/* xsns_53_sml.ino - SML,OBIS,EBUS,RAW,COUNTER interface for Tasmota Created by Gerhard Mutz on 07.10.11. adapted for Tasmota Copyright (C) 2020 Gerhard Mutz and Theo Arends This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ #ifdef USE_SML_M #define XSNS_53 53 // default baudrate of D0 output #define SML_BAUDRATE 9600 // send this every N seconds (for meters that only send data on demand) // not longer supported, use scripting instead //#define SML_SEND_SEQ // debug counter input to led for counter1 and 2 //#define DEBUG_CNT_LED1 2 //#define DEBUG_CNT_LED1 2 // use analog optical counter sensor with AD Converter ADS1115 (not yet functional) //#define ANALOG_OPTO_SENSOR // fototransistor with pullup at A0, A1 of ADS1115 A3 and +3.3V // level and amplification are automatically set #include // use special no wait serial driver, should be always on #define SPECIAL_SS // addresses a bug in meter DWS74 //#define DWS74_BUG // JSON Strings do not translate // max 23 char #define DJ_TPWRIN "Total_in" #define DJ_TPWROUT "Total_out" #define DJ_TPWRCURR "Power_curr" #define DJ_TPWRCURR1 "Power_p1" #define DJ_TPWRCURR2 "Power_p2" #define DJ_TPWRCURR3 "Power_p3" #define DJ_CURR1 "Curr_p1" #define DJ_CURR2 "Curr_p2" #define DJ_CURR3 "Curr_p3" #define DJ_VOLT1 "Volt_p1" #define DJ_VOLT2 "Volt_p2" #define DJ_VOLT3 "Volt_p3" #define DJ_METERNR "Meter_number" #define DJ_METERSID "Meter_id" #define DJ_CSUM "Curr_summ" #define DJ_VAVG "Volt_avg" #define DJ_COUNTER "Count" struct METER_DESC { uint8_t srcpin; uint8_t type; uint16_t flag; int32_t params; char prefix[8]; int8_t trxpin; uint8_t tsecs; char *txmem; uint8_t index; uint8_t max_index; }; // this descriptor method is no longer supported // but still functional for simple meters // use scripting method instead // meter list , enter new meters here //===================================================== #define EHZ161_0 1 #define EHZ161_1 2 #define EHZ363 3 #define EHZH 4 #define EDL300 5 #define Q3B 6 #define COMBO3 7 #define COMBO2 8 #define COMBO3a 9 #define Q3B_V1 10 #define EHZ363_2 11 #define COMBO3b 12 #define WGS_COMBO 13 #define EBZD_G 14 // select this meter #define METER EHZ161_1 #if METER==EHZ161_0 #undef METERS_USED #define METERS_USED 1 struct METER_DESC const meter_desc[METERS_USED]={ [0]={3,'o',0,SML_BAUDRATE,"OBIS",-1,1,0}}; const uint8_t meter[]= "1,1-0:1.8.0*255(@1," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" "1,1-0:2.8.0*255(@1," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" "1,1-0:21.7.0*255(@1," D_TPWRCURR1 ",W," DJ_TPWRCURR1 ",0|" "1,1-0:41.7.0*255(@1," D_TPWRCURR2 ",W," DJ_TPWRCURR2 ",0|" "1,1-0:61.7.0*255(@1," D_TPWRCURR3 ",W," DJ_TPWRCURR3 ",0|" "1,=m 3+4+5 @1," D_TPWRCURR ",W," DJ_TPWRCURR ",0|" "1,1-0:0.0.0*255(@#)," D_METERNR ",," DJ_METERNR ",0"; #endif //===================================================== #if METER==EHZ161_1 #undef METERS_USED #define METERS_USED 1 struct METER_DESC const meter_desc[METERS_USED]={ [0]={3,'o',0,SML_BAUDRATE,"OBIS",-1,1,0}}; const uint8_t meter[]= "1,1-0:1.8.1*255(@1," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" "1,1-0:2.8.1*255(@1," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" "1,=d 2 10 @1," D_TPWRCURR ",W," DJ_TPWRCURR ",0|" "1,1-0:0.0.0*255(@#)," D_METERNR ",," DJ_METERNR ",0"; #endif //===================================================== #if METER==EHZ363 #undef METERS_USED #define METERS_USED 1 struct METER_DESC const meter_desc[METERS_USED]={ [0]={3,'s',0,SML_BAUDRATE,"SML",-1,1,0}}; // 2 Richtungszähler EHZ SML 8 bit 9600 baud, binär const uint8_t meter[]= //0x77,0x07,0x01,0x00,0x01,0x08,0x00,0xff "1,77070100010800ff@1000," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" //0x77,0x07,0x01,0x00,0x02,0x08,0x00,0xff "1,77070100020800ff@1000," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" //0x77,0x07,0x01,0x00,0x10,0x07,0x00,0xff "1,77070100100700ff@1," D_TPWRCURR ",W," DJ_TPWRCURR ",0|" //0x77,0x07,0x01,0x00,0x00,0x00,0x09,0xff "1,77070100000009ff@#," D_METERNR ",," DJ_METERNR ",0"; #endif //===================================================== #if METER==EHZH #undef METERS_USED #define METERS_USED 1 struct METER_DESC const meter_desc[METERS_USED]={ [0]={3,'s',0,SML_BAUDRATE,"SML",-1,1,0}}; // 2 Richtungszähler EHZ SML 8 bit 9600 baud, binär // verbrauch total const uint8_t meter[]= //0x77,0x07,0x01,0x00,0x01,0x08,0x00,0xff "1,77070100010800ff@1000," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" //0x77,0x07,0x01,0x00,0x01,0x08,0x01,0xff "1,77070100020800ff@1000," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" //0x77,0x07,0x01,0x00,0x0f,0x07,0x00,0xff "1,770701000f0700ff@1," D_TPWRCURR ",W," DJ_TPWRCURR ",0"; #endif //===================================================== #if METER==EDL300 #undef METERS_USED #define METERS_USED 1 struct METER_DESC const meter_desc[METERS_USED]={ [0]={3,'s',0,SML_BAUDRATE,"SML",-1,1,0}}; // 2 Richtungszähler EHZ SML 8 bit 9600 baud, binär // verbrauch total const uint8_t meter[]= //0x77,0x07,0x01,0x00,0x01,0x08,0x00,0xff "1,77070100010800ff@1000," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" //0x77,0x07,0x01,0x00,0x01,0x08,0x01,0xff "1,77070100020801ff@1000," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" //0x77,0x07,0x01,0x00,0x0f,0x07,0x00,0xff "1,770701000f0700ff@1," D_TPWRCURR ",W," DJ_TPWRCURR ",0"; #endif #if METER==EBZD_G #undef METERS_USED #define METERS_USED 1 struct METER_DESC const meter_desc[METERS_USED]={ [0]={3,'s',0,SML_BAUDRATE,"strom",-1,1,0}}; const uint8_t