: OK \t Offset=%d\n", vcnlOffset);
|
708 |
} |
709 |
} |
710 |
|
711 |
void shellRequestCheck(BaseSequentialStream *chp, int __unused argc, char __unused *argv[]) { |
712 |
chprintf(chp, "shellRequestCheck\n");
|
713 |
boardPeripheryCheck(chp); |
714 |
|
715 |
} |
716 |
|
717 |
void shellRequestGetVcnl(BaseSequentialStream *chp, int argc, char *argv[]) { |
718 |
chprintf(chp, "shellRequestGetVcnl\n");
|
719 |
// Print the sensor information
|
720 |
if (argc != 1) { |
721 |
chprintf(chp, "Usage: %s\n","get_vcnl <rep>"); |
722 |
return;
|
723 |
} |
724 |
for (int32_t rep = 0x00; rep < atoi(argv[0]); ++rep) { |
725 |
for (uint8_t idx = 0x00; idx < global.vcnl4020.size(); idx++) { |
726 |
chprintf(chp, "%d: Ambi %d\tProx raw %d\tProx scaled %d\n", idx, global.vcnl4020[idx].getAmbientLight(), global.vcnl4020[idx].getProximity(), global.vcnl4020[idx].getProximityScaledWoOffset());
|
727 |
} |
728 |
chprintf(chp, "\n\n");
|
729 |
BaseThread::sleep(MS2ST(250));
|
730 |
} |
731 |
} |
732 |
|
733 |
void shellRequestCalib(BaseSequentialStream *chp, int __unused argc, char __unused *argv[]) { |
734 |
chprintf(chp, "shellRequestCalib\n");
|
735 |
global.robot.calibrate(); |
736 |
|
737 |
} |
738 |
|
739 |
void shellRequestGetRobotId(BaseSequentialStream *chp, int __unused argc, char __unused *argv[]) { |
740 |
chprintf(chp, "shellRequestGetRobotId\n");
|
741 |
chprintf(chp, "Robot ID: %u\n", global.robot.getRobotID());
|
742 |
if (global.robot.getRobotID() == 0) { |
743 |
chprintf(chp, "Warning: The ID seems to be uninitialized. Is CAN communication working correctly?\n");
|
744 |
} |
745 |
} |
746 |
|
747 |
void shellRequestGetSystemLoad(BaseSequentialStream *chp, int argc, char *argv[]) { |
748 |
chprintf(chp, "shellRequestGetSystemLoad\n");
|
749 |
uint8_t seconds = 1;
|
750 |
if (argc >= 1) { |
751 |
seconds = atoi(argv[0]);
|
752 |
} |
753 |
chprintf(chp, "measuring CPU load for %u %s...\n", seconds, (seconds>1)? "seconds" : "second"); |
754 |
|
755 |
const systime_t before = chThdGetTicks(chSysGetIdleThread());
|
756 |
BaseThread::sleep(S2ST(seconds)); |
757 |
const systime_t after = chThdGetTicks(chSysGetIdleThread());
|
758 |
const float usage = 1.0f - (float(after - before) / float(seconds * CH_FREQUENCY)); |
759 |
|
760 |
chprintf(chp, "CPU load: %3.2f%%\n", usage * 100); |
761 |
const uint32_t memory_total = 0x1C000; |
762 |
const uint32_t memory_load = memory_total - chCoreStatus();
|
763 |
chprintf(chp, "RAM load: %3.2f%% (%u / %u Byte)\n", float(memory_load)/float(memory_total) * 100, memory_load, memory_total); |
764 |
} |
765 |
|
766 |
void shellRequestSetCharging(BaseSequentialStream *chp, int argc, char *argv[]) { |
767 |
chprintf(chp, "shellRequestSetCharging\n");
|
768 |
if (argc < 1) { |
769 |
chprintf(chp, "Usage: %s\n","set_charging <enable>"); |
770 |
chprintf(chp, "\n");
|
771 |
chprintf(chp, "\tenable\n");
|
772 |
chprintf(chp, "Whether to enable (1) or to disable (0) the power path controller of the DiWheelDrive board.\n");
|
773 |
chprintf(chp, "\n");
|
774 |
return;
|
775 |
} |
776 |
|
777 |
const bool enable = atoi(argv[0]); |
778 |
