#include "knx_facade.h" #include "knx/bau57B0.h" #include "knx/bau27B0.h" #include "knx/bau07B0.h" #include "knx/group_object_table_object.h" #include "knx/bits.h" #include #include #include #include #include #include #include #include "fdsk.h" volatile sig_atomic_t loopActive = 1; void signalHandler(int sig) { (void)sig; // can be called asynchronously loopActive = 0; } bool sendHidReport(uint8_t* data, uint16_t length) { return false; } bool isSendHidReportPossible() { return false; } #if MASK_VERSION == 0x57B0 KnxFacade knx; #elif MASK_VERSION == 0x27B0 KnxFacade knx; #elif MASK_VERSION == 0x07B0 KnxFacade knx; #else #error Mask version not supported yet! #endif long lastsend = 0; #define GO_CURR knx.getGroupObject(1) #define GO_MAX knx.getGroupObject(2) #define GO_MIN knx.getGroupObject(3) #define GO_RESET knx.getGroupObject(4) void measureTemp() { long now = millis(); if ((now - lastsend) < 10000) return; lastsend = now; int r = rand(); double currentValue = (r * 1.0) / (RAND_MAX * 1.0); currentValue *= 100; currentValue -= 50; // currentValue *= (670433.28 + 273); // currentValue -= 273; println(currentValue); GO_CURR.value(currentValue); double max = GO_MAX.value(); if (currentValue > max) GO_MAX.value(currentValue); if (currentValue < (double)GO_MIN.value()) GO_MIN.value(currentValue); } void resetCallback(GroupObject& go) { if (go.value()) { GO_MAX.valueNoSend(-273.0); GO_MIN.valueNoSend(670433.28); } } void appLoop() { if (!knx.configured()) return; measureTemp(); } void setup() { srand((unsigned int)time(NULL)); knx.readMemory(); if (knx.individualAddress() == 0) knx.progMode(true); if (knx.configured()) { GO_CURR.dataPointType(Dpt(9, 1)); GO_MIN.dataPointType(Dpt(9, 1)); GO_MIN.value(670433.28); GO_MAX.dataPointType(Dpt(9, 1)); GO_MAX.valueNoSend(-273.0); GO_RESET.dataPointType(Dpt(1, 15)); GO_RESET.callback(resetCallback); printf("Timeout: %d\n", knx.paramWord(0)); printf("Zykl. senden: %d\n", knx.paramByte(2)); printf("Min/Max senden: %d\n", knx.paramByte(3)); printf("Aenderung senden: %d\n", knx.paramByte(4)); printf("Abgleich %d\n", knx.paramByte(5)); } else println("not configured"); knx.start(); } int main(int argc, char** argv) { printf("main() start.\n"); uint8_t serialNumber[] = { 0x00, 0xFA, 0x01, 0x02, 0x03, 0x04}; uint8_t key[] = { 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0A, 0x0B, 0x0C, 0x0D, 0x0E, 0x0F}; FdskCalculator calc; char fdskString[42]; // 6 * 6 chars + 5 dashes + nullbyte = 42 calc.snprintFdsk(fdskString, sizeof(fdskString), serialNumber, key); printf("FDSK: %s\n", fdskString); // Prevent swapping of this process struct sched_param sp; memset(&sp, 0, sizeof(sp)); sp.sched_priority = sched_get_priority_max(SCHED_FIFO); sched_setscheduler(0, SCHED_FIFO, &sp); mlockall(MCL_CURRENT | MCL_FUTURE); // Register signals signal(SIGINT, signalHandler); signal(SIGTERM, signalHandler); knx.platform().cmdLineArgs(argc, argv); setup(); while (loopActive) { knx.loop(); if (knx.configured()) appLoop(); delayMicroseconds(100); } // pinMode() will automatically export GPIO pin in sysfs // Read or writing the GPIO pin for the first time automatically // opens the "value" sysfs file to read or write the GPIO pin value. // The following calls will close the "value" sysfs fiel for the pin // and unexport the GPIO pin. #ifdef USE_RF gpio_unexport(SPI_SS_PIN); gpio_unexport(GPIO_GDO2_PIN); gpio_unexport(GPIO_GDO0_PIN); #endif printf("main() exit.\n"); }