#include "globals.h" #include "payload.h" PayloadConvert::PayloadConvert(uint8_t size) { buffer = (uint8_t *)malloc(size); cursor = 0; } PayloadConvert::~PayloadConvert(void) { free(buffer); } void PayloadConvert::reset(void) { cursor = 0; } uint8_t PayloadConvert::getSize(void) { return cursor; } uint8_t *PayloadConvert::getBuffer(void) { return buffer; } /* ---------------- plain format without special encoding ---------- */ #if (PAYLOAD_ENCODER == 1) void PayloadConvert::addByte(uint8_t value) { buffer[cursor++] = (value); } void PayloadConvert::addCount(uint16_t value, uint8_t snifftype) { buffer[cursor++] = highByte(value); buffer[cursor++] = lowByte(value); } void PayloadConvert::addAlarm(int8_t rssi, uint8_t msg) { buffer[cursor++] = rssi; buffer[cursor++] = msg; } void PayloadConvert::addVoltage(uint16_t value) { buffer[cursor++] = highByte(value); buffer[cursor++] = lowByte(value); } void PayloadConvert::addConfig(configData_t value) { buffer[cursor++] = value.loradr; buffer[cursor++] = value.txpower; buffer[cursor++] = value.adrmode; buffer[cursor++] = value.screensaver; buffer[cursor++] = value.screenon; buffer[cursor++] = value.countermode; buffer[cursor++] = highByte(value.rssilimit); buffer[cursor++] = lowByte(value.rssilimit); buffer[cursor++] = value.sendcycle; buffer[cursor++] = value.wifichancycle; buffer[cursor++] = value.blescantime; buffer[cursor++] = value.blescan; buffer[cursor++] = value.wifiant; buffer[cursor++] = value.vendorfilter; buffer[cursor++] = value.rgblum; buffer[cursor++] = value.payloadmask; buffer[cursor++] = value.monitormode; memcpy(buffer + cursor, value.version, 10); cursor += 10; } void PayloadConvert::addStatus(uint16_t voltage, uint64_t uptime, float cputemp, uint32_t mem, uint8_t reset1, uint8_t reset2) { buffer[cursor++] = highByte(voltage); buffer[cursor++] = lowByte(voltage); buffer[cursor++] = (byte)((uptime & 0xFF00000000000000) >> 56); buffer[cursor++] = (byte)((uptime & 0x00FF000000000000) >> 48); buffer[cursor++] = (byte)((uptime & 0x0000FF0000000000) >> 40); buffer[cursor++] = (byte)((uptime & 0x000000FF00000000) >> 32); buffer[cursor++] = (byte)((uptime & 0x00000000FF000000) >> 24); buffer[cursor++] = (byte)((uptime & 0x0000000000FF0000) >> 16); buffer[cursor++] = (byte)((uptime & 0x000000000000FF00) >> 8); buffer[cursor++] = (byte)((uptime & 0x00000000000000FF)); buffer[cursor++] = (byte)(cputemp); buffer[cursor++] = (byte)((mem & 0xFF000000) >> 24); buffer[cursor++] = (byte)((mem & 0x00FF0000) >> 16); buffer[cursor++] = (byte)((mem & 0x0000FF00) >> 8); buffer[cursor++] = (byte)((mem & 0x000000FF)); buffer[cursor++] = (byte)(reset1); buffer[cursor++] = (byte)(reset2); } void PayloadConvert::addGPS(gpsStatus_t value) { #if(HAS_GPS) buffer[cursor++] = (byte)((value.latitude & 0xFF000000) >> 24); buffer[cursor++] = (byte)((value.latitude & 0x00FF0000) >> 16); buffer[cursor++] = (byte)((value.latitude & 0x0000FF00) >> 8); buffer[cursor++] = (byte)((value.latitude & 0x000000FF)); buffer[cursor++] = (byte)((value.longitude & 0xFF000000) >> 24); buffer[cursor++] = (byte)((value.longitude & 0x00FF0000) >> 