chprintf(chp, "%s power path controller\n", enable ? "enabling" : "disabling"); |
779 |
global.robot.getPowerStatus().charging_flags.content.diwheeldrive_enable_power_path = enable; |
780 |
|
781 |
return;
|
782 |
} |
783 |
|
784 |
void shellRequestPrintVCNL(BaseSequentialStream *chp, int argc, char *argv[]) { |
785 |
chprintf(chp, "shellRequestPrintVCNL\n");
|
786 |
if (argc < 1) { |
787 |
chprintf(chp, "Warning: no arguments specified.\n");
|
788 |
chprintf(chp, "Using default values (prints one measurement).\n");
|
789 |
chprintf(chp, "Type 'print_vcnl help' for help.\n");
|
790 |
chprintf(chp, "----------------------------------------\n");
|
791 |
} |
792 |
|
793 |
if (strcmp(argv[0],"help") == 0) { |
794 |
chprintf(chp, "Usage: %s\n","print_vcnl [<seconds>] [<frequency>]"); |
795 |
chprintf(chp, "\n");
|
796 |
chprintf(chp, "\tseconds\n");
|
797 |
chprintf(chp, "Number of seconds to print the VCNL values. (default: 1)\n");
|
798 |
chprintf(chp, "\n");
|
799 |
chprintf(chp, "\tfrequency\n");
|
800 |
chprintf(chp, "Number prints per second. (default: 1)\n");
|
801 |
return;
|
802 |
} |
803 |
|
804 |
const uint32_t seconds = (argc >= 1) ? atoi(argv[0]) : 1; |
805 |
const uint32_t freq = (argc >= 2) ? atoi(argv[1]) : 1; |
806 |
|
807 |
uint16_t ambient = 0;
|
808 |
uint16_t proximity = 0;
|
809 |
|
810 |
for (uint32_t loop = 0; loop < seconds*freq; ++loop) { |
811 |
// Print proximity and ambilight values
|
812 |
for (uint8_t i = 0x00; i < global.vcnl4020.size(); ++i) { |
813 |
ambient = global.vcnl4020[i].getAmbientLight(); |
814 |
proximity = global.vcnl4020[i].getProximity(); |
815 |
chprintf(chp, "#%d: ambient=0x%04X\tproximity=0x%04X\n", i, ambient, proximity);
|
816 |
} |
817 |
chprintf(chp, "----------------------------------------\n");
|
818 |
|
819 |
BaseThread::sleep(US2ST(1000000 / freq));
|
820 |
} |
821 |
|
822 |
return;
|
823 |
} |
824 |
|
825 |
void shellSwitchBoardCmd(BaseSequentialStream *chp, int argc, char *argv[]) { |
826 |
if (argc != 1) { |
827 |
chprintf(chp, "Call with decimal numbers: shell_board <idx>\n");
|
828 |
return;
|
829 |
} |
830 |
uint8_t boardIdx = static_cast<uint8_t>(atoi(argv[0])); |
831 |
|
832 |
chprintf(chp, "shellSwitchBoardCmd\n");
|
833 |
global.sercanmux1.sendSwitchCmd(boardIdx); |
834 |
} |
835 |
|
836 |
void shellRequestGetBootloaderInfo(BaseSequentialStream* chp, int argc, char *argv[]) { |
837 |
// check the magic number
|
838 |
switch (*((uint32_t*)(BL_CALLBACK_TABLE_ADDR))) {
|
839 |
case (('A'<<24) | ('-'<<16) | ('B'<<8) | ('L'<<0)): |
840 |
chprintf((BaseSequentialStream*) &SD1, "Bootloader %u.%u.%u\n",
|
841 |
((blVersion_t*)(BL_CALLBACK_TABLE_ADDR + (1*4)))->major, |
842 |
((blVersion_t*)(BL_CALLBACK_TABLE_ADDR + (1*4)))->minor, |
843 |
((blVersion_t*)(BL_CALLBACK_TABLE_ADDR + (1*4)))->patch); |
844 |
break;
|
845 |
|
846 |
case BL_MAGIC_NUMBER:
|
847 |
chprintf((BaseSequentialStream*) &SD1, "Bootloader %u.%u.%u\n",
|
848 |
*((uint32_t*)(BL_CALLBACK_TABLE_ADDR + (1*4))), |
849 |
*((uint32_t*)(BL_CALLBACK_TABLE_ADDR + (1*4))), |
850 |
*((uint32_t*)(BL_CALLBACK_TABLE_ADDR + (1*4)))); |
851 |
break;
|
852 |
|
853 |
default:
|
854 |