meter[]= //0x77,0x07,0x01,0x00,0x01,0x08,0x00,0xff "1,77070100010800ff@1000," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" // .. "1,77070100020800ff@1000," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" //0x77,0x07,0x01,0x00,0x01,0x08,0x01,0xff "1,77070100010801ff@1000," D_TPWRCURR1 ",kWh," DJ_TPWRCURR1 ",4|" //0x77,0x07,0x01,0x00,0x01,0x08,0x02,0xff "1,77070100010802ff@1000," D_TPWRCURR2 ",kWh," DJ_TPWRCURR2 ",4|" // 77 07 01 00 10 07 00 FF "1,77070100100700ff@1," D_TPWRCURR ",W," DJ_TPWRCURR ",0|" // .. "1,77070100600100ff@#," D_METERNR ",," DJ_METERNR ",0"; #endif //===================================================== #if METER==Q3B #undef METERS_USED #define METERS_USED 1 struct METER_DESC const meter_desc[METERS_USED]={ [0]={3,'s',0,SML_BAUDRATE,"SML",-1,1,0}}; const uint8_t meter[]= //0x77,0x07,0x01,0x00,0x01,0x08,0x01,0xff "1,77070100010800ff@1000," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" //0x77,0x07,0x01,0x00,0x02,0x08,0x01,0xff "1,77070100020801ff@1000," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" //0x77,0x07,0x01,0x00,0x01,0x07,0x00,0xff "1,77070100010700ff@1," D_TPWRCURR ",W," DJ_TPWRCURR ",0"; #endif #if METER==COMBO3 // 3 Zähler Beispiel #undef METERS_USED #define METERS_USED 3 struct METER_DESC const meter_desc[METERS_USED]={ [0]={3,'o',0,SML_BAUDRATE,"OBIS",-1,1,0}, // harware serial RX pin [1]={14,'s',0,SML_BAUDRATE,"SML",-1,1,0}, // GPIO14 software serial [2]={4,'o',0,SML_BAUDRATE,"OBIS2",-1,1,0}}; // GPIO4 software serial // 3 Zähler definiert const uint8_t meter[]= "1,1-0:1.8.0*255(@1," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" "1,1-0:2.8.0*255(@1," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" "1,1-0:21.7.0*255(@1," D_TPWRCURR1 ",W," DJ_TPWRCURR1 ",0|" "1,1-0:41.7.0*255(@1," D_TPWRCURR2 ",W," DJ_TPWRCURR2 ",0|" "1,1-0:61.7.0*255(@1," D_TPWRCURR3 ",W," DJ_TPWRCURR3 ",0|" "1,=m 3+4+5 @1," D_TPWRCURR ",W," DJ_TPWRCURR ",0|" "1,1-0:0.0.0*255(@#)," D_METERNR ",," DJ_METERNR ",0|" "2,77070100010800ff@1000," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" "2,77070100020800ff@1000," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" "2,77070100100700ff@1," D_TPWRCURR ",W," DJ_TPWRCURR ",0|" "3,1-0:1.8.1*255(@1," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" "3,1-0:2.8.1*255(@1," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" "3,=d 2 10 @1," D_TPWRCURR ",W," DJ_TPWRCURR ",0|" "3,1-0:0.0.0*255(@#)," D_METERNR ",," DJ_METERNR ",0"; #endif #if METER==COMBO2 // 2 Zähler Beispiel #undef METERS_USED #define METERS_USED 2 struct METER_DESC const meter_desc[METERS_USED]={ [0]={3,'o',0,SML_BAUDRATE,"OBIS1",-1,1,0}, // harware serial RX pin [1]={14,'o',0,SML_BAUDRATE,"OBIS2",-1,1,0}}; // GPIO14 software serial // 2 Zähler definiert const uint8_t meter[]= "1,1-0:1.8.1*255(@1," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" "1,1-0:2.8.1*255(@1," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" "1,=d 2 10 @1," D_TPWRCURR ",W," DJ_TPWRCURR ",0|" "1,1-0:0.0.0*255(@#)," D_METERNR ",," DJ_METERNR ",0|" "2,1-0:1.8.1*255(@1," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" "2,1-0:2.8.1*255(@1," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" "2,=d 6 10 @1," D_TPWRCURR ",W," DJ_TPWRCURR ",0|" "2,1-0:0.0.0*255(@#)," D_METERNR ",," DJ_METERNR ",0"; #endif #if METER==COMBO3a #undef METERS_USED #define METERS_USED 3 struct METER_DESC const meter_desc[METERS_USED]={ [0]={3,'o',0,SML_BAUDRATE,"OBIS1",-1,1,0}, // harware serial RX pin [1]={14,'o',0,SML_BAUDRATE,"OBIS2",-1,1,0}, [2]={1,'o',0,SML_BAUDRATE,"OBIS3",-1,1,0}}; // 3 Zähler definiert const uint8_t meter[]= "1,=h --- Zähler Nr 1 ---|" "1,1-0:1.8.1*255(@1," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" "1,1-0:2.8.1*255(@1," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" "1,=d 2 10 @1," D_TPWRCURR ",W," DJ_TPWRCURR ",0|" "1,1-0:0.0.0*255(@#)," D_METERNR ",," DJ_METERNR ",0|" "2,=h --- Zähler Nr 2 ---|" "2,1-0:1.8.1*255(@1," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" "2,1-0:2.8.1*255(@1," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" "2,=d 6 10 @1," D_TPWRCURR ",W," DJ_TPWRCURR ",0|" "2,1-0:0.0.0*255(@#)," D_METERNR ",," DJ_METERNR ",0|" "3,=h --- Zähler Nr 3 ---|" "3,1-0:1.8.1*255(@1," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" "3,1-0:2.8.1*255(@1," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" "3,=d 10 10 @1," D_TPWRCURR ",W," DJ_TPWRCURR ",0|" "3,1-0:0.0.0*255(@#)," D_METERNR ",," DJ_METERNR ",0"; #endif //===================================================== #if METER==Q3B_V1 #undef METERS_USED #define METERS_USED 1 struct METER_DESC const meter_desc[METERS_USED]={ [0]={3,'o',0,SML_BAUDRATE,"OBIS",-1,1,0}}; const uint8_t meter[]= "1,1-0:1.8.1*255(@1," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" "1,=d 1 10 @1," D_TPWRCURR ",W," DJ_TPWRCURR ",0|" "1,1-0:0.0.0*255(@#)," D_METERNR ",," DJ_METERNR ",0"; #endif //===================================================== #if METER==EHZ363_2 #undef METERS_USED #define METERS_USED 1 struct METER_DESC const meter_desc[METERS_USED]={ [0]={3,'s',0,SML_BAUDRATE,"SML",-1,1,0}}; // 2 direction meter EHZ SML 8 bit 9600 baud, binary const uint8_t meter[]= //0x77,0x07,0x01,0x00,0x01,0x08,0x00,0xff "1,77070100010800ff@1000," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" //0x77,0x07,0x01,0x00,0x02,0x08,0x00,0xff "1,77070100020800ff@1000," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" //0x77,0x07,0x01,0x00,0x01,0x08,0x01,0xff "1,77070100010801ff@1000," D_TPWRCURR1 ",kWh," DJ_TPWRCURR1 ",4|" //0x77,0x07,0x01,0x00,0x01,0x08,0x02,0xff "1,77070100010802ff@1000," D_TPWRCURR2 ",kWh," DJ_TPWRCURR2 ",4|" //0x77,0x07,0x01,0x00,0x10,0x07,0x00,0xff "1,77070100100700ff@1," D_TPWRCURR ",W," DJ_TPWRCURR ",0|" //0x77,0x07,0x01,0x00,0x00,0x00,0x09,0xff "1,77070100000009ff@#," D_METERNR ",," DJ_METERNR ",0"; #endif // example OBIS power meter + gas and water counter #if METER==COMBO3b #undef METERS_USED #define METERS_USED 3 struct METER_DESC const meter_desc[METERS_USED]={ [0]={3,'o',0,SML_BAUDRATE,"OBIS",-1,1,0}, // harware serial RX pin [1]={14,'c',0,50,"Gas"}, // GPIO14 gas counter [2]={1,'c',0,10,"Wasser"}}; // water counter // 3 meters defined const uint8_t meter[]= "1,1-0:1.8.1*255(@1," D_TPWRIN ",kWh," DJ_TPWRIN ",4|" "1,1-0:2.8.1*255(@1," D_TPWROUT ",kWh," DJ_TPWROUT ",4|" "1,=d 2 10 @1," D_TPWRCURR ",W," DJ_TPWRCURR ",0|" "1,1-0:0.0.0*255(@#)," D_METERNR ",," DJ_METERNR ",0|" // with counters the comparison string must be exactly this string "2,1-0:1.8.0*255(@100," D_GasIN ",cbm," DJ_COUNTER ",2|" "3,1-0:1.8.0*255(@100," D_H2oIN ",cbm," DJ_COUNTER ",2"; #endif #if METER==WGS_COMBO #undef METERS_USED #define METERS_USED 3 struct METER_DESC const meter_desc[METERS_USED]={ [0]={1,'c',0,10,"H20",-1,1,0}, // GPIO1 water counter [1]={4,'c',0,50,"GAS",-1,1,0}, // GPIO4 gas counter [2]={3,'s',0,SML_BAUDRATE,"SML",-1,1,0}}; // SML harware serial RX pin const uint8_t meter[]= //----------------------------Wasserzähler--sensor53 c1------------------------------------ //"1,=h==================|" "1,1-0:1.8.0*255(@10000," D_H2oIN ",cbm," DJ_COUNTER ",4|" // 1 //----------------------------Gaszähler-----sensor53 c2------------------------------------ // bei gaszählern (countern) muss der Vergleichsstring so aussehen wie hier "2,=h==================|" "2,1-0:1.8.0*255(@100," D_GasIN ",cbm," DJ_COUNTER ",3|" // 2 //----------------------------Stromzähler-EHZ363W5--sensor53 d0---------------------------- "3,=h==================|" //0x77,0x07,0x01,0x00,0x01,0x08,0x00,0xff "3,77070100010800ff@1000," D_TPWRIN ",kWh," DJ_TPWRIN ",3|" // 3 Zählerstand Total "3,=h==================|" //0x77,0x07,0x01,0x00,0x10,0x07,0x00,0xff "3,77070100100700ff@1," D_TPWRCURR ",W," DJ_TPWRCURR ",2|" // 4 Aktuelle Leistung "3,=h -------------------------------|" "3,=m 10+11+12 @100," D_StL1L2L3 ",A," DJ_CSUM ",2|" // 5 Summe Aktuelle Ströme //"3,=h -------------------------------|" "3,=m 13+14+15/#3 @100," D_SpL1L2L3 ",V," DJ_VAVG ",2|" // 6 Mittelwert Spannungen "3,=h==================|" //0x77,0x07,0x01,0x00,0x24,0x07,0x00,0xff "3,77070100240700ff@1," D_TPWRCURR1 ",W," DJ_TPWRCURR1 ",2|" // 7 Wirkleistung L1 //0x77,0x07,0x01,0x00,0x38,0x07,0x00,0xff "3,77070100380700ff@1," D_TPWRCURR2 ",W," DJ_TPWRCURR2 ",2|" // 8 Wirkleistung L2 //0x77,0x07,0x01,0x00,0x4c,0x07,0x00,0xff "3,770701004c0700ff@1," D_TPWRCURR3 ",W," DJ_TPWRCURR3 ",2|" // 9 Wirkleistung L3 "3,=h -------------------------------|" //0x77,0x07,0x01,0x00,0x1f,0x07,0x00,0xff "3,770701001f0700ff@100," D_Strom_L1 ",A," DJ_CURR1 ",2|" // 10 Strom L1 //0x77,0x07,0x01,0x00,0x33,0x07,0x00,0xff "3,77070100330700ff@100," D_Strom_L2 ",A," DJ_CURR2 ",2|" // 11 Strom L2 //0x77,0x07,0x01,0x00,0x47,0x07,0x00,0xff "3,77070100470700ff@100," D_Strom_L3 ",A," DJ_CURR3 ",2|" // 12 Strom L3 "3,=h -------------------------------|" //0x77,0x07,0x01,0x00,0x20,0x07,0x00,0xff "3,77070100200700ff@100," D_Spannung_L1 ",V," DJ_VOLT1 ",2|" // 13 Spannung L1 //0x77,0x07,0x01,0x00,0x34,0x07,0x00,0xff "3,77070100340700ff@100," D_Spannung_L2 ",V," DJ_VOLT2 ",2|" // 14 Spannung L2 //0x77,0x07,0x01,0x00,0x48,0x07,0x00,0xff "3,77070100480700ff@100," D_Spannung_L3 ",V," DJ_VOLT3 ",2|" // 15 Spannung L3 "3,=h==================|" //0x77,0x07,0x01,0x00,0x00,0x00,0x09,0xff "3,77070100000009ff@#," D_METERSID ",," DJ_METERSID ",0|" // 16 Service ID "3,=h--------------------------------"; // letzte Zeile #endif // this driver uses double because meter vars would not fit in float //===================================================== // median filter eliminates outliers, but uses much RAM and CPU cycles // 672 bytes extra RAM with SML_MAX_VARS = 16 // default compile on, but must be enabled by descriptor flag 16 // may be undefined if RAM must be saved #define USE_SML_MEDIAN_FILTER // max number of vars , may be adjusted #ifndef SML_MAX_VARS #define SML_MAX_VARS 20 #endif // max number of meters , may be adjusted #define MAX_METERS 5 double meter_vars[SML_MAX_VARS]; // calulate deltas #define MAX_DVARS MAX_METERS*2 double dvalues[MAX_DVARS]; uint32_t dtimes[MAX_DVARS]; uint8_t meters_used; struct METER_DESC const *meter_desc_p; const uint8_t *meter_p; uint8_t meter_spos[MAX_METERS]; // software serial pointers TasmotaSerial *meter_ss[MAX_METERS]; // serial buffers, may be made larger depending on telegram lenght #define SML_BSIZ 48 uint8_t smltbuf[MAX_METERS][SML_BSIZ]; // meter nr as string #define METER_ID_SIZE 24 char meter_id[MAX_METERS][METER_ID_SIZE]; #define EBUS_SYNC 0xaa #define EBUS_ESC 0xa9 uint8_t sml_send_blocks; uint8_t sml_100ms_cnt; uint8_t sml_desc_cnt; #ifdef USE_SML_MEDIAN_FILTER // median filter, should be odd size #define MEDIAN_SIZE 5 struct SML_MEDIAN_FILTER { double buffer[MEDIAN_SIZE]; int8_t index; } sml_mf[SML_MAX_VARS]; #ifndef FLT_MAX #define FLT_MAX 99999999 #endif double sml_median_array(double *array,uint8_t len) { uint8_t ind[len]; uint8_t mind=0,index=0,flg; double min=FLT_MAX; for (uint8_t hcnt=0; hcntbuffer[mf->index]=in; mf->index++; if (mf->index>=MEDIAN_SIZE) mf->index=0; return