16); buffer[cursor++] = (byte)((value.longitude & 0x0000FF00) >> 8); buffer[cursor++] = (byte)((value.longitude & 0x000000FF)); #if (!PAYLOAD_OPENSENSEBOX) buffer[cursor++] = value.satellites; buffer[cursor++] = highByte(value.hdop); buffer[cursor++] = lowByte(value.hdop); buffer[cursor++] = highByte(value.altitude); buffer[cursor++] = lowByte(value.altitude); #endif #endif } void PayloadConvert::addSensor(uint8_t buf[]) { #if(HAS_SENSORS) uint8_t length = buf[0]; memcpy(buffer, buf + 1, length); cursor += length; // length of buffer #endif } void PayloadConvert::addBME(bmeStatus_t value) { #if(HAS_BME) int16_t temperature = (int16_t)(value.temperature); // float -> int uint16_t humidity = (uint16_t)(value.humidity); // float -> int uint16_t pressure = (uint16_t)(value.pressure); // float -> int uint16_t iaq = (uint16_t)(value.iaq); // float -> int buffer[cursor++] = highByte(temperature); buffer[cursor++] = lowByte(temperature); buffer[cursor++] = highByte(pressure); buffer[cursor++] = lowByte(pressure); buffer[cursor++] = highByte(humidity); buffer[cursor++] = lowByte(humidity); buffer[cursor++] = highByte(iaq); buffer[cursor++] = lowByte(iaq); #endif } void PayloadConvert::addButton(uint8_t value) { #ifdef HAS_BUTTON buffer[cursor++] = value; #endif } void PayloadConvert::addTime(time_t value) { uint32_t time = (uint32_t)value; buffer[cursor++] = (byte)((time & 0xFF000000) >> 24); buffer[cursor++] = (byte)((time & 0x00FF0000) >> 16); buffer[cursor++] = (byte)((time & 0x0000FF00) >> 8); buffer[cursor++] = (byte)((time & 0x000000FF)); } /* ---------------- packed format with LoRa serialization Encoder ---------- */ // derived from // https://github.com/thesolarnomad/lora-serialization/blob/master/src/LoraEncoder.cpp #elif (PAYLOAD_ENCODER == 2) void PayloadConvert::addByte(uint8_t value) { writeUint8(value); } void PayloadConvert::addCount(uint16_t value, uint8_t snifftype) { writeUint16(value); } void PayloadConvert::addAlarm(int8_t rssi, uint8_t msg) { writeUint8(rssi); writeUint8(msg); } void PayloadConvert::addVoltage(uint16_t value) { writeUint16(value); } void PayloadConvert::addConfig(configData_t value) { writeUint8(value.loradr); writeUint8(value.txpower); writeUint16(value.rssilimit); writeUint8(value.sendcycle); writeUint8(value.wifichancycle); writeUint8(value.blescantime); writeUint8(value.rgblum); writeBitmap(value.adrmode ? true : false, value.screensaver ? true : false, value.screenon ? true : false, value.countermode ? true : false, value.blescan ? true : false, value.wifiant ? true : false, value.vendorfilter ? true : false, value.monitormode ? true : false); writeBitmap(value.payloadmask && GPS_DATA ? true : false, value.payloadmask && ALARM_DATA ? true : false, value.payloadmask && MEMS_DATA ? true : false, value.payloadmask && COUNT_DATA ? true : false, value.payloadmask && SENSOR1_DATA ? true : false, value.payloadmask && SENSOR2_DATA ? true : false, value.payloadmask && SENSOR3_DATA ? true : false, value.payloadmask && BATT_DATA ? true : false); writeVersion(value.version); } void PayloadConvert::addStatus(uint16_t voltage, uint64_t uptime, float