chprintf((BaseSequentialStream*) &SD1, "Bootloader incompatible\n");
|
855 |
break;
|
856 |
} |
857 |
|
858 |
return;
|
859 |
} |
860 |
|
861 |
void shellRequestWiiSteering(BaseSequentialStream* chp, int argc, char *argv[]) { |
862 |
// if Wii steering is currently active, stop it
|
863 |
if (global.userThread.getCurrenState() == UserThread::WII_STEERING) {
|
864 |
global.userThread.setNextState(UserThread::IDLE); |
865 |
} |
866 |
// check arguments and (try to) enable Wii steering
|
867 |
else {
|
868 |
// if arguments invalid
|
869 |
if (argc < 1 || argc > 2 || global.userThread.setWiiAddress(argv[0]) != RDY_OK) { |
870 |
chprintf(chp, "Warning: invalid arguments\n");
|
871 |
chprintf(chp, "Usage: %s\n", "wii_steering <address> [<deadzone>]"); |
872 |
chprintf(chp, "\n");
|
873 |
chprintf(chp, "\taddress\n");
|
874 |
chprintf(chp, "bluetooth address of the Wiimote controller to pair with.\n");
|
875 |
chprintf(chp, "\tdeadzone\n");
|
876 |
chprintf(chp, "deadzone to set for the Wiimote controller [default = 10%%].\n");
|
877 |
return;
|
878 |
} |
879 |
else {
|
880 |
// set deadzone
|
881 |
const float deadzone = global.userThread.setWiiDeadzone((argc == 2) ? std::atof(argv[1]) : 0.1f); |
882 |
chprintf(chp, "deadzone set to %u%%\n", (unsigned int)(deadzone * 100.0f)); |
883 |
|
884 |
// start Wii steering behaviour
|
885 |
global.userThread.setNextState(UserThread::WII_STEERING); |
886 |
} |
887 |
} |
888 |
return;
|
889 |
} |
890 |
|
891 |
|
892 |
void shellRequestSetGlobalStrategy(BaseSequentialStream *chp, int argc, char *argv[]){ |
893 |
uint8_t strategy = 0;
|
894 |
if(argc == 1){ |
895 |
strategy = atoi(argv[0]);
|
896 |
} |
897 |
// send over can
|
898 |
// global.strategyTest = strategy;
|
899 |
// global.triggerCan = true;
|
900 |
global.robot.setStrategy(strategy); |
901 |
} |
902 |
|
903 |
void shellRequestGetPower(BaseSequentialStream *chp, int argc, char *argv[]){ |
904 |
|
905 |
// send over can
|
906 |
// global.strategyTest = strategy;
|
907 |
// global.triggerCan = true;
|
908 |
types::power_status state = global.robot.getPowerStatus(); |
909 |
global.bq27500[constants::PowerManagement::BAT_A].selftest(); |
910 |
chprintf(chp, "-----------------------------------------------\n");
|
911 |
global.bq27500[constants::PowerManagement::BAT_B].selftest(); |
912 |
chprintf(chp, "State of charge: %d\n", state.state_of_charge);
|
913 |
} |
914 |
|
915 |
|
916 |
static const ShellCommand commands[] = { |
917 |
{"shutdown", shellRequestShutdown},
|
918 |
{"check", shellRequestCheck},
|
919 |
{"reset_memory", shellRequestResetMemory},
|
920 |
{"get_board_id", shellRequestGetBoardId},
|
921 |
{"set_board_id", shellRequestSetBoardId},
|
922 |
{"get_memory_data", shellRequestGetMemoryData},
|
923 |
{"get_vcnl", shellRequestGetVcnl},
|
924 |
{"calib_vcnl_offset", shellRequestCalib},
|
925 |
{"set_vcnl_offset", shellRequestSetVcnlOffset},
|
926 |
{"reset_vcnl_offset", shellRequestResetVcnlOffset},
|
927 |
{"get_vcnl_offset", shellRequestGetVcnlOffset},
|
928 |
{"get_robot_id", shellRequestGetRobotId},
|
929 |
{"get_system_load", shellRequestGetSystemLoad},
|
930 |