sml_median_array(mf->buffer,MEDIAN_SIZE); /* // sort list and take median memmove(tbuff,mf->buffer,sizeof(tbuff)); for (byte ocnt=0; ocnttbuff[count+1]) { tmp=tbuff[count]; tbuff[count]=tbuff[count+1]; tbuff[count+1]=tmp; flag=1; } } if (!flag) break; } return tbuff[MEDIAN_SIZE/2]; */ } #endif #ifdef ANALOG_OPTO_SENSOR // sensor over ADS1115 with i2c Bus uint8_t ads1115_up; // ads1115 driver #define SAMPLE_BIT (0x8000) #define ADS1115_COMP_QUEUE_SHIFT 0 #define ADS1115_COMP_LATCH_SHIFT 2 #define ADS1115_COMP_POLARITY_SHIFT 3 #define ADS1115_COMP_MODE_SHIFT 4 #define ADS1115_DATA_RATE_SHIFT 5 #define ADS1115_MODE_SHIFT 8 #define ADS1115_PGA_SHIFT 9 #define ADS1115_MUX_SHIFT 12 enum ads1115_comp_queue { ADS1115_COMP_QUEUE_AFTER_ONE = 0, ADS1115_COMP_QUEUE_AFTER_TWO = 0x1 << ADS1115_COMP_QUEUE_SHIFT, ADS1115_COMP_QUEUE_AFTER_FOUR = 0x2 << ADS1115_COMP_QUEUE_SHIFT, ADS1115_COMP_QUEUE_DISABLE = 0x3 << ADS1115_COMP_QUEUE_SHIFT, ADS1115_COMP_QUEUE_MASK = 0x3 << ADS1115_COMP_QUEUE_SHIFT, }; enum ads1115_comp_latch { ADS1115_COMP_LATCH_NO = 0, ADS1115_COMP_LATCH_YES = 1 << ADS1115_COMP_LATCH_SHIFT, ADS1115_COMP_LATCH_MASK = 1 << ADS1115_COMP_LATCH_SHIFT, }; enum ads1115_comp_polarity { ADS1115_COMP_POLARITY_ACTIVE_LOW = 0, ADS1115_COMP_POLARITY_ACTIVE_HIGH = 1 << ADS1115_COMP_POLARITY_SHIFT, ADS1115_COMP_POLARITY_MASK = 1 << ADS1115_COMP_POLARITY_SHIFT, }; enum ads1115_comp_mode { ADS1115_COMP_MODE_WINDOW = 0, ADS1115_COMP_MODE_HYSTERESIS = 1 << ADS1115_COMP_MODE_SHIFT, ADS1115_COMP_MODE_MASK = 1 << ADS1115_COMP_MODE_SHIFT, }; enum ads1115_data_rate { ADS1115_DATA_RATE_8_SPS = 0, ADS1115_DATA_RATE_16_SPS = 0x1 << ADS1115_DATA_RATE_SHIFT, ADS1115_DATA_RATE_32_SPS = 0x2 << ADS1115_DATA_RATE_SHIFT, ADS1115_DATA_RATE_64_SPS = 0x3 << ADS1115_DATA_RATE_SHIFT, ADS1115_DATA_RATE_128_SPS = 0x4 << ADS1115_DATA_RATE_SHIFT, ADS1115_DATA_RATE_250_SPS = 0x5 << ADS1115_DATA_RATE_SHIFT, ADS1115_DATA_RATE_475_SPS = 0x6 << ADS1115_DATA_RATE_SHIFT, ADS1115_DATA_RATE_860_SPS = 0x7 << ADS1115_DATA_RATE_SHIFT, ADS1115_DATA_RATE_MASK = 0x7 << ADS1115_DATA_RATE_SHIFT, }; enum ads1115_mode { ADS1115_MODE_CONTINUOUS = 0, ADS1115_MODE_SINGLE_SHOT = 1 << ADS1115_MODE_SHIFT, ADS1115_MODE_MASK = 1 << ADS1115_MODE_SHIFT, }; enum ads1115_pga { ADS1115_PGA_TWO_THIRDS = 0, //±6.144 V ADS1115_PGA_ONE = 0x1 << ADS1115_PGA_SHIFT, //±4.096 V ADS1115_PGA_TWO = 0x2 << ADS1115_PGA_SHIFT, //±2.048 V ADS1115_PGA_FOUR = 0x3 << ADS1115_PGA_SHIFT, //±1.024 V ADS1115_PGA_EIGHT = 0x4 << ADS1115_PGA_SHIFT, //±0.512 V ADS1115_PGA_SIXTEEN = 0x5 << ADS1115_PGA_SHIFT, //±0.256 V ADS1115_PGA_MASK = 0x7 << ADS1115_PGA_SHIFT, }; enum ads1115_mux { ADS1115_MUX_DIFF_AIN0_AIN1 = 0, ADS1115_MUX_DIFF_AIN0_AIN3 = 0x1 << ADS1115_MUX_SHIFT, ADS1115_MUX_DIFF_AIN1_AIN3 = 0x2 << ADS1115_MUX_SHIFT, ADS1115_MUX_DIFF_AIN2_AIN3 = 0x3 << ADS1115_MUX_SHIFT, ADS1115_MUX_GND_AIN0 = 0x4 << ADS1115_MUX_SHIFT, ADS1115_MUX_GND_AIN1 = 0x5 << ADS1115_MUX_SHIFT, ADS1115_MUX_GND_AIN2 = 0x6 << ADS1115_MUX_SHIFT, ADS1115_MUX_GND_AIN3 = 0x7 << ADS1115_MUX_SHIFT, ADS1115_MUX_MASK = 0x7 << ADS1115_MUX_SHIFT, }; class ADS1115 { public: ADS1115(uint8_t address = 0x48); void begin(); uint8_t trigger_sample(); uint8_t reset(); bool is_sample_in_progress(); int16_t read_sample(); float sample_to_float(int16_t val); float read_sample_float(); void set_comp_queue(enum ads1115_comp_queue val) { set_config(val, ADS1115_COMP_QUEUE_MASK); } void set_comp_latching(enum ads1115_comp_latch val) { set_config(val, ADS1115_COMP_LATCH_MASK); } void set_comp_polarity(enum ads1115_comp_polarity val) { set_config(val, ADS1115_COMP_POLARITY_MASK); } void set_comp_mode(enum ads1115_comp_mode val) { set_config(val, ADS1115_COMP_MODE_MASK); } void set_data_rate(enum ads1115_data_rate val) { set_config(val, ADS1115_DATA_RATE_MASK); } void set_mode(enum ads1115_mode val) { set_config(val, ADS1115_MODE_MASK); } void set_pga(enum ads1115_pga val) { set_config(val, ADS1115_PGA_MASK); m_voltage_range = val >> ADS1115_PGA_SHIFT; } void set_mux(enum ads1115_mux val) { set_config(val, ADS1115_MUX_MASK); } private: void set_config(uint16_t val, uint16_t mask) { m_config = (m_config & ~mask) | val; } uint8_t write_register(uint8_t reg, uint16_t val); uint16_t read_register(uint8_t reg); uint8_t m_address; uint16_t m_config; int m_voltage_range; }; enum ads1115_register { ADS1115_REGISTER_CONVERSION = 0, ADS1115_REGISTER_CONFIG = 1, ADS1115_REGISTER_LOW_THRESH = 2, ADS1115_REGISTER_HIGH_THRESH = 3, }; #define FACTOR 32768.0 static float ranges[] = { 6.144 / FACTOR, 4.096 / FACTOR, 2.048 / FACTOR, 1.024 / FACTOR, 0.512 / FACTOR, 0.256 / FACTOR}; ADS1115::ADS1115(uint8_t address) { m_address = address; m_config = ADS1115_COMP_QUEUE_AFTER_ONE | ADS1115_COMP_LATCH_NO | ADS1115_COMP_POLARITY_ACTIVE_LOW | ADS1115_COMP_MODE_WINDOW | ADS1115_DATA_RATE_128_SPS | ADS1115_MODE_SINGLE_SHOT | ADS1115_MUX_GND_AIN0; set_pga(ADS1115_PGA_ONE); } uint8_t ADS1115::write_register(uint8_t reg, uint16_t val) { Wire.beginTransmission(m_address); Wire.write(reg); Wire.write(val>>8); Wire.write(val & 0xFF); return Wire.endTransmission(); } uint16_t ADS1115::read_register(uint8_t reg) { Wire.beginTransmission(m_address); Wire.write(reg); Wire.endTransmission(); uint8_t result = Wire.requestFrom((int)m_address, 2, 1); if (result != 2) { return 0; } uint16_t val; val = Wire.read() << 8; val |= Wire.read(); return val; } void ADS1115::begin() { Wire.begin(); } uint8_t ADS1115::trigger_sample() { return write_register(ADS1115_REGISTER_CONFIG, m_config | SAMPLE_BIT); } uint8_t ADS1115::reset() { Wire.beginTransmission(0); Wire.write(0x6); return Wire.endTransmission(); } bool ADS1115::is_sample_in_progress() { uint16_t val = read_register(ADS1115_REGISTER_CONFIG); return (val & SAMPLE_BIT) == 0; } int16_t ADS1115::read_sample() { return read_register(ADS1115_REGISTER_CONVERSION); } float ADS1115::sample_to_float(int16_t val) { return val * ranges[m_voltage_range]; } float ADS1115::read_sample_float() { return sample_to_float(read_sample()); } ADS1115 adc; void ADS1115_init(void) { ads1115_up=0; if (!i2c_flg) return; adc.begin(); adc.set_data_rate(ADS1115_DATA_RATE_128_SPS); adc.set_mode(ADS1115_MODE_CONTINUOUS); adc.set_mux(ADS1115_MUX_DIFF_AIN0_AIN3); adc.set_pga(ADS1115_PGA_TWO); int16_t val = adc.read_sample(); ads1115_up=1; } #endif char sml_start; uint8_t dump2log=0; #define SML_SAVAILABLE Serial_available() #define SML_SREAD Serial_read() #define SML_SPEAK Serial_peek() bool Serial_available() { uint8_t num=dump2log&7; if (num<1 || num>meters_used) num=1; return meter_ss[num-1]->available(); } uint8_t Serial_read() { uint8_t num=dump2log&7; if (num<1 || num>meters_used) num=1; return meter_ss[num-1]->read(); } uint8_t Serial_peek() { uint8_t num=dump2log&7; if (num<1 || num>meters_used) num=1; return meter_ss[num-1]->peek(); } uint8_t sml_logindex; void Dump2log(void) { int16_t index=0,hcnt=0; uint32_t d_lastms; uint8_t dchars[16]; //if (!SML_SAVAILABLE) return; if (dump2log&8) { // combo mode while (SML_SAVAILABLE) { log_data[index]=':'; index++; log_data[index]=' '; index++; d_lastms=millis(); while ((millis()-d_lastms)<40) { if (SML_SAVAILABLE) { uint8_t c=SML_SREAD; sprintf(&log_data[index],"%02x ",c); dchars[hcnt]=c; index+=3; hcnt++; if (hcnt>15) { // line complete, build asci chars log_data[index]='='; index++; log_data[index]='>'; index++; log_data[index]=' '; index++; for (uint8_t ccnt=0; ccnt<16; ccnt++) { if (isprint(dchars[ccnt])) { log_data[index]=dchars[ccnt]; } else { log_data[index]=' '; } index++; } break; } } } if (index>0) { log_data[index]=0; AddLog(LOG_LEVEL_INFO); index=0; hcnt=0; } } } else { if (meter_desc_p[(dump2log&7)-1].type=='o') { // obis while (SML_SAVAILABLE) { char c=SML_SREAD&0x7f; if (c=='\n' || c=='\r') { log_data[sml_logindex]=0; AddLog(LOG_LEVEL_INFO); sml_logindex=2; log_data[0]=':'; log_data[1]=' '; break; } log_data[sml_logindex]=c; if (sml_logindex2) { log_data[index]=0; AddLog(LOG_LEVEL_INFO); } } } } #ifdef ED300L uint8_t sml_status[MAX_METERS]; uint8_t g_mindex; #endif // skip sml entries uint8_t *skip_sml(uint8_t *cp,int16_t *res) { uint8_t len,len1,type; len=*cp&0xf; type=*cp&0x70; if (type==0x70) { // list, skip entries // list cp++; while (len--) { len1=*cp&0x0f; cp+=len1; } *res=0; } else { // skip len *res=(signed char)*(cp+1); cp+=len; } return cp; } // get sml binary value // not defined for unsigned >0x7fff ffff ffff ffff (should never happen) double sml_getvalue(unsigned char *cp,uint8_t index) { uint8_t len,unit,type; int16_t scaler,result; int64_t value; double dval; // scan for values // check status #ifdef ED300L unsigned char *cpx=cp-5; // decode OBIS 0180 amd extract direction info if (*cp==0x64 && *cpx==0 && *(cpx+1)==0x01 && *(cpx+2)==0x08 && *(cpx+3)==0) { sml_status[g_mindex]=*(cp+3); } #endif cp=skip_sml(cp,&result); // check time cp=skip_sml(cp,&result); // check unit cp=skip_sml(cp,&result); // check scaler cp=skip_sml(cp,&result); scaler=result; // get value type=*cp&0x70; len=*cp&0x0f; cp++; if (type==0x50 || type==0x60) { // shift into 64 bit uint64_t uvalue=0; uint8_t nlen=len; while (--nlen) { uvalue<<=8; uvalue|=*cp++; } if (type==0x50) { // signed switch (len-1) { case 1: // byte value=(signed char)uvalue; break; case 2: // signed 16 bit #ifdef DWS74_BUG if (scaler==-2) { value=(uint32_t)uvalue; } else { value=(int16_t)uvalue; } #else value=(int16_t)uvalue; #endif break; case 3: case 4: // signed 32 bit value=(int32_t)uvalue; break; case 5: case 6: case 7: case 8: // signed 64 bit value=(int64_t)uvalue; break; } } else { // unsigned value=uvalue; } } else { if (!(type&0xf0)) { // octet string serial number // no coding found on the net // up to now 2 types identified on Hager if (len==9) { // serial number on hager => 24 bit - 24 bit cp++; uint32_t s1,s2; s1=*cp<<16|*(cp+1)<<8|*(cp+2); cp+=4; s2=*cp<<16|*(cp+1)<<8|*(cp+2); sprintf(&meter_id[index][0],"%u-%u",s1,s2); } else { // server id on hager char *str=&meter_id[index][0]; for (type=0; type= 'A' && chr <= 'F') rVal = chr + 10 - 'A'; } return rVal; } uint8_t sb_counter; // need double precision in this driver double CharToDouble(const char *str) { // simple ascii to double, because atof or strtod are too large char strbuf[24]; strlcpy(strbuf, str, sizeof(strbuf)); char *pt = strbuf; while ((*pt != '\0') && isblank(*pt)) { pt++; } // Trim leading spaces signed char sign = 1; if (*pt == '-') { sign = -1; } if (*pt == '-' || *pt=='+') { pt++; } // Skip any sign double left = 0; if (*pt != '.') { left = atoi(pt); // Get left part while (isdigit(*pt)) { pt++; } // Skip number } double right = 0; if (*pt == '.') { pt++; right = atoi(pt); // Decimal part while (isdigit(*pt)) { pt++; right /= 10.0; } } double result = left + right; if (sign < 0) { return -result; // Add negative sign } return result; } // remove ebus escapes void ebus_esc(uint8_t *ebus_buffer, unsigned char len) { short count,count1; for (count=0; countavailable()) { meter_ss[meters]->read(); } } void sml_shift_in(uint32_t meters,uint32_t shard) { uint32_t count; if (meter_desc_p[meters].type!