cputemp, uint32_t mem, uint8_t reset1, uint8_t reset2) { writeUint16(voltage); writeUptime(uptime); writeUint8((byte)cputemp); writeUint32(mem); writeUint8(reset1); writeUint8(reset2); } void PayloadConvert::addGPS(gpsStatus_t value) { #if(HAS_GPS) writeLatLng(value.latitude, value.longitude); #if (!PAYLOAD_OPENSENSEBOX) writeUint8(value.satellites); writeUint16(value.hdop); writeUint16(value.altitude); #endif #endif } void PayloadConvert::addSensor(uint8_t buf[]) { #if(HAS_SENSORS) uint8_t length = buf[0]; memcpy(buffer, buf + 1, length); cursor += length; // length of buffer #endif } void PayloadConvert::addBME(bmeStatus_t value) { #if(HAS_BME) writeFloat(value.temperature); writePressure(value.pressure); writeUFloat(value.humidity); writeUFloat(value.iaq); #endif } void PayloadConvert::addButton(uint8_t value) { #ifdef HAS_BUTTON writeUint8(value); #endif } void PayloadConvert::addTime(time_t value) { uint32_t time = (uint32_t)value; writeUint32(time); } void PayloadConvert::uintToBytes(uint64_t value, uint8_t byteSize) { for (uint8_t x = 0; x < byteSize; x++) { byte next = 0; if (sizeof(value) > x) { next = static_cast((value >> (x * 8)) & 0xFF); } buffer[cursor] = next; ++cursor; } } void PayloadConvert::writeUptime(uint64_t uptime) { writeUint64(uptime); } void PayloadConvert::writeVersion(char *version) { memcpy(buffer + cursor, version, 10); cursor += 10; } void PayloadConvert::writeLatLng(double latitude, double longitude) { // Tested to at least work with int32_t, which are processed correctly. writeUint32(latitude); writeUint32(longitude); } void PayloadConvert::writeUint64(uint64_t i) { uintToBytes(i, 8); } void PayloadConvert::writeUint32(uint32_t i) { uintToBytes(i, 4); } void PayloadConvert::writeUint16(uint16_t i) { uintToBytes(i, 2); } void PayloadConvert::writeUint8(uint8_t i) { uintToBytes(i, 1); } void PayloadConvert::writeUFloat(float value) { writeUint16(value * 100); } void PayloadConvert::writePressure(float value) { writeUint16(value * 10); } /** * Uses a 16bit two's complement with two decimals, so the range is * -327.68 to +327.67 degrees */ void PayloadConvert::writeFloat(float value) { int16_t t = (int16_t)(value * 100); if (value < 0) { t = ~-t; t = t + 1; } buffer[cursor++] = (byte)((t >> 8) & 0xFF); buffer[cursor++] = (byte)t & 0xFF; } void PayloadConvert::writeBitmap(bool a, bool b, bool c, bool d, bool e, bool f, bool g, bool h) { uint8_t bitmap = 0; // LSB first bitmap |= (a & 1) << 7; bitmap |= (b & 1) << 6; bitmap |= (c & 1) << 5; bitmap |= (d & 1) << 4; bitmap |= (e & 1) << 3; bitmap |= (f & 1) << 2; bitmap |= (g & 1) << 1; bitmap |= (h & 1) << 0; writeUint8(bitmap); } /* ---------------- Cayenne LPP 2.0 format ---------- */ // see specs // http://community.mydevices.com/t/cayenne-lpp-2-0/7510 (LPP 2.0) // https://github.com/myDevicesIoT/cayenne-docs/blob/master/docs/LORA.md // (LPP 1.0) PAYLOAD_ENCODER == 3 -> Dynamic Sensor Payload, using channels -> // FPort 1 PAYLOAD_ENCODER == 4 -> Packed Sensor Payload, not using channels -> // FPort 2 #elif ((PAYLOAD_ENCODER == 3) || (PAYLOAD_ENCODER == 4)) void PayloadConvert::addByte(uint8_t