{"set_charging", shellRequestSetCharging},
|
931 |
{"print_vcnl", shellRequestPrintVCNL},
|
932 |
{"shell_board", shellSwitchBoardCmd},
|
933 |
{"get_bootloader_info", shellRequestGetBootloaderInfo},
|
934 |
{"wii_steering", shellRequestWiiSteering},
|
935 |
{"setStrategy", shellRequestSetGlobalStrategy},
|
936 |
{"getBatteryState", shellRequestGetPower},
|
937 |
{NULL, NULL} |
938 |
}; |
939 |
|
940 |
static const ShellConfig shell_cfg1 = { |
941 |
(BaseSequentialStream *) &global.sercanmux1, |
942 |
commands |
943 |
}; |
944 |
|
945 |
void charger_logic() {
|
946 |
/*
|
947 |
* if supply connected, activate charger, else
|
948 |
* deactivate charger
|
949 |
*/
|
950 |
if (global.ltc4412.isPluggedIn()) {
|
951 |
boardChargerSetState(0x03u, 1), chprintf((BaseSequentialStream*) &SD1, "Charging.\n"); |
952 |
} else {
|
953 |
boardChargerSetState(0x03u, 0), chprintf((BaseSequentialStream*) &SD1, "Not charging.\n"); |
954 |
} |
955 |
} |
956 |
|
957 |
void init_powermonitor(INA219::Driver &ina219, const float shunt_resistance_O, const float max_expected_current_A, const uint16_t current_lsb_uA) |
958 |
{ |
959 |
INA219::CalibData calib_data; |
960 |
INA219::InitData init_data; |
961 |
|
962 |
calib_data.input.configuration.content.brng = INA219::Configuration::BRNG_16V; |
963 |
calib_data.input.configuration.content.pg = INA219::Configuration::PGA_40mV; |
964 |
calib_data.input.configuration.content.badc = INA219::Configuration::ADC_68100us; |
965 |
calib_data.input.configuration.content.sadc = INA219::Configuration::ADC_68100us; |
966 |
calib_data.input.configuration.content.mode = INA219::Configuration::MODE_ShuntBus_Continuous; |
967 |
calib_data.input.shunt_resistance_O = shunt_resistance_O; |
968 |
calib_data.input.max_expected_current_A = max_expected_current_A; |
969 |
calib_data.input.current_lsb_uA = current_lsb_uA; |
970 |
if (ina219.calibration(&calib_data) != BaseSensor<>::SUCCESS)
|
971 |
chprintf((BaseSequentialStream*)&SD1, "WARNING: calibration of INA219 failed.\n");
|
972 |
|
973 |
init_data.configuration.value = calib_data.input.configuration.value; |
974 |
init_data.calibration = calib_data.output.calibration_value; |
975 |
init_data.current_lsb_uA = calib_data.output.current_lsb_uA; |
976 |
if (ina219.init(&init_data) != BaseSensor<>::SUCCESS)
|
977 |
chprintf((BaseSequentialStream*)&SD1, "WARNING: initialization of INA219 failed.\n");
|
978 |
|
979 |
if (calib_data.input.current_lsb_uA != init_data.current_lsb_uA)
|
980 |
{ |
981 |
chprintf((BaseSequentialStream*)&SD1, "NOTE: LSB for current measurement was limited when initializing INA219 (%u -> %u)", calib_data.input.current_lsb_uA, init_data.current_lsb_uA);
|
982 |
} |
983 |
|
984 |
return;
|
985 |
} |
986 |
|
987 |
/*
|
988 |
* Application entry point.
|
989 |
*/
|
990 |
int main(void) { |
991 |
|
992 |
Thread *shelltp = NULL;
|
993 |
|
994 |
/*
|
995 |
* System initializations.
|
996 |
* - HAL initialization, this also initializes the configured device drivers
|
997 |
* and performs the board-specific initializations.
|
998 |
* - Kernel initialization, the main() function becomes a thread and the
|
999 |
* RTOS is active.