='e' && meter_desc_p[meters].type!='m' && meter_desc_p[meters].type!='M' && meter_desc_p[meters].type!='p') { // shift in for (count=0; countread(); if (meter_desc_p[meters].type=='o') { smltbuf[meters][SML_BSIZ-1]=iob&0x7f; } else if (meter_desc_p[meters].type=='s') { smltbuf[meters][SML_BSIZ-1]=iob; } else if (meter_desc_p[meters].type=='r') { smltbuf[meters][SML_BSIZ-1]=iob; } else if (meter_desc_p[meters].type=='m' || meter_desc_p[meters].type=='M') { smltbuf[meters][meter_spos[meters]] = iob; meter_spos[meters]++; if (meter_spos[meters]>=9) { SML_Decode(meters); sml_empty_receiver(meters); meter_spos[meters]=0; } } else if (meter_desc_p[meters].type=='p') { smltbuf[meters][meter_spos[meters]] = iob; meter_spos[meters]++; if (meter_spos[meters]>=7) { SML_Decode(meters); sml_empty_receiver(meters); meter_spos[meters]=0; } } else { if (iob==EBUS_SYNC) { // should be end of telegramm // QQ,ZZ,PB,SB,NN ..... CRC, ACK SYNC if (meter_spos[meters]>4+5) { // get telegramm lenght uint8_t tlen=smltbuf[meters][4]+5; // test crc if (smltbuf[meters][tlen]=ebus_CalculateCRC(smltbuf[meters],tlen)) { ebus_esc(smltbuf[meters],tlen); SML_Decode(meters); } else { // crc error //AddLog_P(LOG_LEVEL_INFO, PSTR("ebus crc error")); } } meter_spos[meters]=0; return; } smltbuf[meters][meter_spos[meters]] = iob; meter_spos[meters]++; if (meter_spos[meters]>=SML_BSIZ) { meter_spos[meters]=0; } } sb_counter++; if (meter_desc_p[meters].type!='e' && meter_desc_p[meters].type!='m' && meter_desc_p[meters].type!='M' && meter_desc_p[meters].type!='p') SML_Decode(meters); } // polled every 50 ms void SML_Poll(void) { uint32_t meters; for (meters=0; metersavailable()) { sml_shift_in(meters,0); } } } } void SML_Decode(uint8_t index) { const char *mp=(const char*)meter_p; int8_t mindex; uint8_t *cp; uint8_t dindex=0,vindex=0; delay(0); while (mp != NULL) { // check list of defines // new section mindex=((*mp)&7)-1; if (mindex<0 || mindex>=meters_used) mindex=0; mp+=2; if (*mp=='=' && *(mp+1)=='h') { mp = strchr(mp, '|'); if (mp) mp++; continue; } if (index!=mindex) goto nextsect; // start of serial source buffer cp=&smltbuf[mindex][0]; // compare if (*mp=='=') { // calculated entry, check syntax mp++; // do math m 1+2+3 if (*mp=='m' && !sb_counter) { // only every 256 th byte // else it would be calculated every single serial byte mp++; while (*mp==' ') mp++; // 1. index double dvar; uint8_t opr; uint32_t ind; ind=atoi(mp); while (*mp>='0' && *mp<='9') mp++; if (ind<1 || ind>SML_MAX_VARS) ind=1; dvar=meter_vars[ind-1]; for (uint8_t p=0;p<5;p++) { if (*mp=='@') { // store result meter_vars[vindex]=dvar; mp++; SML_Immediate_MQTT((const char*)mp,vindex,mindex); break; } opr=*mp; mp++; uint8_t iflg=0; if (*mp=='#') { iflg=1; mp++; } ind=atoi(mp); while (*mp>='0' && *mp<='9') mp++; if (ind<1 || ind>SML_MAX_VARS) ind=1; switch (opr) { case '+': if (iflg) dvar+=ind; else dvar+=meter_vars[ind-1]; break; case '-': if (iflg) dvar-=ind; else dvar-=meter_vars[ind-1]; break; case '*': if (iflg) dvar*=ind; else dvar*=meter_vars[ind-1]; break; case '/': if (iflg) dvar/=ind; else dvar/=meter_vars[ind-1]; break; } while (*mp==' ') mp++; if (*mp=='@') { // store result meter_vars[vindex]=dvar; mp++; SML_Immediate_MQTT((const char*)mp,vindex,mindex); break; } } } else if (*mp=='d') { // calc deltas d ind 10 (eg every 10 secs) if (dindex='0' && *mp<='9') mp++; if (ind<1 || ind>SML_MAX_VARS) ind=1; uint32_t delay=atoi(mp)*1000; uint32_t dtime=millis()-dtimes[dindex]; if (dtime>delay) { // calc difference dtimes[dindex]=millis(); double vdiff = meter_vars[ind-1]-dvalues[dindex]; dvalues[dindex]=meter_vars[ind-1]; meter_vars[vindex]=(double)360000.0*vdiff/((double)dtime/10000.0); mp=strchr(mp,'@'); if (mp) { mp++; SML_Immediate_MQTT((const char*)mp,vindex,mindex); } } dindex++; } } else if (*mp=='h') { // skip html tag line mp = strchr(mp, '|'); if (mp) mp++; continue; } } else { // compare value uint8_t found=1; uint32_t ebus_dval=99; float mbus_dval=99; while (*mp!='@') { if (meter_desc_p[mindex].type=='o' || meter_desc_p[mindex].type=='c') { if (*mp++!=*cp++) { found=0; } } else { if (meter_desc_p[mindex].type=='s') { // sml uint8_t val = hexnibble(*mp++) << 4; val |= hexnibble(*mp++); if (val!=*cp++) { found=0; } } else { // ebus mbus pzem or raw // XXHHHHSSUU if (*mp=='x' && *(mp+1)=='x') { //ignore mp+=2; cp++; } else if (!strncmp(mp,"UUuuUUuu",8)) { uint32_t val= (cp[0]<<24)|(cp[1]<<16)|(cp[2]<<8)|(cp[3]<<0); ebus_dval=val; mbus_dval=val; mp+=8; cp+=4; } else if (*mp=='U' && *(mp+1)=='U' && *(mp+2)=='u' && *(mp+3)=='u'){ uint16_t val = cp[1]|(cp[0]<<8); mbus_dval=val; ebus_dval=val; mp+=4; cp+=2; } else if (!strncmp(mp,"SSssSSss",8)) { int32_t val= (cp[0]<<24)|(cp[1]<<16)|(cp[2]<<8)|(cp[3]<<0); ebus_dval=val; mbus_dval=val; mp+=8; cp+=4; } else if (*mp=='u' && *(mp+1)=='u' && *(mp+2)=='U' && *(mp+3)=='U'){ uint16_t val = cp[0]|(cp[1]<<8); mbus_dval=val; ebus_dval=val; mp+=4; cp+=2; } else if (*mp=='u' && *(mp+1)=='u') { uint8_t val = *cp++; mbus_dval=val; ebus_dval=val; mp+=2; } else if (*mp=='s' && *(mp+1)=='s' && *(mp+2)=='S' && *(mp+3)=='S') { int16_t val = *cp|(*(cp+1)<<8); mbus_dval=val; ebus_dval=val; mp+=4; cp+=2; } else if (*mp=='S' && *(mp+1)=='S' && *(mp+2)=='s' && *(mp+3)=='s') { int16_t val = cp[1]|(cp[0]<<8); mbus_dval=val; ebus_dval=val; mp+=4; cp+=2; } else if (*mp=='s' && *(mp+1)=='s') { int8_t val = *cp++; mbus_dval=val; ebus_dval=val; mp+=2; } else if (!strncmp(mp,"ffffffff",8)) { uint32_t val= (cp[0]<<24)|(cp[1]<<16)|(cp[2]<<8)|(cp[3]<<0); float *fp=(float*)&val; ebus_dval=*fp; mbus_dval=*fp; mp+=8; cp+=4; } else if (!strncmp(mp,"FFffFFff",8)) { // reverse word float uint32_t val= (cp[1]<<0)|(cp[0]<<8)|(cp[3]<<16)|(cp[2]<<24); float *fp=(float*)&val; ebus_dval=*fp; mbus_dval=*fp; mp+=8; cp+=4; } else if (!strncmp(mp,"eeeeee",6)) { uint32_t val=(cp[0]<<16)|(cp[1]<<8)|(cp[2]<<0); mbus_dval=val; mp+=6; cp+=3; } else if (!strncmp(mp,"vvvvvv",6)) { mbus_dval=(float)((cp[0]<<8)|(cp[1])) + ((float)cp[2]/10.0); mp+=6; cp+=3; } else if (!strncmp(mp,"cccccc",6)) { mbus_dval=(float)((cp[0]<<8)|(cp[1])) + ((float)cp[2]/100.0); mp+=6; cp+=3; } else if (!strncmp(mp,"pppp",4)) { mbus_dval=(float)((cp[0]<<8)|cp[1]); mp+=4; cp+=2; } else { uint8_t val = hexnibble(*mp++) << 4; val |= hexnibble(*mp++); if (val!