value) { /* not implemented */ } void PayloadConvert::addCount(uint16_t value, uint8_t snifftype) { switch (snifftype) { case MAC_SNIFF_WIFI: #if (PAYLOAD_ENCODER == 3) buffer[cursor++] = LPP_COUNT_WIFI_CHANNEL; #endif buffer[cursor++] = LPP_LUMINOSITY; // workaround since cayenne has no data type meter buffer[cursor++] = highByte(value); buffer[cursor++] = lowByte(value); break; case MAC_SNIFF_BLE: #if (PAYLOAD_ENCODER == 3) buffer[cursor++] = LPP_COUNT_BLE_CHANNEL; #endif buffer[cursor++] = LPP_LUMINOSITY; // workaround since cayenne has no data type meter buffer[cursor++] = highByte(value); buffer[cursor++] = lowByte(value); break; } } void PayloadConvert::addAlarm(int8_t rssi, uint8_t msg) { #if (PAYLOAD_ENCODER == 3) buffer[cursor++] = LPP_ALARM_CHANNEL; #endif buffer[cursor++] = LPP_PRESENCE; buffer[cursor++] = msg; #if (PAYLOAD_ENCODER == 3) buffer[cursor++] = LPP_MSG_CHANNEL; #endif buffer[cursor++] = LPP_ANALOG_INPUT; buffer[cursor++] = rssi; } void PayloadConvert::addVoltage(uint16_t value) { uint16_t volt = value / 10; #if (PAYLOAD_ENCODER == 3) buffer[cursor++] = LPP_BATT_CHANNEL; #endif buffer[cursor++] = LPP_ANALOG_INPUT; buffer[cursor++] = highByte(volt); buffer[cursor++] = lowByte(volt); } void PayloadConvert::addConfig(configData_t value) { #if (PAYLOAD_ENCODER == 3) buffer[cursor++] = LPP_ADR_CHANNEL; #endif buffer[cursor++] = LPP_DIGITAL_INPUT; buffer[cursor++] = value.adrmode; } void PayloadConvert::addStatus(uint16_t voltage, uint64_t uptime, float celsius, uint32_t mem, uint8_t reset1, uint8_t reset2) { uint16_t temp = celsius * 10; uint16_t volt = voltage / 10; #if (defined BAT_MEASURE_ADC || defined HAS_PMU) #if (PAYLOAD_ENCODER == 3) buffer[cursor++] = LPP_BATT_CHANNEL; #endif buffer[cursor++] = LPP_ANALOG_INPUT; buffer[cursor++] = highByte(volt); buffer[cursor++] = lowByte(volt); #endif // BAT_MEASURE_ADC #if (PAYLOAD_ENCODER == 3) buffer[cursor++] = LPP_TEMPERATURE_CHANNEL; #endif buffer[cursor++] = LPP_TEMPERATURE; buffer[cursor++] = highByte(temp); buffer[cursor++] = lowByte(temp); } void PayloadConvert::addGPS(gpsStatus_t value) { #if(HAS_GPS) int32_t lat = value.latitude / 100; int32_t lon = value.longitude / 100; int32_t alt = value.altitude * 100; #if (PAYLOAD_ENCODER == 3) buffer[cursor++] = LPP_GPS_CHANNEL; #endif buffer[cursor++] = LPP_GPS; buffer[cursor++] = (byte)((lat & 0xFF0000) >> 16); buffer[cursor++] = (byte)((lat & 0x00FF00) >> 8); buffer[cursor++] = (byte)((lat & 0x0000FF)); buffer[cursor++] = (byte)((lon & 0xFF0000) >> 16); buffer[cursor++] = (byte)((lon & 0x00FF00) >> 8); buffer[cursor++] = (byte)(lon & 0x0000FF); buffer[cursor++] = (byte)((alt & 0xFF0000) >> 16); buffer[cursor++] = (byte)((alt & 0x00FF00) >> 8); buffer[cursor++] = (byte)(alt & 0x0000FF); #endif // HAS_GPS } void PayloadConvert::addSensor(uint8_t buf[]) { #if(HAS_SENSORS) // to come /* uint8_t length = buf[0]; memcpy(buffer, buf+1, length); cursor += length; // length of buffer */ #endif // HAS_SENSORS } void PayloadConvert::addBME(bmeStatus_t value) { #if(HAS_BME) // data value conversions to meet cayenne data type definition // 0.1°C per bit => -3276,7 .. +3276,7 °C int16_t temperature = (int16_t)(value.temperature * 10.0); // 0.1 hPa per bit => 0 .. 