|
1000 |
*/
|
1001 |
halInit(); |
1002 |
System::init(); |
1003 |
|
1004 |
/*
|
1005 |
* TODO: detect the reason why the system was started by reading the 1st backup register of the RTC.
|
1006 |
* To do that, it is probably required to extend the RTC LLD by the required methods.
|
1007 |
* For further details, how to interprete the data in the backu register, please have a look at the bootloader project.
|
1008 |
*/
|
1009 |
|
1010 |
/*
|
1011 |
* Activates the serial driver 1 using the driver default configuration.
|
1012 |
*/
|
1013 |
sdStart(&SD1, &global.sd1_config); |
1014 |
|
1015 |
chprintf((BaseSequentialStream*) &SD1, "\n");
|
1016 |
chprintf((BaseSequentialStream*) &SD1, BOARD_NAME " " BOARD_VERSION "\n"); |
1017 |
switch (*((uint32_t*)(BL_CALLBACK_TABLE_ADDR))) {
|
1018 |
case (('A'<<24) | ('-'<<16) | ('B'<<8) | ('L'<<0)): |
1019 |
chprintf((BaseSequentialStream*) &SD1, "Bootloader %u.%u.%u\n",
|
1020 |
((blVersion_t*)(BL_CALLBACK_TABLE_ADDR + (1*4)))->major, |
1021 |
((blVersion_t*)(BL_CALLBACK_TABLE_ADDR + (1*4)))->minor, |
1022 |
((blVersion_t*)(BL_CALLBACK_TABLE_ADDR + (1*4)))->patch); |
1023 |
break;
|
1024 |
|
1025 |
case BL_MAGIC_NUMBER:
|
1026 |
chprintf((BaseSequentialStream*) &SD1, "Bootloader %u.%u.%u\n",
|
1027 |
*((uint32_t*)(BL_CALLBACK_TABLE_ADDR + (1*4))), |
1028 |
*((uint32_t*)(BL_CALLBACK_TABLE_ADDR + (1*4))), |
1029 |
*((uint32_t*)(BL_CALLBACK_TABLE_ADDR + (1*4)))); |
1030 |
break;
|
1031 |
|
1032 |
default:
|
1033 |
chprintf((BaseSequentialStream*) &SD1, "Bootloader incompatible\n");
|
1034 |
break;
|
1035 |
} |
1036 |
chprintf((BaseSequentialStream*) &SD1, "ChibiOS " CH_KERNEL_VERSION "\n"); |
1037 |
// make sure that the info text is completetly printed
|
1038 |
BaseThread::sleep(10);
|
1039 |
|
1040 |
// boardWriteSystemPower(1);
|
1041 |
// boardWriteIoPower(1);
|
1042 |
// boardWriteWarmRestart(0);
|
1043 |
|
1044 |
global.robot.start(HIGHPRIO - 1);
|
1045 |
|
1046 |
pwmStart(&PWMD3, &global.pwm3_config); |
1047 |
pwmDisableChannel(&PWMD3, 1);
|
1048 |
|
1049 |
adcStart(&ADCD1, NULL);
|
1050 |
|
1051 |
extStart(&EXTD1, &extcfg); |
1052 |
|
1053 |
boardClearI2CBus(GPIOB_GAUGE_SCL1, GPIOB_GAUGE_SDA1); |
1054 |
boardClearI2CBus(GPIOB_GAUGE_SCL2, GPIOB_GAUGE_SDA2); |
1055 |
|
1056 |
global.HW_I2C1.start(&global.i2c1_config); |
1057 |
global.HW_I2C2.start(&global.i2c2_config); |
1058 |
|
1059 |
uint16_t i2c_test = 0;
|
1060 |
while (global.ina219[INA_VIO18].readRegister(INA219::Driver::REG_BUS_VOLTAGE, i2c_test) != RDY_OK) {
|
1061 |
chprintf((BaseSequentialStream*)&global.sercanmux1, "I2C #1 stalled! trying to clear the bus... (this will take 20 seconds)\n");
|
1062 |
boardWriteLed(1);
|
1063 |
boardResetBQ27500I2C(GPIOB_GAUGE_SCL2, GPIOB_GAUGE_SDA2); |
1064 |
boardWriteLed(0);
|
1065 |
} |
1066 |
while (global.ina219[INA_VDD].readRegister(INA219::Driver::REG_BUS_VOLTAGE, i2c_test) != RDY_OK) {
|
1067 |
chprintf((BaseSequentialStream*)&global.sercanmux1, "I2C #2 stalled! trying to clear the bus... (this will take 20 seconds)\n");
|
1068 |
boardWriteLed(1);
|
1069 |