=*cp++) { found=0; } } } } } if (found) { // matches, get value mp++; #ifdef ED300L g_mindex=mindex; #endif if (*mp=='#') { // get string value mp++; if (meter_desc_p[mindex].type=='o') { for (uint8_t p=0;p>=shift; ebus_dval&=1; mp+=2; } if (*mp=='i') { // mbus index mp++; uint8_t mb_index=strtol((char*)mp,(char**)&mp,10); if (mb_index!=meter_desc_p[mindex].index) { goto nextsect; } uint16_t crc = MBUS_calculateCRC(&smltbuf[mindex][0],7); if (lowByte(crc)!=smltbuf[mindex][7]) goto nextsect; if (highByte(crc)!=smltbuf[mindex][8]) goto nextsect; dval=mbus_dval; //AddLog_P2(LOG_LEVEL_INFO, PSTR(">> %s"),mp); mp++; } else { if (meter_desc_p[mindex].type=='p') { uint8_t crc = SML_PzemCrc(&smltbuf[mindex][0],6); if (crc!=smltbuf[mindex][6]) goto nextsect; dval=mbus_dval; } else { dval=ebus_dval; } } } #ifdef USE_SML_MEDIAN_FILTER if (meter_desc_p[mindex].flag&16) { meter_vars[vindex]=sml_median(&sml_mf[vindex],dval); } else { meter_vars[vindex]=dval; } #else meter_vars[vindex]=dval; #endif //AddLog_P2(LOG_LEVEL_INFO, PSTR(">> %s"),mp); // get scaling factor double fac=CharToDouble((char*)mp); meter_vars[vindex]/=fac; SML_Immediate_MQTT((const char*)mp,vindex,mindex); } } } nextsect: // next section if (vindex=meters_used) lastmind=0; while (mp != NULL) { // setup sections mindex=((*mp)&7)-1; if (mindex<0 || mindex>=meters_used) mindex=0; mp+=2; if (*mp=='=' && *(mp+1)=='h') { mp+=2; // html tag if (json) { mp = strchr(mp, '|'); if (mp) mp++; continue; } // web ui export uint8_t i; for (i=0;isml_counters[index].sml_debounce) { RtcSettings.pulse_counter[index]++; InjektCounterValue(sml_counters[index].sml_cnt_old_state,RtcSettings.pulse_counter[index]); } } else { // rising edge sml_counters[index].sml_counter_ltime=millis(); } } void SML_CounterUpd1(void) { SML_CounterUpd(0); } void SML_CounterUpd2(void) { SML_CounterUpd(1); } void SML_CounterUpd3(void) { SML_CounterUpd(2); } void SML_CounterUpd4(void) { SML_CounterUpd(3); } #ifdef USE_SCRIPT struct METER_DESC script_meter_desc[MAX_METERS]; uint8_t *script_meter; #endif #ifndef METER_DEF_SIZE #define METER_DEF_SIZE 3000 #endif bool Gpio_used(uint8_t gpiopin) { #ifdef LEGACY_GPIO_ARRAY for (uint16_t i=0;i 0)) { return true; } #endif return false; } void SML_Init(void) { meters_used=METERS_USED; meter_desc_p=meter_desc; meter_p=meter; sml_desc_cnt=0; for (uint32_t cnt=0;cntM",-2,0); if (meter_script==99) { // use script definition if (script_meter) free(script_meter); script_meter=0; uint8_t *tp=0; uint16_t index=0; uint8_t section=0; uint8_t srcpin=0; char *lp=glob_script_mem.scriptptr; sml_send_blocks=0; while (lp) { if (!section) { if (*lp=='>' && *(lp+1)=='M') { lp+=2; meters_used=strtol(lp,0,10); section=1; uint32_t mlen=0; for (uint32_t cnt=0;cnt') { if (*(tp-1)=='|') *(tp-1)=0; break; } if (*lp=='+') { // add descriptor +1,1,c,0,10,H20 //toLogEOL(">>",lp); lp++; index=*lp&7; lp+=2; if (index<1 || index>meters_used) goto next_line; index--; srcpin=strtol(lp,&lp,10); if (Gpio_used(srcpin)) { AddLog_P(LOG_LEVEL_INFO, PSTR("gpio rx double define!")); dddef_exit: if (script_meter) free(script_meter); script_meter=0; meters_used=METERS_USED; goto init10; } script_meter_desc[index].srcpin=srcpin; if (*lp!=',') goto next_line; lp++; script_meter_desc[index].type=*lp; lp+=2; script_meter_desc[index].flag=strtol(lp,&lp,10); if (*lp!=',') goto next_line; lp++; script_meter_desc[index].params=strtol(lp,&lp,10); if (*lp!=',') goto next_line; lp++; script_meter_desc[index].prefix[7]=0; for (uint32_t cnt=0; cnt<8; cnt++) { if (*lp==SCRIPT_EOL || *lp==',') { script_meter_desc[index].prefix[cnt]=0; break; } script_meter_desc[index].prefix[cnt]=*lp++; } if (*lp==',') { lp++; script_meter_desc[index].trxpin=strtol(lp,&lp,10); if (Gpio_used(script_meter_desc[index].trxpin)) { AddLog_P(LOG_LEVEL_INFO, PSTR("gpio tx double define!")); goto dddef_exit; } if (*lp!=',') goto next_line; lp++; script_meter_desc[index].tsecs=strtol(lp,&lp,10); if (*lp==',') { lp++; char txbuff[256]; uint32_t txlen=0,tx_entries=1; for (uint32_t cnt=0; cnt>",lp); // add meters line -1,1-0:1.8.0*255(@10000,H2OIN,cbm,COUNTER,4| if (*lp=='-') lp++; uint8_t mnum=strtol(lp,0,10); if (mnum<1 || mnum>meters_used) goto next_line; while (1) { if (*lp==SCRIPT_EOL) { if (*(tp-1)!