6553,6 hPa uint16_t pressure = (uint16_t)(value.pressure * 10); // 0.5% per bit => 0 .. 128 %C uint8_t humidity = (uint8_t)(value.humidity * 2.0); int16_t iaq = (int16_t)(value.iaq); #if (PAYLOAD_ENCODER == 3) buffer[cursor++] = LPP_TEMPERATURE_CHANNEL; #endif buffer[cursor++] = LPP_TEMPERATURE; // 2 bytes 0.1 °C Signed MSB buffer[cursor++] = highByte(temperature); buffer[cursor++] = lowByte(temperature); #if (PAYLOAD_ENCODER == 3) buffer[cursor++] = LPP_BAROMETER_CHANNEL; #endif buffer[cursor++] = LPP_BAROMETER; // 2 bytes 0.1 hPa Unsigned MSB buffer[cursor++] = highByte(pressure); buffer[cursor++] = lowByte(pressure); #if (PAYLOAD_ENCODER == 3) buffer[cursor++] = LPP_HUMIDITY_CHANNEL; #endif buffer[cursor++] = LPP_HUMIDITY; // 1 byte 0.5 % Unsigned buffer[cursor++] = humidity; #if (PAYLOAD_ENCODER == 3) buffer[cursor++] = LPP_AIR_CHANNEL; #endif buffer[cursor++] = LPP_LUMINOSITY; // 2 bytes, 1.0 unsigned buffer[cursor++] = highByte(iaq); buffer[cursor++] = lowByte(iaq); #endif // HAS_BME } void PayloadConvert::addButton(uint8_t value) { #ifdef HAS_BUTTON #if (PAYLOAD_ENCODER == 3) buffer[cursor++] = LPP_BUTTON_CHANNEL; #endif buffer[cursor++] = LPP_DIGITAL_INPUT; buffer[cursor++] = value; #endif // HAS_BUTTON } void PayloadConvert::addTime(time_t value) { #if (PAYLOAD_ENCODER == 4) uint32_t t = (uint32_t)value; uint32_t tx_period = (uint32_t)SENDCYCLE * 2; buffer[cursor++] = 0x03; // set config mask to UTCTime + TXPeriod // UTCTime in seconds buffer[cursor++] = (byte)((t & 0xFF000000) >> 24); buffer[cursor++] = (byte)((t & 0x00FF0000) >> 16); buffer[cursor++] = (byte)((t & 0x0000FF00) >> 8); buffer[cursor++] = (byte)((t & 0x000000FF)); // TXPeriod in seconds buffer[cursor++] = (byte)((tx_period & 0xFF000000) >> 24); buffer[cursor++] = (byte)((tx_period & 0x00FF0000) >> 16); buffer[cursor++] = (byte)((tx_period & 0x0000FF00) >> 8); buffer[cursor++] = (byte)((tx_period & 0x000000FF)); #endif } #endif // PAYLOAD_ENCODER void PayloadConvert::addPM10( float value) { #if (HAS_SDS011) #if (PAYLOAD_ENCODER == 1) // plain char tempBuffer[10+1]; sprintf( tempBuffer, ",%5.1f", value); addChars(tempBuffer, strlen(tempBuffer)); #elif (PAYLOAD_ENCODER == 2 ) // packed writeUint16( (uint16_t) (value*10) ); #elif (PAYLOAD_ENCODER == 3 ) // Cayenne LPP dynamic #error not implemented yet #elif (PAYLOAD_ENCODER == 4 ) // Cayenne LPP packed #error not implemented yet #endif #endif // HAS_SDS011 } void PayloadConvert::addPM25( float value) { #if (HAS_SDS011) #if (PAYLOAD_ENCODER == 1) // plain char tempBuffer[10+1]; sprintf( tempBuffer, ",%5.1f", value); addChars(tempBuffer, strlen(tempBuffer)); #elif (PAYLOAD_ENCODER == 2 ) // packed writeUint16( (uint16_t) (value*10) ); #elif (PAYLOAD_ENCODER == 3 ) // Cayenne LPP dynamic #error not implemented yet #elif (PAYLOAD_ENCODER == 4 ) // Cayenne LPP packed #error not implemented yet #endif #endif // HAS_SDS011 } void PayloadConvert::addChars( char * string, int len) { for (int i=0; i < len; i++) addByte(string[i]); }