boardResetBQ27500I2C(GPIOB_GAUGE_SCL1, GPIOB_GAUGE_SDA1); |
1070 |
boardWriteLed(0);
|
1071 |
} |
1072 |
|
1073 |
global.memory.init(); |
1074 |
uint8_t i = 0;
|
1075 |
if (global.memory.getBoardId(&i) == fileSystemIo::FileSystemIoBase::OK) {
|
1076 |
chprintf((BaseSequentialStream*) &SD1, "Board ID: %u\n", i);
|
1077 |
} else {
|
1078 |
chprintf((BaseSequentialStream*) &SD1, "Error reading board ID\n");
|
1079 |
} |
1080 |
chprintf((BaseSequentialStream*) &SD1, "\n");
|
1081 |
|
1082 |
shelltp = shellCreate(&shell_cfg1, THD_WA_SIZE(1024), NORMALPRIO);
|
1083 |
|
1084 |
// initialize the power monitors
|
1085 |
init_powermonitor(global.ina219[INA_VDD], 0.1f, 0.075f, 10); |
1086 |
init_powermonitor(global.ina219[INA_VIO18], 0.01f, 1.5f, 100); |
1087 |
init_powermonitor(global.ina219[INA_VIO33], 0.01f, 1.5f, 100); |
1088 |
init_powermonitor(global.ina219[INA_VIO42], 0.01f, 1.5f, 100); |
1089 |
init_powermonitor(global.ina219[INA_VIO50], 0.01f, 1.5f, 100); |
1090 |
|
1091 |
// start the ADC watchdog
|
1092 |
global.adc1_vsys.start(NORMALPRIO); |
1093 |
|
1094 |
// start the ina threads
|
1095 |
for (i = 0; i < global.ina219.size(); ++i) |
1096 |
global.ina219[i].start(NORMALPRIO); |
1097 |
|
1098 |
// // calibrate the fuel gauges (TODO)
|
1099 |
// BQ27500::CalibData bq27500_calib_data;
|
1100 |
// bq27500_p7.calibration(&bq27500_calib_data);
|
1101 |
|
1102 |
// start the fuel gauge threads
|
1103 |
for (i = 0; i < global.bq27500.size(); ++i) |
1104 |
global.bq27500[i].start(NORMALPRIO); |
1105 |
|
1106 |
// start the proximity sensor threads
|
1107 |
for (i = 0; i < global.vcnl4020.size(); ++i) { |
1108 |
uint16_t buffer; |
1109 |
global.memory.getVcnl4020Offset(&buffer,i); |
1110 |
global.vcnl4020[i].setProximityOffset(buffer); |
1111 |
global.vcnl4020[i].start(NORMALPRIO); |
1112 |
} |
1113 |
|
1114 |
/* Start uart port connecting bluetooth chip */
|
1115 |
global.wt12.bluetoothStart(); |
1116 |
|
1117 |
global.mpr121.configure(&global.mpr121_run_config); |
1118 |
global.mpr121.start(NORMALPRIO); |
1119 |
|
1120 |
global.userThread.start(NORMALPRIO); |
1121 |
|
1122 |
/* let the SYS_SYNC_N pin go, to signal that the initialization of the module is done */
|
1123 |
palWritePad(GPIOC, GPIOC_SYS_INT_N, PAL_HIGH); |
1124 |
|
1125 |
/* wait until all modules are done */
|
1126 |
while (palReadPad(GPIOC, GPIOC_SYS_INT_N) == PAL_LOW) {
|
1127 |
continue;
|
1128 |
} |
1129 |
|
1130 |
while (true) { |
1131 |
|
1132 |
if (!shelltp)
|
1133 |
shelltp = shellCreate(&shell_cfg1, THD_WA_SIZE(1024), NORMALPRIO);
|
1134 |
else if (chThdTerminated(shelltp)) { |
1135 |
chThdRelease(shelltp); /* Recovers memory of the previous shell. */
|
1136 |
shelltp = NULL; /* Triggers spawning of a new shell. */ |
1137 |
} |
1138 |
|
1139 |
// Let the LED just blink as an alive signal
|
1140 |
boardWriteLed(1);
|
1141 |
BaseThread::sleep(MS2ST(250));
|
1142 |
boardWriteLed(0);
|
1143 |
BaseThread::sleep(MS2ST(250));
|
1144 |
|
1145 |
/*
|
1146 |
* Charger logic before shutdown logic,
|
1147 |
* so we don't need to call it twice.