='|') *tp++='|'; goto next_line; } *tp++=*lp++; index++; if (index>=METER_DEF_SIZE) break; } } } next_line: if (*lp==SCRIPT_EOL) { lp++; } else { lp = strchr(lp, SCRIPT_EOL); if (!lp) break; lp++; } } *tp=0; meter_desc_p=script_meter_desc; meter_p=script_meter; } #endif init10: typedef void (*function)(); function counter_callbacks[] = {SML_CounterUpd1,SML_CounterUpd2,SML_CounterUpd3,SML_CounterUpd4}; uint8_t cindex=0; // preloud counters for (byte i = 0; i < MAX_COUNTERS; i++) { RtcSettings.pulse_counter[i]=Settings.pulse_counter[i]; sml_counters[i].sml_cnt_last_ts=millis(); } for (uint8_t meters=0; metersbegin(meter_desc_p[meters].params)) { meter_ss[meters]->flush(); } if (meter_ss[meters]->hardwareSerial()) { if (meter_desc_p[meters].type=='M') { Serial.begin(meter_desc_p[meters].params, SERIAL_8E1); } ClaimSerial(); } } } } #ifdef USE_SML_SCRIPT_CMD uint32_t SML_SetBaud(uint32_t meter, uint32_t br) { if (meter<1 || meter>meters_used) return 0; meter--; if (!meter_ss[meter]) return 0; if (meter_ss[meter]->begin(br)) { meter_ss[meter]->flush(); } if (meter_ss[meter]->hardwareSerial()) { if (meter_desc_p[meter].type=='M') { Serial.begin(br, SERIAL_8E1); } } return 1; } uint32_t SML_Status(uint32_t meter) { if (meter<1 || meter>meters_used) return 0; meter--; #ifdef ED300L return sml_status[meter]; #else return 0; #endif } uint32_t SML_Write(uint32_t meter,char *hstr) { if (meter<1 || meter>meters_used) return 0; meter--; if (!meter_ss[meter]) return 0; SML_Send_Seq(meter,hstr); return 1; } #endif void SetDBGLed(uint8_t srcpin, uint8_t ledpin) { pinMode(ledpin, OUTPUT); if (digitalRead(srcpin)) { digitalWrite(ledpin,LOW); } else { digitalWrite(ledpin,HIGH); } } // fast counter polling void SML_Counter_Poll(void) { uint16_t meters,cindex=0; uint32_t ctime=millis(); for (meters=0; meters0) { if (ctime-sml_counters[cindex].sml_cnt_last_ts>meter_desc_p[meters].params) { sml_counters[cindex].sml_cnt_last_ts=ctime; if (meter_desc_p[meters].flag&2) { // analog mode, get next value #ifdef ANALOG_OPTO_SENSOR if (ads1115_up) { int16_t val = adc.read_sample(); if (val>sml_counters[cindex].ana_max) sml_counters[cindex].ana_max=val; if (val10) { sml_counters[cindex].sml_cnt_last_ts=ctime; #ifdef DEBUG_CNT_LED1 if (cindex==0) SetDBGLed(meter_desc_p[meters].srcpin,DEBUG_CNT_LED1); #endif #ifdef DEBUG_CNT_LED2 if (cindex==1) SetDBGLed(meter_desc_p[meters].srcpin,DEBUG_CNT_LED2); #endif } } cindex++; } } } #ifdef USE_SCRIPT char *SML_Get_Sequence(char *cp,uint32_t index) { if (!index) return cp; uint32_t cindex=0; while (cp) { cp=strchr(cp,','); if (cp) { cp++; cindex++; if (cindex==index) { return cp; } } } } void SML_Check_Send(void) { sml_100ms_cnt++; char *cp; for (uint32_t cnt=sml_desc_cnt; cnt=0 && script_meter_desc[cnt].txmem) { //AddLog_P2(LOG_LEVEL_INFO, PSTR("100 ms>> %d - %s - %d"),sml_desc_cnt,script_meter_desc[cnt].txmem,script_meter_desc[cnt].tsecs); if ((sml_100ms_cnt>=script_meter_desc[cnt].tsecs)) { sml_100ms_cnt=0; //AddLog_P2(LOG_LEVEL_INFO, PSTR("100 ms>> 2"),cp); if (script_meter_desc[cnt].max_index>1) { script_meter_desc[cnt].index++; if (script_meter_desc[cnt].index>=script_meter_desc[cnt].max_index) { script_meter_desc[cnt].index=0; sml_desc_cnt++; } cp=SML_Get_Sequence(script_meter_desc[cnt].txmem,script_meter_desc[cnt].index); //SML_Send_Seq(cnt,cp); } else { cp=script_meter_desc[cnt].txmem; //SML_Send_Seq(cnt,cp); sml_desc_cnt++; } //AddLog_P2(LOG_LEVEL_INFO, PSTR(">> %s"),cp); SML_Send_Seq(cnt,cp); if (sml_desc_cnt>=meters_used) { sml_desc_cnt=0; } break; } } else { sml_desc_cnt++; } if (sml_desc_cnt>=meters_used) { sml_desc_cnt=0; } } } uint8_t sml_hexnibble(char chr) { uint8_t rVal = 0; if (isdigit(chr)) { rVal = chr - '0'; } else { if (chr >= 'A' && chr <= 'F') rVal = chr + 10 - 'A'; if (chr >= 'a' && chr <= 'f') rVal = chr + 10 - 'a'; } return rVal; } // send sequence every N Seconds void SML_Send_Seq(uint32_t meter,char *seq) { uint8_t sbuff[32]; uint8_t *ucp=sbuff,slen=0; char *cp=seq; while (*cp) { if (!*cp || !*(cp+1)) break; if (*cp==',') break; uint8_t iob=(sml_hexnibble(*cp) << 4) | sml_hexnibble(*(cp+1)); cp+=2; *ucp++=iob; slen++; if (slen>=sizeof(sbuff)) break; } if (script_meter_desc[meter].type=='m' || script_meter_desc[meter].type=='M') { *ucp++=0; *ucp++=2; // append crc uint16_t crc = MBUS_calculateCRC(sbuff,6); *ucp++=lowByte(crc); *ucp++=highByte(crc); slen+=4; } if (script_meter_desc[meter].type=='o') { for (uint32_t cnt=0;cntwrite(sbuff,slen); } #endif // USE_SCRIPT uint16_t MBUS_calculateCRC(uint8_t *frame, uint8_t num) { uint16_t crc, flag; crc = 0xFFFF; for (uint32_t i = 0; i < num; i++) { crc ^= frame[i]; for (uint32_t j = 8; j; j--) { if ((crc & 0x0001) != 0) { // If the LSB is set crc >>= 1; // Shift right and XOR 0xA001 crc ^= 0xA001; } else { // Else LSB is not set crc >>= 1; // Just shift right } } } return crc; } uint8_t SML_PzemCrc(uint8_t *data, uint8_t len) { uint16_t crc = 0; for (uint32_t i = 0; i < len; i++) crc += *data++; return (uint8_t)(crc & 0xFF); } // for odd parity init with 1 uint8_t CalcEvenParity(uint8_t data) { uint8_t parity=0; while(data) { parity^=(data &1); data>>=1; } return parity; } // dump to log shows serial data on console // has to be off for normal use // in console sensor53 d1,d2,d3 .. or. d0 for normal use // set counter => sensor53 c1 xxxx // restart driver => sensor53 r bool XSNS_53_cmd(void) { bool serviced = true; if (XdrvMailbox.data_len > 0) { char *cp=XdrvMailbox.data; if (*cp=='d') { // set dump mode cp++; uint8_t index=atoi(cp); if ((index&7)>meters_used) index=1; if (index>0 && meter_desc_p[(index&7)-1].type=='c') { index=0; } dump2log=index; ResponseTime_P(PSTR(",\"SML\":{\"CMD\":\"dump: %d\"}}"),dump2log); } else if (*cp=='c') { // set ounter cp++; uint8_t index=*cp&7; if (index<1 || index>MAX_COUNTERS) index=1; cp++; while (*cp==' ') cp++; if (isdigit(*cp)) { uint32_t cval=atoi(cp); while (isdigit(*cp)) cp++; RtcSettings.pulse_counter[index-1]=cval; uint8_t cindex=0; for (uint8_t meters=0; meters