|
1148 |
*/
|
1149 |
if (pathdc_change) {
|
1150 |
pathdc_change = 0x00u;
|
1151 |
// charger_logic();
|
1152 |
} |
1153 |
|
1154 |
/*
|
1155 |
* Shutdown logic before user logic,
|
1156 |
* so user does not get hopes up and
|
1157 |
* prepares wheels to drive into the
|
1158 |
* next wall or something like that.
|
1159 |
*/
|
1160 |
if (shutdown_now != SHUTDOWN_NONE) {
|
1161 |
if ((*((uint32_t*)(BL_CALLBACK_TABLE_ADDR)) != (('A'<<24) | ('-'<<16) | ('B'<<8) | ('L'<<0))) && (*((uint32_t*)(BL_CALLBACK_TABLE_ADDR)) != BL_MAGIC_NUMBER)) { |
1162 |
chprintf((BaseSequentialStream*) &SD1, "ERROR: unable to shut down (bootloader deprecated).\n");
|
1163 |
shutdown_now = SHUTDOWN_NONE; |
1164 |
} else {
|
1165 |
uint32_t blCallbackPtrAddr = BL_CALLBACK_TABLE_ADDR; |
1166 |
// handle bootloader version 0.2.x
|
1167 |
if ((*((uint32_t*)(BL_CALLBACK_TABLE_ADDR)) == BL_MAGIC_NUMBER) &&
|
1168 |
(*((uint32_t*)(BL_CALLBACK_TABLE_ADDR + (1*4))) == 0 && *((uint32_t*)(BL_CALLBACK_TABLE_ADDR + (2*4))) == 2)) { |
1169 |
switch (shutdown_now) {
|
1170 |
case SHUTDOWN_TRANSPORTATION:
|
1171 |
blCallbackPtrAddr += 6 * 4; |
1172 |
break;
|
1173 |
case SHUTDOWN_DEEPSLEEP:
|
1174 |
blCallbackPtrAddr += 5 * 4; |
1175 |
break;
|
1176 |
case SHUTDOWN_HIBERNATE:
|
1177 |
blCallbackPtrAddr += 4 * 4; |
1178 |
break;
|
1179 |
case SHUTDOWN_HANDLE_REQUEST:
|
1180 |
case SHUTDOWN_RESTART:
|
1181 |
blCallbackPtrAddr += 10 * 4; |
1182 |
break;
|
1183 |
default:
|
1184 |
blCallbackPtrAddr = 0;
|
1185 |
break;
|
1186 |
} |
1187 |
} |
1188 |
// handle bootloader version 0.3.x
|
1189 |
else if ((*((uint32_t*)(BL_CALLBACK_TABLE_ADDR)) == BL_MAGIC_NUMBER) && |
1190 |
(*((uint32_t*)(BL_CALLBACK_TABLE_ADDR + (1*4))) == 0 && *((uint32_t*)(BL_CALLBACK_TABLE_ADDR + (2*4))) == 3)) { |
1191 |
switch (shutdown_now) {
|
1192 |
case SHUTDOWN_TRANSPORTATION:
|
1193 |
blCallbackPtrAddr += 6 * 4; |
1194 |
break;
|
1195 |
case SHUTDOWN_DEEPSLEEP:
|
1196 |
blCallbackPtrAddr += 5 * 4; |
1197 |
break;
|
1198 |
case SHUTDOWN_HIBERNATE:
|
1199 |
blCallbackPtrAddr += 4 * 4; |
1200 |
break;
|
1201 |
case SHUTDOWN_RESTART:
|
1202 |
blCallbackPtrAddr += 7 * 4; |
1203 |
break;
|
1204 |
case SHUTDOWN_HANDLE_REQUEST:
|
1205 |
blCallbackPtrAddr += 8 * 4; |
1206 |
break;
|
1207 |
default:
|
1208 |
blCallbackPtrAddr = 0;
|
1209 |
break;
|
1210 |
} |
1211 |
} |
1212 |
// handle bootloader version 1.0.x and 1.1.x
|
1213 |
else if ((*((uint32_t*)(BL_CALLBACK_TABLE_ADDR)) == (('A'<<24) | ('-'<<16) | ('B'<<8) | ('L'<<0))) && |
1214 |
((blVersion_t*)(BL_CALLBACK_TABLE_ADDR + (1*4)))->major == 1 && (((blVersion_t*)(BL_CALLBACK_TABLE_ADDR + (1*4)))->minor == 0 || ((blVersion_t*)(BL_CALLBACK_TABLE_ADDR + (1*4)))->minor == 1)) { |
1215 |
switch (shutdown_now) {
|
1216 |
case SHUTDOWN_TRANSPORTATION:
|
1217 |
blCallbackPtrAddr += 6 * 4; |
1218 |
break;
|
1219 |
case SHUTDOWN_DEEPSLEEP:
|
1220 |
blCallbackPtrAddr += 5 * 4; |
1221 |
break;
|
1222 |
case SHUTDOWN_HIBERNATE:
|
1223 |
blCallbackPtrAddr += 4 * 4; |
1224 |
break;
|
1225 |
case SHUTDOWN_RESTART:
|
1226 |
blCallbackPtrAddr += 7 * 4; |
1227 |
break;
|
1228 |
case SHUTDOWN_HANDLE_REQUEST:
|
1229 |
blCallbackPtrAddr += 8 * 4; |
1230 |
break;
|
1231 |
default:
|
1232 |
blCallbackPtrAddr = 0;
|
1233 |
break;
|
1234 |
} |
1235 |
} |
1236 |
|
1237 |
void (*blCallback)(void) = NULL; |
1238 |
if (blCallbackPtrAddr > BL_CALLBACK_TABLE_ADDR) {
|
1239 |
blCallback = (void (*)(void))(*((uint32_t*)blCallbackPtrAddr)); |
1240 |
|
1241 |
if (!blCallback) {
|
1242 |
chprintf((BaseSequentialStream*) &SD1, "ERROR: Requested shutdown not supported.\n");
|
1243 |
shutdown_now = SHUTDOWN_NONE; |
1244 |
} else {
|
1245 |
chprintf((BaseSequentialStream*) &SD1, "initiating shutdown sequence...\n");
|
1246 |
palWritePad(GPIOC, GPIOC_SYS_INT_N, PAL_LOW); |
1247 |
palWritePad(GPIOC, GPIOC_SYS_PD_N, PAL_LOW); |
1248 |
|
1249 |
chprintf((BaseSequentialStream*) &SD1, "stopping all threads and periphery...");
|
1250 |
systemStop(); |
1251 |
chprintf((BaseSequentialStream*) &SD1, "\tdone\n");
|
1252 |
BaseThread::sleep(MS2ST(10)); // sleep to print everything |
1253 |
|
1254 |
blCallback(); |
1255 |
} |
1256 |
|
1257 |
} else {
|
1258 |
chprintf((BaseSequentialStream*) &SD1, "ERROR: invalid shutdown requested (%u).\n", shutdown_now);
|
1259 |
shutdown_now = SHUTDOWN_NONE; |
1260 |
} |
1261 |
} |
1262 |
|
1263 |
// shutdown_now = 0x00u;
|
1264 |
// if (palReadPad(GPIOC, GPIOC_PATH_DC))
|
1265 |
// systemStop();
|
1266 |
// else
|
1267 |
// systemShutdown();
|
1268 |
// //boardStop(0x00u, 0x00u);
|
1269 |
// //chprintf((BaseSequentialStream*) &SD1, "Stop exit\n");
|
1270 |
} |
1271 |
|
1272 |
} |
1273 |
|
1274 |
global.HW_I2C2.stop(); |
1275 |
global.HW_I2C1.stop(); |
1276 |
|
1277 |
return 0; |
1278 |
} |